DOCSLIB.ORG

HTP-Hybrid-Water-Heater.Pdf

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
HTP-Hybrid-Water-Heater.Pdf Advanced Heating & Hot Water Systems u e SEfficientp r Hybrid Heat Pump Water Heater Hybrid Heat Pump Water Heater 2.26 Energy Factor: EF (energy factor) The Most Energy Efficient is the over all efficiency rating of the water heater. The higher the EF the more efficient the model. 50-Gallon Electric Water Standard Electric Water Heater: 0.90 EF Versus Heater You Can Buy HTP Hybrid Heat Pump Water Heater: 2.26 EF HTP’s Hybrid has an EF that’s more than 2.5 times better Standard Electric. That’s Real Energy savings! Over Twice The HTP’s Hybrid also exceeds energy star performance of 2.0 Efficiency of Standard Fast Recovery Electric Water Heaters 60 GPH First Hour Rating 3.0 COP (Coefficient of performance): For every Unit of power that Easy Installation the heat pump uses it can produce 3 units of heated water output Eco Friendly - Low NOx 2 kw & Low CO2 Emissions 3 kw Heat Water Output Electric Backup Save The Most Where Electricity Rates Are Highest And Where The Weather Is The Warmest Zone 3 Zone 2 Zone 1 Zone 1 Mostly heat pump Zone 3 Heat pump in operation Zone 2 conjunction with Heat pump and electric heating backup electric elements for quick recovery Recycle Conditioned Exhaust Air 10 Year Warranty to Dehumidify or Cool Your Home The only Heat Pump on the market Coil is wrapped outside the tank. No contamination potential. with up to 15 ft vent length Cool Air Output Warm Air Inlet Up to 15 ft Refrigerant outlet Filter Refrigerant Inlet The Filter Slides Out for Easy Cleaning A Family Can Save Over $300 Per Year In Energy Costs! How does the heat pump work? 1. A variable speed fan brings in air 2. Heat in the air is absorbed by the refrigerant inside the evaporator coil 3. The warm refrigerant is pumped through a compressor, which raises the temperature even more 4. A condenser coil cradles the tank and transfers heat in to the tank 5. Hot water is produced super efficiently 6. Cooler and dehumidified air is a welcome by-product Save Money on Annual Operating Cost Comparison Cost of Operation Standard 50 Gal. Electric WH vs HTP 50 Gal. Heat Pump WH $600 Estimated $500 Homeowner Payback: $400 BIG Standard Savings! 3 YEAR $300 50 Gal. Electric Payback $200 Water Heater HTP Heat Pump Payback with the application 50 Gal. Electric of 2011 federal tax credit, other $100 Water Heater rebates may also apply 0 Take Charge of Efficiency with Four Operating Modes Economy Mode Vacation Mode The most efficient energy saving mode. The unit Save energy while away by using vacation mode. extracts energy from surrounding air and delivers it While in energy mode the unit will drop temperature to the stored water. This mode provides an industry down to 50 °F to save energy and prevent water from leading 2.26 energy factor (EF) with a first hour rating freezing. Set the unit from 3 to 99 days away. The unit that reaches up to 60 gallons. will automatically turn on one day before you come back, ensuring warm water on your return. Auto Mode The unit decide’s which mode to achieve optimum Standard Electric efficiency and comfort. Auto mode uses the heat This mode is used during high load conditions pump as the primary heat source while the standard where the unit may need to expand more energy electrical elements provide a backup heat source when than usual. extra recovery is needed. Demand Response HTP’s Hybrid Heat Pump Top Cover Electronic Water Heater has the ability to Control Box utilize the Demand Response Blower Filter System that many utility Assembly companies provide. This water heater, equipped with a DR module, will automatically Rear Shroud Front Shroud recognize which energy cost rate is available and adjust its mode and temperature setting Display to use less energy when rates Evaporator T2 are at their highest and then adjust to utilize more energy TCO when rates are at their lowest. P&T Valve This is a real money saver! Demand Cover, Electric HTP Heat Pump Response Heating Element 64.6 inches 64.6 Water Heater Input (Upper) Water Outlet Model: HPW-50-6 Water Inlet TOD Weight: 200 lbs. First Hour Rating: 60 Gal. Front Decorative Handles for Easy COP: 3.0 Installation Cover EF Rating: 2.26 Ambient Temp: up to 115°F Cover, Electric Electric Heating Water Temp: 110° to 140°F Heating Element Element (Upper) (Lower) Height: 64.6” Drain Valve Diameter: 22.3” Electric Heating 50 Gallon Element (Lower) 22.3 inches www.htproducts.com • HTP, East Freetown, MA © HTP 4/2011 • MKTLIT-29.
