DOCSLIB.ORG

Solar Thermal Collector Ultrasol

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Solar Thermal Collector Ultrasol Solar thermal collector UltraSol Ultra slim, ultra lightweight, ultra efficient. A range of collectors for all installation methods. 1 Front page: aluFrame – the new diecast aluminium frame for the UltraSol collector range offers maximum strength whilst still boasting an exceptionally slimline, light and shapely design. Solar thermal collector. UltraSol. The sun is an inexhaustible source of energy that costs nothing. Integrating this energy into the heating system as efficiently as possible enables you to conserve resources and, above all, save money. With a Hoval solar energy system, you are opting for an environmentally friendly and sophisticated solution for your heating and hot water supply. The new UltraSol product range is a Hoval innovation that is de- signed to meet today's requirements for top quality, maximum effi- ciency and easy installation. UltraSol offers two types of collectors (UltraSol and UltraSol eco), each of which is available in both a horizontal and a vertical design. They have been designed to have an exceptionally low construction height and weigh very little. Thanks to the installation system and plug-and-play hydraulic kits, all the collectors are suitable for any method of installation – whether they're being placed in a roof, on a roof, incorporated into a flat roof, or simply acting as a free-standing structure. Marking a first for the industry, these products also come with the Hoval aluFrame, an ultra-lightweight diecast aluminium frame whose seamless design keeps the collectors firmly in place and enhances their resilience. To increase its efficiency, the Hoval UltraSol collec- tor features a special antireflective coating applied to the solar glass, which blends discreetly into the roof. The UltraSol collector As a system provider, Hoval integrates the UltraSol collectors into offers flexible design and installation options. the heating system with maximum efficiency – and provides every- thing from a single source, including the TopTronic®T control unit. 2 3 UltraSol. UltraSol. UltraSol. Your advantages at a glance. Shapely, flexible, easy to install. Your advantages at a glance. The solar energy system uses free, sustainable solar energy to heat water and even the The solar energy system uses free, sustainable solar energy to heat water and even the building itself, depending on the season – an excellent reason to choose an economical, building itself, depending on the season – an excellent reason to choose an economical, environmentally friendly system like this one. The Hoval UltraSol solar collectors offer a flexible environmentally friendly system like this one. The Hoval UltraSol solar collectors offer a flexible Large, almost borderless Solar safety glass with Heat insulation solution, as each of the two collector types can be installed both horizontally and vertically. collector area antireflective coating made from mineral wool solution, as each of the two collector types can be installed both horizontally and vertically. for maximum solar yield for maximum efficiency Their low construction height, plus the option of an extra-slim diecast aluminium frame and the (standard surface for UltraSol eco) Their low construction height, plus the option of an extra-slim diecast aluminium frame and the UltraSol antireflective solar glass, combine to form a remarkably sleek yet discreet look. UltraSol antireflective solar glass, combine to form a remarkably sleek yet discreet look. Sophisticated Easy to use Sophisticated Easy to use Flexible design One installation system Flexible design One installation system and installation for all collectors and installation for all collectors ▪ Low height and high stability due to a ▪ Quick and easy installation due to an easy-to- ▪ Low height and high stability due to a ▪ Quick and easy installation due to an easy-to- sophisticated design with an exceptionally use connection system for the entire UltraSol range sophisticated design with an exceptionally use connection system for the entire UltraSol range slim diecast aluminium frame ▪ Simple hydraulic integration slim diecast aluminium frame ▪ Simple hydraulic integration ▪ All installation methods possible due to a meander absorber and 4 connections ▪ All installation methods possible due to a meander absorber and 4 connections with one range of collectors ▪ Convenient operation due to a single TopTronic® T with one range of collectors ▪ Convenient operation due to a single TopTronic® T ▪ Minimal glare from the sun control for heating, hot water and solar power ▪ Minimal glare from the sun control for heating, hot water and solar power thanks to antireflective solar glass ▪ Perfect integration into the heating system thanks to antireflective solar glass ▪ Perfect integration into the heating system using