Misc Papers

A comparative analysis of market available solar thermal heat pump systems
2012 - PDF 0.96MB
Document Number: 2012.022
During the last years, many combined solar thermal heat pump systems have entered the market for residential heating systems. Regarding testing and assessment of these systems, existing methods and standards are limited on national and international level. Currently, several approaches are developed and presented. The precondition for any such work is a thorough review of the existing market, revealing for example the relevance of non-standard components and configurations.
A simplified heat pump model for use in solar plus heat pump system simulation studies
2012
ISBN: 2012.018
Direct coupling solar and heat pump at large scale: experimental feedback from an existing plant
2012
Document Number: 2012.010
Ein Jahr Feldmessung von fünf Solar-Kombianlagen mit Wärmepumpen
2012 - PDF 1.98MB
Document Number: 2012.024
Heizungs- und Warmwasserbereitungssysteme basierend auf Kombinationen aus Solarthermie und Wärmepumpen werden aktuell am Markt mehr und mehr nachgefragt und inzwischen auch von vielen Systemanbietern angeboten. Die Integration der Wärmepumpe in ein Solarkombisystem ist aber um einiges komplexer als andere Zusatzheizenergiequellen, da auch die Energiequelle der Wärmepumpe (Verdampferkreis) mit dem gesamten System verknüpft sein kann. Neben den typischen Quellen Umgebungsluft oder Erdreich kann auch der Solarkollektor oder auch der Pufferspeicher als Energiequelle in unterschiedlichsten Schaltungen genutzt werden.
Experiments for combined solar and heat pump systems
Experiments for combined solar and heat pump systems
2012 - PDF 0.36MB
Document Number: 2012.019
The operation of ground coupled heat pumps in combination with solar collectors requires comprising knowledge of the component behavior under non-nominal conditions. Especially higher source and lower sink temperatures, varying flow rates, material characteristics and sophisticated control strategies have to be taken into account.
Field test of a novel combined solar thermal and heat pump system with an ice store
2012
Document Number: 2012.016
IEA Solar and Heat pump systems
2012
Document Number: 2012.012
Impact of solar heat pump system concepts on seasonal performance - Simulation studies
2012 - PDF 0.4MB
Document Number: 2012.001
Solar and heat pump systems promise a significant efficiency improvement for heating systems. In this context three different system concepts are compared within TRNSYS simulations for solar heat pump systems with borehole heat exchangers and flat plate collectors. The concepts are examined with solar heat injection either to the hot side for domestic hot water preparation, to the cold side of the heat pump for thermal borehole support or in terms of a combination of both, hot and cold side injection. Connected to the hot side of the heat pump, the increase of the seasonal performance factor is 1.2. If connected to the cold side, the impact is typically below 0.2, but it significantly depends on the specific heat exchanger length and the collector area.
Investigation of combined solar thermal and heat pump systems - Field and laboratory tests
2012 - PDF 0.24MB
Document Number: 2012.015
The technological combination of solar thermal systems with hear pumps continues to be a highly topical subject in the market of sustainable domestic hot water and space heating concepts.
Kompakte Solarheizung mit integrierter Systemüberwachung
Kompakte Solarheizung mit integrierter Systemüberwachung
2012 - PDF 0.24MB
Document Number: 2012.026
Ein großer Anteil der Endenergie wird für Heizwärme im Gebäudebestand verbraucht. Von einer zügigen Reduktion des Heizwärmeverbrauchs in diesem Sektor hängt maßgeblich das Erreichen der Klimaziele ab. Grundsätzlich haben Solartechniken zur Bereitstellung von Niedertemperaturwärme das Potential, kombiniert mit Gebäudesanierungsmaßnahmen einen Großteil der konventionell dafür aufgewandten Primärenergie zu ersetzen bzw. zu vermeiden. Als integrierte Systeme mit anderen EE-Techniken sind Einsparungen bis zu 100 % möglich. Dies ist nicht nur technisch, sondern auch wirtschaftlich mit heutigen Techniken möglich. Auf der anderen Seite erfordert die effiziente Integration von Solarthermie in die Hauswärmeversorgung und die gleichzeitige Reduktion des Verbrauchs eine hohe Fachkompetenz für jede individuelle Anlage. Dies ist ein Hauptbremsfaktor für die rasche Verbreitung von solar beheizten Häusern, bei denen der verbleibende Energiebedarf nur noch durch eine Unterstützung (fossil, elektrischer Strom aus dem Netz) gedeckt wird.