Load more

Recommended publications
  • COMFORT™ SERIES PACKAGED HEAT PUMP and PACKAGED HYBRID HEAT® SYSTEMS High-Efficiency Packaged Products with Your Comfort in Mind
    COMFORT™ SERIES PACKAGED HEAT PUMP AND PACKAGED HYBRID HEAT® SYSTEMS High-efficiency packaged products with your comfort in mind Models 50VT, 48VT DESIGNED WITH YOUR COMFORT IN MIND Innovation, efficiency, quality: Our Comfort™ Series packaged heat pumps and packaged Hybrid Heat® systems represent years of research and design with one goal in mind – helping your family with comfort solutions. With durable, lasting comfort and the option to choose a traditional heat pump or gas furnace and heat pump combined, Comfort™ Series packaged products offer the Carrier quality, environmental stewardship and lasting durability that have endured for more than a century. While both of these packaged products provide comfort all year long, our Hybrid Heat systems can be an excellent choice in areas where having both gas and electric heat pump heating are desirable for maximum comfort and energy savings. EFFICIENCY SEER (Seasonal Energy Efficiency Ratio), HSPF (Heating Seasonal Performance Factor) and AFUE (Annual Fuel Utilization Efficiency) ratings are like your car’s MPG – the higher the number, the greater the potential for savings. Comfort™ Series packaged heat pumps and packaged Hybrid Heat systems offer up to 14.5 SEER cooling and 8.0 HSPF heating. The packaged Hybrid Heat system also reaches 81% AFUE gas heating. DURABILITY A galvanized steel cabinet and heavy-duty wire coil guard provide protection against dings, dents and other outdoor threats. Our unique cabinet design puts the condensing coil above ground level and further out of harm’s way. The bottom half of the cabinet is fully sealed to help keep moisture, leaves, dirt and other potential corrosives out.
    [Show full text]
  • New Low-Temperature Central Heating System Integrated with Industrial Exhausted Heat Using Distributed Electric Compression Heat Pumps for Higher Energy Efficiency
    energies Article New Low-Temperature Central Heating System Integrated with Industrial Exhausted Heat Using Distributed Electric Compression Heat Pumps for Higher Energy Efficiency Fangtian Sun 1,2,*, Yonghua Xie 1, Svend Svendsen 2 and Lin Fu 3 1 Beijing Research Center of Sustainable Energy and Buildings, Beijing University of Civil Engineering and Architecture, Beijing 100044, China; [email protected] 2 Department of Civil Engineering, Technical University of Denmark, 2800 Lyngby, Denmark; [email protected] 3 Department of Building Science, Tsinghua University, Beijing 100084, China; [email protected] * Correspondence: [email protected]; Tel.: +86-010-6832-2133; Fax: +86-010-8836-1680 Received: 23 October 2020; Accepted: 9 December 2020; Published: 14 December 2020 Abstract: Industrial exhausted heat can be used as the heat source of central heating for higher energy efficiency. To recover more industrial exhausted heat, a new low-temperature central heating system integrated with industrial exhausted heat using distributed electric compression heat pumps is put forward and analyzed from the aspect of thermodynamics and economics. The roles played by the distributed electric compression heat pumps in improving both thermal performance and financial benefit of the central heating system integrated with industrial exhausted heat are greater than those by the centralized electric compression heat pumps. The proposed low-temperature central heating system has higher energy efficiency, better financial benefit, and longer economical distance of transmitting exhausted heat, and thus, its configuration is optimal. For the proposed low-temperature central heating system, the annual coefficient of performance, annual product exergy efficiency, heating cost, and payback period are about 22.2, 59.4%, 42.83 ¥/GJ, and 6.2 years, respectively, when the distance of transmitting exhausted heat and the price of exhausted heat are 15 km and 15 ¥/GJ, respectively.