Hoval system solutions – everything from a using Hoval system solutions – everything from a single source single source Ecological Economical Ecological Economical Built-in hydraulic connections Full-surface meander absorber 4 hydraulic connections for quick and simple installation for a uniform flow for maximum flexibility Using clean solar High solar yield and reliable connection of even large Using clean solar High solar yield energy efficiently saves on heating costs collector areas. energy efficiently saves on heating costs ▪ Free from CO2 and emissions ▪ High solar yield due to cutting-edge technology ▪ Free from CO2 and emissions ▪ High solar yield due to cutting-edge technology ▪ 60-80% of the energy for water heating ▪ Savings made on energy consumption costs Technical data UltraSol UltraSol eco Designs ▪ 60-80% of the energy for water heating ▪ Savings made on energy consumption costs through the use of free solar energy. Solar Keymark certification yes vertical installation horizontal installation through the use of free solar energy. ▪ 20-50% of the energy for heating backup ▪ 20-50% of the energy for heating backup Efficiency η 0.851 0.797 supplies ▪ Further savings made on electricity costs 0 supplies ▪ Further savings made on electricity costs through the use of solar heat for washing machines Total surface area m2 2.52 H through the use of solar heat for washing machines and dishwashers H and dishwashers Absorber surface m2 2.36 ▪ Savings made due to regional subsidy programmes W ▪ Savings made due to regional subsidy programmes Dimensions (WxHxD) vertical design 1230 x 2050 x 54 mm horizontal design 2050 x 1230 x 54 W Subject to modification 4 7 4 UltraSol. Sophisticated design for a sleek look, easy installation and a high solar yield. Perfect integration into every Unique, slim, diecast aluminium Meander absorber with Coated antireflective solar glass A flexible installation system for A design to suit your needs roof type frame 4 connections all collectors The Hoval UltraSol collector range The specially-made diecast aluminium The full-surface meander absorber in Selecting the coating for the solar The sophisticated fastening system If requested, Hoval is able to comprises two collector types, each frame, aluFrame, is the largest in the UltraSol system creates a uniform glass not only meant considering its for both types of collectors means that help design the entire solar of which is available in a vertical and Europe to be produced using this flow and excellent heat transmission visual effect and ensuring limited installation takes no time at all, energy system. This includes a horizontal design. This flexibility, manufacturing technique. Its benefits from the solar energy to the solar glare; above all else, it was also whether it involves in-roof, on-roof, the quantity and orientation of coupled with the absorber surface come in the form of a seamless fluid. necessary to select a coating that flat roof or free-standing methods. the collectors, the sets of solar gained from the ultra-slim, diecast frame, which offers a greater level of would maximise solar yield. The fittings, the buffer storage The 4 UltraSol connections enable The matching components form part aluminium frame, allow for optimum stability than types with joints. This is antireflective coating on the UltraSol tanks, the additional heat simple hydraulic integration whilst of the installation kit for each variant. use of the roof space. The range ideal not only when transporting the collector reflects less incidental generators for months when it offering a high level of flexibility: the This means that each kit contains the accommodates every type of installa- frame, but also when handling it sunlight, allowing it to use and store is less sunny, and the control individual collectors can be connected fastening system required for installa- tion (in-roof, on-roof, flat roof and during the installation process. Once more heat. unit. in parallel or in series, as required. tion, plus a hydraulic kit. For in-roof free-standing) thanks to coordinated on the roof, the slim side profile of the This enables the hydraulic resistance Both UltraSol collectors easily meet installations, the cladding can either As a complete provider, Hoval installation systems and hydraulic kits. frame makes the collector area to be adjusted precisely to the needs annual minimum yield requirements be supplied by Hoval or provided by ensures that all system appear almost as if it had no borders, of the application, making the UltraSol for collectors (525 kWh/m2) and have the customer, depending on require- com ponents are perfectly coor- creating a harmonious visual effect. ideal even for large systems. The been granted Solar Keymark certifica-
Load more

Recommended publications
  • Solar Energy: State of the Art
