Passive Solar Design Strategies: Guidelines for Horne Building

Passive Solar Industries Council National Laboratory Charles Eley Associates With SufrPort From: U.S. Department of Energy Passive Solar Design Strategies: Guidelines for Home Builders

Salem, Oregon

Passive Solar Industries Council Research Institute Charles Eley Associates This document was prepared under the sponsorship of the Solar Energy Research Institute and produced with funds made available by the United States Department of Energy. Neither the United States Department of Energy, the Solar Energy Research Institute, the Passive Solar Industries Council nor any of its member organizations, nor any of their employees, nor any of their contractors, subcontractors, or their employees, makes any warranty, expressed or implied, or assumes any legall1abillty or responsibility for the accuracy, completeness or usefulness of any information, apparatus, product or process disclosed, or represents that its use would not infringe privately owned rights. The views and opinions do not necessarily state or reflect those of the United States government, the Solar Energy Research Institute, or any agency thereof. This document was prepared with the assistance and participation of representatives from many organizations, but the views and opinions expressed represent general consensus and available information. Unanimous approval by all organizations is not implied. vVIV I c;;,IV I V

Guidelines

JJGlrit ()rt~. IrttJr()«lL<:ti(Jrt...... 1 1. Introduction to the Passive Solar Design Strategies Package...... 2 2. Passive Solar Performance Potential...... 5

Part Two. Basics of Passiv~ &lIar ...... 7 1. Why Passive Solar? More than a Question of Energy...... 8 2. Key Concepts: . Suntempering. Passive Solar ...... 9 3. Improving Conservation Performance...... 10 4. Mechanical Systems ...... 13 5. South-Facing Glass ...... l4 6. Thermal Mass...... 15 7. Orientation...... 16 8. Site Planning for Solar Access...... 17 9. Interior Space Planning ...... 18 10. Putting it Together: The House as a System ...... 18

JJGlrit Thr~~. StJrGlt~gies f(Jr Improvirtg Ert~rgy JJ~r:f(JrmGlrt<:~ irt SGlI~m, ()r~gort...... 21 1. The Example Tables...... 22 2. Suntempering...... 23 3. Direct Gain...... 24 4. Sunspaces...... 27 5. Thennal Storage Wall...... 30 6. Combined Systems...... 32 7. Natural Cooling Guidelines...... 32

Worksheets

Blank Worksheets. Data Tables. and Worksheet Instructions

Worked Example

Description of the Example Building...... 40 Filled in Worksheets...... 43 Annotated Worksheet Tables ...... 48

Appendix

Glossary of Terms...... 51 References...... 52 Summary Tables...... 54 Technical BaSis for the Builder GUidelines...... 56

Salem. Oregon J I , " __ ... _ ~ __, II. ___ • __ .. _ I I II •• __ • __

PSIC expresses particular financial and technical support gratitude to the following of the GUidelines. several individuals: J. Douglas contributed way beyond the call Balcomb. SERI and LANL . of duty. Stephen Szoke. whose work is the baSis of the National Masonry Acknowledgements GUidelines: Robert McFarland. AsSOCiation. Chairman of PSIC's LANL. for developing and Board of Directors: James Tann. programming the calculation Institute of America. Passive Solar Design Strategies: procedures: Alex Lekov. SERI. Region 4. Chairman of PSIC's Guidelines for Home BuUd.ers for assistance in the analysis: Technical Committee: and Blon represents over three years of Subrato Chandra and Philip W. Howard. NAHB National effort by a unique group of Fairey. FSEC. whose research Research Center. past Chairman organizations and individuals. has guided the natural cooling of the Technical Committee. all The challenge of creating an sections of the gUidelines: the gave unstintingly of their time. effective design tool that could members of the NAHB Standing their expertise. and their be customized for the specific Committee on Energy, especially enthUSiasm. needs of builders in Cities and Barbara B. Harwood. Donald L. towns allover the U. S. called for Carr. James W. Leach and the talents and experience of Craig Eymann. for the benefit of specialists in many different their long experience in building areas of expertise. energy-efficient homes: at U.S. Passive Solar Design DOE. Frederick H. Morse. Strategies is based on research Director of the Office of Solar sponsored by the United States Heat Technologies and Mary­ Department of Energy (DOE) Margaret Jenior. Program Solar Buildings Program. and Manager: Nancy Carlisle and carried out primarily by the Los Paul Notari at SERI: Helen Alamos National Laboratory English. Executive Director of (LANL). the Solar Energy PSIC: Michael Bell. former Research Institute (SERI) and Chairman of PSIC. and Layne the Florida Solar Energy Center Ridley and Elena Marcheso­ (FSEC). Moreno. former Executive The National AsSOCiation of Directors of PSIC: Arthur W. Home Builders (NAHB) Standing Johnson. for technical Committee on Energy has assistance in the development of provided invaluable advice and the Guidelines and worksheets: assistance during the Michael Nicklas. who worked development of the Guidelines. on the Guidelines from their Valuable information was early stages and was drawn from the 14-country instrumental in the success of International Energy Agency the first pilot workshop in North (lEA). Solar Heating and Cooling Carolina: Charles Eley. for his program. Task VIII on Passive help in every aspect of the and Hybrid Solar Low Energy production of the Guidelines Buildings (see next page for package. more about the international Although all the members of context of Passive Solar Design PSIC. especially the Technical Strategies) . Committee. contributed to the

Salem. oregon PASSIVE SOLAR DESIGN STRATEGIES

Solar Design guidelines for cities and towns in Strategies and the the U.S. • Booklet 4: "Design Tool International Energy Selection and Use" provides Agency guidance in the selection of design tools appropriate for each Valuable infonnation from the step of the design process. International Energy Agency's • Booklet 5: "Construction Solar Heating and Cooling Details" identifies solutions to research program has been construction problems unique to integrated into Solar Design passive solar bUildings. Strategies. • Booklet 6: "Passive Solar Under the leadership of the Homes: Case Studies" highlights U.S. Department of Energy thepertonnanceofbuildings (Michael J. Holtz. Operating constructed and monitored by Agent on behalf of DOE) the lEA Task VIII countries. Task VIII is producing a series of • Booklet 7: "Design Design Infonnation Booklets on Language" written primarily for a number of issues related to the design professionals and design and construction of students. describes an approach passive solar residential to generating whole building buildings. Among the booklets design solutions based on will be design guidelines for each climate analysis and design­ of the 14 nations participating in centered analysis. Task VIII. Solar Design • Booklet 8: "Post­ Strategies is the U.S. Construction Activities" contribution to this part of the discusses aspects of passive Design Infonnation Booklet homes that are unique and may series. require attention by the All the lEA Task VIII Design occupants and home builders. Infonnation Booklets will be PSIC would like to express its available from PSIC. The thanks to the Task VIII member booklets include: nations for the wealth of • Booklet 1: "Energy Design infonnation their long-tenn Principles in Buildings" explains commitment to international the principles solar research has made critical to the thennal comfort of possible. passive solar buildings. • Booklet 2: "Design Context" presents a checklist of factors to be considered in the design process. • Booklet 3: "Design Guidelines" specifically developed for each nation. "Solar Design Strategies" will present site-specific design

Salem. oregon Passive Solar Design Strategies GUIDELINES

Passive Solar Industries Council National Renewable Energy Laboratory Charles Eley Associates With Support From: U.S. Department of Energy PASSIVE SOLAR DESIGN STRATEGIES 1

Part One: Introduction

1. Introduction to the Passive Solar Design Strategies Package

2. Passive Solar Performance Potential

Salem. Oregon 2 GUIDEUNES PART ONE: INTRODUCTION

1. Introduction to the Passive Solar Design Strategies BuilderGuide Passive Solar Design is a package in three basic parts: A special builder-friendly • The Guidelines contain computer program called Strategies Package information about passive solar BuUderGutde has been developed. techniques and how they work. to automate the calculations The idea. of passive solar is and provides specific examples involved in tnllng out the four simple. but applying it effectively of systems which will save worksheets. The program does require information and various percentages of energy: operates l1ke a spreadsheet: the attention to the details of design • The Worksheets offer a user fills in values for the and construction. Some passive simple. fill-in-the-blank method buUding. and the computer solar techniques are modest and to pre·evaluate the performance completes the calculations, low-cost. and require only small of a specific design. including all table lookups, and changes in a builder's standard • The Worked Example prints out the answers. The practice. At the other end of the demonstrates how to complete results are the same as if you spectrum. some passive solar the worksheets for a typical completed the worksheets systems can almost eliminate a residence. manually but it is much faster, house's need for purchased more convienient. and less prone energy - but probably at a to arithmetic error. Many design relatively high first cost. variations can be evaluated very In between are a broad range quickly. of energy-conservtng passive solar techniques. Whether or BuilderGwde is available from not they are cost-effective, the Passive Solar Industries practical and attractive enough Council. See page 53 for the to offer a market advantage to address. Computer data files any individual builder depends containing the information on on very specific factors such as pages 48-49 are available for local costs. climate and market 235 locations within the United characteristics. States. The user can then adjust Passive Solar Design for local conditions so Strategies: Guidelines Jor Home performance can be evaluated BuUders is written to help give virtually anywhere. builders the information they need to make these decisions.

Salem, Oregon PASSIVE SOLAR DESIGN STRATEGIES 3

The Guidelines Part Three gives more The Base Case House is a Some principles of passive solar specUlc advice about techniques reasonably energy-efficient design remain the same in every for suntempering, direct gain house based on a 1987 National climate. But the important systems. thermal storage mass AsSOCiation of Home Builders thing about passive solar is that walls and sunspaces. and for study of housing characteristics, it makes better use of the natural cooling strategies to help divided into seven different opportunities in a house's offset air-conditioning needs. regions. The Base Case used for surroundings. So, many The Example Tables in Part Salem. Oregon is from the fundamental aspects of the Three are also related to 3.500-5.000 heating degree days passive solar house's design will Worksheet numbers, so that you region. The house is assumed depend on the conditions in a can compare them to the to be built over a ventilated small local area, and even on the designs you are evaluating. For crawlspace. because this is features of the building site example. the Passive Solar typical in Oregon. itself. Many of the suggestions Sunspace Example Case which The examples show how to in this section apply specifically uses 40% less energy than the achieve 20, 40 and 600;6 energy­ to Salem, Oregon, but there is Base Case House (page 29) has: use reductions using three basic also information in each section • a Conservation Performance strategies: of the booklet which will be Level of apprOximately 28.554 • Added Insulation: useful in any climate. Btu/yr-sf. increasing insulation levels Part One introduces Passive • an Auxiliary Heat without adding solar features. Solar Design Strategies, and Performance Level of • Suntempering: increasing presents the performance apprOximately 20.765 Btu/yr-sf, south-faCing glazing to a potential of several different and maximum of 7% of the house's passive solar systems in the • a Summer Cooling total floor area, but without Salem climate. Although in Performance Level of 1.920 adding thermal mass (energy practice many factors will affect Btu/yr-sf. storage) beyond what is already actual energy performance, this (In this example. the energy in the framing. standard floor information will give you a savings are achieved by coverings and gypsum wall­ general idea of how various increasing insulation about 31% board and ceiling surfaces. systems will perform in your over the Base Case. adding a Insulation levels are also area. sunspace with south glazing increased. Part Two discusses the basic area equal to 11% of the house's concepts of passive solar design floor area. and using a ceiling and construction: what the to cut some of the air advantages of passive solar are, conditioning load.) how passive solar relates to A Base Case house is other kinds of energy compared with a series of conservation measures, how the Example cases to illustrate primary passive solar systems exactly how these increased work, and what the builder's levels of energy-efficiency might most important considerations be achieved. should be when evaluating and using different passive solar strategies.

Salem. Oregon 4 GUIDELINES PART ONE: INTRODUCTION

• Passive Solar: using three The Worksheets for example, from the Solar different design approaches: The Worksheets are specifically System Savings Fraction table or Direct Gain. Sunspace. and tailored for Salem, Oregon, and from the Heat Gain Factor table. Thennal Storage Wall. and are a very important part of this The Worksheets allow increased levels of insulation. package because they allow you calculation of the following For all strategies. the energy to compare on paper different perfonnance indicators: savings indicated are based on passive solar strategies or • Worksheet I: Conservation the assumption that the energy­ combinations of strategies, and Performance Level: determines efficient design and construction the effect that changes will have how well the house's basic guidelines have been followed. so on the overall performance of the energy consexvation measures the houses are properly sited house. (insulation, sealing, caulking, and tightly built with high­ The most effective way to use etc.) are working to prevent quality windows and doors. the Worksheets is to make unwanted heat loss in the The Guidelines section has multiple copies before you fill winter. The bottom line of this been kept as brief and them out the first time. You can Worksheet is a number straightforward as possible. but then use the Worksheets to measuring heat loss in British more detailed infonnation is calculate several different thermal units per square foot available if needed. Some designs. For instance, you could per year (Btu/sf-yr) - the lower references are indicated in the first calculate the perfonnance of the heat loss, the better. text. and a list of other the baSic house you build now, • Worksheet U: AuxiUary infonnation sources can be then fill out Worksheets for that Heat Performance Level: found in the References. Also house plus added insulation determines how much heat has included at the end of this book plus a sunspace, and then for a to be supplied (that is, provided are a brief Glossary. a summary third possibility such as a by the ) after of the Example Tables for Salem. Thennal Storage Wall. taking into account the heat Oregon, and two pages The Worksheets provide a contributed by passive solar. explaining some of the way to calculate quickly and This worksheet arrives at a background and assumptions with reasonable accuracy how number estimating the amount behind the Guidelines and well a design is likely to perfonn of heating energy the house's Worksheets called Technical in four key ways: how well it will non-solar heating system has to Basis for the Builder Guidelines. conseIVe heat energy: how much provide in Btu/yr-sf. Again, the the solar features will contribute lower, the better. to its total heating energy needs; • Worksheet m: Thermal how comfortable the house will Mass/Comfort: detennines be; and how much the house's whether the house has adequate annual cooling load (need for air thennal mass to assure comfort conditioning) will be. and good thermal performance. The Worksheets are Worksheet III calculates the supported by "look-up" tables number of degrees the containing pre-calculated factors temperature inside the house is and numbers for the local area. likely to vary. or "swing". during Some of the blanks in the a sunny winter day without the Worksheets call for information heating system operating. A about the house - for example, well-designed house should have floor area, projected area of a temperature swing of no more passive solar glazing, and so than 13 degrees. and the less forth. Other blanks require a the better. number from one of the tables -

Salem, Oregon PASSIVE SOLAR DESIGN STRATEGIES 5

• Worksheet IV: Summer 2. Passive Solar The energy savings Cooling Performance Level: Performance presented in this example indicates how much air assume that all the systems are conditioning the house will need Potential designed and built according to in the summer (it is not. the suggestions in these however, intended for use in The energy performance of Guidelines. It's also important sizing equipment, but as an passive solar strategies varies to remember that the figures indication of the reductions in significantly, depending on below are for annual net heating climate, the specific design of annual cooling load made benefits. The natural cooling possible by the use of natural the system, and the way it is section in Part Three gives cooling). The natural cooling built and operated. Of course, advice about shading and other guidelines should make the energy performance is not the techniques which would make house's total cooling load - the only consideration. A system sure the winter heating benefits bottom line of this Worksheet. in which will give excellent energy are not at the expense of higher Btu/yr-sf - smaller than in a performance may not be as summer cooling loads. "conventional" house. marketable in your area or as Please note that throughout So, the Worksheets provide easily adaptable to your designs the Guidelines and Worksheets you with four key numbers as a system which saves less the glazing areas given are for indicating the projected energy but fits your other needs. the actual net area of the glass performance of the various In the following table, several itself. A common rule of thumb designs you are evaluating. different passive solar systems is that the net glass area is 80 • The Worked Example: To are presented along with two percent of the rough frame assist in understanding how the numbers which indicate their opening. For example, if a south design strategies outlined in the performance. The Percent Solar glass area of 100 sfts desired, Guidelines affect the overall Savings is a measure of how the required area of the rough performance of a house. a much the passive solar system is frame opening would be about worked example is included. reducing the house's need for 125 sf. The example house. constructed purchased energy. For example, of materials and design elements the Percent Solar Savings for the typical of the area, is a one Base Case is 6.7%. because even story, single-family 1500 sf in a non-solar house, the south­ passive solar design. Various facing windows are contributing design features. such as direct some heat energy. gain spaces. sunspaces. The Yield is the annual net increased levels of insulation heating energy benefit of adding and thermal mass. are included the passive solar system. to illustrate the effects combined measured in Btu saved per year systems have on the per square foot of additional performance of a house. Also. south glazing. many features are covered to The figures given are for a demonstrate how various 1,500 sf. single-story house with conditions and situations are a floor over a crawlspace. The addressed in the worksheets. A Base Case has 45 sf of south­ description of the design facing glazing. For the purposes features. along with the house of this example. the plans. elevations and sections. Suntempered house has 100 sf are included for additional of south-facing glass, and each support information. passive solar system has 145 sf.

Salem, Oregon 6 GUIDELINES PART ONE: INTRODUCTION

Performance Potential of Passive Solar Strategies In Salem, Oregon 1,500 sf, Single Story House Yield Percent Btu Saved per Solar Square Foot of Case Savings South Glass

Base Case 6.7 not applicable (45 sf of south-facing double glass) Suntempered 13.5 53,581 (100 sf of south-facing double glass)

Direct Gain (145 sf of south glass) Double Glass 17.4 45,872 Triple or low-e glass 19.6 61,987 Double glass with R-4 night insulation 1 22.4 78,402 Double glass with R-9 night insulation 1 23.5 84,549

Sunspace (145 sf of south glass) Attached with opaque end walls2 18.5 59,093 Attached with glazed end walls2 17.8 55,220 Semi-enclosed with vertical glazing3 17.9 51,379 Semi-enclosed with 50· sloped glazing3 23.3 83,077

Thermal Storage Wall - Masonry/Concrete (145 sf of south glass) Black surface, double glazing 16.6 47,529 Selective surface, single glazing 22.2 78,009 Selective surface, double glazing 21.6 75,718

Thermal Storage Wall - Wall (145 sf of south glass) Selective surface, single glazing 25.2 92,972

1. Night insulation is assumed to cover the south glass each night and removed when sun is available. Experience has shown that many homeowners find this inconvenient and so the potential energy savings are often not achieved. Using low-e or other energy-efficient glazing is more reliable.

2. The attached sunspace is assumed to have, in addition to glazed walls, root glazing at a slope of 30 degrees trom the horizontal, or a 7:12 pitch. (See diagram SSB1 in the Worksheets.)

3. The semi-enclosed sunspace has only the south wall exposed to the out-ot-doors. The glazing has a slope ot 50· trom the horizontal, or a 14:12 pitch. The side walls are adjacent to conditioned space in the house. {See diagram SSD1 in the Worksheets.)