Measurement and modelling of a multifunctional solar plus heat pump systems from Nilan. Experiences from one year of test operation
2012 - PDF 0.44MB
Document Number: 2012.020
A multifunctional solar and heat pump unit from Nilan has been installed in the Performance Test Facility (PTF) at DTU Byg Denmark. It is part of the IEA Task 44 cooperation. Multifunctional means in this case: Hot water, Air heating, Ventilation, Air heat recovery, Air filtering and Floor heating. Nilan units, with additional air cooling and CO2 control, are also available. The unit has been in operation for more than one year. The aim has been to stress the system operation to different conditions in the lab, to learn more about the performance, but also to find possible improvements especially concerning advanced control. The operation into extreme states of high hot water demand and low air ventilation rates, has also been done to develop and validate a TRNSYS system model. The model was developed and validated for the first period of operation mainly winter and early spring conditions. Now the system has been in operation during all seasons and a full year model could be developed and validated. The model also includes new possibilities for solar collector loop and heat pump operation control.
Mobile solar assisted heat pump with direct expansion
2012 - PDF 0.7MB
Document Number: 2012.005
This paper presents development of direct-expansion solar assisted heat pump system (DX-SAHP) along with the results of the trial testing. The main purpose of the developed unit with 300 l water tank is to heat up the water by 45 to 55°C. The unit is designed as a test rig enabling all necessary measurements to evaluate potential of solar irradiation for domestic water heating on various locations. A mobile and compact-in-form-and-size device has been developed representing a gradual step towards the commercial application. First set of measurements has been carried out explaining procedures in examination of the working parameters. The evaporation dynamics of the refrigerant in the collector/evaporator has been examined by means of quantitative infra-red thermography method. Computational fluid dynamics simulation has been carried out providing temperature distribution in the water tank. It was compared with the results obtained by temperature measurements by means of thermocouples that were placed in the water tank.
Modell eines unverglasten photovoltaisch-thermischen Kollektors basierend auf genormten Prüfverfahren
2012 - PDF 0.51MB
Document Number: 2012.023
Existierende Modelle für photovoltaisch-thermische Kollektoren (PVT-Kollektoren) simulieren die Energieströme mit Hilfe von physikalischen Ansätzen. Daher benötigen sie zur Parametrierung konstruktive Details, was die Parametrierung aufwendig bis unmöglich macht. Zudem gelten die meisten dieser Modelle für verglaste PVTKollektoren. Aus diesem Grund wurde innerhalb des Projektes „Solare Gebäude-Wärmeversorgung mit unverglasten photovoltaisch-thermischen Kollektoren, Erdsonden und Wärmepumpen“1 ein neues Modell für unverglaste PVT-Kollektoren entwickelt, das zur Parametrierung ausschließlich Daten aus genormten Prüfverfahren benötigt. Dementsprechend lässt sich das Verhalten eines PVT-Kollektors mit für den Anwender leicht zugänglichen Daten ohne Kenntnis des inneren Aufbaus einschließlich der physikalischen Eigenschaften der Komponenten beschreiben. Das Modell wurde in einen TRNSYS-Type umgesetzt und während einer einjährigen Messung in einer Pilotanlage validiert.
Numerical analysis of heat pump models. Comparative study between equation-fit and refrigerant cycle based models
2012 - PDF 0.13MB
Document Number: 2012.004
An equation-fit (EF) and a refrigerant cycle (RC) based heat pump models have been implemented, validated, analyzed and compared to each other under steady state conditions for a brine to water heat pump. Models validations have been provided through comparisons against experimental data obtained at ISFH. The advantages and disadvantages of the both models have been identified. This work provides significant inputs regarding the selection of a specific model depending on the needs. Analysis of mass flow rates and calculations far from typical catalogue data (non-standard conditions) are provided. The main conclusions can be summarized as: i) the EF model is recommended when the boundary conditions for the estimation and prediction modes are the same and when non-standard conditions are considered; ii) the RC model is the chosen alternative when the mass flow rates are modified from the estimation to the prediction mode.