    Downloaded from orbit.dtu.dk on: Sep 27, 2021 Solar energy: state of the art Furbo, Simon; Shah, Louise Jivan; Jordan, Ulrike Publication date: 2003 Document Version Publisher's PDF, also known as Version of record Link back to DTU Orbit Citation (APA): Furbo, S., Shah, L. J., & Jordan, U. (2003). Solar energy: state of the art. BYG Sagsrapport No. SR 03-14 General rights Copyright and moral rights for the publications made accessible in the public portal are retained by the authors and/or other copyright owners and it is a condition of accessing publications that users recognise and abide by the legal requirements associated with these rights. Users may download and print one copy of any publication from the public portal for the purpose of private study or research. You may not further distribute the material or use it for any profit-making activity or commercial gain You may freely distribute the URL identifying the publication in the public portal If you believe that this document breaches copyright please contact us providing details, and we will remove access to the work immediately and investigate your claim. Editors: Simon Furbo Louise Jivan Shah Ulrike Jordan Solar Energy State of the art DANMARKS TEKNISKE UNIVERSITET Internal Report BYG·DTU SR-03-14 2003 ISSN 1601 - 8605 Solar Energy State of the art Editors: Simon Furbo Louise Jivan Shah Ulrike Jordan Department of Civil Engineering DTU-bygning 118 2800 Kgs. Lyngby http://www.byg.dtu.dk 2003 PREFACE In June 2003 the Ph.D. course Solar Heating was carried out at Department of Civil Engineering, Technical University of Denmark.
    [Show full text]
  • UCS 240 IOM Rev. D
    Model UCS-240 CONDENSING GAS FIRED FLOOR OR WALL MOUNTED BOILER INSTALLATION, OPERATION & MAINTENANCE MANUAL Manufactured by: ECR International Inc. 2201 Dwyer Avenue, Utica, NY 13501 Tel. 800 253 7900 www.ecrinternational.com P/N 240011654 Rev. D [09/15/2017] VERIFY CONTENTS RECEIVED Safety Relief Valve Fully Assembled Boiler Metal Wall Bracket (Maximum 50 PSI) Temperature Includes essential documents. TP Gauge and Safety Relief Drain Valve Gas Shutoff Valve Document Package Valve Connections Used for measuring outside Used for connecting temperature condensate piping to boiler Condensate Drain Outdoor Sensor Connections 2 P/N 240011654, Rev. D [09/15/2017] TABLE OF CONTENTS 1 - Important Information .................................... 5 9 - Start Up Procedure ........................................ 52 2 - Introduction .................................................... 6 9.1 Fill Condensate Trap with Water ....................52 3 - Component Listing .......................................... 7 9.2 Commission Setup (Water) ...........................52 4 - Locating Boiler ................................................ 8 9.3 Commission Setup (Gas) .............................53 5 - Hydronic Piping ............................................. 11 9.4 Commission Setup (Electric) .........................53 5.2 Special Conditions .......................................11 9.5 Control Panel............................................. 54 5.3 Safety Relief Valve and Air Vent ....................12 9.6 Deaeration Function.....................................55
    [Show full text]
  • A Review of Building Integrated Solar Thermal (Bist)
    enewa f R bl o e ls E a n t e n r e g Journal of y m a a n d d Zhang et al., n u A J Fundam Renewable Energy Appl 2015, 5:5 F p f p Fundamentals of Renewable Energy o l i l ISSN: 2090-4541c a a DOI: 10.4172/2090-4541.1000182 n t r i o u n o s J and Applications Review Article Open Access Building Integrated Solar Thermal (BIST) Technologies and Their Applications: A Review of Structural Design and Architectural Integration Xingxing Zhang*1, Jingchun Shen1, Llewellyn Tang*1, Tong Yang1, Liang Xia1, Zehui Hong1, Luying Wang1, Yupeng Wu2, Yong Shi1, Peng Xu3 and Shengchun Liu4 1Department of Architecture and Built Environment, University of Nottingham, Ningbo, China 2Department of Architecture and Built Environment, University of Nottingham, UK 3Beijing Key Lab of Heating, Gas Supply, Ventilating and Air Conditioning Engineering, Beijing University of Civil Engineering and Architecture, China 4Key Laboratory of Refrigeration Technology, Tianjin University of Commerce, China Abstract Solar energy has enormous potential to meet the majority of present world energy demand by effective integration with local building components. One of the most promising technologies is building integrated solar thermal (BIST) technology. This paper presents a review of the available literature covering various types of BIST technologies and their applications in terms of structural design and architectural integration. The review covers detailed description of BIST systems using air, hydraulic (water/heat pipe/refrigerant) and phase changing materials (PCM) as the working medium. The fundamental structure of BIST and the various specific structures of available BIST in the literature are described.