Salem. Oregon PASSIVE SOLAR DESIGN STRATEGIES 7

Part Two: Basics of Passive Solar

1. Why Passive Solar? More than a Question of Energy

2. Key Concepts: Energy Conservation. Suntempering. Passive Solar

3. Improving Conservation Performance

4. Mechanical Systems

5. South-Facing Glass

6. Thermal Mass

7. Orientation

8. Site Planning for Solar Access

9. Interior Space Planning

10. Putting it Together: The House as a System

Salem, oregon 8 GUIDELINES PART TWO: BASICS OF PASSIVE SOLAR

1. Why Passive Solar? energy-efficiency - but added They just present their houses More than a Question insulation is invisible to the as the state of the art in energy­ prospective home buyer. A efficiency and style. and they of Energy sunny. open living area lit by use passive solar as a part of the south-facing windows. on the package Houses today are more energy­ other hand. may be a key selling The U. S. Department of efficient than ever before. point. Windows in general are Energy and the Solar Energy However. the vast majority of popular with homebuyers. and Research Institute (SERI) new houses still ignore a lot of passive solar can make Windows conducted extensive national energy saving opportunities - energy producers instead of surveys of passive solar homes. opportunities available in the energy liabilities. home owners and potential sunlight falling on the house. in Another example: high­ buyers. Some key findingS: the landscaping. breezes and effiCiency heating equipment can • passive solar homes work other natural elements of the account for significant energy - they generally require an site. and opportunities in the savings - but it won't be as average of about 300A> less structure and materials of the much fun on a winter mOrning energy for heating than house itself. which. with as breakfast in a bright. "conventional" houses. with thoughtful design. could be used attractive sunspace. some houses saving much more. to collect and use free energy. The point is not that a • occupants of passive solar Passive solar (the name builder should choose passive homes are pleased with the distinguishes it from "active" or solar instead. of other energy­ performance of their homes (over mechanical solar technologies) is conserving measures. The 90% "very satisfied"). but they simply a way to take maximum important thing is that passive rank the comfort and pleasant advantage of these solar can add not only energy­ living environment as just as opportunities. effiCiency. but also very saleable important (in some regions. Home buyers are also amenities - style. comfort. more important) to their increasingly sophisticated about attractive interiors. curb appeal satisfaction. and in their energy issues. although the and resale value. decision to buy the house. as average home buyer is probably In fact. in some local energy considerations. much more familiar with markets. builders report that • passive solar home owners insulation than with passive they don·t even make specific and lenders perceive the solar. The "energy crisis" may reference to "passive solar". resale value of passive solar be temporarily over. but very few houses as high. people perceive their own household energy bills as getting Advantages of Passive Solar smaller - quite the opposite. So • Energy performance: Lower energy bills all year-round a house with Significantly lower Attractive living environment: large windows and views, sunny monthly energy costs year-round • interiors, open floor plans will have a strong market Comfort: quiet (no operating noise), solid construction, warmer in advantage over a comparable • winter, cooler in summer (even during a power failure) house down the street. no Value: high owner satisfaction, high resale value matter what international oil • Low Maintenance: durable, reduced operation and repairs prices may be. • But there are many different Investment: independence from future rises in fuel costs, will continue • to save money long after any initial costs have been recovered ways to reduce energy bills. and some are more marketable than Environmental Concerns: clean, renewable energy to combat • growing concerns over global warming, acid rain and others. For instance. adding ozone depletion insulation can markedly improve

Salem. Oregon PASSIVE SOLAR DESIGN STRATEGIES 9

2. Key Concepts: In the same way, many of Although the concept is the measures that are often simple, in practice the Energy Conservation, conSidered part of suntemperIng relationship between the amount Suntempering, or passive solar - such as of glazing and the amount of orienting to take advantage of mass is complicated by many Passive Solar summer breezes, or landscaping factors, and has been a subject for natural cooling, or facing a of conSiderable study and The strategies for enhancing long wall of the house south - experiment. From a comfort and energy performance which are can help a. house conseIVe energy standpOint, it would be presented here fall into three energy even if no "solar" features difficult to add too much mass. general categories: are planned. Thermal mass will hold warmth • Energy Conservation: The essential elements in a longer In winter and keep Insulation levels. control of air passive solar house are south­ houses cooler in summer. But . glazing type and facing glass and thermal mass. thermal mass has a cost, and so location and mechanical In the simplest terms, a adding too much mass for just equipment. passive solar system collects thermal storage purposes can be • Suntempering: a limited use solar energy through south­ unnecessarily expensive. of passive solar techniques; facing glass and stores solar The following sections of the modestly increasing south-facing energy In thermal mass - Guidelines discuss the size and window area, usually by materials with a high capacity location of glass and mass, as relocating windows from other for storing heat (e.g., brick, well as other considerations sides of the house, but without concrete masonry. , which are baSic to both adding thermal mass. tile, water). The more south­ suntempered and full passive • Passive Solar: going beyond facing glass Is used In the solar houses: improving conservation and suntemperIng house, the more thermal mass conseIVation performance: to a complete system of must be provided, or the house mechanical systems; orientation; collection, storage and use of will overheat and the solar site planning for solar access; solar energy: using more south system will not perform as interior space planning; and glass, adding significant thermal expected. taking an integrated approach to mass, and taking steps to With too much glass and/or the house as a total system. control and distribute heat insuffiCient mass, solar energy energy throughout the house. can work too well, and the house What is immediately clear is can be uncomfortably hot even that these categories overlap. on a winter day. For instance, a good energy­ conservation package is the necessary starting point of all well-designed suntempered and passive solar houses. There's no use collecting solar energy if it is immediately lost through leaky windows or poorly Insulated walls.

Salem, Oregon 10 GUIDELINES PART TWO: BASICS OF PASSIVE SOLAR

3. Improving The thennal reSistance of Slab edge insulation should ceiling/roof assembUes, walls be at least two feet deep, Conservation and floors is affected not only by extending from the surface of the Performance the R-value of the insulation floor. Materials for slab edge itself, but also the resistance of insulation should be selected for The techniques desCribed in this other elements in the underground durability. One section relate to Worksheet I: construction assembly - material with a proven track Conservation Performance framing effects, sheathing, record is extruded polystyrene. Level, which measures the interior drywall, and so on. The Exposed insulation should be house's heat loss. The energy Worksheets include tables that protected from physical damage conservation measures that show Equivalent Construction by attaching a protection board, reduce heat loss also tend to R-Values which account for for instance, or by covering the reduce the house's need for air these and other effects. For insulation with a protective conditioning. instance, ventilated crawlspaces surface. The most important and unheated basements Heated basement walls measures for improving the provide a buffering effect which should be fully insulated to at house's baSic ability to conserve is accounted for in the least four feet below grade, but the heat generated either by the Worksheet tables. the portion of the wall below that sun or by the house's With attics, framing effects depth only needs to be insulated conventional heating system are are minimized if the insulation to about half the R-value of the in the following areas: covers the ceiling trusses, either upper portion. Insulation can be • Insulation by using blown-in insulation or placed on the outside surface of • Air infiltration by running an additional layer of the Wall. or on the inside surface • Non-solar glazing batts in the opposite direction of of the wall, or in the cores of the the ceiling jOists. Ridge and/or masonry units. Insulation eave vents are needed for If the basement walls are Adding insulation to walls, ventilation. insulated on the outside. the floors, ceilings, roof and materials should be durable foundation improves their underground. and exposed thennal reSistance (R-valuel - insulation should be protected their reSistance to heat flowing from damage. In the case of a out of the house. finished basement or walk-out A quality job of installing the basement. placing insulation on insulation can have almost as the interior may be less costly much effect on energy than insulating the exterior perfonnance as the R-value, so foundation. careful construction supervision is important. An inspection just Insulation In an Attic Insulation should extend over the top ceiling before the drywall is hung joists and ventilation should be provided at identifies improvements which the eaves. are easy at that time but will In framed ceiling/roof make a big difference in the assemblies, an insulating energy use of the home for years sheathing over the top decking to come. will increase the R-value.

Salem, Oregon PASSIVE SOLAR DESIGN STRATEGIES 11

Air Infiltration Sealing the house carefully to Checklist for Minimizing Air Leakage reduce air infiltration - air ~ Tighten seals around windows and doors, and weatherstripping leakage - is as necessary to around all openings to the outside or to unconditioned rooms; energy conseIVation as adding .t Caulk around all windows and doors before drywall is hung; seal all insulation. Air will flow rapidly penetrations (plumbing, electrical, etc.); through cracks and crevices in the wall. in the same way water .t Insulate behind wall outlets and/or plumbing lines in exterior walls; flows through the drain in a .t Caulk under headers and sills; bathtub. so even a small opening can allow heat to .t Chink spaces between rough openings and millwork with insulation, or bypass the insulation and lead for a better seal, fill with foam; to big energy losses. .t Seal larger openings such as ducts into attics or crawlspaces with The tightness of houses is taped polyethylene covered with insulation; generally measured in the number of .t Locate continuous vapor retardants located on the warm side of the insulation (building wrap, continuous interior polyethylene, etc.); (ACH). A good. comfortable. energy-efficient house. built .t Install dampers and/or glass doors on ; combined with along the gUidelines in the table outside combustion air intake; on this page. will have .t Install backdraft dampers on all exhaust fan openings; approximately 0.35 to 0.50 air changes per hour under normal .t Caulk and seal the joint between the basement slab (or the slab on winter conditions. grade) and the basement wall; Increasing the tightness of .t Remove wood grade stakes from slabs and seal; the house beyond that may improve the energy performance. .t Cover and seal sump cracks; but it may also create problems .t Close core voids in top of block foundation walls; with . moisture build-up. and inadequately .t Control concrete and masonry cracking; vented fireplaces and . The use of house sealing .t Use of air tight drywall methods are also acceptable (see Reference 11); subcontractors to do the tightening and check it with a .t Employ appropriate techniques (see can often save the Reference !2J. builder time and problems. especially when trying to achieve particularly high levels of infiltration control.

Salem. Oregon 12 GUIDELINES PART TWO: BASICS OF PASSIVE SOLAR

Non-50lar Glazing Triple-glazing or double­ problems in summer. If the South-facing windows are glazing with a low-e coating is views or other elements in the considered solar glazing. The advisable. Low-e glazing on all house's design dictate east south windows in any house are non-solar windows may be an Windows, shading should be contributing some solar heat especially useful solution done with particular care. energy to the house's heating because some low-e coatings can West windows may be the needs - whether it's a insulate in winter and shield most problematic, and there are significant, usable amount or against unwanted heat gain in few shading systems that will be hardly worth measuring will summer. effective enough to offset the depend on design. location and Manufacturers will provide potential for overheating from a other factors which are dealt actual R-values for their large west-facing window. Glass with later under the discussions windows (the thermal with a low shading coeffiCient of suntempertng and passive perfonuance of glazing can be may be one effective approach - solar systems. expressed either as an R-value for example, tinted glass or some North windows in almost or its reciprocal. U-value; here types oflow-e glass which every climate lose significant all thennal perfonnance values provide some shading while heat energy and gain very little are given in tenus ofR-value). A allowing almost clear views. The useful sunlight in the winter. chart is also provided with the cost of properly shading both East and west windows are likely Worksheets to show east and west windows should to increase approximate window R-values be balanced against the benefits. needs unless heat gain is for various types. (the As many windows as minimized with careful attention Equivalent Glazing R-Value possible should be kept operable to shading. pertains to the entire rough for easy natural ventilation in But most of the reasons frame opening of the window.) summer. (See also Orientation, people want windows have very North windows should be page 16, Recommended Non­ little to do with energy. so the used with care. Sometimes South Glass GUidelines, page best design will probably be a views or the diffuse northern 3'1, and Shading, page 35) good working compromise light are desirable. but in between efficiency and other general north-facing windows benefits. such as bright living should not be large. Very large spaces and views. north-facing windows should have high insulation value. or R-value. Since north windows receive relatively little direct sun in summer. they do not present much of a shading problem. So if the choice were between an average-sized north-facing window and an east or west­ faCing window, north would actually be a better choice, considering both summer and winter performance. East windows catch the morning sun. Not enough to provide significant energy, but, unfortunately, usually enough to cause potential overheating

Salem. Oregon PASSIVE SOLAR DESIGN STRATEGIES 13

4. Mechanical • Night Setback. Clock In the National AsSOCiation of Systems for automatic night Home Builders' Energy-EffiCient setback are usually very effective House Project, all the rooms were fed with low, central air The passIve solar features in the - but in passive solar systems with large amounts of thermal supplies, as opposed to the house and the mechanical mass (and thus a large capacity usual placement of registers heating, ventilating and air for storing energy and releasing under windows at the end of conditioning systems (HVAC) will it during the night), night long runs. This resulted in good interact all year round and so setback of the may comfort and energy performance. the most effective approach will not save very much energy. The performance of even the be to desIgn the system as an • Ducts. most beautifully designed integrated whole. HVAC design One area often is, of course, a complex subject, neglected but of key importance passive solar house can easily be but the three areas below are to the house's energy undermined by details like particularly worth noting in performance is the design and uninsulated ducts, or by location of the ducts. Both the overlooking other basic energy passive solar houses: • System Sizing. Mechanical supply and return ducts should conservation measures. systems are often oversized for be located within insulated the relatively low heating loads areas, or well insulated if they in well-insulated passive solar run in cold areas of the house, houses. Oversized systems w1l1 and well sealed at the jOints. cost more in the first place, and The joints where the ducts tum will cycle on and off more often, up into exterior walls or wasting energy. The back-up penetrate the ceiling should be systems in passive solar houses particularly tight and caulked. should be sized to provide 100016 of the heating or cooling load on the design day, but no larger. Comparing estimates on system sizes from more than one contractor is probably a good idea.

Salem, oregon 14 GUIDELINES PART TWO: BASICS OF PASSIVE SOLAR

5. South-Facing Glass The third limit on south­ When the solar glazing is facing glass is the total of all tilted. its winter effectiveness as South-facing solar glass is a key passive solar systems combined. a solar collector usually component of any passive solar which should not exceed 200A> of increases. However, tilted system. The system must total floor area. Using more glazing can cause serious include enough solar glazing for south glass than this limit could overheating in the summer if it good performance in winter. but lead to overheating even in is not shaded very carefully. not so much that cooling winter. Ordinary vertical glazing is performance in summer will be For example. a paSSive solar easier to shade, less Ukely to compromised. The amount of system for a 1,500 sf house overheat. less susceptible to solar glazing must also be might combine 150 sf of direct damage and leaking, and so is carefully related to the amount gain glazing with 120 sf of almost always a better year­ of thermal mass. Suntempered sunspace glazing for a total of round solution. houses require no additional 270 sf of solar glazing. or 18% of thermal mass beyond that the total floor area, well within already in the wallboard. the direct gain limit of 12% and framing and furnishings of a the overall limit of 20%. For a typical house. Passive solar design like this. thermal mass houses must have additional would be required both in the thermal mass. house and within the sunspace. There are three types of The Natural Cooling limits on the amount of south­ guidelines in Part Three include facing glass that can be used recommendations on the window effectively in a house. The first area that should be operable to is a limit on the amount of allow for natural ventilation. . glazing for suntempered houses. This limit (without adding thermal mass) is 7% of the house's total floor area. For direct gain systems in passive solar houses, the maximum amount of south­ facing glazing is 12% of total floor area. regardless of how much additional thennal mass Is provided. Further details about the most effective sizing of south glass and thennal mass for direct gain systems are provided in Part Three.

Salem, Oregon PASSIVE SOLAR DESIGN STRATEGIES 15

6. Thermal Mass The thermal storage The design issues related to capabilities of a given material thermal mass depend on the Some heat storage capacity. or depend on the material's passive system type. For thermal mass. is present in all conductivity. specific heat and sunspaces and thermal storage houses. in the framing. gypsum . Most of the concrete wall systems. the required mass wall and ceiling board. typical and masonry materials typically of the system is included in the furnishings and floor coverings. used in passive solar have design itself. For direct gain. the In suntempered houses. this similar specific heats. added mass must be within the modest amount of mass is Conductivity tends to increase rooms receiving the sunlight. sufficient for the modest amount with increasing density. So the The sections on Direct Gain of south-faCing glass. But more major factor affecting Systems. Sunspaces and thermal mass is required in performance is density. Thermal Storage Walls contain passive solar houses. and the Generally. the higher the density more information on techniques question is not only how much. the better. for sizing and locating thermal but what kind and where it mass in those systems. should be located. The thermal mass in a passive solar system is usually a conventional construction material such as brick. cast concrete. concrete masonry. Heat Storage Properties of Materials concrete slabs. or tile. and is Density usually placed in the floor or Material (lb/ft3) (Btu/in-sf-OF) interior walls. Other materials can also be used for thermal Poured Concrete 120 - 150 2.0 - 2.5 mass. such as "phase change" Clay Masonry materials. which store and Molded Brick 120 - 130 2.0 - 2.2 release heat through a chemical Extruded Brick 125 - 135 2.1 - 2.3 reaction. Water actually has a Pavers 130 - 135 2.2 - 2.3 higher unit thermal storage Concrete Masonry capacity than concrete or Block 80 - 140 1.3 - 2.3 masonry. Water tubes and units Brick 115-140 1.9 - 2.3 Pavers called "water walls" are 130 - 150 2.2 - 2.5 commercially available (general Gypsum Wallboard 50 0.83 recommendations for these systems are included in the Water 62.4 5.2 section on Thermal Storage Wall systems).

Salem. Oregon 16 GUIDELINES PART TWO: BASICS OF PASSIVE SOLAR

7. Orientation When glazing is oriented In the ideal situation. the more than 15 degrees off true house should be oriented east­ The ideal. orientation for solar south. not only is winter solar west and so have its longest wall glazing Is Within 5 degrees of perfonnance reduced. but facing south. But as a practical true south. This orientation will summer air conditioning loads matter. if the house's short side provide maximum perfonnance. also significantly increase. has good southern exposure it Glazing oriented to Within 15 especially as the orientation goes will usually accommodate degrees of true south Will west. The wanner the climate. suffiCient glazing for an effective perfonn almost as well. and the more east- and west-facing passive solar system. provided orientations up to 30 degrees off glass will tend to cause the heat can be transferred to - although less effective - will overheating problems. In the northern zones of the house. still provide a substantial level of general. southeast orientations solar contribution. present less of a problem than In Salem. magnetic north as southwest. indicated on the compass is actually 20 degrees east of true north. and this should be corrected for when planning for orientation of south glazing.

Salem. oregon PASSIVE SOLAR DESIGN STRATEGIES 17 ,...... l1li ... ,. 8. Site Planning for also the figure on page 35 Solar Access shOwing landscaping for summer shade. The basic objective of site ~: planning for maximum energy performance is to allow the south side as much unshaded exposure as possible during the winter months. As discussed above, a good Solar Subdivision Layouts solar orientation is possible Solar access may be provided to the rear yard, the side yard or the front yard of solar within a relatively large southern ~ 2 Story Buildings A11o\Wd homes. arc, so the flexibility exists to

achieve a workable balance Ideal Solar Access between energy performance and Buildings, trees or other obstructions should not be located so as to shade the south wall other important factors such as of solar buildings. At this latitude, A = 20 ft., the slope of the site, the B = 35 ft., andC = 80 ft. individual house plan, the direction of prevailing breezes for Of course, not all lots are large summer cooling, the views, the enough to accommodate this street lay-out, and so on. kind of optimum solar access, so But planning for solar access it's important to carefully assess does place some restrictions shading patterns on smaller lots even on an individual site, and to make the best compromise. presents even more challenges Protecting solar access is when planning a complete easiest in subdivisions with subdivision. Over the years, streets that run within 25 developers and builders of many degrees of east-west, because all dilTerent kinds of projects all lots will either face or back up to over the country have come up south. Where the streets run Solar Subdivision Layouts north- south, creation of east­ Short east-west cul-de-sacs tied into north­ with flexible ways to provide south collectors is a good street pattern for adequate solar access. west cul-de-sacs will help ensure solar access. Once again, there is an ideal solar access. Two excellent references for situation and then some degree ideas about subdivision lay-out of flexibility to address practical to protect solar access are concerns. Ideally, the glazing on the house should be exposed to Builder's Guide to Passive Solar sunlight with no obstructions Home Design and Land within an arc of 60 degrees on Development and Site Planning either side of true south, but Jor Solar Access. (See References IS and 16) reasonably good solar access will still be guaranteed if the glazing is unshaded within an arc of 45 degrees. The figure on this page shows the optimum situation for providing unshaded southern exposure during the winter. See

Salem, Oregon 18 GUIDELINES PART TWO: BASICS OF PASSIVE SOLAR

9. Interior Space Another general principle is 10. Putting it Planning that an open floor plan will allow Together: The House the collected solar heat to as a System Planning room lay-out by circulate freely through natural . considering how the rooms will Many different factors will affect be used in different seasons, and Other ideas from effective passive solar houses: a house's overall performance, at different times of day, can and these factors all interact: save energy and increase • Orienting internal mass walls as north-south partitions the mechanical system, the comfort. In houses with passive insulation. the house's solar features, the lay-out of that can be "charged" on both sides thus making maximum tightness, the effects of the rooms - and interior zones passive solar features, the which may include more than use of the mass. • Using an east-west partition appliances, and. very one room - is particularly importantly, the actions of the important. wall for thermal mass, but make sure the interior space isn't people who live in the house. In In general, living areas and each of these areas, changes are other high-activity rooms should divided into a south zone which may get too warm and a north possible which would improve be located on the south side to the house's energy performance. benefit from the solar heat. The zone which may get too cold. • Using thermal storage walls Some energy savings are closets, storage areas, garage relatively easy to get. Others and other less-used rooms can (see page 30); the walls store energy all day and slowly release can be more expensive and more act as buffers along the north difficult to achieve, but may side, but entry-ways should be it at night, and can be a good alternative to ensure privacy and provide benefits over and above located away from the wind. good energy performance. Clustering baths, kitchens and to buffer noise when the south side faces the street; A sensible energy-efficient laundry-rooms near the water house uses a combination of heater will save the heat that • Collecting the solar energy in one zone of the house and techniques. would be lost from longer water In fact, probably the most lines. transporting it to another by fans or natural convection important thing to remember through an open floor plan. about designing for energy performance in a way that will • Providing south-facing clerestOries to "charge" north also enhance the comfort and zones. value of the house is to take an integrated approach, keeping in mind the house as a total system. On the the following page is a basic checklist for energy-efficient design. These techniques are dealt with in more detail, including their impact in your location, in Part

Int~rlor Space Planning Three. Uvmg and high activity spaces should be located on the south.

Salem, Oregon PASSIVE SOLAR DESIGN STRATEGIES 19

Checklist for Good Design

.t 1. Building orientation: A number of innovative techniques can be used for obtaining good solar access on less-than-ideal sites (see References 15 and 16). No matter what the house's design, and no matter what the site, some options for orientation will be more energy-efficient than others, and even a very simple review of the site will probably help you choose the best option available .

.t 2. Upgraded levels of insulation: It is possible, of course, to achieve very high energy-efficiency with a "superinsulated" design. But in many cases, one advantage of passive solar design is that energy-efficiency can be achieved with more modest increases in insulation. On the other hand, if very high energy performance is a priority - for example, in areas where the cost of fuel is high - the most cost-effective way to achieve it is generally through a combination of high levels of insulation and passive solar features.

" 3. Reduced air Infiltration: Air tightness is not only critical to energy performance, but it also makes the house more comfortable. Indoor air quality is an important issue, and too complex for a complete discussion here, but in general, the suntempered and passive solar houses built according to the guidelines provide an alternative approach to achieving improved energy efficiency without requiring air quality controls such as air to air heat exchangers, which would be needed if the house were made extremely airtight.