    [Show full text]
  • Small Office Incentive Workbook
    BUSINESS New Buildings SMALL OFFICE INCENTIVE WORKBOOK SIMPLE SOLUTIONS FOR BIG ENERGY SAVINGS Boost operating income and asset value boost of $168,700. Energy-efficient value through energy efficiency solutions also can contribute to enhanced tenant comfort, higher occupancy rates and Energy Trust of Oregon knows that reducing lower operation and maintenance costs. building energy use by installing energy- efficient equipment and systems has been Energy Trust can help you capture these benefits shown to increase net operating income, or and earn cash incentives for energy-efficient NOI, and asset value. For example, according equipment and building practices with our market to ENERGY STAR®, installing a highly efficient solutions package for office buildings less than variable refrigerant flow, or VRF, heating 70,000 square feet. Whether you’re planning system in a 40,000-square-foot office to build a new office or kicking off a major building can save up to $0.34 per square foot renovation, it provides a simple way to identify every year in energy costs, translating into an the best energy solutions for your office space. additional NOI of $13,496. At a cap rate* of eight percent, this results in a potential asset * NOI divided by the sales price or value of a property expressed as a percentage. Energy Trust outreach managers can offer input and feedback as you make energy-related decisions and assist you in completing this workbook. If you have questions or need help getting started, contact the outreach manager listed here. Name Email Phone Number 1 HOW TO USE THIS WORKBOOK What is the small office incentive package? This package offers an all-in-one, step-by-step process for designing and selecting energy-efficient systems and equipment that are cost-effective and qualify for cash incentives.
    [Show full text]
  • Impact of Cogeneration System Performance on Energy, Environment, and Economics †
    energies Article Decarbonization of Residential Building Energy Supply: Impact of Cogeneration System Performance on Energy, Environment, and Economics † Praveen K. Cheekatamarla Buildings and Transportation Science Division, Oak Ridge National Laboratory, 1 Bethel Valley Road, Oak Ridge, TN 37830, USA; [email protected]; Tel.: +1-865-341-0417 † This manuscript has been authored by UT-Battelle, LLC under Contract No. DE-AC05-00OR22725 with the U.S. Department of Energy. The United States Government retains and the publisher, by accepting the article for publication, acknowledges that the United States Government retains a non-exclusive, paid-up, irrevoca-ble, world-wide license to publish or reproduce the published form of this manuscript, or allow others to do so, for United States Government purposes. The Department of Energy will provide public access to these re-sults of federally sponsored research in accordance with the DOE Public Access Plan (http://energy.gov/downloads/doe-public-access-plan). Abstract: Electrical and thermal loads of residential buildings present a unique opportunity for onsite power generation, and concomitant thermal energy generation, storage, and utilization, to decrease primary energy consumption and carbon dioxide intensity. This approach also improves resiliency and ability to address peak load burden effectively. Demand response programs and grid-interactive buildings are also essential to meet the energy needs of the 21st century while addressing climate impact. Given the significance of the scale of building energy consumption, this study investigates how cogeneration systems influence the primary energy consumption and carbon footprint in residential buildings. The impact of onsite power generation capacity, its electrical and thermal efficiency, and its Citation: Cheekatamarla, P.K.