    [Show full text]
  • Consumer Guide: Balancing the Central Heating System
    Consumer Guide: Balancing the central heating system System Balancing Keep your home heating system in good working order. Balancing the heating system Balancing of a heating system is a simple process which can improve operating efficiency, comfort and reduce energy usage in wet central heating systems. Many homeowners are unaware of the merits of system balancing -an intuitive, common sense principle that heating engineers use to make new and existing systems operate more efficiently. Why balance? Balancing of the heating system is the process of optimising the distribution of water through the radiators by adjusting the lockshield valve which equalizes the system pressure so it provides the intended indoor climate at optimum energy efficiency and minimal operating cost. To provide the correct heat output each radiator requires a certain flow known as the design flow. If the flow of water through the radiators is not balanced, the result can be that some radiators can take the bulk of the hot water flow from the boiler, leaving other radiators with little flow. This can affect the boiler efficiency and home comfort conditions as some rooms may be too hot or remain cold. There are also other potential problems. Thermostatic radiator valves with too much flow may not operate properly and can be noisy with water “streaming” noises through the valves, particularly as they start to close when the room temperature increases. What causes an unbalanced system? One cause is radiators removed for decorating and then refitted. This can affect the balance of the whole system. Consequently, to overcome poor circulation and cure “cold radiators” the system pump may be put onto a higher speed or the boiler thermostat put onto a higher temperature setting.
    [Show full text]
  • Microgeneration Strategy: Progress Report
    MICROGENERATION STRATEGY Progress Report JUNE 2008 Foreword by Malcolm Wicks It is just over two years since The Microgeneration Strategy was launched. Since then climate change and renewables have jumped to the top of the global and political agendas. Consequently, it is more important than ever that reliable microgeneration offers individual householders the chance to play their part in tackling climate change. In March 2006, there was limited knowledge in the UK about the everyday use of microgeneration technologies, such as solar thermal heating, ground source heat pumps, micro wind or solar photovolatics. Much has changed since then. Thousands of people have considered installing these technologies or have examined grants under the Low Carbon Buildings Programme. Many have installed microgeneration and, in doing so, will have helped to reduce their demand for energy, thereby cutting both their CO2 emissions and their utility bills. The Government’s aim in the Strategy was to identify obstacles to creating a sustainable microgeneration market. I am pleased that the majority of the actions have been completed and this report sets out the excellent progress we have made. As a consequence of our work over the last two years, we have benefited from a deeper understanding of how the microgeneration market works and how it can make an important contribution to a 60% reduction in CO2 emissions by 2050. Building an evidence base, for example, from research into consumer behaviour, from tackling planning restrictions and from tracking capital costs, means that we are now in a better position to take forward work on building a sustainable market for microgeneration in the UK.