" 4. Proper window sizing and location: Even if the total amount of glazing is not changed, rearranging the location alone can often lead to significant energy savings at little or no added cost. Some energy-conserving designs minimize window area on all sides of the house - but it's a fact of human nature that people like windows, and windows can be energy producers if located correctly.

" 5. Selection of glazing: Low-emissivity (low-e) glazing types went from revolutionary to commonplace in a very short time, and they can be highly energy-efficient choices. But the range of glazing possibilities is broader than that, and the choice will have a significant impact on energy performance. Using different types of glazing for windows with different orientations is worth considering for maximum energy performance; for example, using heat-rejecting glazing on west windows, high R-value glazing for north and east windows, and clear double-glazing on solar glazing.

" 6. Proper shading of windows: If windows are not properly shaded in summer - either with shading devices, or by high-performance glazing with a low shading coefficient - the air conditioner will have to work overtime and the energy savings of the winter may be canceled out. Even more important, unwanted solar gain is uncomfortable.

" 7. Interior design for easy air distribution: If the rooms in the house are planned carefully, the flow of heat in the winter will make the passive solar features more effective, and the air movement will also enhance ventilation and comfort during the summer. Often this means the kind of open floor plan which is highly marketable in most areas. Planning the rooms with attention to use patterns and energy needs can save energy in other ways, too - for instance, using less-lived-in areas like storage rooms as buffers on the north side.

" B. Addition of thermal mass: Adding effective thermal mass - for example, tiled or paved concrete slab, masonry walls, brick fireplaces, tile floors, etc. - can greatly improve the comfort in the house, holding heat better in winter and keeping rooms cooler in summer. In a passive solar system, of course, properly sized and located thermal mass is essential.

" 9. Selection and proper sizing of mechanical systems, and selection of energy-efficient appliances: High-performance heating, cooling and hot water systems are extremely energy-efficient, and almost always a good investment. Mechanical equipment should have at least a 0.80 Annual Fuel Utilization Efficiency (AFUE). Well-insulated passive solar homes will have much lower energy loads than conventional homes, and should be sized accordingly. Oversized systems will cost more and reduce the house's performance. For guides to the selection of energy-efficient appliances, see References 13 and 14.

Salem, oregon 20 GUIDELINES PART TWO: BASICS OF PASSIVE SOLAR

Salem, oregon PASSIVE SOLAR DESIGN STRATEGIES ~I

Part Three: Strategies for Improving Energy Performance in Salem, oregon

1. The Example Tables

2. Suntempering

3. Direct Gain

4. Sunspaces

5. Thermal Storage Wall

6. Combined Systems

7. Natural Cooling Guidelines

Salem, Oregon 22 GUIDELINES PART THREE: STRATEGIES FOR IMPROVING ENERGY PERFORMANCE

1. The Example • Three numbers The R-values indicated in the corresponding to those on the Example tables are. of course. Tables Worksheets: ConselVation. apprOXimate and are intended to AuxilIary Heat. and Cooling show how incremental In the folloWing sections of the Performance (see page 4) improvements can be achieved. Guidelines. the primary passive The Example tables then show All R-values in the Examples solar systems - Suntempering. how the house design could be and Worksheets are equivalent Direct Gain. Thermal Storage changed to reduce winter R-values for the entire Walls and Sunspaces - are heating energy by 20. 40 and construction assembly. not just described in more detail. 60%. compared to this Base for the cavity insulation itself, As part of the explanation of Case. and take into account framing each system. an Example table There are. of course. other and buffering effects. is provided. The Examples ways to achieve energy savings Other assumptions are noted present the folloWing information than those shown in the for each Example. However. one about a Base Case house. based Examples. The Examples are more general assumption is on a National Association of designed to show an effective important to note here. When Home Builders study of a typical integration of strategies. and a the Examples were calculated. it construction: useful approach to the design of was assumed that natural • Insulation levels (ceilings the house as a total system. cooling strategies such as those and walls): Using any of these combinations deSCribed in these Guidelines • Tightness (measured in air would result in excellent were used. particularly in the changes per hour. ACH); performance in your area. very high-performance systems. • The amount of glass area on However. they are general The greater the percentage each side (measured as a indications only. and using the reduction in heating energy percentage of floor area; the Worksheets will give you more needs using passive solar actual square footage for a 1.500 information about your specifiC design. the more shading and sf house is also given as a design. natural cooling were assumed. reference point): The Example assumes a The Examples show passive • The "percent solar savings" 1.500 sf house. but the solar strategies. but an (the part of a house's heating percentages apply to a house of Insulation Only Example table energy saved by the solar any size or configuration. (achieving energy savings only features); and by increasing insulation levels. Without solar features) is provided in the Sunnnary beginning on page 54. for comparison.

Salem. Oregon PASSIVE SOLAR DESIGN STRATEGIES 23 2. Suntempering Examples of Heat Energy Savings Suntempered and passive solar Suntempered 1,500 sf Single Story House houses both: • begin with good basic Base energy-conservation. Case 20% 40% 60% R-Values • take maximum advantage of Ceiling/Roof 28 32 38 49 the building site through the Walls 16 18 22 28 right orientation for year-round Floor 18 21 25 31 energy savings. and Glass 1.8 1.8 1.8 2.7 • have increased south-facing Air Changes/Hour 0.67 0.61 0.57 0.43 glass to collect solar energy. Suntempertng is the simplest Glass Area (percent of total floor area) passive solar system. and refers West 3.0% 2.0% 2.0% 2.0% North 3.0% 4.0% 4.0% 4.0% to modest increases in windows East 3.0% 4.0% 4.0% 4.0% on the south side. South 3.0% 6.7% 6.7% 6.7% No additional thermal mass Solar System Size (square feet) is necessary. only the "free South Glass 45 100 100 100 mass" in the house - the framing. gypsum wall-board and Percent Solar Savings furnishings. 7% 14% 17% 22% In a "conventional" house. Performance (Btu/yr-sf) about 25% of the windows face Conservation 36,001 32,367 25,321 18,052 south. which amounts to about Auxiliary Heat 33,596 27,543 20,801 14,054 3% of the house's total floor Cooling 3,532 2,929 2,907 1,915 area. In a suntempered house. Summary: Insulation values and tightness of the house (as measured in the percentage is increased to a ACH) have been increased. The window area has been slightly maximum of about 7%. decreased on the west, increased slightly on the east and north, and The energy savings are more increased significantly on the south. modest with this system. but suntempering is a very low-cost strategy. Of course. even though the necessity for precise sizing of glazing and thermal mass does not apply to suntempering (as long as the total south-facing glass does not exceed 7% of the total house floor area). all other recommendations about energy­ efficient design such as the basic energy conseIVation measures. room lay-out, siting. glazing type and so on are still important for penormanceandcomfortin suntempered homes.

Salem. Oregon 24 GUIDELINES PART THREE: STRATEGIES FOR IMPROVING ENERGY PERFORMANCE

3. Direct Gain Glazing incorporation of significant Double glazing is recommended amounts of heavy thermal mass The most common passive solar for direct gain glazing in Salem. is a little more difficult. Thermal system is called direct gain: The Performance Potential table mass floor coverings over sunlight through south-facing on page 6 shows the relative basements. crawlspaces and glazing falls directly into the performance of different types of lower stories would generally be space to be heated. and is stored direct gain glazing. You will note limited to thin set tile or other in thermal mass incorporated from this table that yield thin mass floors. into the floor or interior walls. increases by 35% between When more mass is required. double and triple or low-e the next best option Is for glazing. Night insulation also interior walls or interior masonty improves energy performance fireplaces. When evaluating dramatically. In fact. as the costs. the dual function of mass Performance Potential table walls should be remembered. shows. covering the windows at They often serve as structural night or on cloudy days with the elements or for fire protection as equivalent of R-4 shades or well as for thermal storage. other material w1l1 save almost Another option is to switch to as much energy as with R-9 another passive solar system material. But studies have type such as attached slab-on­ shown that only relatively few grade sunspaces or thermal homeowners will be diligent storage walls built directly on enough about operating their exterior foundation walls. Direct Gain night insulation to achieve those Sunlit thermal mass floors Direct gain is the most common passive solar system in residential applications savings. Energy-effiCient should be relatively dark in glazing. on the other hand. color. to absorb and store energy Sizing Limit needs no operation. and more effectively. However, mass Total direct gain glass area therefore is a more convenient walls and ceilings should be should not exceed about 12% of and reliable option. light in color to help distribute the house's floor area. Beyond both heat and light more evenly. that. problems with glare or Thermal Mass fading of fabriCS are more likely Thermal mass can be to occur, and it becomes more incorporated easily into slab-on­ difficult to provide enough grade type buildings as either thermal mass for year-round floor covering. walls or veneers comfort. over interior walls. If the mass So the total south-facing is placed in the floor. it will be glass area in a direct gain much more effective if sunlight system should be between 10k falls directly on it. (the maximum for suntempered Effective materials for floors houses) and 12%. depending on include painted. colored or vinyl­ how much thermal mass will be covered concrete. brick (face used in the design. as discussed brick or pavers have even higher below. density than ordinary building brick). quarry tile. and dark­ colored ceramic tile. For houses built with crawlspaces or basements. the

Salem. Oregon PASSIVE SOLAR DESIGN STRATEGIES

Ratio of Glass to Mass. The More south-facing glazing Thickness. For most materials, following procedure can be used than the maximum as the effectiveness of the thermal to detennine the maximum detennined here would tend to mass in the floor or interior wall amount of direct-gain glazing for overheat the room, and to increases proportionally with a given amount of thermal mass. reduce energy performance as thickness up to about 4 inches. If the amount of direct-gain well. After that, the effectiveness glazing to be used is already doesn't increase as significantly. known, thennal mass can be A two-inch mass floor will be added until this procedure about two-thirds as effective in a produces the desired direct gain system as a four-inch proportions: mass floor. But a six-inch mass • Start with a direct gain glass floor will only perform about area equal to 7% of the house's eight percent better than a four­ total floor area. As noted above, inch floor. the "free mass" in the house will The following figure shows be able to accommodate this the effectiveness of thermal much solar energy. mass in relation to density and axis • An additional 1.0 sf of direct 1:40 lor Roar thickness. The vertical gain glazing may be added for nolinSll1 shows how many square feet of every 5.5 sf of uncovered, sunlit mass area are needed for each Mass Location and Effectiveness mass floor. Carpet or area rugs Additional mass must be provided for south added square foot of direct gain. will seriously reduce the facing glass over 7"k. of the floor area. The As you can see, performance ratio of mass area to additional glass area effectiveness of the mass. The depends on its location within the direct gain increases start leveling off after a space. maximum floor mass that can be few inches of thermal mass. considered as "sunlit" may be estimated as about 1.5 times the 40 south window area. -B as 5O#/cI • An additional 1.0 square foot a: :&30 of direct gain glazing may be < added for every 40 sf of thermal 75#/cI .!!I'" mass in the floor of the room, C}2Q lii but not in the sun. a. 1

Salem. Oregon 26 GUIDELINES PART THREE: STRATEGIES FOR IMPROVING ENERGY PERFORMANCE

Examples of Heat Energy Savings Passive Solar-Dlrect Gain 1,500 sf Single Story House

Base Case 20% 40% 60% R·values Ceiling/Roof 28 31 37 46 Walls 16 18 22 27 Floor 18 20 24 30 Glass 1.8 1.8 1.8 2.7

Air Changes/Hour 0.67 0.60 0.45 0.41

Glass Area (percent of total floor area) West 3.0% 2.0% 2.0% 2.0% North 3.0% 4.0% 4.0% 4.0% East 3.0% 4.0% 4.0% 4.0% South 3.0% 7.5% 9.3% 12.0%

Added Thermal Mass Percent of Floor Area 0.0% 3.1% 13.6% 30.0%

Solar System Size (square feet) South Glass 45 112 139 180 Added Thermal Mass 0 47 204 450

Percent Solar Savings 7% 16% 21% 29%

Performance (Btu/yr-sf) Conservation 36,001 32,800 26,426 19,933 Auxiliary Heat 33,596 27,534 20,792 14,041 Cooling 3,532 3,211 3,753 3,637

Summary: Insulation and tightness have been increased. South-facing glazing has been substantially increased. For these examples, added mass area is assumed to be six times the excess south glass area.

Salem. Oregon PASSIVE SOLAR DESIGN STRATEGIES ~I

4. Sunspaces The sunspace floor is a good location for thermal mass. The The sunspace is a very popular mass floors should be dark in passive solar feature, adding an color. No more than 15-25% of attractive living space as well as the floor slab should be covered energy performance. There are with rugs or plants. The lower many variations on the basic edge of the south-facing theme of the sunspace, and the windows should be no more possibilities for sunspace design than six inches from the floor or are extraordinarily diverse the planter bed to make sure the (References 17 through 20 mass in the floor receives include specific design ideas). sufficient direct sunlight. If the Sun_paces The sunspace concept used Sunspaces provide useful passive solar windows sills are higher than in these Guidelines can be used heating and also provide a valuable amenity that, additional mass will have to homes. year-round. will provide most or to be located in the wall. all of its own energy needs, and Thermal Mass Another good location for will contribute to the energy A sunspace has extensive south­ thermal mass is the common needs of the rest of the house as facing glass, so suffiCient wall (the wall separating the well. thermal mass is very important. sunspace from the rest of the Sunspaces are referred to as Without it, the sunspace is liable house). Options for the common "isolated gain" passive solar to be uncomfortably hot during wall are discussed in more detail systems. because the sunlight is the day. and too cold for plants below. collected in an area which can or people at night. Water in various types of be closed off from the rest of the However, the temperature in containers is another form of house. During the day, the the sunspace can vary more energy storage often used in doors or windows between the than in the house itself. so sunspaces. sunspace and the house can be about three square feet of four opened to circulate collected inch thick thermal mass for each Glazing heat. and then closed at night, square foot of sunspace glazing Clear, double-glazing is and the temperature in the should be adequate. With this recommended for sunspaces. sunspace allowed to drop. glass-to-mass ratio, on a clear Adding the second pane makes a The sunspace should not be winter day a temperature swing large improvement in energy on the same heating system as of about 30'F should be savings. Triple-glazing or low-e the rest of the house. A well expected. coatings. on the other hand. will designed sunspace will probably further improve comfort. but will need no mechanical heating have little effect on energy system, but if necessary, a small savings. fan or heater may be used to Windows on the east and protect plants on extremely cold west walls should be small (no winter nights. more than 10% of the total The sunspace should be just sunspace floor area) but they are as tightly constructed and useful for cross-ventilation. insulated as the rest of the Like tilted or sloped glazing, house. glazed roofs can increase solar gain. but they can also present big overheating problems and become counter-productive. If either glazed roofs or tilted

Salem, Oregon 28 GUIDELINES PART THREE: STRATEGIES FOR IMPROVING ENERGY PERFORMANCE glazing are used in the Common Wall Some solar energy may be sunspace, special care should be There are a number of options transferred from the sunspace to taken to make sure they can be for the sunspace common wall. the rest of the house by effectively shaded during the In mild climates, and when the conduction through the common summer and, if necessary, on sunspace is very tightly wall if it is made of thermal sunny days the rest of the year, constructed, an uninsulated mass. But energy is mainly too. The manufacturers of frame wall is probably adequate. transferred by natural sunspaces and glazing are However, insulating the common convection through openings in developing products with better wall to about R-lO is a good the common wall - doors, ability to control both heat loss idea, especially in cold climates. windows and/ or vents. and heat gain (for example, roof An insulated common wall will • Doors are the most common glazing with low shading help guard against heat loss opening in the common wall. If coefficients, shading treatments during prolonged cold, cloudy only doorways are used, the and devices, etc.). periods, or if the thermal storage open area should be at least You'll note that in the in the sunspace is insuffiCient. 15% of the sunspace south-glass Performance Potential chart on If the common wall is a area. page 6, sunspaces with glazed masonry wall, it can also be • Windows will also provide roofs or sloped glazing perform used for thermal mass, in which Ught and views. The window very well. This analysis case it should be solid masonry area in the common wall should assumes effective shading in the approximately 4 to 8 inches be no larger than about 40% of summer. If such shading is not thick. Another option is a frame the entire common wall area. If economical or marketable in wall with masonry veneer. only windows are used, the your area. you should conSider Probably the most important operable area should be about using only vertical glazing, and factor in controlling the 25% of the sunspace's total accepting somewhat less energy temperature in the sunspace, south glass area. performance in winter. and thus keeping it as comfortable and effiCient as possible, is to make sure the exterior walls are tightly constructed and well-insulated.

Salem, Oregon PASSIVE SOLAR DESIGN STRATEGIES

Summer ventilation The sunspace must be vented to Examples of Heat Energy Savings the outside to avoid overheating Passive Solar-Sunspace 1,500 sf Single Story House in the summer or on warm days in spring and fall. A properly Base vented and shaded sunspace Case 20% 40% 60% R·Values can function much like a Ceiling/Roof 28 30 36 44 screened-in porch. Walls 16 18 21 25 Operable Windows and/ or Floor 18 20 23 28 vent openings should be located Glass 1.8 1.8 1.8 2.7 for effective cross-ventilation. Air Changes/Hour 0.67 0.65 0.49 0.45 and to take advantage of the prevailing summer wind. Low Glass Area (percent of total floor area) inlets and high outlets can be West 3.0% 2.0% 2.0% 2.0% North 3.0% 4.0% 4.0% 4.0% used in a "". since East 3.0% 4.0% 4.0% 4.0% warm air will rise. These South (windows) 3.0% 3.0% 3.0% 3.0% ventilation areas should be at Sunspace 0.0% 7.2% 10.9% 17.0% least 15% of the total sunspace Solar System Size (square feet) glass areas. South Glass 45 45 45 45 Where natural ventilation is Sunspace Glass 0 107 164 255 insuffiCient. or access to natural Sunspace Thermal Mass 0 321 492 765 breezes is blocked. a small. Percent Solar Savings thermostat-controlled fan set at 7% 19% 27% 38% about 76'F will probably be a useful addition. Perfonnance (Btu/yr-sf) Conservation 36,001 34,198 28,554 22,532 Auxiliary Heat 33,596 27,478 20,765 13,976 Cooling 3,532 2,050 1,920 989 Summary: Insulation and tightness have been increased. North and east­ facing glazing have been increased slightly. The sunspace assumed here is semi-enclosed (surrounded on three sides by conditioned rooms of the house, as in Figure SSD1 of the worksheets), with its south glazing tilted at 50 degrees. The common wall is a thermal mass wall made of masonry. Sunspace glazing is assumed to be double.

Salem. Oregon 30 GUIDELINES PART THREE: STRATEGIES FOR IMPROVING ENERGY PERFORMANCE

5. Thermal Storage Selective Surfaces Wall A selective surface is a special adhesive foil applied to the The ThelTIlal Storage Wall- exterior side of the mass of also sometimes referred to as a ThelTIlal Storage Walls. or an indirect gain Selective surfaces absorb a large system - is a south-facing percentage of solar radiation but Glazing radiate very little heat back to glazed wall. usually built of the out-of-doors (low emittance). heavy masonry. but sometimes ~ using water containers or phase To be effective. selective Thermal Storage Wall , surfaces must be applied change materials. The masonry A thermal storage wall is an effe,ctive, pas,slVe solar system, especially to proVIde mghttlme carefully for 100% adhesion to is separated from the glazing heating. only by a small air space. the mass surface. Sunlight is absorbed directly In Salem, Oregon. a selective A masonry ThelTIlal Storage Wall surface will improve ThelTIlal into the wall instead of into the should be solid. and there living space. The energy is then Storage Wall perfolTIlance by should be no openings or vents about 64%. released into the living space either to the outside or to the over a relatively long period. The living space. Although vents to Mass Material and time lag varies with different the living space were once materials. thicknesses and other Thickness commonly built into ThelTIlal In general. the effectiveness of factors, but typically, energy Storage Walls, experience has stored in a Thermal Storage Wall the ThelTIlal Storage Wall will demonstrated that they are increase as the density of the during the day is released ineffective. Vents between the during the evening and material increases. ThelTIlal Storage Wall and the The optimum thickness of nighttime hours. house tend to reduce the the wall depends on the density The outside surface of a system's nighttime heating of the material chosen. The thelTIlal storage wall should be a capability. and to increase the following chart indicates the very dark color - an temperature fluctuation in the recommended thickness of absorptance greater than 0.92 is house. Vents to the outside are ThelTIlal Storage Walls made of recommended. similarly ineffective. and do little various materials. The summer heat gain from to reduce summer heat gains. a ThelTIlal Storage Wall is much less - roughly 97% less - than Glazing from a comparable area of direct Double glazing is recommended gain glazing. for ThelTIlal Storage Walls unless a selective surface is used. In this case, single glazing perfolTIls about the same as double glazing. The space between the glazing and the thelTIlal mass should be one to three inches.