    [Show full text]
  • A Pocket Guide to All-Electric Retrofits of Single-Family Homes
    Sean Armstrong’s House in Arcata, CA The Heat Pump Store in Portland, Oregon Jon and Kelly’s Electrified Home in Cleveland, OH Darby Family Home, New York A Pocket Guide to All-Electric Retrofits of Single-Family Homes A Water Vapor Fireplace by Nero Fire Design A Big Chill Retro Induction Range A NeoCharge Smart Circuit Splitter February 2021 Contributing Authors Redwood Energy Sean Armstrong, Emily Higbee, Dylan Anderson Anissa Stull, Cassidy Fosdick, Cheyenna Burrows, Hannah Cantrell, Harlo Pippenger, Isabella Barrios Silva, Jade Dodley, Jason Chauvin, Jonathan Sander, Kathrine Sanguinetti, Rebecca Hueckel, Roger Hess, Lynn Brown, Nicholas Brandi, Richard Thompson III, Romero Perez, Wyatt Kozelka Menlo Spark Diane Bailey, Tom Kabat Thank you to: The many generous people discussed in the booklet who opened their homes up for public scrutiny, as well as: Li Ling Young of VEIC Rhys David of SMUD Nate Adams of Energy Smart Ohio Jonathan and Sarah Moscatello of The Heat Pump Store The Bay Area Air Quality Management for their contribution in support of this guide Erika Reinhardt Thank you for contributing images of your beautiful homes and projects! Barry Cinnamon, Diane Sweet of EmeraldECO, Dick Swanson, Eva Markiewicz and Spencer Ahrens, Indra Ghosh, Jeff and Debbie Byron, Mary Dateo, Pierre Delforge And thank you to those who reviewed and edited! Bruce Naegel, David Coale, David Moller, Edwin Orrett, Nick Carter, Reuben Veek, Robert Robey, Rob Koslowsky, Sara Zimmerman, Sean Denniston, Steve Pierce Contact This report was produced for Menlo Spark, a non-profit, Sean Armstrong, Redwood Energy community-based organization that unites businesses, residents, (707) 826-1450 and government partners to achieve a climate-neutral Menlo [email protected] Park by 2025.
    [Show full text]
  • Assessment of Energetic, Economic and Environmental Performance of Ground-Coupled Heat Pumps
    energies Article Assessment of Energetic, Economic and Environmental Performance of Ground-Coupled Heat Pumps Matteo Rivoire, Alessandro Casasso ID , Bruno Piga and Rajandrea Sethi * Department of Environment, Land and Infrastructure Engineering, Politecnico di Torino, Corso Duca degli Abruzzi 24, 10129 Torino, Italy; [email protected] (M.R.); [email protected] (A.C.); [email protected] (B.P.) * Correspondence: [email protected]; Tel.: +39-011-090-7735 Received: 15 June 2018; Accepted: 24 July 2018; Published: 26 July 2018 Abstract: Ground-coupled heat pumps (GCHPs) have a great potential for reducing the cost and climate change impact of building heating, cooling, and domestic hot water (DHW). The high installation cost is a major barrier to their diffusion but, under certain conditions (climate, building use, alternative fuels, etc.), the investment can be profitable in the long term. We present a comprehensive modeling study on GCHPs, performed with the dynamic energy simulation software TRNSYS, reproducing the operating conditions of three building types (residential, office, and hotel), with two insulation levels of the building envelope (poor/good), with the climate conditions of six European cities. Simulation results highlight the driving variables for heating/cooling peak loads and yearly demand, which are the input to assess economic performance and environmental benefits of GCHPs. We found that, in Italy, GCHPs are able to reduce CO2 emissions up to 216 g CO2/year per euro spent. However, payback times are still quite high, i.e., from 8 to 20 years. This performance can be improved by changing taxation on gas and electricity and using hybrid systems, adding a fossil-fuel boiler to cover peak heating loads, thus reducing the overall installation cost compared to full-load sized GCHP systems.
    [Show full text]
  • State Premier Hybrid Heat Pumps
    CHOOSE FROM THREE OPERATIONAL MODES AND A CONVENIENT VACATION SETTING Choose the right efficiency setting, based on climate, demand and installation. ® EFFICIENCY MODE ELECTRIC MODE STATE PREMIER HYBRID HEAT PUMPS The high efficiency setting utilizes only the heat pump to extract In electric mode, the unit operates as a conventional electric water AT A GLANCE ® heat from the surrounding air and transfers it to the water. heater utilizing the elements only. State Premier Electric Water Heaters • A heat pump water heater absorbs heat from ambient air and HYBRID MODE VACATION SETTING transfers it to the water. One touch operation maintains tank temperatures of 60˚F (15.6˚C) When hot water demand is at its peak, this setting utilizes both during extended absences to reduce operating costs and provide • While heating the water in the tank, it is also cooling and the heat pump and conventional electric elements to provide the freeze protection. Vacation setting on HPX and HP6 models are dehumidifying the surrounding air. necessary amount of hot water. programmable up to 99 days. • More storage means more energy savings. With an 80-gallon tank, more energy can be stored that has been created through the heat pump, resulting in greater savings. ADVANCED ELECTRONIC CONTROLS • User-friendly displays for easy interaction • High energy factors (UEF) result in more energy conservation, • The models are easy for minimizing operating costs. homeowners to use. It is customized to meet their • Eligible for local rebates and tax incentive programs which provide cash-back to consumers. Go to statewaterheaters.com unique needs with 3 operating and see “Find Local Incentives.” modes, and a convenient programmable vacation • ENERGY STAR® Qualified setting.