    [Show full text]
  • The Role of Micro-Generation Technologies in Alleviating Fuel
    The role of micro -generation technologies in alleviating fuel poverty In a bid to ease the burden of fuel poverty, social housing providers are increasingly turning to micro-generation technologies to help reduce fuel costs. However, with many different types of micro-generation technologies on the market, designers need to know which technologies offer the best chance of alleviating fuel poverty The aim of the study was to determine the The three different types of micro-generation impact of micro-renewable energy technologies technologies were evaluated across three in alleviating fuel poverty. In particular, it sought different case study schemes in South to establish which micro-renewable energy Yorkshire and the West Midlands. Evaluation technologies offered the most cost-effective of the technologies involved monitoring their means of alleviating fuel poverty; and the factors performance, interviewing residents, collecting that influenced the cost-effectiveness of such longitudinal household energy consumption technologies. In doing so we focused on three data and modelling the financial payback of types of technology: ground source heat pumps the systems. (GSHPs); solar thermal hot water (STHW) systems; and solar photovoltaic (PV) systems. Key findings Solar thermal hot water systems The study was conducted by Fin O'Flaherty of STHW systems are not a cost-effective the Centre for Infrastructure Management and measure for alleviating fuel poverty, based on James Pinder, Visiting Fellow, Sheffield Hallam University. the data from our case studies. Although they are relatively cheap to purchase and install (at Background around £3,500 each), the net financial savings This report is based on the findings of a two generated from STHW systems are relatively year study into the role that micro-generation small (approximately £50 per year in this technologies can play in alleviating fuel study), particularly for under-performing poverty in the UK.
    [Show full text]
  • Boiler Recognized KD Navien Fulfilling Social and Environment That Brings Creativity by Global Market Responsibility for Better Tomorrow
    Smarter Living Environment Partner, KD Navien O N E R O A D , O N E H E R I T A G E Great Heritage preserving Energy and Environment, creating the right path Introduction of KD Navien C O N T E N T S KD Navien’s response to Energy KD Navien’s pride in technology Korea’s No. 1 Boiler recognized KD Navien fulfilling social and Environment that brings creativity by Global Market responsibility for better tomorrow R E S P O N S E O R I G I N A L I T Y A C H I E V E M E N T D R E A M KD Navien’s R E S P O N S E To Energy and Environment 1951 Musan briquet factory MuSan, the name chosen in the hope that mountains would be covered opening in ruins in Korean rich with woods by reducing the use of firewood. postwar In those days when it was extremely hard to survive cold winter, KyungDong’s journey had started at this small factory making and selling 茂山 good quality briquet. 1978 The beginning of the great In the 1970s that suffered twice from oil crisis, KD Navien which took its dream opening the era of first step with the name of KyungDong machinery during this global zero energy energy crisis, presented a new way to Korean heating industry by launching an all-in-one quadrangle boiler, which was the first residential boiler in domestic market. 1988 The first condensing KD Navien developed the first condensing boiler in Asia with the belief boiler in Asia that condensing is the right way, and with the principle of preserving energy and environment, and been continuing its sole path with condensing technology despite the market ignorance and numerous interference from competitors 1991 Development of artificial KD Navien has successfully developed and supplied the first artificial soil soil creating urban in Korea to purify air pollution in populous cities and is improving urban ecological greenery environment to breath by greenery project utilizing the forsaken area.
    [Show full text]
  • (2015): Performance Rating of Commercial Space Heating Boilers
    ANSI/AHRI Standard 1500 2015 Standard for Performance Rating of Commercial Space Heating Boilers Approved by ANSI on 28 November 2014 IMPORTANT SAFETY DISCLAIMER AHRI does not set safety standards and does not certify or guarantee the safety of any products, components or systems designed, tested, rated, installed or operated in accordance with this standard/guideline. It is strongly recommended that products be designed, constructed, assembled, installed and operated in accordance with nationally recognized safety standards and code requirements appropriate for products covered by this standard/guideline. AHRI uses its best efforts to develop standards/guidelines employing state-of-the-art and accepted industry practices. AHRI does not certify or guarantee that any tests conducted under its standards/guidelines will be non-hazardous or free from risk. Note: This standard supersedes AHRI Hydronics Institute Standard BTS-2000 Rev. 06.07. INFORMATIVE NOTE AHRI CERTIFICATION PROGRAM PROVISIONS Scope of the Certification Program (See Section 2 for Scope of the Standard) The certification program includes all gas- and oil-fired steam and hot water Heating Boilers with inputs ranging from 300,000 Btu/h to 2,500,000 Btu/h. Models within a model series, or individual boiler models, having inputs over 2,500,000 Btu/h may be included in the program at the Participant’s option. Certified Ratings The following certification program ratings are verified by test: All steam boilers, and hot water boilers from 300,000 Btu/h up to and including 2,500,000 Btu/h. 1. Thermal Efficiency, % (required) 2. Combustion Efficiency, % (optional) Hot water boilers above 2,500,000 Btu/h.