Salem, Oregon PASSIVE SOLAR DESIGN STRATEGIES ~l

Mass Wall Thickness Examples of Heat Energy Savings (inches) Passive Solar-Thermal Storage Wall 1,500 sf Single Story House Density Thickness Material (lb/cf) (inches) Base Case 20% 40% 60% Concrete 140 8-24 R-Values Concrete Block 130 7-18 Ceiling/Roof 28 28 33 39 Clay Brick 120 7-16 Walls 16 16 19 22 Ltwt. Concrete 110 6-12 Floor 18 18 21 25 Block Glass 1.8 1.8 1.8 2.7 Adobe 100 6-12 Air Changes/Hour 0.67 0.63 0.55 0.56

Glass Area (percent of total floor area) Water Walls West 3.0% 2.0% 2.0% 2.0% Water provides about twice the North 3.0% 4.0% 4.0% 4.0% heat storage per unit volume as East 3.0% 4.0% 4.0% 4.0% South 3.0% 3.0% 3.0% 3.0% masonry. so a smaller volume of Thermal Storage Wall 0.0% 6.7% 10.9% 17.0% mass can be used. In "water walls" the water is in light. rigid Solar System Size (square feet) containers. The containers are South Glass 45 45 45 45 Thermal Storage Wall 0 101 163 255 shipped empty and easily installed. Manufacturers can Percent Solar Savings provide information about 7% 22% 33% 47% durability. installation. Performance (Btu/yr-sf) protection against leakage and Conservation 36,001 35,698 31,227 26,421 other characteristics. At least Auxiliary Heat 33,596 27,531 20,755 13,957 30 pounds (3.5 gallons) of water Cooling 3,532 2,110 1,964 1,054 should be provided for each Summary: In the case of a Thermal Storage Wall, south-facing glazing square foot of glazing. This is and thermal mass are incorporated together. The estimates here assume equivalent to a water container a 12-inch thick concrete Thermal Storage Wall with a selective surface about six inches thick. having and single glazing. the same area as the glazing.

Salem. Oregon 32 GUIDELINES PART THREE: STRATEGIES FOR IMPROVING ENERGY PERFORMANCE

6. Combined Systems 7. Natural Cooling Fortunately, many ofthe Guidelines features that help maintain Although the previous sections comfort and reduce energy have presented separate needs in winter also work well in The tenn "natural cooling" is discussions of four different used here to describe techniques summer. For instance, systems, it isn't necessary to which help a house stay cool in additional thennal mass choose one and only one system. summer but which require Uttle perfonns well year-round. In fact, passive solar features or no energy. Natural cooling Masonry materials are equally work well in combination. techniques work to help reduce effective in staying cool and For example, direct gain air-conditioning, not replace it. storing heat. If mass surfaces works very well in conjunction These techniques are useful can be exposed to cool night­ with a sunspace or thennal not only in passive solar houses, time temperatures - a storage wall. Since thennal but in "conventional" houses as technique referred to as "night storage walls release energy well. The strategies outlined ventilation" - they will help the more slowly than direct gain below - attention to the house stay cooler the next day. systems, they are useful for location, size and shading of A California utility found during supplying heat in the evening glazing, using the opportunities studies of small test buildings and at night, whereas the direct on the site for shading and that on hot summer days the gain system works best during natural ventilation, and using workmen at the facility always the day. Although using a ate lunch in the masonry test fans - can reduce air sunspace, thennal storage wall conditioning needs and increase building because it stayed much and direct gain system in the comfort even if the house has no cooler than any of the others. same house may result in passive solar heating features. (See Reference 9) excellent perfonnance, such But shading is particularly The additional insulation combinations do require a large important in passive solar that increases winter south-facing area, and careful houses, because the same performance will also work to design to make sure the systems features that collect sunlight so improve summer perfonnance by are well-integrated with each effectively in winter will go right conserving the conditioned air inside the house. And some other and with the house's on collecting it in summer - mechanical system. resulting in uncomfortably hot low-e Windows and other glazing with high R-value can help rooms and big air conditioning bills - unless they are shaded shield against unwanted heat and the house is designed to gain in summer. help cool itself.

Salem, Oregon PASSIVE SOLAR DESIGN STRATEGIES 33

The potential of some natural and low-energy cooling Cooling Potential strategies is shown in the Basecase 3,532 Btu/yr-sf following table for Salem. Energy Worksheet IV: Coollng Savings Percent Performance Level indicates Strategy (Btu/yr-sf) Savings the total annual cooling load. No Night Ventilation 1 and so can give an idea of how without ceiling fans 0 0% the passive solar features with ceiling fans 1,430 40% increase the cooling load and Night Ventilation1 how much reduction is possible without ceiling fans 1,180 33% when natural cooling techniques with ceiling fans 2,300 65% are used. High Mass2 It should be noted that the without ceiling fans 360 10% Cooling Performance numbers with ceiling fans 060 2% presented in the Examples for each passive solar strategy 1 With night ventilation, the house is ventilated at night when assume that the design also temperature and conditions are favorable. includes the recommended 2 A "high mass" building is one with a thermal mass area at least equal natural cooling techniques. This to the house floor area. is especially true of the higher percentage reductions; these assume better heating performance. but also better shading and other natural cooling strategies.

Salem. Oregon 34 GUIDELINES PART THREE: STRATEGIES FOR IMPROVING ENERGY PERFORMANCE

Glazing and so they may interfere with As mentioned earlier. poorly Added WIndow Cooling Load desirable views. It is important placed windows can increase air > to note. however. that some Added Annual conditioning loads dramatically. Cooling Load types of low-e windows block It is generally best in tenns of Orientation (Btu/yr -sf) solar tranSmission but also energy perfonnance to carefully allow clear views. These North 12,990 size non-solar glazing as East 41,250 treatments are not indicated in the following table. South 36,390 recommended for south West 41,410 Windows. Skylights 77,620 As the table shows. skylights Recommended Non-south present a high potential for Glass GuIdelines These values are based on double glass with a shading overheating. and are usually Percent coefficient of 0.88. When glazing difficult to shade properly. But of Total with a different shading skylights are very popular Orientation Floor Area coefficient is used the values may be scaled proportionally. features. and they save East 4% electricity by providing good North 4% natural daylight to the house. West 2% These numbers can be reduced In some parts of the country by shading as deSCribed in the almost every new house has at next section. least one skylight. A good As mentioned earlier. west­ Using special glazing or working compromise can usually facing windows present window films that block solar be achieved if skylight area is particularly difficult shading tranSmission (low shading limited. and if careful attention problems. If glazing is added coeffiCient) is an option often is paid to shading. either by above the levels indicated. the used in particularly hot trees or by devices such as roller need for shading will become climates. but the more effective shades or blinds. The even more critical. they are at blocking sunlight. manufacturer can usually give Cooling loads increase as the less clear they are. as a rule. guidance on shading options for window area increases. This a partIcular skylight design. relationship for Salem is shown in the following table for each of the cardinal window orientations. For instance when a square foot of west area is added or subtracted. the annual cooling load increases or decreases by 41.410 Btu/yr-sf.

Salem. oregon PASSIVE SOLAR DESIGN STRATEGIES

Shading Roof Overhangs. Fixed Shading strategies generally fall overhangs are an inexpensive into three categories: feature, and require no landscaping. roof overhangs and operation by the home owner. exterior or interior shading They must be carefully designed. devices. however. Otherw1se, an overhang that blocks summer Landscaping. The ideal site for sun may also block sun in the summer shading has deciduous Landscaping for Summer Shade spring. when solar heating is trees to shade the east and west Trees and other landscaping features may be desired. and, by the same token, effectively used to shade east and west windows. Even small trees such windows from summer solar gains, an overhang sized for maximum as fruit trees can help block sun solar gain in winter will allow hitting the first story of a house. Other landscaping ideas for solar gain in the fall on hot days. Trees on the south side can summer shade: The following figure may be used present a difficult choice. Even • Trellises on east and west to determine the optimum deciduous trees will shadow the covered with vines. overhang size. solar glazing during the winter • Shrubbery or other plantings In Salem. an ideal overhang and interfere with solar gain. In to shade paved areas. projection for a four foot high fact. trees on the south side can • Use of ground cover to window would be 31 inches and all but eliminate passive solar prevent glare and heat the bottom of the overhang perfonnance. unless they are absorption. would be 15 inches above the very close to the house and the • Trees. fences. shrubbery or top of the window. low branches can be removed. other plantings to "channel" allowing the winter sun to summer breezes into the house. penetrate under the tree canopy. • Deciduous trees on the east However. in many cases the and west sides of the house. as trees around the house are shown above. to balance solar bigger selling paints than the gains in all seasons. energy effiCiency and the builder must make a choice. If a careful study of the shading patterns is done before, construction. it should be possible to accomodate the south-facing glazing while leaving in as many trees as possible (see page 17. Site Planning for Solar Access). South Overhang Sizing In Salem, an ideally sized south overhang should allow full exposure of the window when the sun has a noon altitude of 26 degrees (angle A) and fully shade the window when the sun has a noon altitude of 63 degrees (angle B).

Salem. Oregon 36 GUIDELINES PART THREE: STRATEGIES FOR IMPROVING ENERGY PERFORMANCE

A combination of carefully sized Ceiling Fans overhangs on the south windows Ceiling fans will probably save Ceiling Fan Sizes and shading devices on the other more energy than any other Minimum Fan windows will probably be an single cooling strategy. Studies Largest Room Diameter effective solution. Adjustable show that air movement can Dimension (inches) overhangs that can be make people feel comfortable at 12 feet or less 36 As seasonally regulated are another higher temperatures. a 12 - 16 feet 48 option. general rule. the thermostat can 16 - 17.5 feet 52 be set 4 degrees higher without 17.5 - 18.5 feet 56 Shading Devices. External affecting comfort if the air is 18.5 or more feet 2 fans shades are the most effective moving at 100-150 feet per because they stop solar gain minute. This is enough air before the sun hits the building. movement to greatly improve A ceiling fan should have a A wide range of products are comfort but not enough to minimum clearance of ten available. from canvas awnings disturb loose papers. inches between ceiling and fan to solar screens to roll-down to provide adequate ventilation blinds to shutters to vertical in a standard room with eight­ . They are adjustable foot ceilings. In rooms with and perform very well. but their higher ceilings. fans should be limitation is that they require mounted 7.5 to 8.0 feet above the home owner's cooperation. the floor. Usually external screens that can be put up and taken down once a year like storm windows are more acceptable to home owners than those requiring more frequent operation. Interior shades must be operated. too. and have the further disadvantage of permitting the sun to enter the house and be trapped between the window and the shading device. But highly reflective interior blinds and curtains are relatively low-cost and easy to operate. Another shading "device" well worth considering is a porch. Especially on the east and west sides. porches add pleasant spaces to houses and are excellent for proViding shade to windows. Carports located on the east or west are another option.

Salem. Oregon PASSIVE SOLAR DESIGN STRATEGIES .;)/

Ventilation The best possible When possible. the house should performance of a whole-house be positioned on the site to take fan results when a timer. a advantage of prevailing winds. thermostat and a "" During the cooling season. the are used. so that the fan would prevailing wind is from the west. only operate when there is less Windows. staiIwells. transoms than 60% relative humidity and and other elements should be a temperature of less than 76°F. located for maximum cross­ Natural ventilation and ventilation in each room. The whole-house fans are effective at free vent area (unobstructed Ventilation for Summer Cooling removing heat. but not at Natural ventilation is often impaired by openings like open windows) vegetation and topography. Ventilation fans moving air. Ceiling fans. on the do not depend on surroundings to be should be between 6-7.5% of effective. other hand. can often create total floor area. half located on enough of a breeze to maintain the leeward and half on the In cooling climates. a whole­ comfort at higher temperatures. windward side of the building. house fan is a good idea for and stm use less power than Insect screens can reduce the assisting ventilation. especially required by air conditioning. By effective free vent area by as in houses with sites or designs using natural cooling strategies much as 50%. Casement or that make natural ventilation and low-energy fans. the days awning windows have a 90% difficult. On the other hand. when air-conditioning is needed open area: double hung windows when the temperature is higher can be reduced substantially. have only 50%. than about 76°F. a whole-house Natural ventilation can help fan will not be very effective. keep houses cool and Research indicates that a comfortable at the beginning and whole-house fan should pull end of the cooling season and approximately 10 ACH. A rule of thus shorten the time when air thumb: for rooms with eight foot conditioning is required. But ceilings. total floor area natural ventilation can seldom multiplied by 1.34 wm equal the do the entire cooling job. necessary CFM of the fan. For especially for less than ideal 10 foot ceilings. multiply floor sites with little natural air area by l.67. movement.

Salem, Oregon 38 GUIDELINES PART THREE: STRATEGIES FOR IMPROVING ENERGY PERFORMANCE

Salem. oregon Passive Solar Design Strategies EXAMPLE

Passive Solar Industries Council National Renewable Energy Laboratory Charles Eley Associates With Support From: U.S. Department ofEnerg,y ______39

Salem The Worked Oregon Example 40 WORKED EXAMPLE

The Worked Example The house has a semi­ The house is equipped with a enclosed sunspace with glazing ceiling fan to help reduce the Description of sloped at 50 degrees. The air-conditioning load. North Example Building sunspace floor has a four-inch windows have an overhang with A 1.504 square foot passive thick slab-on-grade with quarry a projection factor of 0.30. East solar. single-family home is used tile set in a mortar bed. The and west windows are small and to illustrate how to fill in the sunspace is separated from the have no effective overhang worksheets. See sketches for conditioned portion of the house because of the gable roof. South the bullcUng layout. A variety of by sliding glass doors and a windows. including the design features have been masonry wall. sunspace windows. have an incorporated into the house to Sunspace ventilation is provided overhang with a projection factor help illustrate how to handle to the outside by awning of 0.20. different situations in the windows located at the top and Take-otIs from the house are worksheets. bottom of the south wall. given in the worksheets. Refer The building selected has South facing windows to the Circled values in the good insulation as descnbed on provide direct gain solar heating worksheet tables to locate where Worksheet L to the d1n1ng area. kitchen and the various values which show The east portion of the house master bedroom. The south up in the worksheets come from. is slab on grade. The great room glazing in the kitchen and dining Performance is found to be and master bedroom are area provides heat to an exposed satisfactory on all four constructed over a crawlspace. slab-on-grade finished with worksheets. ceramic tile to provide direct gain heat storage. The house faces 10 degrees to the east of true south.

Garage

3040 3040

4040

Bedroom

Great Room

Master Bedroom

4050 5030 8088

o 2 4 8 12 Floor Plan ...... PASSIVE SOLAR DESIGN STRATEGIES

- South Elevation

North Elevation

Section

Salem, Oregon 42 WORKED EXAMPLE

Salem. Oregon 43

NOTE: These worksheets are completed for the example house described on the previous pages. Also the reference tables are marked up showing how the numbers are selected.

Sale:m Worksheets Oregon

Salem. Oregon 44 General Project Information

Project Name Floor Area Location Date Designer

Worksheet I: Conservation Performance Level

A. Envelope Heat Loss Construction R-value Heat Description Area [Table A) Loss Ceilings/roofs 'it- >8 ltJ. ",1""T\c:..- IO'~ + ]5·;; = 1. 0 'i.- "tc) ,..I L.p. .D' 2-'-v5 ~"i~f'tHlAt.. Gfll.lu6 + = 11 Walls 12..-~~ :t ~~ Slt£«r", IN G 9~"2. + '2.-2..J = kt!::t \1.1 ~- l~ ~"i 6AC.A~~ I~Q + = ~ Insulated Floors ll-l4\ ,..J ~~ ~w~c.£ ,~j + 7.S.6 = JO + = Non-solar Glazing ::)M1U: 6~1-f"9 "'1oJ~: !..A>--€ 5'2.. + ~\ = Ii + = Doors ~("(AL.. -"OOL !:l WlA"", CtfC.£ 40 + "5.q = ., + = !2~ Btu/oF-h Total

B. Foundation Perimeter Heat Loss Heat Loss Factor Heat Description Perimeter [Table B) Loss Slabs-on·Grade ~-~ D\Il"S".OC. £~\I.16 140 X o.~C> = 56 Heated Basements X = Unheated Basements X = Perimeter Insulated Crawlsl2aces X = 5..,6 Btu/OF·h Total

C. Infiltration Heat Loss 11..,~~J X 0·50 X .018 = '. '.2- Btu/oF-h Building Air Changes Volume per Hour

5. \ 2-~ D. Total Heat Loss per Square Foot 24 X TZ-I + ''':;oLf = Btu/DO-sf Total Heat Loss Floor Area (A+B+C)

E. Conservation Performance Level

5. \ 'l-"L X 4 ~1L-t X O,'?t1 "'!.t.5?,7..2- Btu/yr-sf Total Heat Heating Degree Heating Degree Loss per Days [Table C) Day Multiplier Square Foot [Table C)

F. Comparison Conservation Performance (From Previous Calculation or from Table 0) 16Ct'1. Btu/yr-sf

Compare Line E to Line F

Salem, Oregon 45 Worksheet U: Auxiliary Heat Performance Level

A. Projected Area of Passive Solar Glazing

Solar System ROU~h Frame Net Area Adjustment Projected Reference Code rea Factor Factor [Table E) Area "')6C.-\. 86. X 0.80 X Q. tt f3 = 6,{ ";5C -I 2dG X 0.80 X 17· tiG = I~~ X 0.80 X = X 0.80 X = X 0.80 X = X 0.80 X = X 0.80 X = '2-'\6 "Z..:J 7... sf Total Area Total Projected Area 2-"1'Z. + = d. ,~ Total '''04Floor Total Projected Projected Area Area per Area Square Foot

B. Load Collector Ratio 24 X '12.-1 + '2..."12- '33 Total Total = Heat Loss Projected [Worksheet I] Area

C. Solar Savings Fraction System Solar Savings Solar System Projected Fraction Reference Code Area [Table F] -"c;..c . \ 6" X D.V'\ = 7>'.01 2:;; c\ ( l. :> X Q.">' = 5,0, '" X = X = X = X = X = :Z6.~~ + 1->"Z... = 1:'. 3~ Total Total Solar Projected Savings Area Fraction

D. Auxlliary Heat Performance Level

[1 - c.>(j X V5z..:z...2... 1'l{.95 Btu/yr-sf Solar Conservation = Savings Performance Fraction Level [Worksheet I, StepE]

E. Comparative AwdUary Heat Performance (From Previous Calcula~on or from Table G) »~"'!{ Btulyr-sf

Compare Line D to Line E

Salem, Oregon 46 Worksheet m: Thermal Mass/Comfort

A. Heat Capacity of Sheetrock and Interior Furnishings Unit Total Heat Heat Floor Area Capacity Capacity

Rooms with Direct Gain Lib4 X 4.7 = 'Z..l ~! SQaces Connected to Direct Gain Se!C8S :14'1. X 4.5 = /..t?--1.l b '14" Z- Btul"F Total

B. Heat Capacity of Mass Surfaces Enclosing Direct Gain Spaces Unit Heat Mass Description capaci~ Total Heat (include thickness) Area [Table ] Capacity Trombe Walls X 8.8 = Water Walls X 10.4 = Exoosed Slab in Sun X 13.4 = \"160 EXJ)Qsed Slab Not in Sun X 1.8 = 7...... ( X = X = X = \ to L-"t Btu/OF Total

C. Heat Capacity of Mass Surfaces Enclosing Spaces Connected to Direct Gain Spaces Unit Heat Mass Description Total Heat (include thickness) Area [TC=ci~ Ie ] Capacity Trombe Walls X 3.8 = Water Walls X 4.2 = , \ ~ ~A~, ""l~ 4" X 1·-> = L1 '.' X = X = L4 \ : Btu/OF Total

D. Total Heat Capacity ~yt{r Btu/OF (A+B+C)

E. Total Heat Capacity per Square Foot BLi I\(J + \ 5CL-/ = 5.(- Btu/OF-sf Total Heat Conditioned Capacity Floor Area

F. Clear Winter Day Temperature Swing Total Comfort PtWlected Area Factor orksheet II] [Table I] Direct Gain 65 X JiD ~11 JC' 6 SunsQaces or ) X 'L6O = y-z..:18 \' \ \. 'Z... Vented Trombe Walls 1~<7 1 () + B~"c = Total Total Heat Capacity

G. Recommended Maximum Temperature Swing "\ J Compare Line F to Line G

Salem, Oregon 47 Worksheet IV: Summer Cooling Performance Level

A. Opaque Surfaces Radiant Barrier Absorp- Heat Gain Heat Loss Factor tance Factor Description [Worksheet I) [TableJ) [Table K) [Table L) Load Ceilings/roofs '10 X 1.00 X t'.'-'!I X U:3 = :rl.l I: X 1.0" X s:2. ~-r X U·J = 1...'" X X X = Walls ~~ X na O.{O X \:l.<;; = L·Hb X na X = Doors 1 X na ". ~C' X 1'1.7' = \2... '()O~ kBtu/yr Total

B. Non-solar Glazing Rough Frame Net Area Shade Factor Heat Gain Description Area Factor [Table M] Factor [Table L) Load

North Glass Lib X 0.80 X a·~~ X n·/! = 25~ East Glass b. X 0.80 X t-~ X Y'·"Z... = Itt 8 West Glass 6 X 0.80 X '.0 Co X 4 \. L.I = '''4 Sk~lights X 0.80 X X = "~5' kBtu/yr Total

C. Solar Glazing Solar System Rough Frame Net Area Shade Factor Heat Gain Description Area Factor [Table M) Factor [Table L) Load

Direct Gain 6..e X 0.80 X 6.G:~ X 3(·t.t = 7.:Z.~5' Storage Walls X 0.80 X X = 1 ' t , r SunsQace l..€'~ X 0.80 X O.~B X " . = & X 0.80 X X = Z,.qlb kBtu/yr Total

D. Internal Gain 1I1t) +( L.n O X :3 ) = '2-$40 kBtulyr Constant Variable Number o! Component Component Bedrooms [Table N] [Table N)

E. Cooling Load per Square Foot 1,000 X 6,1...0 + !~OLf = Y'-t~B Btu/yr-s! (A+B+C+D) Floor Area

F. Adjustment for Thermal Mass and Ventilation 14Lf~o Btu/yr-s! [Table 0) ~o NlGl<\T v<=,,,,,, ,LAT\corJ I 'Ie. s C..Gl c...ltJ(- IAt.)