    [Show full text]
  • Catalog 256-13 Rebel™ Commercial Packaged Rooftop Systems Heating & Cooling Models DPS 003 – 028 3 to 28 Tons R-410A Refrigerant Energy Recovery Wheel
    Catalog 256-13 Rebel™ Commercial Packaged Rooftop Systems Heating & Cooling Models DPS 003 – 028 3 to 28 Tons R-410A Refrigerant Energy Recovery Wheel 3–6 tons 7–15 tons Shown with Energy Recovery 16–28 tons Shown with Energy Recovery TABLE OF CONTENTS TABLE OF CONTENTS Introduction . 3 Application Considerations . 16 Rebel, the most energy efficient packaged rooftop unit ..........3 Unit Location .......................................16 Agency Listed........................................3 Service Clearance ...................................16 Features and Options . 4 Curb Installation .....................................16 Cabinet, Casing, and Frame . 6 Acoustical Considerations ...............................21 Compressor . .6 Ductwork Considerations ................................21 Outdoor Coil .........................................7 Return Duct ........................................21 Indoor Coil . 7 Supply Duct . 21 Heat Pump Heating ...................................7 Duct High Limit ......................................21 Modulating Hot Gas Reheat .............................8 Vibration Isolation....................................21 Supply Fan ..........................................8 Smoke and Fire Protection...............................22 Variable Air Volume Control .............................8 Variable Air Volume Application ...........................22 Exhaust Fan .........................................8 Single Zone Variable Air Volume Application .................22 Filters . 8 Fan Operating Range...................................22
    [Show full text]
  • Daikin Altherma Hybrid Heat Pump 2 a New Opportunity in Residential Heating!
    The natural combination DAIKIN ALTHERMA HYBRID HEAT PUMP 2 A new opportunity in residential heating! There is a growing demand from home owners to replace heating systems, especially replacing of gas boilers, with more efficient, more cost-effective and more environmentally friendly systems that reduce CO2 emissions, reduce energy consumption and protect their budget. The answer is the Daikin Altherma hybrid heat pump. For space heating, the Daikin Altherma hybrid heat pump will combine Hybrid technology air-to-water heat pump technology with gas condensing technology by searching for the optimum economical condition for its operation, combining parameters of energy costs (electricity, gas), heat pump efficiency and heat load requirements to deliver up to 35% more heating efficiency, plus major cost savings. For domestic hot water, the Daikin Altherma hybrid heat pump optimises the operation of the most efficient gas condensing boiler. Your benefits 9 Low running costs for heating and domestic hot water 9 Low investment cost 9 Provides sufficient heat in renovation applications 9 Easy and fast installation 3 What is an air-to-water heat pump? The Daikin Altherma air-to-water heat pump uses a sustainable energy source: extracting heat from the outside air. In a closed loop containing a refrigerant, a thermodynamic cycle is created through evaporation, 4/5 condensation, compression and expansion. This ‘pumps’ ambient heat heat from a lower to a higher temperature level. The heat gained is transferred to your home’s central 1/5 heating distribution system via a heat exchanger. electricity Depending on the model and conditions, a Daikin Altherma heat pump delivers about 5kWh of usable heat for every kWh of electricity it consumes.