    [Show full text]
  • Energy Saving Trust CE131. Solar Water Heating Systems: Guidance For
    CE131 Solar water heating systems – guidance for professionals, conventional indirect models Contents 1 Solar hot water systems 3 1.1 Scope 3 1.2 Introduction 3 1.3 Safety 4 1.4 Risk assessment 5 1.5 Town and country planning 5 2 Design overview 6 2.1 Introduction 6 2.2 Solar domestic hot water (SDHW) energy 6 2.3 SDHW systems 7 3 Design detail 8 3.1 Collectors 8 3.2 Solar primary types 9 3.3 Primary system components 10 3.4 Secondary systems 11 3.5 Pre-heat storage 11 3.6 Auxiliary DHW heating 14 3.7 Combined storage – twin-coil cylinders 15 3.8 Separate storage – two stores 15 3.9 Separate storage – direct DHW heaters 16 3.10 Risk of scalding 16 3.11 Risk of bacteria proliferation 17 3.12 Risk of limescale 17 3.13 Energy conservation 18 3.14 Controls and measurement 20 4 Installation and commissioning 23 4.1 Installation tasks: site survey – technical 23 4.2 Installation tasks: selecting specialist tools 28 4.3 Installation tasks: Initial testing 28 4.4 Commissioning 29 5 Maintenance and documentation 30 6 Appendices 31 6.1 Sample commissioning sheet 31 6.2 Annual solar radiation (kWh/m2) 33 6.3 Sample installation checklist 33 6.4 Further reading 37 6.5 Regulations 38 6.6 Other publications 39 7 Glossary 40 The Energy Saving Trust would like to thank the Solar Trade Association for their advice and assistance in producing this publication. 2 Solar water heating systems – guidance for professionals, conventional indirect models 1 Solar hot water systems 1.1 Scope By following the Energy Saving Trust’s best practice This guide is designed to help installers, specifiers and standards, new build and refurbished housing will commissioning engineers ensure that conventional be more energy efficient – reducing these emissions indirect solar domestic hot water systems (SDHW) and saving energy, money and the environment.
    [Show full text]
  • Sulfur Heating Oil and Condensing Appliances
    IMPROVED EFFICIENCY AND EMISSIONS WITH LOW- SULFUR HEATING OIL AND CONDENSING APPLIANCES Wai-Lin Litzke, Dr. Thomas Butcher and Roger McDonald ABSTRACT High levels of fine particulate matter (PM2.5) in NYC and surrounding metropolitan areas have been attributed mostly to diesel engines with contributions from oil used for heating during the wintertime. No. 2 heating oil consumption, typically high-sulfur, is concentrated in the Northeast region with about 3.4 billion gallons (1997 data) used annually in the Mid-Atlantic states (NJ, NY and PA). Improved energy efficiency of furnaces and boilers with significant reductions in sulfur oxides and total particulate matter can be achieved through the use of low-sulfur fuels. Reducing sulfur levels even further to ultra-low levels, which is now available as transportation diesel, allows for continued advances in condensing oil-fired systems. These advances allow for up to 10% improvements in energy efficiency or 94% efficient systems. Brookhaven National Laboratory is developing these technologies with the objectives of quantifying the efficiency benefits in addition to characterization of emissions. These new technologies offer significant energy benefits but it is not known what their impacts will be on particulate emissions. For example, in the case of condensing boilers do these systems provide an opportunity to capture some of the particles on wet surfaces before being emitted? This poster will present specific data on the correlation between sulfur levels and PM2.5 using a new, portable dilution tunnel sampling system for condensing boilers and furnaces in residential systems. Schematic of PM2.5 Measurement System Energy Consumption Estimates by Sector (2001), DOE/EIA EPA Conditional Test Method CTM 39 Distillate for Residential Heating Distillate for Transportation Stack 142-mm Filter Heated Box 40000 Mixing Cone R.H.