G. Cooling Performance Level ~ Btu/yr-s! (E -F)

H. Comparison CooHng Performance (From Previous Calculation or from Table P) 3":7 J"Z.. Btu/yr-s!

Compare Line G to Line H

Salem, Oregon 48

Table A-Equivalent Thermal Table A-continueci •• Table D-Base Case Conse"ation Performance of AsaembUes Performance (Btu/yr-s1) R-values (hr-F-sf/Btu) Base Case 36,001 AS-Doors Solid wood with 2.2 Al-C.HlngsiRoof. Weatherstripping Table E-ProJected Area Attic Inin R-value Metal with rigid Adjustment Factors Construction R-3O R-38 R-49 R-60 foam core Degrees off Solar System Type 27.9 35. 46.9 57.9 True 00, TW, SSA SSB, South WW, SSC SSD SSE Framed Insulation ~e Construction R-19 R-22 ~~ R-38 Table B-Perimeter Heat Lo.. o 1.00 0.77 0.75 2x6 at 16"oc 14.7 15.8 16.3 Facton for Slabs-on-Grade and 5 ~: 0.76 0.75 2x6 at 24"oc 15.3 16.5 17.1 BBBements(Btu/b-F-ft) 10 0.75 0.74 2x8 at 16"oc 17.0 18.9 20.6 21.1 Heated 15 0.74 0.73 Unheated Insulated 20 0.94 0.72 0.70 2x8 at 24"oc 17.6 19.6 ~ 22.2 Perimeter Slabs-on- Base- Base- Crawl­ 25 0.91 0.69 0.68 2xl 0 at 16"oc 18.1 20.1 24. 25.7 Insulation Grade men1S men1S spaces 30 0.87 0.66 0.65 2xl0 at 24"oc 18.4 20.7 .5 26.8 1.1 1.1 2x12 at 16"oc 18.8 21.0 25.5 30.1 ~e 1.3 2x12 at 24"oc 19.0 21.4 27.3 31.4 0.8 0.7 0.6 R-7 0.7 0.6 0.5 R-ll ~0.3 0.6 0.5 0.4 R-19 0.2 0.4 0.5 0.3 Table F-solar System Saving A2-FrarnecI Walls R-30 0.1 0.3 0.4 0.2 Fractions Single Wall Insulation R-value Framing R-l1 R-13 R-19 R-25 Fl-Dlrsct Gain 2x4 at 16"oc 12.0 13.6 Table C-Hea~ Degree Days load DGCl "i)6U- DGC3 2x4 at 24"oc 12.7 13.9 @ (F-day) Collector Double low-e R-9 Ni~ht 2x6 at 16"oc 14.1 15.4 7.. ~ 19.2 Ratio Glazing Glazing Insulation 2x6 at 24"oc 14.3 15.6 19.8 400 0.04 0.05 0.06 Double ~ ce. -> f\.(£"\'n' "'" 6 C1-H.atlng Degree Day. (Bas. 65°F) 300 0.05 0.06 0.08 Wall Total Thickness (inches) 200 0.08 0.09 0.11 Framing 8 10 12 14 Salem ~ 150 0.10 0.12 0.15 Cottage Grove 4,926 100 0.15 0.17 0.21 25.0 31.3 37.5 43.8 Corvalis 4,987 80 0.17 0.20 0.25 Dallas 4,985 60 0.21 0.25 0.31 The R-value of insulating sheathing should be added to Eugene 4,799 the values in this table. 50 0.23 0.29 0.35 McMinnville 4,977 45 0.25 0.31 0.38 Stayton 4,836 40 0.26 0.33 0.41 35 H.'" -z.. ~ 0.36 0.45 A3-lnsulated Floors 30 (OJ?' 0.40 0.50 In~n R-value 25 0.34 0.44 0.55 Framing R-ll 8:19' R-3O R-38 C2-Heatlng Degree Day Multiplier 20 0.37 0.49 0.62 15 0.41 0.56 0.70 2x6s at 16"oc 18.2 23.8 29.9 Passive Solar 2x6s at 24"oc 18.4 24.5 31.5 Heat Loss Glazing Area per 2x8s at 16"oc 18.8 24.9 31.7 36.0 per Square per Square Foot 2x8s at 24"oc 18.9 33.1 37.9 Foot .00 .05 .10 .15 .20 F2-Trombe Walla 2xl0 at 16"oc 19.3 . 33.4 38.1 1.13 1.14 1.15 1.15 TWF3 TWA3 TWJ2 TWI4 .1 34.4 39.8 12.00 1.12 2xl 0 at 24"oc 19.3 ~ 11.50 1.11 1.12 1.13 1.14 1.15 load Unvented Vented Unvented Unvented 2x12 at 16"oc 19.7 26.5 34.7 39.8 11.00 1.10 1.12 1.12 1.13 1.14 Collector Non- Non- Selec- Night 2x12 at 24"oc 19.6 26.7 35.5 41.2 10.50 1.09 1.11 1.12 1.13 1.14 Ratio selective selective tive Insulation These R-values indude the buffering effect of a 10.00 1.08 1.10 1.11 1.12 1.13 400 0.03 0.05 0.03 0.00 ventilated crawlspace or unconditioned basement. 9.50 1.07 1.09 1.10 1.11 1.12 300 0.04 0.06 0.05 0.02 9.00 1.06 1.07 1.09 1.10 1.11 200 0.06 0.09 0.10 0.06 8.50 1.04 1.06 1.08 1.09 1.10 150 0.09 0.12 0.15 0.10 8.00 1.03 1.05 1.06 1.08 1.09 A4-Wlndow. 100 0.13 0.16 0.22 0.17 7.50 1.01 1.03 1.05 1.07 1.08 80 0.15 0.19 0.27 0.21 Metal 7.00 0.99 1.01 1.03 1.05 1.07 60 0.19 0.23 0.34 0.27 Standard Frame wI 6.50 0.97 1.00 1.02 1.04 1.05 50 0.22 0.26 0.38 0.32 Wood Metal Thermal 6.00 0.94 0.97 1.00 1.02 1.04 45 0.24 0.27 0.41 0.34 Frame Frame Break "t.., 5.50 0.91 0.95 0.98 ~ 1/1.02 40 0.26 0.29 0.44 0.38 ~.' ~5.oo 0.87 0.91 0.95 0.98· 1.01 35 0.28 0.32 0.48 0.41 Double 4.50 0.82 0.87 0.92 0.96 0.99 1/4" space 1.8 1.4 1.5 30 0.31 0.35 0.52 0.45 4.00 0.77 0.83 0.88 0.93 0.96 25 0.35 0.38 0.58 0.51 112" space 2.1 1.6 1.8 3.50 0.70 0.78 0.84 0.89 0.93 low-e ~ 2.2 3.0 20 0.39 0.43 0.64 0.57 3.00 0.60 0.71 0.79 0.85 0.90 15 0.45 0.49 0.72 0.66 Triple 2.50 0.48 0.62 0.73 0.80 0.86 1/4" space 2.7 1.8 2.1 2.00 0.34 0.51 0.64 0.74 0.81 1/2" space 3.3 2.2 2.7 These R-values are for the entire rough frame window opening. When storm sash is added, an additional 1.1 may be added. One half the R-value of mov~le insulation may also be added, when appropnate.

Salem. Oregon 49

F3-Water Walls Table B-Unit Beat Capacities Table L-Beat Gain Factors (Btu/F-s1) Load WWA3 WWB4 WWC2 Ceiling/roofs /26.3\ Collector No Night Night Selective Walls and Doors ! 13.5 Ratio Insulation Insulation Surface North Glass \ 13.0 H1-Mass Enclosing Direct Gain East Glass , 41.2 0.04 0.00 0.01 SUrface. 400 Spec .. West Glass U1.~ 300 0.06 0.03 0.04 Skylights -n:&- 200 0.09 0.08 0.09 Thickness (inches) 1 2 3 4 6 8 12 Direct Gain Glazing (36.4 150 0.12 0.13 0.13 Material Trombe Walls and 1.1 100 0.17 0.21 0.21 Poured Cone. 1.8 4.3 6.7 8.8 11.3 11.5 10.3 Water Walls 80 0.20 0.26 0.26 Cone. Masonry 1.8 4.2 6.5 8.4 10.2 10.0 9.0 Sunspaces 60 0.25 0.33 0.33 Face Brick 2.0 4.7 7.1 9.0 10.4 9.9 9.0 SSA1 10.7 50 0.28 0.38 0.37 Flag Stone 2.1 4.8 7.1 8.5 8.6 8.0 7.6 SSB1 1M .. 45 0.30 0.41 0.40 Buifder Brick 1.5 3.7 5.4 6.5 6.6 6.0 5.8 SSC1 (1.1' 40 0.32 0.45 0.43 Adobe 1.3 3.2 4.8 5.5 5.4 4.9 4.8 SSD1 fO.7 35 0.35 0.49 0.47 0.38 0.53 0.52 Hardwood 0.4 1.4 1.8 1.7 1.5 1.5 1.5 SSE1 10.7 30 Water 5.2 10.4 15.6 20.8 31.2 41.6 62.4 25 0.41 0.59 0.57 20 0.46 0.65 0.63 15 0.52 0.74 0.71 H2-Roorns with no Direct Solar Gain Table M-8bacling Factors Thickness (inches) Projection F4-Sunspaces Material 2 3 4 6 8 12 Factor South East North West Load Poured Conc. 1.7 3.0 3.6 3.8 3.7 3.6 3.4 0.00 If]o) Collector Sunspace Type Conc. Masonry 1.6 2.9 3.5 Jf., 3.6 3.4 3.2 1.00 1.00 Ratio SSA1 SSB1 SSC1 SSD1 SSE1 Face Brick 1.8 3.1 3.6 3.5 3.4 3.2 0.20 0.88 ~.96 i#- 0.95 1.9 3.1 3.4 3.4 3.2 3.1 3.0 0.40 0.59 0.86 =8f' 0.85 400 0.10 0.08 0.04 0.10 0.07 FI~Stone Buider Brick 1.4 2.6 3.0 3.1 2.9 2.7 2.7 0.60 0.42 0.76 0.71 0.74 300 0.12 0.10 0.05 0.12 0.09 0.80 0.32 0.64 0.61 0.63 200 0.15 0.12 0.08 0.16 0.13 Adobe 1.2 2.4 2.8 2.8 2.6 2.4 2.4 Hardwood 0.5 1.1 1.3 1.2 1.1 1.0 1.1 1.00 0.30 0.56 0.51 0.54 150 0.18 0.15 0.11 0.20 0.16 1.20 0.28 0.47 0.41 0.45 100 0.22 0.19 0.15 0.25 0.21 80 0.25 0.21 0.18 0.29 0.24 MV~\.pL'i "\\-1 0.60 f'cnt. LcW-~, 60 0.29 0.25 0.22 0.33 0.28 50 0.32 0.28 0.24 0.36 0.31 Table I-Comfort Factors (Btu/sf) 45 0.34 0.29 0.26 0.38 0.33 Table N-Internal Gain Factors 40 0.36 0.31 {S.8 0.41 0.35 Direct Gain 770 35 0.38 0.33 0.43 0.37 Constant Component r1.13Q kBtu/yr ..1 ! Sunspaces and 260 30 0.41 0.36 . 0.46 0.40 Variable Component '@OJ kBtu/yr-BR 25 0.44 0.39 0.36 0.50 0.43 Vented Trombe Walls 20 0.48 0.43 0.40 0.54 0.47 15 0.53 0.48 0.46 0.59 0.52

Table J-Radiant Barrier Factors Table o-Thermal Mass and Ventilation Adjustment (Btu/yr-s1) Radiant Barrier 0.75 Total Heat Night Night No Night No Night No Radiant Barrier @Q) Capacity Vent w/ Vent w/ No Vent w/ Vent wINo per SF Ceil. Fan Ceil. Fan Ceil. Fan Ceil. Fan 0.0 3,570 2,020 2,700 850 1.0 4,760 3,350 3,900 2,170 Table K-80lar Absorptances 2.0 5,150 4,030 4,280 2,850 3.0 5,270 4,380 4,400 3,200 Color Absorptance 4.0 5,310 4,560 4,440 3,380 Gloss White kQ 5,320 4,650 ~. 3,470 Semi-gloss White '6.0 5,330 4,700 4,46().t 3,520 Light Green 7.0 5,330 4,720 4,460 3,540 Kelly Green 8.0 5,330 4,730 4,460 3,560 i 9.0 5,330 4,740 4,460 3,560 Medium Blue 0.51 Medium Yellow 0.57 10.0 5,330 4,740 4,460 3,570 Medium Orange 0.58 Total heat capacity per square foot is calculated on Medium Green 0.59 Worksheet III, Step E. Light Buff Brick 0.60 Bare Concrete Red Brick Medium Red ~0:00 Medium Brown 0.84 Table P-Base Case CooUng Dark Blue-Grey 0.88 Performance (Btu/sf-yr) Dark Brown 0.88 Base Case 3,532

Table G-Base Case AuziUary Beat Performance (Btu/yr-sf) Base Case 33,596

Salem. Oregon 50 WORKED EXAMPLE

Salem. oregon PASSIVE SOLAR DESIGN STRATEGIES

Passive Solar: design and construction Suntempering: a modest fonn of a direct techniques which help a building make gain passive solar system; suntempered use of solar energy by non-mechanical houses increase south-facing glass to means. as opposed to active solar about 7 percent of a total floor area. but techniques which use equipment such add no thermal mass beyond the "free" as roof-top collectors. mass already in a typical house -­ gypsum board. framing. conventional Glossary Pbase-Cbange Materials: materials furnishings and floor coverings. such as salts or waxes which store and release energy by changing "phase": most Temperature SwiDg: a measure of the AwdUary Heating System: a tenn for store energy when they tum liqUid at a number of degrees the temperature in a the system (gas. electric. oil. etc.) which certain temperature and release energy space will vary during the course of a provides the non-solar portion of the when they tum sclid at a certain sunny winter day without the house's heating energy needs. referred to temperature. but some remain solid but operating; an indicator of the amount of as the "auxilary heat." undergo chemical changes which store thermal mass in the passive solar and release energy. Phase change system. British Thermal Unit (Btu): a unit used materials can be used as thermal mass to measure heat. One Btu is about equal but few products are commercially Thermal Mass: material that stores to the heat released from burning one available at this time.. energy. although mass will also retain kitchen match. coolness. The thermal storage capacity Purchased Energy: although the terms of a material is a measure of the Conservation: in addition to energy are often used interchangably. a house's material's ability to absorb and store conservation in the general sense. the "purchased energy" is generally greater heat. Thermal mass in passive solar tenn is used to refer to the non-solar. than its "auxilary heat" because heating buildings is usually dense material such energy-saving measures in a house systems are seldom 100% effiCient. and as brick or concrete masonry. but can which are prlmarlly involved with more energy is purchased than is also be tile. water. phase change improving the to guard actually delivered to the house. materials. etc. against heat loss -- the insulation. the air infiltration reduction measures. and R-Value: a unit that measures the Thermal Storage WaD: a passive solar so forth. resistance to heat flow through a given system also sometimes called Trombe material. The higher the R-value, the Wall or indirect gain system; a south­ Direct Gain: a passive solar system in better insulating capability the material facing glazed wall. usually made of which the sunlight falls directly into the has. The R-value is the reciprocal of the masonry but can also be made of space where it is stored and used. U-value. (see below) containers of water.

Glazing: often used interchangeably with Radiant Barrier: reflective material used Trombe Wall: a thermal storage wall. window or glass. the tenn actually refers in hot climates to block radiant heat. referred to by the name of its inventor. to specifically just to the clear material particularly in a house's roof. Dr. Felix Trombe. which admits sunlight. and so can also be plastic. Double and triple glazing Shading Coefficient: a measure of how U-Value: a unit representing the heat refer to two or three panes. much solar heat will be transmitted by a loss per square foot of surface area per glazing material. as compared to a single degree OF of temperature difference (see Indirect Gain: a passive solar system in pane of clear uncoated glass. which has R-value above). which the sunlight falls onto thermal a shading coefficient (SC) of 1. For mass which is positioned between the example, clear double-pane glass might glazing and the space to be heated. i.e. a have an SC in the range of .88. Thermal Storage Wall or Trombe Wall. Reflective glass might have SC's of .03- .06. In general. lower shading Low-Emissivity: the tenn refers to a coefficients are desirable when heat gain surface's ability to absorb and re-radiate is a problem. heat. A material with a low emissivity absorbs and re-radiates relatively small Sunspace: passive solar system amounts of heat. Low-emissivity or "low­ sometimes also referred to as an isolated e" glass sandwiches a thin layer of gain system. where sunlight is collected metallic film or coating between two and stored in a space separate from the panes of glass. The low-e glass blocks living space. and must be transferred radiant heat. so it will tend to keep heat there either by natural convection or by energy inside the house during the fans. winter. and kcep heat energy outside the house during the summer.

Salem. Oregon 52 APPENDIX

References e. Glazings: The Design Considerations Insulation Aren't As Clear As Glass f. Ideas for Passive Solar Remodeling 10. NAHB Insulation Manual. National g. Passive Homes in the Marketplace Association of Home Builders, National General (Class C Studies) Research Center. Available from NAHB h. Daylightlng in Commercial Bookstore, 15th and M Streets N.W., 1. A Sunbuilder's Primer, Solar Energy Buildings Washington, D.C. 20005. (202) 822- Research Institute. 1. Human Comfort and Passive Solar 0200. Design 2. Passive: It's a Natural, Solar Energy j. Passive Design for Commercial 11. Lischkoff, James K. The Airtight Research Institute. Buildings House: Using the Airtight Drywall k. Passive Solar: Principles and Approach, Iowa State University 3. The Passive Solar Construction Products Research Foundation. Available for Handbook, Steven Winter 1. Increasing Design Flexibility $14.95; Attn: Sarah Terrones, EES Associates/Northeast Solar Energy m. Utilities and Passive: Predicting the Building, Iowa State University, Ames, Center/National Concrete I\,fasoruy Pay-off IA 50011 Association/Portland Cement Association/Brick Institute of America. 12. Spears, John. Radon Reduction in Available for $29.95 plus $3.00 New Construction, Interim Guide, handling, from Steven Winter Associates, National Association of Home Builders, Attn: Publications, 6100 Empire State Environmental Protection Agency OPA Building, New York, N.Y. 10001 87-009, , August 1987. Available from the EPA or the NAHB Bookstore, 15th 4. Suntemperlng in the Northeast. Steven and M Streets N.W .. Washington, D.C. Winter Associates. Available from them 20005. (202) 822-0200. at the address above for $9.50.

5. Passive Solar Design Handbook, AppUances Volume I, II. III. Available from National Technical Information SelVice, U.S. Dept. 13. Saving Energy and Money with Home of Commerce, 5285 Port Royal Road, Appliances, Environmental Science Springfield, Va. 22161, $32.00 each for I Department, Massachusetts Audobon and II, $12.00 for III. Society/American Council for an Energy Efficient Economy. Available for $2.00 6. Balcomb, J.D., et al. Passive Solar apiece from ACEE, 100 1 Connecticut Heating Analysis. This volume Ave. N.W., Suite 535, Washington D.C. supercedes and expands Volume III of 20036 the Passive Solar Design Handbook (Ref. 5). Available from ASHRAE, 14. The Most Energy EJftctentAppliances, Publications, 1791 full1e Circle NE, 1988 Edition, ACEEE, $2.00 apiece at Atlanta, Ga. 30329, $30.00 for ASHRAE address above. members, $60.00 for non-members.