Performance of solar collectors under low temperature conditions: measurements and simulations results
Performance of solar collectors under low temperature conditions: measurements and simulations results
2012 - PDF 0.31MB
Document Number: 2012.025
The performance of four solar thermal collectors (flat plate, evacuated tube, unglazed with rear insulation and unglazed without rear insulation) was experimentally measured and simulated for temperatures below ambient. The influence of several parameters (e.g. collector inlet temperature, air temperature, condensation) is investigated under different operating conditions (day and night). Under some conditions condensation might occur and heat gains could represent up to 55% of the total unglazed collector energy by night. Two TRNSYS collector models including condensation heat gains are also evaluated and results compared to experimental measurements. A mathematical model is also under development to include, in addition to the condensation phenomena, the frost, the rain and the long-wave radiation gains/losses on the rear of the solar collector. While the potential gain from rain was estimated to be around 2%, frost heat gains were measured to be up to 40% per day, under specific conditions. Overall, results have shown that unglazed collectors are more efficient than flat plate or evacuated tube collectors at low operation temperatures or for night conditions, making them more suitable for heat pump applications.
Review of component models for the simulation of combined solar and heat pump heating systems
2012
Document Number: 2012.014
Solar and heat pump systems. An analysis of several combinations in Mediterranean areas
2012 - PDF 0.41MB
Document Number: 2012.018
Recently the systems that combine solar thermal technology and heat pumps have been marketed to heat houses and produce domestic hot water. [1] This new combination of technologies is a welcome advancement, and need to be improved in the configuration. These systems will be cleaner as long as the electricity will improve the renewable energy fraction and they improve the efficiency. In Mediterranean areas, where there are less months of heating and higher temperatures, the solar thermal systems for heating have combined with water-water heat pump with a big storage tank can have better efficiency and less emissions than the geothermal heat pump system or a conventional heat pump.
Solar assisted heat pump for domestic hot water production
2012
Document Number: 2012.008
System evaluation of combined solar & heat pump systems
2012
Document Number: 2012.007
System-Jahresarbeitszahl grösser 4.0 mit Luft-Wasser Wärmepumpe kombiniert mit Solarwärme
2012
ISBN: 2012.013
Unglazed PVT collectors as additional heat source in heat pump systems with borehole heat exchanger
2012
Document Number: 2012.002
Uniform representation of system performance for solar hybrid systems
2012
Document Number: 2012.009
Validation of the numerical model of a turnkey Solar Combi+ system
2012
Document Number: 2012.006
Wärmepumpensysteme mit unabgedeckten photovoltaisch- termischen Kollektoren
2012
Document Number: 2012.003
Heat pump systems with borehole heat exchanger and unglazed PVT collector
September 2011 - PDF 0.89MB
Document Number: 2011.03
In the future energy supply both efficient heat pump systems for heat generation and photovoltaic (PV) electricity production will play an important role. Therefore, a heat pump system with a combined heat source consisting of a photovoltaic-thermal (PVT) collector and a borehole heat exchanger (BHE) is assumed to be a promising solution, because this particular combination provides a double benefit compared to conventional heat pump and PV-systems. First, the PV cells in the PVT collector are cooled, leading to lower cell temperatures and a higher PV efficiency. Second, the heat from the PVT collector raises the temperature level of the heat pump and the borehole heat exchanger. Consequently, the temperature increase of the heat source leads to a higher heat pump performance factor. Within a research project, a pilot system has been built up and experimentally evaluated. Simulation studies allow analyzing the system behavior and extrapolating the results.