    [Show full text]
  • HYBRID HEAT® Dual Fuel System
    HYBRID HEAT ® Dual Fuel System The Best Combination of Comfort and Savings from Two Fuel Sources Efficiency With today's rising uncertainty surrounding utility costs, homeowners nationwide are becoming more and more interested in finding the best, most economical solution for indoor heating and cooling. Carrier specializes in creating customized home comfort systems tailored to your needs with a broad selection of residential heating and cooling products. Your Carrier ® dealer can help you choose the best system for your home, including a HYBRID HEAT ® dual fuel system designed to deliver maximum comfort and economy. Performance HYBRID HEAT dual fuel systems deliver exceptional performance by using a heating source that provides its most energy-efficient comfort during moderate heating conditions. As the temperature drops outside, the system automatically switches to your second heating source when that becomes the most economical way to keep your family comfortable. A 28% increase in the cost of natural gas results in only a 6% increase in cost to heat a home with a HYBRID HEAT dual fuel system. This example represents a home in Pittsburgh, PA. Ask your dealer for an estimate on how much you can save in your area. Comfort Heating Cooling The ultimate Carrier HYBRID HEAT dual fuel system Because a Carrier HYBRID HEAT dual fuel system also includes an Infinity ® 98 gas furnace with our Infinity ® 20 provides cool, indoor comfort when it's hot outside, this heat pump to provide soothing, superior comfort during system becomes your total, year-round indoor comfort both heat pump and furnace operation. This powerful solution.
    [Show full text]
  • Technical and Economical Feasibility of the Hybrid Adsorption Compression Heat Pump Concept for Industrial Applications M
    Technical and Economical Feasibility of the Hybrid Adsorption Compression Heat Pump Concept for Industrial Applications M. van der Pal A.K. Wemmers S.F. Smeding R. de Boer September 2012 ECN-M--12-074 TECHNICAL AND ECONOMICAL FEASIBILITY OF THE HYBRID ADSORPTION COMPRESSION HEAT PUMP CONCEPT FOR INDUSTRIAL APPLICATIONS M. van der Pal, A. Wemmers, S. Smeding, R. de Boer Group Thermal Systems, Energy research Centre of the Netherlands (ECN), PO Box 1, 1755 ZG, Petten, The Netherlands, email: [email protected] Abstract Heat pump technologies offer a significant potential for primary energy savings in industrial processes. Thermally driven heat pumps can use waste heat as driving energy source to provide either heating or cooling. A chemi-sorption heat transformer can upgrade a waste heat source to temperatures of 150- 200°C. The specific heat transformer process however requires waste heat temperatures in the range of 120°C, whereas waste heat sources of lower temperatures are more abundant. Using this lower temperature waste heat, and still reach the desired higher output temperatures can be achieved by the integration of a chemi-sorption and mechanical compression step in a single hybrid heat pump concept. This concept can offer an increased flexibility in temperatures, both for the waste heat source as for the heat delivery. The technical and economical feasibility of the proposed hybrid heat pump concept is evaluated. The range of operating temperatures of different chemi-sorption working pairs for as heat driven and as hybrid systems are defined, as well as their energy efficiencies. Investment costs for the hybrid systems are derived and payback times are calculated.
    [Show full text]
  • Ancillary Services Provided by Hybrid Residential Renewable Energy Systems Through Thermal and Electrochemical Storage Systems
    energies Article Ancillary Services Provided by Hybrid Residential Renewable Energy Systems through Thermal and Electrochemical Storage Systems Lorenzo Bartolucci, Stefano Cordiner, Vincenzo Mulone * and Marina Santarelli Department of Industrial Engineering, University of Rome Tor Vergata, via del Politecnico 1, 00133 Rome, Italy; [email protected] (L.B.); [email protected] (S.C.); [email protected] (M.S.) * Correspondence: [email protected] Received: 21 March 2019; Accepted: 11 June 2019; Published: 24 June 2019 Abstract: Energy Management System (EMS) optimal strategies have shown great potential to match the fluctuating energy production from renewables with an electric demand profile, which opens the way to a deeper penetration of renewable energy sources (RES) into the electric system. At a single building level, however, handling of different energy sources to fulfill both thermal and electric requirements is still a challenging task. The present work describes the potential of an EMS based on Model Predictive Control (MPC) strategies to both maximize the RES exploitation and serve as an ancillary service for the grid when a Heat Pump (HP) coupled with a Thermal Energy Storage (TES) is used in a residential Hybrid Renewable Energy System (HRES). Cost savings up to 30% as well as a reduction of the purchased energy unbalance with the grid (about 15%–20% depending on the season) have been achieved. Moreover, the thermal energy storage leads to a more efficient and reliable use of the Heat Pump by generally decreasing the load factor smoothing the power output. The proposed control strategy allows to have a more stable room temperature, with evident benefits also in terms of thermal comfort.
    [Show full text]