7. Lfuing With the Sun (for consumers) and BuUding With the Sun (for builders), PPG Industries.

8. The Passive Solar Iriformation Guide, PSIC.

9. Passive Solar Trends. Technical briefs fromPSIC. a. Infiltration in Passive Solar Construction b. The State of the Art in Passive Solar Construction c. Passive Solar in Factory-Built Housing d. Radiant Barriers: Top Performers in Hot Climates

Salem, Oregon PASSIVE SOLAR DESIGN STRATEGIES

Site Planning Sunspaces More Information

15. BuUder's Guide to Passive Solar 17. Jones, Robert W. and Robert D. Conservation and Renewable Energy Home Design and Land Development, McFarland. The Sunspace Primer. A Inquiries and Referral Service National Fenestration Council. Available Guide Jar Passive Solar Heating, available (CAREms) 1-800-523-2929, Renewable for $12.00 from NFC. 3310 Harrison, for $32.50 from Van Nostrand Reinhold, Energy Information, Box 8900, Silver White Lakes Professional Building, 115 5th Avenue, New York, N.Y. 10003 Spring, Md. 20907 Topeka, KS. 66611 18. Greenhousesfor living, from Steven National AIIsociation of Home Builders 16. Site PlanningJorSolar Access, U.S. Winter Associates, Attn: Publications, Attention: Technical Services Department of Housing and Urban 6100 Empire State Building, New York, 15th & M Streets N.W. Development/American Planning N.Y. 10001. $6.95. Washington, D.C. 20005 Association. Available for $6.50 from Superintendent of Documents, U.S. 19. ConceptN, from Andersen National Concrete Masonry Government Printing Office, Washington Corporation, Bayport, MN. 55003, $6.95. AIIsoclation D.C. 20402 Attention: Energy Engineer 20. Passive Solar Greenhouse Design and 2302 Horse Pen Road Construction, Ohio Department of Herndon, Va. 22070 Energy/John Spears, 8821 Silver Spring, Md., 20910. Brick Institute of America Attention: Energy Engineer 11490 Commerce Park Drive Suite 300 Reston, Va. 22091

Solar Energy Research Institute Attention: Solar Buildings 1617 Cole Boulevard Golden, Co. 80401

Passive Solar Industries Council 1511 K Street Suite 600 Washington, D.C. 20005

Salem, Oregon 54 SUMMARY FOR SALEM, OREGON

Example Tables Examples of Heat Energy Savings Passive Solar-Direct Gain Examples of Heat Energy Savings 1,500 sf Single Story House Added Insulation Base 1,500 sf Single Story House Case 20% 40% 60% R·values Base Ceiling/Roof 28 31 37 46 Case 20% 40% 60% Walls 16 18 22 27 R·values Floor 18 20 24 30 Ceiling/Roof 28 33 40 51 Glass 1.8 1.8 1.8 2.7 Walls 16 19 23 29 Floor 18 22 26 33 Air Changes/Hour 0.67 0.60 0.45 0.41 Glass 1.8 1.8 2.7 3.3 Glass Area (percent of total floor area) Air ChangeslHour 0.67 0.56 0.53 0.40 West 3.0% 2.0% 2.0% 2.0% North 3.0% 4.0% 4.0% 4.0% Glass Area (percent of total floor area) East 3.0% 4.0% 4.0% 4.0% West 3.0% 2.0% 2.0% 2.0% South 3.0% 7.5% 9.3% 12.0% North 3.0% 4.0% 4.0% 4.0% East 3.0% 4.0% 4.0% 4.0% Added Thermal Mass South 3.0% 3.0% 3.0% 3.0% Percent of Floor Area 0.0% 3.1% 13.6% 30.0%

Percent Solar Savings Solar System Size (square feet) 7% 8% 10% 14% South Glass 45 112 139 180 Added Thermal Mass 0 47 204 450 Performance (Btu/yr-sf) Conservation 36,001 30,039 23,343 16,363 Percent Solar Savings Auxiliary Heat 33,596 27,580 20,879 14,059 7% 16% 21% 29% Cooling 3,532 1,912 1,784 787 Performance (Btu/yr-sf) Conservation 36,001 32,800 26,426 19,933 Auxiliary Heat 33,596 27,534 20,792 14,041 Cooling 3,532 3,211 3,753 3,637

Examples of Heat En~y Savings Summary: Insulation and tightness have been increased. South- Suntempe facing glazing has been substantially increased. For these 1,500 sf Single Story House examples, added mass area is assumed to be six times the added south glass area. Base Case 20% 40% 60% R·Values Ceiling/Roof 28 32 38 49 Walls 16 18 22 28 Floor 18 21 25 31 Glass 1.8 1.8 1.8 2.7

Air Changes/Hour 0.67 0.61 0.57 0.43

Glass Area (percent of total floor area) West 3.0% 2.0% 2.0% 2.0% North 3.0% 4.0% 4.0% 4.0% East 3.0% 4.0% 4.0% 4.0% South 3.0% 6.7% 6.7% 6.7%

Solar System Size (square feet) South Glass 45 100 100 100

Percent Solar Savings 7% 14% 17% 22%

Performance (Btu/yr-sf) Conservation 36,001 32,367 25,321 18,052 Auxiliary Heat 33,596 27,543 20,801 14,054 Cooling 3,532 2,929 2,907 1,915 Summary: Insulation values and tightness of the house (as measured in ACH) have been increased. The window area has been slightly decreased on the west, increased slightly on the east and north, and increased significantly on the south. PASSIVE SOLAR DESIGN STRATEGIES

Examples of Heat Energy Savings Examples of Heat Energy Savings Passive Solar-Sunspace Passive Solar-Thermal Storage Wall 1,500 sf Single Story House 1,500 sf Single Story House

Base Base Case 20% 40% 60% Case 20% 40% 60% R-Values R-Values Ceiling/Roof 2B 30 36 44 Ceiling/Roof 2B 2B 33 39 Walls 16 lB 21 25 Walls 16 16 19 22 Floor 18 20 23 28 Floor 18 18 21 25 Glass 1.B 1.8 1.8 2.7 Glass 1.B 1.8 1.8 2.7

Air Changes/Hour 0.67 0.65 0.49 0.45 Air Changes/Hour 0.67 0.63 0.55 0.56

Glass Area (percent of total floor area) Glass Area (percent of total floor area) West 3.0% 2.0% 2.0% 2.0% West 3.0% 2.0% 2.0% 2.0% North 3.0% 4.0% 4.0% 4.0% North 3.0% 4.0% 4.0% 4.0% East 3.0% 4.0% 4.0% 4.0% East 3.0% 4.0% 4.0% 4.0% South (windows) 3.0% 3.0% 3.0% 3.0% South 3.0% 3.0% 3.0% 3.0% Sunspace 0.0% 7.2% 10.9% 17.0% Thermal Storage Wall 0.0% 6.7% 10.9% 17.0%

Solar System Size (square feet) Solar System Size (square feet) South Glass 45 45 45 45 South Glass 45 45 45 45 Sunspace Glass 0 107 164 255 Thermal Storage Wall 0 101 163 255 Sunspace Thermal Mass 0 321 492 765 Percent Solar Savings Percent Solar Savings 7% 22% 33% 47% 7% 19% 27% 38% Performance (Btu/yr-sf) Performance (Btu/yr-sf) Conservation 36,001 35,698 31,227 26,421 Conservation 36,001 34,198 28,554 22,532 Auxiliary Heat 33,596 27,531 20,755 13,957 Auxiliary Heat 33,596 27,478 20,765 13,976 Cooling 3,532 2,110 1,964 1,054 Cooling 3,532 2,050 1,920 989 Summary: In the case of a Thermal Storage Wall, south-facing Summary: Insulation and tightness have been increased. North glazing and thermal mass are incorporated together. The estimates and east-facing glazing have been increased slightly. The here assume a 12-inch thick concrete Thermal Storage Wall with a sunspace assumed here is semi-enclosed (surrounded on three selective surface and single glazing. sides by conditioned rooms of the house, as in Figure SSD 1 of the worksheets), with its south glazing tilted at 50 degrees. The common wall is a thermal mass wall made of masonry. Sunspace glazing is assumed to be double. Cooling Potential Basecase 3,532 Btu/yr-sf

Energy Savings Percent Strategy (Btu/yr-sf) Savings

No Night Ventilation 1 without ceiling fans 0 0% with ceiling fans 1,430 40

Night Ventilation 1 without ceiling fans 1,180 33 with ceiling fans 2,300 65

High Mass2 without ceiling fans 360 10 with ceiling fans 060 2

With night ventilation, the house is ventilated at night when temperature and humidity conditions are favorable.

2 A "high mass" building is one with a thermal mass area at least equal to the house floor area.

Salem. Oregon 56 APPENDIX

Technical Basis for Los Alamos National Laboratory with Annual Auxiliary Heat funding from the U.S. Department of (Worksheet n) the Builder Energy Solar Buildings Program. See the Guidelines references for more information. The tables of passive solar savings fractions are calculated using the solar Annual Heat Loss load ratio (SLR) method (references 1 and (Worksheet 1) 2). Monthly solar savings fraction (SSF) How the Builder values are determined using correlation fits to the results of hourly computer Guidelines Were The heat-loss calculation is based on a simulation calculations for a variety of straightforward summation of the Produced climates. These 12 values are converted traditional elements that make up the into an annual value and entered into The text of the Builder Guidelines book building heat-loss coefficient (excluding worksheet Tables FI-F4. The SLR is generated by merging two computer the solar components). The worksheet method gives answers that agree within files. The first is a word-processor file procedure estimates the annual heat loss about 5% of the hourly computer containing the text; It does not change by multiplying the heat-loss coefficient simulations and within 11% of the from location to location. The second by annual degree days (times 24 to measured passive solar performance of contains numbers and text and is convert from days to hours). Degree days 55 bUildings monitored under the Solar location dependent. This second file is for each month were determined using Buildings Program. The SSF estimates produced by running a computer an appropriate base temperature that account properly for both solar gains program that calculates performance accounts for an assumed thermostat and heat losses through the solar numbers based on long-term monthly setting of 70 degrees, an assumed aperture and, thus, correct for omitting weather and solar data compiled by the internal heat generation of 36 Btu/day the solar components from the National Oceanic and AtmospheriC per sq ft of floor area, and the total calculation of annual heat loss. Administration for a particular location. building loss coefficient. This forms the The merge operation slots the numbers basis of the table of heating degree day and text in the second file into their multipliers. The result of the worksheet Temperature Swing correct locations in the first file. This is is an estimate of the annual heat (Worksheet III) then laser printed to produce the required to maintain comfort, excluding camera-ready manuscript. both positive and negative effects The temperature swing estimate on resulting from the solar components. In worksheet III is based on the diurnal More than a Decade of this estimate, no solar heating credit is heat capacity (dhc) method (reference 3). given to east, west, and north windows, The method is an analytic procedure in Experience because it is assumed that these will be which the total heat stored in the protected by vegetation or other shading building during one day is estimated by The concentrated effort of research, in accordance with the Builder Guideline summing the effective heat storage design, construction, monitoring, and recommendations. This is a conservative potential of the all the various materials evaluation of actual buildings that assumption because there will always be in the building for a 24-hour periodic started at the First Passive Solar some solar gain through these windows. cycle of solar input. Rooms with direct Conference in Albuquerque in 1976 has gain are assumed to have radiative continued up to the present. It is coupling of the solar heat to the mass. estimated that more than 200,000 Rooms connected to rooms with direct passive solar homes have been built in gain are assumed to have convective the United States during this time. This coupling, which is rather less effective, wealth of experience has been reviewed especially for massive elements. The dhc by SERI, the Technical Committee of of the sheetrock, framing, and furniture PSIC, and by the Standing Committee on is approximated as 4.5 or 4.7 Bluj"F per Energy of the National Association of sq ft of floor area. Worksheet Tables HI Home Builders and is distilled into these and H2 list the increased value of Guidelines. diurnal heat capacity for various conventional materials that are often Analysis Procedures used to provide extra heat storage, assuming these materials replace The analysis procedures used sheetrock. throughout the Guidelines were developed using simple, well-established methods for estimating the performance of passive solar heating and natural cooling strategies. These procedures (described below) were developed at the PASSIVE SOLAR DESIGN STRATEGIES ~{

The only numbers in worksheet III underestimates very large cooling loads or minus 20%. the result could be that are location dependent are the in poorly designed buildings. adjusted. based on a ratio of cooling comfort factors. taken from Table I. The The adjustment factors for degree days. However. this adjustment is dlrcct -gain comfort factor is 61% of the ventilation properly account for not done automatically within the solar gain transmitted through vertical. maintaining comfort in hot and humid worksheet. south-facing double glazing on a clear climates. Ventilation is restricted to January day. The driving effect of times when the outside dew-point suns paces and vented Trombe walls is temperature is less than 62 OF. This Getting Data assumed to result in one-third this restriction avoids ventilation when high Heating and cooling degree-day data can value. based on data from monitored humidity might cause discomfort. be obtained from the National Climatic buildings. The origin of the 61 % factor is Center. Asheville. NC. Refer to described in the references. Notfor Sizing Equipment Climatography of the United States No. 81 which lists monthly normals for the Annual Auxiliary Cooling All heating and cooling values given in period 1951-1980 on a state-by-state (WorksheetIV1 the Builder Guidelines Tables and basis. More than 2400 locations are numbers calculated using the listed in this data base. The purpose of including the summer worksheets are for annual heat delivered cooling estimates in the Builder or removed by the mechanical heating or Guidelines is to (1) determine if design cooling system. You cannot directly use elements added to promote passive solar these numbers for sizing the capacity of heating will cause excessive summer this equipment. The methods developed cooling loads and (2) provide a rough by the American Society of Heating. estimate of the effectiveness of solar Refrigerating. and Air Conditioning shading and natural cooling strategies. Engineers for sizing eqUipment are well­ The analysis method is based on a established and are recommended. The modified monthly degree-day procedure purpose of the guidance provided in in which the day is divided into day and these booklets is to minimize the night periods (reference 4). All estimates operating time and resources consumed are derived from correlations based on by this equipment. hourly computer simulations. Solar. conduction. and internal gains are Using the Worksheets in estimated for each half-day period in each month. Delay factors are used to Nearby Locations account for heat carryover from day to The applicability ofworkshects I and II night and night to day. The results are can be extended somewhat by using the estimates of annual sensible cooling base-65 "F degree-day value for a site delivered by the air conditioner and do which is close to the location for which not include latent loads. the worksheet tables were generated. We Because the the original Los Alamos recommend limiting such applications to monthly procedure is too complex to be sites where the annual heating degree­ implemented in a worksheet. a Simplified days are within plus or minus l00f0 of the procedure is adopted on worksheet IV. parent location and where it is Heat Gain Factors and Internal Gain reasonable to assume that the solar Factors in Tables L and N are the radiation is abou t the same as in the calculated annual incremental cooling parent location. The procedure is simple: loads resulting from a one-unit Use the measured base-65 OF degree-day incremental change in the respective value in worksheet I. line F. instead of heat input parameter (that is. a one-unit change in UA. glazing area. or number of the degree-day value for the parent location. bedrooms). The combined heat load resulting from all inputs is summed and Worksheet III depends only slightly then adjusted for thermal mass and on location. The only variables are the ventilation. This correction includes a Comfort Factors in Table I. which only constant required to match the change with latitude. Thus. this calculated cooling load of the base-case worksheet can be used anywhere within 4 degrees of latitude of the parent bUilding. This linearized procedure gives location. accurate estimates for cooling loads that The cooling estimate obtained from are less than about 150% of the base­ worksheet IV is specific to the location. case building; however. it Within the same vicinity and within plus

Salem. Oregon 58 APPENDIX References

1. J. Douglas Balcomb. Robert W. Jones. Robert D. McFarland. and William O. Wray. "Expanding the SLR Method". Passive Solar Journal. Vol. 1. No.2. 1982. pp. 67-90. Available from the American Solar Energy Society. 2400 Central Ave. Unit B-1. Boulder. CO 80301.

2. J. Douglas Balcomb. Robert W. Jones. Robert D. McFarland. and William O. Wray. Passive Solar Heating Analysis. American Society of Heating. Refrigerating. and Air-Conditioning Engineers. 1984. Available from ASHRAE. 1719 Tullie Circle. NE. Atlanta. GA 30329.

3. J. Douglas Balcomb and William O. Wray. Passive Solar Heating Analysis. Supplement One. Thermal Mass Effects and Additional SLR Correlations. American Society of Heating. Refrigerating. and Air Conditioning Engineers. 1987. See ASHRAE address above.

4. Robert D. McFarland and Gloria Lazarus. Monthly Auzillary CooRng Estimation for Residential Buildings. LA-11394-MS. Los Alamos National Laboratory. Los Alamos. NM 87545. 1989.

5. J. Douglas Balcomb and Alexander B. Lekov. Algorithms for Builder Guidelines. SERl/TP-254-3492. Solar Energy Research Institute. Golden co. Also contained in the Proceedings of the 14th Passive Solar Conference. Denver. June 19-23. 1989. See ASES address above.

Salem. Oregon PASSIVE SOLAR DESIGN STRATEGIES 59

Note: This is a generic example to explain how to fill out the worksheets. For an example specific to this book, refer to the worked example on the prior pages. The actual house design used for both examples is the same, but specific numerical values will be different.

Anytown , USA

Anytown, USA 60 INTRODUCTION Introduction A separate worksheet is The estimates from provided for each of four Worksheets I and II are based on Purpose separate performance levels a heating thermostat setting of perfo~ance level and 70°F. The .estimates from The purpose of the Any Town, associated target. These are Worksheet IV are based on a USA section is to explain how to deSCribed below: cooling thermostat setting of use the passive solar Worksheet I: Conservation 78°F with no ceiling fans and worksheets in the Passive Solar Performance Level: the 82°F with ceiling fans. Design Strategies: Guidelines for estimated heat energy needed by The worksheets are Home BUilding. Separate the building each year from both supported by a number of data Worksheets booklets are the solar and auxiliary heating tables. The data tables are given available for specific locations systems. The units are a letter deSignation and are throughout the continental Btu/yr-sf. referenced when applicable next USA. Each booklet contains Worksheet II: Auxiliary Heat to each worksheet entry. detailed technical data for a Performance Level: the A description and drawings specific location. Although the estimated heat that must be of the example building are example presented in this provided each year by the provided below, followed by booklet is for a moderate mid­ auxiliary heating system. This completed worksheets. Data Atlantic climate, the procedure worksheet accounts for the solar tables have also been included is presented in a general savings. The units are when appropriate. manner and is intended to be . Btu/yr-sf. Each step of the worksheets used for all locations. Worksheet III: Thermal is then explained in detail. Mass / Comfort: the temperature General Description swing expected on aclear winter day with the auxiliary heating of Worksheets system not operating. The units \ are OF. The Worksheets booklet for each location provides an easy-to-use Worksheet N: Summer Cooling calculation procedure, allowing Performance Level: the the designer to estimate the estimated annual cooling load of performance level of a particular the building. The units are building design and compare it Btu/yr-sf. against a base-case performance level or against the performance of the builder's more conventional house.

Anytown, USA PASSIVE SOLAR DESIGN STRATEGIES 61

Description of The building has an South facing windows attached sunspace. The provide direct gain solar heating Example Building ( sunspace floor has a four-inch to the dining area. kitchen and ) thick slab-on-grade with quarry master bedroom. The south A 1.504 square foot passive tile set in a mortar bed. The glazing in the kitchen and solar. single-family home with sunspace is separated from the dining area provides heat to an an 8.3 ft. average ceiling height conditioned portion of the house exposed slab-on-grade. is used to illustrate how to use by sliding glass doors and a The east portion of the the worksheets. A floor plan. masonry fireplace wall. Awning house is slab-on-grade building elevations. building windows located at the top and construction. The great room sections and details are shown bottom of the south wall provide and master bedroom suite are below. outside ventilation for the raised floor construction. The sunspace. slab-on-grade floor in the kitchen and dining area is finished with ceramic tile so that the floor may function as thermal mass. The exterior doors are metal with a foam core center.