    [Show full text]
  • Solar Hot Water & Hydronics
    Solar Hot Water & Hydronics Sizing and Selection Guide List Prices 2009 Contractors • Wholesalers STS Solar Storage Plus System Boiler More Solar, Less Gas Solar Recirc Supply Recirculate Excess Hot Water Solar Heat To Gas Fired Tank To Heating Supply Hydronic Heating Air Handler Electric Radiant Element Solar Convector Hot Hot Water 92% Efficient Heating Return Electric Water Capacities Element Hot Water Coil Electric 92% AFUE Element 130,000 BTU Munchkin 199,000 BTU Solar Pump Boiler Potable Module Potable Solar 80 gallon Expansion Expansion Hot Water Tank Tank Recirculation 119 gallon 10K 10K 10K Sensor Sensor Expansion 10K Sensor Solar Pump Tank Sensor Solar Pump Module Taco Module Solar Coil 003 Solar Coil P1 Cold IFC Solar Coil P1 Potable P2 Expansion Tank Solar Heat Exchanger Drain Cold Cold Connects Circulator to Control Circulator & Check Valve Solar Tank Closed Loop Conventional Gas Water Heater www.stssolar.com Solar Thermal Systems • 4723 Tidewater Avenue • Oakland, CA 94601 • t 800-493-8432 • f 510-434-3142 • www.stssolar.com Solar Booklet_0409 Introduction Solar Thermal Systems About STS STS is a California and Nevada primary packager of certified solar hot water systems, solar collectors, tanks and other solar products serving the wholesale, contracting and specification, community. Our products are represented exclusively by Manufacturers Representative JTG/Muir. For technical information, literature and a list of distributors please call 800- 493-8432 and visit our web site at www.stssolar.com. Experience Our company has a combined 55 years of solar thermal experience. We are committed to providing quality systems and components with excel- lent performance designed to operate reliably and durably.
    [Show full text]
  • Characterization and Energy Performance of a Slurry PCM-Based Solar Thermal Collector: a Numerical Analysis
    View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by PORTO Publications Open Repository TOrino Politecnico di Torino Porto Institutional Repository [Article] Characterization and energy performance of a slurry PCM-based solar thermal collector: a numerical analysis Original Citation: Serale G.; Baronetto S.; Goia F.; Perino M. (2014). Characterization and energy performance of a slurry PCM-based solar thermal collector: a numerical analysis. In: ENERGY PROCEDIA, vol. 48, pp. 223-232. - ISSN 1876-6102 Availability: This version is available at : http://porto.polito.it/2592626/ since: February 2015 Publisher: Elsevier Published version: DOI:10.1016/j.egypro.2014.02.027 Terms of use: This article is made available under terms and conditions applicable to Open Access Policy Article ("Creative Commons: Attribution-Noncommercial-No Derivative Works 3.0") , as described at http: //porto.polito.it/terms_and_conditions.html Porto, the institutional repository of the Politecnico di Torino, is provided by the University Library and the IT-Services. The aim is to enable open access to all the world. Please share with us how this access benefits you. Your story matters. Publisher copyright claim: This is the publisher’s version of a proceedings published on [pin missing: event_title], Publisher [pin missing: publisher], Vol 48 , Number UNSPECIFIED Year 2014 (ISSN epc:pin name ="issn"/> - ISBN [pin missing: isbn] )The present version is accessible on PORTO, the Open Access Repository of the Politecnico of Torino
    [Show full text]