~r--~2~O~' --.....;*~i~ __ ..!:2=2-'--~r· ...... ·.... ·...... g4.'...... :...... \

Garage

4040

Bedroom

Great Room

Master Bedroom ;...,... Suns pace

8088 8088 14' o 2 4 8 12 FLOOR PLAN ----

AnytOWD, USA 62 INTRODUCTION

SOUTH ELEVATION

024 B 12 NORTH ELEVATION

'...... ---- ...... ::::::::::::::J

"r ABOVE GRADE SECTION ) 02...... 4 B 12

Insulation,.---i''ti"*t:=;::::::l I . ., ...... ' : .r'''<:'.:l.-m~'-'-:! """"!1rf"'_'11IT'nl-.LA .' .' • § 1111 § III I;, : .....: . ini~),i~, §1I11 § 1111 ., ..•• ". 1I11§1Il1t=' •.• ' :." .•• 1I11§1II" .• : .' ~'. 1111" ", ....• "II .~. ", . ....111' . .'" .•.... . " . ",'.' . . . -... '. -. .' ... ", .. ' ... " . ,' . • ' II' .' II'

SLAB-ON-GRADE CRAWLSPACE FULL BASEMENT

\ TYPES OF FOUNDATIONS /

Anytown, USA PASSIVE SOLAR DESIGN STRATEGIES 63

General pro~ect Information

~:Area 1504 sf

Worksheet I: Conservation Performance Level

A. Envelope Heat Loss Construction R-value Heat Description Area [Table A] Loss

Q!!iliog~L[QQt~ B-;36 io 8!liQ ]Q64 + ;3f2!:! = ;3Q B-;3Q io Qrull!!Qml Q!!iliog 42Q + 24f2 = ]I ..,... WiillI~ B-l!:!± B-Z SIl!!iillIliog io BigiQ IO~!JliiI!iQO !:!!:!2 24Z = 4Q B-1!:! io ~iilmg!! 14Q + lZZ 6 IO~!JliiI!!!Q EIQQ[~ B-1!:! io EIQQ[ Qll!![ ~!!ois!Q Q[5nIl1~I2ii1Q!! Z64 + 2f26 = ;3Q + = ~Qo-~QliiI[ ~Iiili:iog OQ!Jbl!! !:aliilZ!!Q WQQQ E[iillD!! liZ' iili[ giill2 f22 + 16 2!:! - L.QY:l-i; (!!:;;- 4Q) + OQQ[~ M!!!iilllI:li!1l EQiillD QQ[!! 4Q + f2!:! = Z + = 1121 Btu/OF-h Total B. Foundation Perimeter Heat.Loss Heat Loss Factor Heat Description Perimeter [Table B] Loss

Sliilb~-QO-!:a[iilQ!! B-Z 62 X Q;3Q 2f2 ~ H!!iilis!Q BiilS!!ID!!O!S X = I Uoll!!ru!!Q Eliil~!!ID!!O!~ X = E!![iID!!t!![ IO~!Jliilt!!Q Qmll:ll~I2ii1Q!!~ X = 2f2 Btu/oF-h Total

C. Infiltration Heat Loss 1246;3 X Qf2Q X .018 112 Btu/OF-h Building Air Changes Volume per Hour

D. Total Heat Loss per Square Foot

24 X 2~6 + lf2Q4 = 4Z!2 Btu/DD-sf Total Heat Loss Floor Area (A+B+C)

E. Conservation Performance Level

H!2 X nQ;3 X Qn = lZQn Btu/yr-sf Total Heat Heating Degree Heating Degree Loss per Days [Table C] Day Multiplier Square Foot [Table C]

F. Comparison Conservation Performance (From Previous Calculation or from Table O) 2f2 ;3!2Q Btu/yr-sf Com are Line E to Line F

Anytown, USA 64 CONSERVATION PERFORMANCE LEVEL

Worksheet I: Step A. Envelope Heat Loss Ceilings/Roofs Conservation The first step is to calculate the There are two types of Performance Level heat loss through the building ceiling/roof construction in the) Worksheet I is essentially a heat envelope. The building envelope example building. R-38 mineral \ loss calculation, similar to the consists of all walls, roofs, insulation is located in an attic type of calculation made to size floors, non-solar windows and space, and R-30 insulation is heating and cooling equipment. doors that enclose the located in the framed cathedral The major difference is that the conditioned space of the house. ceiling. The total R-value is calculation does not consider Heat loss for each envelope selected from Table Al for each heat loss through any of the component is calculated by ceiling/ roof component. The passive solar systems. The dividing the surface area of the values in Table Al account for following building corriponents component by the total R-value. the buffering effect of the attic in the example building are not The total envelope heat loss is (when applicable), the ceiling considered in the calculation: the sum of the heat loss for all material (sheetrock) and the • Heat loss through direct gain of the envelope components. effect of framing. solar glazing. Table A in the Worksheets • Heat loss through walls and booklet contains R-values that A 1-Ceilings/Roofs Attic Insulation R-value windows that separate the may be used in the calculation. Construction R-30 I!1J R-49 R-60 house from the sunspace. There are actually five separate 27.9 35 46.9 57.9 Framed Insulation R-value If the example building had tables labeled AI, A2, A3, A4 Construction R-19 R-22 R-30 R-38 2x6 at 16"oc 14.7 15.8 16.3 - Trombe walls or water walls, and A5. A separate table is 2x6 at 24'oc 15.3 16.5 17.1 - heat loss through these passive provided fQr ceilings/roofs, 2x8 at 16"oc 17.0 18.9 20.6 21.1 2x8 at 24"oc 17.6 19.6~ 22.2 solar systems would also be walls, floors, windows and 2x10 at 16"oc 18.1 20.1 24. 25.7 2x10 at 24"oc 18.4 20.7 . 26.8 excluded from the calculation. doors. The R-values' in these 2x12 at 16"oc 18.8 21.0 25.5 30.1 Heat loss from the passive tables include the thermal 2x12 at 24 'oc 19.0 21.4 27.3 31.4 solar energy systems is excluded resistance of both the insulation The area and R-value of the ) since the solar savings fractions and other materials that two different types of in Worksheet II take these losses typically make up the construction are entered on two into account. construction assembly such as lines of the table under exterior sheathing and "ceilings/roofs" and the heat sheetrock. They also account loss is calculated by dividing the for framing members that surface area by the total . penetrate the insulation and R-value. Note that the ceiling reduce the effectiveness. over the sunspace is not included in this calculation.

Anytown, USA PASSIVE SOLAR DESIGN STRATEGIES 65

Walls The R-value of each wall The total R-value is selected There are two types of wall type is detennined from Table from Table A3, which considers '\ construction in the example A2 in the Worksheets booklet. the buffering effect of the ) building. The typical exterior The R-value of both wall types is crawlspace as well as framing wall is of 2x6 wood frame 17.7 from the table, but since and the floor materials. The construction with R-19 mineral the first wall type has R-7 area and R-value is entered on insulation in the cavity. An insulating sheathing, this is one line of the table and the insulating sheathing with an R- added to the value from the heat loss is calculated by . 7 rating is attached to the table so that 24.7 is used in the dividing the area by the R-value. exterior surface of the framing. calculations. These R-values The wall is finished with 1/2 along with the associated areas A3-lnsulated Floors Insulation R·value inch sheetrock on the inside are entered on two lines of the Framing R-11 R-19 R-30 R-38 2x6s at 16"oc 18.2 23.8 29.9 and a brick veneer on the table and the heat loss is 2x6s at 24"oc 18.4 24.5 31.5 outside. calculated by dividing each 2x8s at 16"oc 18.8 24.9 31.7 36.0 2x8s at 24"oc 18.9 33.1 37.9 The second type of wall surface area by the 2x10 at 16"oc 19.3 4W25.8 33.4 38.1 2x10 at 24"oc 19.3 .1 34.4 39.8 construction separates the corresponding R-value. 2x12 at 16"oc 19.7 26.5 34.7 39.8 house from the garage. This 2x12 at 24"oc 19.6 26.7 35.5 41.2 These R·values include the buffering effect of a wall is also of 2x6 wood frame A2-Framed Walls ventilated crawlspace or unconditioned basement. Single Wall Insulation R·value construction With R-19 in the Framing R-11 R-13 R-19 R-25 Had there been different cavity, but it does not have the 2x4 at 16"oc 12.0 13.6 insulation conditions for the 2x4 at 24"oc 12.7 13.9 ~ - insulating sheathing or the 2x6 at 16"oc 14.1 15.4 17. 19.2 raised floor, an additional line of 2x6 at 24"oc 14.3 15.6 . 19.8 brick veneer. Note that the Double the table would be completed for Wall Total Thickness (inches) walls that separate the house Framing 8 10 12 14 each condition. from the sunspace are not 25.0 31.3 37.5 43.8 If the example building had included...... The R·value of insulating. sheathing should be insulated floors over a garage or \ added to the values in this table. / It is necessary to measure unheated basement, these the surface area of each type of components would also be wall construction. The surface Floors included in this step. area may be determined by Only the raised floor is As an alternative to multiplying the length of wall by considered in this step of the insulating between the floor the average height and heat loss calculation; heat loss joists, the perimeter walls of the subtracting the area of doors from the slab-on-grade floor is crawlspace could have b~en and windows. conSidered in Step B. There is insulated and floor insulation one type of raised floor eliminated. When this construction in the example technique is used, the perimeter building. R-19 mineral heat loss method in Step B insulation is placed between should be used. Step A only 2xlO floor joists at 16 inches on includes floors when insulation center; the crawlspace beneath is placed in the floor assembly. is ventilated.

Anytown, USA 66 CONSERVATION PERFORMANCE LEVEL

Non-solar Glazing Windows in the example These values are entered in Next, heat loss from the non­ building are all double-pane the table and the heat loss is solar glazing is calculated. Note wood windows with a 1/2 inch calculated by dividing the door that the passive solar direct gain air space between the panes. areas by the R-value. If the glazing is not included. Also the The R-value for this window example building had more than windows that separate the type is 2.1, selected from Table one door type (different house from the sunspace are A4. R-values), then additional lines not included. The non-solar window area of the table would be completed. The rough frame opening of is taken from the building plans. each window is generally used These values are entered in the Total for the window area. This is table and the heat loss is The heat loss of all components because the R-values presented calculated by dividing the of the building envelope is in Table A4 and most heat loss window area by the window summed at the bottom of the data presented by window R-value. If the example building table and this completes Step A manufacturers is for the rough had more than one window type of the worksheet. frame opening. Using the rough (different R-values), then frame opening also makes it additional lines of the table easier to estimate window areas would be completed. since windows are usually specified on the plans in terms Doors of the rough frame dimensions. The doors are the last component of the envelope to A4-Windows Air Gap consider. The example building 1/4 in. 1/2 in. 1/2 in. argon has two exterior doors: the main Slandar'd Metal Frame Single .9 entrance and an additional door Double 1.1 1.2 1.2 Low-e (e<=0:40) 1.2 1.3 1.3 to the garage. These have a Metal frame with thermal break total surface area of 40 square Double 1.5 1.7 Low-e le<=0.40} 1.6 '. I.S feet and an R-value is selected Low-e e<=0.20} 1.7 2.0 Wood frame with vinyl cladding from Table A5. Note that the Double 2.0 2.1 2.2 Low-e (e<=0.40l 2.1 2.4 2.5 door that separates the garage Low-e le<=0.20 2.2 2.6 2.7 Low-e e<=0.10 2.3 2.6 2.9 from the exterior is not included since the garage is These R-values are based on a 3 mph wind speed and are typical for the entire rough framed opening. unconditioned. Manufacture's data, based on National Fenestration Rating Council procedures, should be used when available. One half the R-value of AS-Doors movable insulation should be added, when Solid wood with 2.2 appropriate. Weatherstripping Metal with rigid C1i) foam core

Anytown, USA PASSIVE SOLAR DESIGN STRATEGIES 67

Table B-Perimeter Heat Loss Factors Step B. Foundation for Slabs·on·Grade and Unheated The building volume is Perimeter Heat Loss . Basements (Btuth·F·ft) calculated by multiplying the Heated Unheated Insulated ) Foundation heat loss from Perimeter Siabs-on- Base· Base- Crawl· average ceiling height by the slabs-on-grade. basements and Insulation Grade ments ments spaces conditioned floor area. In this None 0.8 1.3 1.1 1.1 insulated crawispaces is R 5 ~ 0.8 0.7 0.6 example the average ceiling R:7 0.3 0.7 0.6 0.5 estimated by multiplying the R·11 . 0.6 0.5 0.4 height is 8.3 ft. The conditioned R-19 0.2· 0.4 0.5 0.3 length of perimeter times an R-30 0.1 0.3 0.4 0.2 floor area is 1,504 sf which does appropriate heat loss factor When a raised floor assembly is not include the garage or the taken from Table B. not insulated, for instance, over sunspace. The resulting The dining area, kitchen and crawlspaces insulated at the building volume is 12,483 cubic secondary bedrooms in the perimeter or basements, heat feet. example house have slab-on­ loss occurs primarily at the The units of infiltration heat grade construction. R-7 perimeter. loss are Btu;oF-h, the same as insulation is installed around The example house does not for the building envelope and the perimeter. have a basement or a heated the foundation perimeter. The heat loss factor for the crawlspace, but if it did, the Step D. Total Heat Loss per slab edge is 0.3, selected from foundation heat loss would be Square Foot Table B. The heat loss factor is calculated by multip1ying the The total building heat loss is multiplied by the perimeter to perimeter of these elements by a the sum of the heat loss for the calculate the heat loss. The heat loss factor selected from building envelope (Step A), the units of heat loss, using the Table B. foundation perimeter (Step B) perimeter method, are the same When houses have heated and infiltration (Step C). For as for the building envelope basements, heat loss from , residences this value will range calculated in the previous step. basement walls located above between 200 and 500. It Note that sunspace slab is not grade would be included in represents the Btu of heat loss included in this calculation. Step A. The slab edge perimeter from the building envelope over adjacent to the crawlspace and Step C. Infiltration Heat Loss the period of an hour when it is the sunspace is also excluded. The heat loss from infiltration or one OF colder outside than air leakage is estimated by inside. This total heat loss, of multiplying the building volume course, does not include heat times the air changes per hour loss from the solar systems, times a heat loss factor of 0.018. including direct gain glazing. The example building is The result of Step D, estimated to have an infiltration however, is the annual heat loss rate of 0.50 based on local per degree day per square foot. building experience. This value is calculated by mUltiplying the total heat loss by 24 hours/ day and dividing by the conditioned floor area.

Anytown, USA 68 CONSERVATION PERFORMANCE LEVEL

Step E. Conservation The heating degree days are Step F. Comparison Performance Level selected from Table C 1 and Conservation Performance Once the total heat loss per based on specific locations. The The conservation performance square foot is calculated, the heating degree day multiplier is level for the proposed design conservation perfonnance level selected from Table C2 and is may be compared to the base may be calculated by based on the total heat loss per case perfonnance level for the multiplying the total heat loss square foot (Step D) and the area, given in Table D. per square foot (Step D) by the passive solar glazing area per Table D-Base Case Conservation heating degree days times the square foot of floor area Performance (Btu/v. • heating degree day multiplier. (Worksheet II, Step A). Base Case 25,38 Alternatively, the C1-Heating Degree Days ~ 65°F) C2-Heating Degree Day Multiplier conservation perfonnance level Raleigh·Durham ~ Passive Solar Heat Loss Glazing Area per may be compared to other This value is from TMY weather tapes and per Square per Square Foot should be used for Worksheet Calculations. Foot .00 .05 .10 .15 .20 building designs considered by It will vary from long term averages. 8.00 1.03 1.05 1.07 1.09 1.11 7.50 1.01 1.04 1.06 1.07 1.10 the builder to be typical of the 7.00 0.99 1.02 1.04 1.06 1.08 6.50 0.97 1.00 1.02 1.04 1.06 area. In this case, the 6.00 0.94 0.97 1.00 1.03 1.05 worksheets would first be 0.90 0.94 0.98~. 1.03 .00 0.86 0.91 0.95 . 1.01 completed for the typical design ~5 Q~ Q~ Q~ Q9 Q~ ~. 0 0.77 0.83 0.88 . 2 0.96 and the results of these 3.50 0.72 0.78 0.83 0.88 0.93 calculations would be entered in The conservation Step F. perfonnance level for the If the conservation example building is compared to per.(onnance level of the the base case conservation proposed building (Step E) is perfonnance level in the next greater than the base case or ) step. typical-design conservation perfonnance level. the designer should conSider additional or reduced non-solar glass area.

Anytown; USA PASSIVE SOLAR DESIGN STRATEGIES 69

Worksheet II: Auxili Heat Performance Level / A. Projected Area of Passive Solar Glazing I. ) Solar System Rough Frame Net Area Adjustment Projected Reference Code Area Factor Factor [Table E] Area

Q~QI ee X 0.80 X ~e fl~ SSQI 2Qe X 0.80 X ~e jfl~ X 0.80 X X 0.80 X = X 0.80 X = X 0.80 X = X 0.80 X = 2~fl 2~2 sf Total Area Total Projected Area

2~2 -;- jf!Q4 = jf! Total Floor Total Projected Projected Area Area per Area Square Foot

B. Load Collector Ratio

24 X 2~a + 2~2 = ~Q e~ Total Total Heat Loss Projected [Worksheet I] Area

C. Solar Savings Fraction ) System / Solar Savings Solar System Projected Fraction Reference Code Area [Table F]

Q~Qj fl~ X 44 ~Q ~fl SSQl jfl~ X 4f! = Z~~f! X = X = X = X = X =

jQ~ Zj + 2~2 Q4f! Total Total Solar Projected Savings Area Fraction D. Auxiliary Heat Performance Level

[1 - Q4f! jx 1ZQ~Z = ~Q4~ Btu/yr-sf Solar Conservation Savings Performance Fraction Level [Worksheet I, Step E]

E. Comparative Auxiliary Heat Performance (From Previous Calculation or from Table G) 23 Q99 Btu/yr-sf Com are Line D to Line E ,

Anytown, USA 70 AUXILIARY HEA T PERFORMANCE LEVEL

Worksheet II: The reference codes are shown Auxiliary Heat on Tables FI through F4 for Performance Level various types of solar systems. Worksheet II is used to estimate More information about the the savings from passive solar system types is provided in the systems and to estimate the discussion under Step C of this auxiliary heat performance level.. worksheet. The reference code This is the amount of heat that for the direct gain system is must be provided to the building "DGC 1" because night each year after the solar savings insulation is not proposed. The have been accounted for. reference code for the sunspace The example building has is "ssc 1" since all the sunspace two solar systems: direct gain glazing is vertical. south glazing and a sunspace. The south wall of the

South example building actually faces Step A. Projected Area of Projection 10° east of south because of site Passive Solar Glazing Projected Area of Passive Solar Glazing conditions. The adjustment The solar savings fraction is based on the The first step is to calculate the projected area of solar glazing. factor is therefore 0.98 for both projected area of the solar The worksheet allows the solar systems as selected from glazing. The proj ected area of user to enter the rough frame Table E. Each solar system area passive solar glazing is the area area of solar glazing. since it is is multiplied by the net area projected on a plane facing true generally easier to measure this. factor and the appropriate south (the actual glazing may be The rough frame area is adj ustment factor to calculate oriented slightly east or west of multiplied by a net area factor of the projected area. Both the true south). The projected solar 0.80 to account for window total projected area and the total . glazing also accounts for sloped framing and mullions. If the net area are summed at the bottom glazing in certain types of glass area is entered. the net of the table. sunspaces. area factor is 1.00. For most solar systems the Table E-ProJected Area The example building has Adjustment Factors projected area may be calculated two separate passive solar Degrees off ~solar System Type True D SSA SSB, by multiplying the actual glazing systems: direct gain and a South ,S SSD SSE area times an adjustment factor sunspace. This means that two o 1.00 0.77 0.75 5 c$? 0.76 0.75 taken from Table E. lines of the table must be 10 0.98 0.75 0.74 15 . 0.74 0.73 Alternatively. the projected completed. If the example 20 0.94 0.72 0.70 25 0.91 0.69 0.68 area may be determined by building had other types of solar 30 0.87 0.66 0.65 making a scaled elevation systems. for instance Trombe The last part of Step A is to drawing of the building. looking walls or water walls. additional divide the total projected area by exactly north. Surface areas lines in the table would be the conditioned floor area. giving may then be measured from the completed. the total projected area per scaled elevation drawing. This In the first column. the square foot. This value is used concept is illustrated in the reference code for each type of in Worksheet I. Step E to figure below. solar system is entered along determine the heating degree with a description of the system. day multiplier.

, ./

Anytown, USA PASSIVE SOLAR DESIGN STRATEGIES 71

Step B. Load Collector Ratio A reference code, for The solar savings fraction for The load collector ratio is instance "DGC 1", is also each system is multiplied by the calculated by taking the total provided for each solar system projected area and totaled at the heat loss from Worksheet I, Step variation. These references are bottom of the table. This total is D and multiplying this value entered on the worksheet "Solar then divided by the total times 24 (hours/ day) and System Reference Code". They projected area from Step A to dividing by the total projected are also a key to additional calculate the weighted average area of the solar glazing information about each solar solar savings fraction for the calculated in the previous step. system as provided in Passive whole building. Solar Heating Analysis and The solar savings fractions Step C. Solar Savings Fraction other reference manuals. are based on reference designs. The next step is to calculate the The assumptions made about solar savings fraction for the F1-Direct Gain these reference designs are Load DGCI DGC2 DGC3 building. This is calculated as a Collector Double Low-e R-9 Night summarized below. weighted average of the solar Ratio Glazing Glazing Insulation 200 0.10 0.11 0.13 savings fraction for the separate 155 0.13 0.14 0.17 Direct Gain 100 0.18 0.20 0.24 passive solar systems. The 80 0.22 0.25 0.30 The direct gain reference 60 0.28 0.31 0.38 weightings are based on 50 0.32 0.36 0.44 designs are all assumed to have projected area. 45 0.34 0.39 0.47 40 0.37 0.43 0.51 double-pane glass and sufficient The solar systems used in 0.47 0.56 heat storage to limit the clear 0.52 0.62 this step should be identical to ar ~. 9 0.58 0.69 day temperature swing to 13°F. 20 0.55 0.65 0.77 those used above in Step A. The 15 0.62 0.74 0.85 For the case with night first two columns are simply insulation, the thermal carried down from the first and F4-Sunspaces resistance is assumed to be R-9. Load last columns in· Step A. Collector sunsEace Type ) The solar savings fraction for Ratio SSAI SSBI SCI SSDI SSEI Trombe Walls 200 '0.17 0.14 0.11 0.19 0.15 e9-ch individual system is taken 155 0.20 0.17 0.14 0.23 0.19 The Trombe wall reference 100 0.26 0.22 0.19 0.30 0.26 from Tables F1 through F4 80 0.30 0.25 0.23 0.35 0.30 designs are all assumed to have based on the load collector ratio 60 0.35 0.30 0.28 0.42 0.36 50 0.39 0.34 0.32 0.46 0.40 double-pane glass. The mass calculated in Step B and the 45 0.42 0.36 0.35 0.49 0.43 wall is assumed to be 12 inches 40 0.44 0.39 0.38 0.52 0.46 type of solar system. Table F1 is 0.48 0.42 0.56 0.49 thick and constructed of for direct gain systems, Table F2 0.52 0.46 0.60 0.54 ~ 0.56 0.50 ~.0 0.65 0.59 masonry or concrete. for thermal storage walls, Table 20 0.62 0.56 0.57 0.72 0.65 15 0.70 0.64 0.65 0.79 0.73 F3 for water walls and Table F4 Water Walls for sunspaces. There are The water wall reference designs multiple columns in each table are all assumed to have double­ that account for system design pane glass. The water tank is features such as night assumed to be nine inches insulation or selective surfaces. thick, extending continuously in front of the glazing surface. The space between the water tank and the glazing is assumed to be sealed.

Anytownl USA 72 AUXILIARY HEA T PERFORMANCE LEVEL

Sunspaces Step D. Auxiliary Heat Data is provided for five Performance Level sunspace reference designs as The auxiliary heat performance illustrated on the following level is calculated by multiplying figure. Double glazing is the conservation performance assumed for all reference level from Worksheet I, Step E, designs. Reference designs times one minus the solar SSAl, SSB 1 and SSD 1 are savings fraction, calculated in assumed to have opaque end the previous step. This value walls. All are assumed to have a represents the amount of heat concrete or masonry floor about that must be provided to the six inches thick and a masonry building by the auxiliary heating or concrete common wall system(s). separating the sunspace from the living areas of the house. Step E. Comparative Auxiliary The glazing for designs SSAI Heat Performance and SSD 1 is assumed to be The calculated auxiliary heat sloped at an angle of 50° from performance level may be the horizon. The sloped glazing compared to the performance in designs B and E is assumed level for a typical basecase to be at an angle of 30°. building in the area. This may be taken from Table G and is 23,099 Btu/yr-sf.

\ ) I Alternatively, the performance level may be compared to a previous worksheet calculation made for a typical builder house. If the auxiliary heat performance level calculated in Step D were larger than the base case auxiliary heat performance, the designer should conSider increasing the size of the solar

Sunspace Reference Designs systems, adding additional solar Data is provided for five types of sunspaces. systems or increasing insulation levels.

\ /

Anytown, USA PASSIVE SOLAR DESIGN STRATEGIES 73

Worksheet III: Thermal Mass/Comfort ( \ A. Heat Capacity of Sheetrock and Interior Furnishings '\ ) Unit Total Heat Heat Floor Area Capacity Capacity

BQQIDl! lIlli!b Qi[~Q! !:aiilie 424 X 4.7 2H~1 QRiilQ~l! QQee~Q!~g !Q Qi~Q! !:aiilie QRiilQ~l! ~4~ X 4.5 = 42Z1 2452 Btu/OF Total B. Heat Capacity of Mass Surfaces Enclosing Direct Gain Spaces Unit Heat Mass Description capaci~ Total Heat (include thickness) Area [Table ] Capacity

nQIDb~ WslIIl! X 8.8 , wm~[Wiillll! X 10.4 = E~RQl!~g Qliilb ie Que lQa X 13.4 = laaQ E~RQl!~g Qliilb IlIQ! ie Que laZ X 1.8 = 24Z X = X = X = 122Z Btu/OF Total

C. Heat Capacity of Mass Surfaces Enclosing Spaces Connected to Direct Gain Spaces Unit Heat Mass Description Capacity Total Heat (include thickness) Area [Table H] Capacity I[QIDb~ WslIIl! . X 3.8 W~[WiillIl! X 4.2 = ) EiilQ~ 6[iQis 4" III X 3,Z = 4ll X = X = 4ll Btu/OF Total

D. Total Heat Capacity a4~Q Btu/OF (A+B+C)

E. Total Heat Capacity per Square Foot

a4~Q + 15Q4 = 52 Btu/OF-sf Total Heat Conditioned Capacity Floor Area

F. Clear Winter Day Temperature Swing Total Comfort Projected Area Factor [Worksheet II] [Table I]

Qi~Q! !:aiilie 2~ X a22 = 5~Z54 Quel!RiilQ~l! Q[ 12a X 2~~ = 4a zaz ~e!~g nQIDb~ WslIIl! lQa 4~1 + a4~Q = 12 a OF Total Total Heat Capacity G. Recommended Maximum Temperature Swing 13 OF ) Com are Line F to Line G

Anytown, USA 74 COMFORT PERFORMANCE LEVEL

Worksheet III: Step A. Heat Capacity of In the example building, the Thermal Sheetrock and Interior master bedroom, dining area Mass/Comfort Furnishings and kitchen are all direct gain This worksheet is used to The first step is to estimate the space.s. The secondary calculate the thermal effective heat capacity bedrooms, bathrooms and mass/comfort performance level, associated with low-mass master bedroom closet are which is the temperature swing construction and interior directly connected to the direct expected on a clear winter day furnishings. To complete this gain spaces. The utility room with the auxiliary heating step it is necessary that two and entry foyer are not system not operating. A high sub-areas be identified within conSidered in this calculation temperature swing would the building: those areas that since they are not connected to indicate that inadequate thermal receive direct solar gains and a direct gain space. These areas mass is provided in the building those areas that are connected are illustrated for the example design, which not only creates to rooms that receive direct solar building. discomfort but decreases solar gains. This is because the mass The direct gain space is heating performance. of sheetrock and furnishings multiplied by 4.7 and the spaces The general procedure of the located in direct gain rooms is connected to direct gain spaces worksheet is to calculate the more effective. Rooms that are are multiplied by 4.5. These effective heat capacity of mass separated from direct gain products are summed and elements located within the spaces by more than one door represent the effective heat conditioned space of the should not be included in either capacity associated with the building. The total effective heat category. sheetrock and interior capacity is then combined with furnishings. the direct gain projected area to estimate the clear winter day temperature swing. Note that ) thermal mass elements located within unconditioned spaces such as the sunspace are not included in this calculation.

1i)))1 Direct Gain Spaces Unconditioned Garage I,l@ililm Spaces Connected to Direct Gain Spaces moo Spaces Not Connected to Direct Gain Spaces

Suns pace

Building Sub-areas for Calculating Effective Heat Capacity Worksheet 11/ requires that the building be divided into sub-areas.

Anytown, USA PASSIVE SOLAR DESIGN STRATEGIES 75

Step B. Heat Capacity of Mass Exposed slabs-on-grade Step C. Heat Capacity of Mass Surfaces Enclosing include those with a surface of Surfaces Enclosing Spaces () Direct Gain Spaces vinyl tile. ceramic tile or other Connected to Direct Gain The heat capacity of thermal materials that are highly Spaces mass elements (other than conductive. Slabs that are The same type of calculation is sheetrock and furnishings) that covered with carpet should not performed for mass surfaces enclose the direct gain spaces is be considered to be exposed. that enclose spaces connected conSidered in this step. The The exposed slab area should be to direct gain spaces. The surface area of each element is further reduced. when primary difference is the unit measured from the building appropriate. to account for heat capacity figures taken from plans and multiplied by the unit throw rugs and furnishings. Table H2 instead of Table H 1. heat capacity. The unit heat The exposed slab area is In the example building. the capacity is printed directly in then subdivided into two areas: fireplace wall and hearth are the table for Trombe walls. water that which is expected to be in considered in this category. walls. and exposed slabs-on­ the sun and that which is not. This area and the unit heat grade. The unit heat capacity As a rule-of-thumb. slab area capacity is entered in the table for other mass elements is should be considered in the sun and multiplied by each other. selected from Table H 1. Note only when it is located directly This represents the total that thermal mass located in the behind south glazing. In any effective heat capacity of mass sunspace is not included in this event. the slab area assumed to elements that enclose the calculation. be in the sun should not exceed spaces connected to direct gain 1.5 times the south glass area. spaces. H1-Mass Surfaces Enclosing Direct Gain Spaces . In the example building. the Thickness (inches) slabs-on-grade located in the H2-Rooms with no Direct Solar Gain Material 1 2 3' 4 6 8 12 Thickness (inches) Poured Conc. 1.8 4.3 6.7 8.8 11.311.5 10.3 kitchen and dining room are Material 1 2 ~ 4 6 8 12 ) Conc. Masonry 1.8 4.2 6.5 8.4 10.210.0 9.0 located within direct gain Poured Conc. 1.7 3.0 3.6 3.8 3.7 3.6 3.4 Face Brick 2.0 4.7 7.1 9.0 10.49.9 9.0 Conc. Masonry 1.6 2.9 3.5 ~.6 3.4 3.2 Flag Stone 2.1 4.8 7.1 8.5 8.6 8.0 7.6 spaces. Some of this area is Face Brick 1.8 3.1 3.6 3.7 .5 3.4 3.2 Builder Brick 1.5 3.7 5.4 6.5 6.6 6.0 5.8 Fla~Stone 1.9 3.1 3.4 . 3.2 3.1 3.0 Adobe 1.3 3.2 4.8 5.5 5.4 4.9 4.8 considered to De in the sun and Builder Brick 1.4 2.6 3.0 3.1 2.9 2.7 2.7 Hardwood 0.4 1.4 1.8 1.7 1.5 1.5 1.5 Adobe 1.2 2.4 2.8 2.8 2.6 2.4 2.4 Water 5.2 10.415.6 20.8 31.241.6 62.4 the remainder not. These Hardwood 0.5 1.1 1.3 1.2 1.1 1.0 1.1 surface areas are entered in the table and multiplied by the appropriate unit heat capacity. The products are then summed at the bottom of the table.

Anytown, USA 76 COMFORT PERFORMANCE LEVEL

Step D. Total Heat Capacity Step F. Clear Winter Day Step G. Recommended The total heat capacity is the Temperature Swing Maximum Temperature Swing sum of the heat capacity from The clear winter day The comfort performance target '\ Steps A, B and C. This temperature swing is calculated for all locations is 13°F. If the ) represents the effective heat in Step F. The projected area of comfort performance level capacity of all thermal mass all direct gain glazing is entered calculated in Step F had been within the building. in the first row. This includes greater than 13°F, additional all direct gain systems either thermal mass should be added Step E. Total Heat Capacity with or without night insulation. to the building or direct gain per Square Foot In the second row, the projected glazing should be reduced. The total heat capacity area of sunspace glazing and calculated in Step D is divided Trombe walls vented to the by the total floor area of the indoors is entered. Unvented building to get the total heat Trombe walls and water walls capacity per square foot. The are not included in this floor area used in this calculation since solar gain from calculation should not include these systems does not the sunspace or other contribute to the temperature unconditioned spaces. This swing of the conditioned space. value is calculated here for The appropriate comfort convenience, but it is not used factor is entered in the second until Worksheet IV is completed. column, selected from Table I. ,(he projected areas are multiplied by the appropriate comfort factors and summed. '\ This sum is then divided by the ! total heat capacity from Step D to yield the clear winter day temperature Swing.

Table I-Comfort Fact~rBtu/sf) Direct Gain Suns paces and 99 Vented Trombe Walls

)

Anytown, USA PASSIVE SOLAR DESIGN STRATEGIES 77

Worksheet IV: Summer Coolin Performance Level A. Opaque Surfaces '\ Radiant Barrier Absorp- Heat Gain j Heat Loss Factor tance Factor Description [Worksheet I] [Table J] [Table K] [table L] Load

Q!2i1iDg:!lrQQf:! ~Q X j QQ X Q!lZ X !lZQ = !2!2~ lZ X j QQ X Q!I:Z X !lZQ = ~Z!2 X X X = W§II:! !lQ X na QZQ X 2!2~ = Z~!2 X na X = OQQ[:! ~fi X na Q~Q X 2!2~ = 2a jaQ~ kBtu/yr Total B. Non-solar Glazing Rough Frame Net Area Shade Factor Heat Gain Description Area Factor [Table M] Factor [Table L] Load

t!/Q[tb !:al~:!:! !lQ X 0.80 X Q!2Z X ~ZQ = ~~fi X 0.80 X X = ESI:!t !:a lSi:!:! !2 X 0.80 X QaQ X !2a ~ = ~~j X 0.80 X X = W!2:!t!:aI~:!:! !2 X 0.80 X QaQ X Z~2 = ~fij X 0.80 X X = Slsllligbt:! X 0.80 X X = X 0.80 X X = j!2ZZ kBtu/yr Total C. Solar Glazing Solar System Rough Frame Net Area Shade Factor Heat Gain \ Description Area Factor [Table M] Factor [Table L] Load ) Oi[!2Qt !:a~iD aa X 0.80 X Qa~ X fifiQ = ~2g X 0.80 X X = StQ[~g!2 llll~lI~ X 0.80 X X X 0.80 X X = S!.ID:!J2~Q!2 2Qa X 0.80 X Qa~ X j22 = j!2afi X 0.80 X X = !la~~ kBtu/yr Total D. Internal Gain

22fiQ +( ~!lQ X ~ = fiQZQ kBtu/yr Constant Variable Number of Component Component Bedrooms [Table N] [Table N] E. Cooling Load per Square Foot

1,000 X j~ !I!I~ + jfiQ!I a~!l2 Btu/yr-sf (A+B+C+D) Floor Area F. Adjustment for Thermal Mass and Ventilation No night vent with no ceiling fan Z~!2 Btu/yr-sf [Table 0] G. Cooling Performance Level a2Q!2 Btu/yr-sf (E -F) H. Comparison Cooling Performance (From Previous Calculation or from Table P) 9Z!2!2 Btu/yr-sf Com are Line G to Line H

Anytown, USA 78 SUMMER COOLING PERFORMANCE LEVEL

Worksheet IV: Table J-Radiant Barrier Factors The heat loss from each of Radiant Barrier Summer Cooling No Radiant Barrier .0 these elements is carried over Performance Level from Worksheet I. Note that the Worksheet IV is used to Table K-Solar Absorptances door heat loss is reduced by half . Color Absorptance calculate the summer cooling Gloss White since one of the two doors does performance level. This is the Semi-gloss White not receive sunlight. The Light Green heat that would need to be Kelly Green I proposed building does not have Medium Blue 0.51 removed from the bUilding by an Medium Yellow 0.57 a radiant barrier in the attic, so Medium Orange 0.5B air conditioner in order to Medium Green 0.59 the radiant barrier factor is 1.00. maintain comfort during the Light Buff Brick 0.60 Absorptances are selected based Bare Concrete summer. Red Brick on the exterior building colors Medium Red ~ The worksheet accounts for Medium Brown 0.B4 and the heat gain factors are Dark Blue-Grey O.BB four sources of cooling load: Dark Brown O.BB from Table L. opaque surfaces exposed to the sun, non-solar windows, passive Step B. Non-solar Glazing solar systems, and internal gain. Ceiling/roofs Cooling load associated with the Walls and Doors These loads are then adjusted to North Glass windows that do not face south, East Glass account for ventilation and West Glass i.e. those that are not part of one Skylights of the solar systems, is thermal mass .. Direct Gain Glazing Trombe Walls and calculated by multiplying the Water Walls Step A. Opaque Surfaces Sunspaces surface area in each orientation SSAl 39.3 Not all opaque surfaces SSBl times the net area factor, a contribute to the cooling load of SSCl .~ shade factor (from Table M) and SSDl the building: only those surfaces SSEl 39.3 a heat gain factor (from Table L). exposed to sunlight In the example building, four This calculation gives the (ceilings/roofs and walls) are lines of the table are completed, annual cooling load for each ) included in the calculation. For two for the ceiling/roof types, non-solar glazed surface. The each ceiling and wall surface one for the exterior walls with total for the building is the sum listed on Worksheet I and brick veneer and one for the of the cooling load for each exposed to the sun, the heat entrance door. The wall that surface. loss should be carried over to separates the house from the Table M-Shading Factors this worksheet along with a garage and the door in this wall Projection consistent description. This are not included, since they are Factor South st North 21 0.00 ~ . 1.00 . heat loss is then multiplied by a not exposed to sunlight. 0.20 . .93 ~ .93 . 4I1o,~ 0.40 . 3 ~0.B1 O.Bl • 1 9' c;1JC7 radiant barrier factor when 0.60 0.49 0.71 0.7 '67 0.6B O.BO 0.35 0.60 0.6f 0.56 appropriate (from Table J), the 1.00 0.30 0.50 0.54 0.45 absorptance (from Table K) and 1.20 0.24 0.40 0.46 0.3B a heat gain factor (from Table L). -... Multiply by O.B for low-e glass, 0.7 for tinted glass and 0.6 for low-e tinted Qlass. The end product of this The rough frame area is calculation is an estimate of the generally entered in the table annual cooling load that is and adjusted by the net area associated with each suIface in factor. If the net glazing area is thousands of Btu per year entered instead, then the net (kBtu/yr). area factor is 1.00.

Anytown, USA PASSIVE SOLAR DESIGN STRATEGIES 79

Table M gives the shade If the example building had Step C. Solar Glazing factor for overhangs. The tinted glazing. glazing films or The solar systems addressed on overhang shade factor depends external shading devices. the Worksheet II reduce heating on the orientation of the window shade factors from Table M energy. but they also can and the projection factor. The should not be used. Sunscreen increase cooling energy. The proj ection factor is the overhang and glass manufacturers cooling energy impact of the projection divided by the usually rate the shading effect of solar systems is calculated in distance from the bottom of the their devices by publishing a this step. Each solar system window to the bottom of the shading coefficient. The listed on Worksheet II should be overhang. as illustrated below. shading coefficient is a number carried over to this worksheet. between zero and one that The cooling energy for each A indicates how much solar heat system is calculated by makes it through the window multiplying the total surface compared to an unshaded 1/8 area (not the projected area) inch clear pane. This shading times the net area factor. the coefficient may be used in the appropriate shade factor (as calculation instead of the value discussed above) and a heat from Table M. gain factor (from Table L). This The overhang on the east calculation gives the annual and west is at the eave. well cooling load for each passive above the window. and does not solar system. Overhang Projection Factor provide any useful shading. For A shade factor of 0.83 is The projection factor is the overhang projection divided by the distance between the these windows. the shade factor used because of south bottom of the window and the bottom of the is 1.00. overhangs. This is based on a overhang. Each glazing area is projection factor of about 0.2 as \ The north windows have a multiplied by the net area factor discussed above. height of four feet and the and the appropriate shade The annual cooling load bottom of the overhang is about factor. The products are associated with all the passive six inches above the window summed at the bottom of the solar systems is summed at the head. The overhang projection table. bottom of the table. is 1.5 feet. The projection factor is calculated by dividing the overhang projection by the distance from the bottom of the window to the bottom of the overhang. This is about 0.33. A shade factor of 0.84 is used in the calculations. which is interpolated between the values for a projection factor of 0.2 and 0.4

Anytown, USA 80 SUMMER COOLING PERFORMANCE LEVEL

Step D. Internal Gains Step F. Adjustment for Step G. Cooling The last component of cooling Thermal Mass and Ventilation Performance Level load is from internal gain. The total cooling load calculated The summer cooling \ Internal gain is heat given off by in Step E is adjusted in this step performance level is calculated' ) lights, appliances and people. to account for the effects of by subtracting the adjustment Some of the cooling load thermal mass and ventilation. in Step F from the cooling load associated with internal gain is The adjustment depends on per square foot calculated in considered to be constant for all the total heat capacity per Step E. This is an estimate of houses regardless of the number square foot calculated on the amount of heat that must be of bedrooms or size. This is Worksheet III, Step E, but also removed from the building each because all houses have a depends on whether or not the year by the air conditioner. refrigerator and at least one building has night ventilation or occupant. Another component ceiling fans. The adjustment is Step H. Comparison Cooling of cooling load from internal entered in the blank in Step F. Performance gain is considered to be variable The cooling performance level Table 0-Thermal Mass and Ventilation for the proposed design may be and depends on the number of Adjustment (Btu/yr-sf) bedrooms. These components Total Heat Night Night No Night No Night compared to the base case Capacity Vent wI Vent wI No Vent wI Vent wI N are accounted for separately in per SF Ceil. Fan Ceil. Fan Ceil. Fan Ceil. Fan cooling performance level for the 0.0 4,250 400 2,320 -1,600 the calculation. 1.0 5,550 1,480 3,620 -520 area, given in Table P. 2.0 6,240 2,080 4,310 080 Both the constant 3.0 6,610 2,420 4,680 410 component and the variable 6,800 2,600 4,8 600 . 6,910 2,700 ,0 700 component are taken from Table 6.0 6,960 2,760 5,0 760 dP. 6,990 2,790 , 60 790 N. The variable component is 8.0 7,010 2,810 5,080 810 Alternatively, the cooling 9.0 7,010 2,820 5,080 820 multiplied by the number of 10.0 7,020 2,820 5,090 820 performance level may be compared to other building bedrooms in the house and Total heat capacity per square foot is calculated on added to the constant Worksheet III Ste E. designs conSidered by the ) component to yield the total The example building has a builder to be typical of the area. cooling load from internal gain. total heat capacity per square In this case, the worksheets foot of 5.6. It has neither night would first be completed for the ventilation nor ceiling fans. typical design and the results of Constant Component Variable Component Night ventilation is a these calculations would be building operation strategy entered in Step H. Step E. Cooling Load per where windows are opened at If the cooling performance Square Foot night when the air is cooler. level of the proposed building This step sums the cooling load The cool night air allows heat to (Step G) is greater than the base associated with opaque escape from the thermal mass case or typical-design surfaces, non-solar glazing, elements in the building. The conservation performance level, passive solar systems and cooler thermal mass elements the designer should conSider internal gain (Steps A, B, C and help keep the building measures to reduce the cooling D). The sum is then divided by comfortable the following day performance leveL Such the floor area of the building when air temperatures rise. measures might include and multiplied by 1,000 to reducing non-solar glass, convert the cooling energy into providing additional shading or terms consistent with the base increasing thermal mass. case cooling performance.

Anytown, USA