On the Potential of Using Heat from Solar Thermal Collectors for Heat Pump Evaporators
September 2011 - PDF 0.4MB
Document Number: 2011.011
Solar thermal collectors can be used in combination with heat pumps to cover the heat demand for space heating and domestic hot water preparation. Different concepts exist for the combination of these two components into a system concept. Some of these concepts offer the ability to switch from using heat from the solar collectors directly to serve the demand to using heat from the solar collectors indirectly as a heat source for the evaporator of the heat pump. In the same system concept, the heat pump may be able to switch from using heat from the solar thermal collector to using an alternative low temperature heat source, such as ambient air. In this paper a general mathematical relationship is derived for determining whether using heat from solar collectors for the evaporator of the heat pump instead of using it directly is beneficial for the energetic performance of these systems. It is shown that there is a limit for the solar irradiation on the collector field above which using collector heat for the evaporator of the heat pump instead of using it directly is not advantageous. This irradiation limit depends on the characteristic performance curves of the solar collector and of the heat pump, as well as on the operating conditions, above all on the temperature levels of the heat sink and the different heat sources. Based on dynamic annual simulations, examples are shown for the maximum amount of heat that can be delivered from the collector to the heat pump evaporator at times where this mode of operation is of advantage for the performance of a solar and air source heat pump heating system. Both the mathematical relationship and the examples show that using solar collector heat for the evaporator of a heat pump is more beneficial for systems that operate with a large temperature difference between the non-solar heat source and the heat demand.
Overview on Solar Thermal Plus Heat Pump Systems and Review of Monitoring Results
August 2011 - PDF 0.44MB
Document Number: 2011.028
In recent years several companies started offering Solar thermal And Heat Pump Systems (SAHPS) on the European Market; already in 2009 an overview was given for example by Zörner W. et al (2009). For single family houses the systems are offered as pre defined package (kit) solutions. The systems deliver thermal energy for heating, domestic hot water and eventually as well cooling to the building usually without any further back up burner. The hydraulic schemes of the single systems, especially the degree of integration of the solar thermal and electrical driven heat pump unit vary significantly. The same is true for the used low temperature heat source for the heat pump where ground heat exchangers (horizontal and vertical), ambient air, specific solar collectors, phase change material storages (e.g. ice/water) and exhaust air are implemented.
Integrierte Systemlösungen für Bestand und Neubau als Weg zum Erreichen der Klimaziele
German
July 2011 - PDF 7.73MB
Document Number: 2011.016
Der Solarwärme-Markt befindet sich im Umbruch. In den vergangenen Jahren bestand auf der einen Seite eine starke Abhängigkeit der Marktentwicklung vom Ölpreis und der Fördersituation, auf der anderen Seite entstand eine immer ausgeprägtere Konkurrenzsituation zu anderen Technologien der Erneuerbaren Energien, allen voran der Photovoltaik, aber auch Wärmepumpen oder Pellets. Dies ist eine Konkurrenz in der öffentlichen Wahrnehmung (heute: Solarenergie = Photovoltaik), aber auch der Wettbewerb um Installationskapazitäten, Dachflächen und Endkunden. In Zukunft geht es auch um die direkte ökonomische Konkurrenz für die Wärmeerzeugung, insbesondere durch die Kombination von PVAnlagen mit Luft-Wärmepumpen.
Validation of a Dynamic Model for Unglazed Collectors including Condensation. Application for Standardised Testing and Simulation in TRNSYS and IDA
July 2011 - PDF 1.72MB
Document Number: 2011.025
An improved unglazed collector model has been validated for use in TRNSYS and IDA and also for future extension of the EN12975 collector test standard. The basic model is the same as used in the EN12975 test standard in the QDT dynamic method. In this case with the addition of a condensation term that can handle the operation of unglazed collectors below the dew point of the air. This is very desirable for simulation of recharging of ground source energy systems and direct operation of unglazed collectors together with a heat pump.
Field Test for Performance Monitoring of Combined Solar Thermal and Heat Pump Systems
June 2011 - PDF 1.72MB
Document Number: 2011.018
The technological combination of solar thermal systems with heat pumps continues to be a highly topical subject in the context of sustainable heating concepts, especially for single family houses. In the past years more and more different types of such combined systems have been developed and introduced to the market for both domestic hot water and space heating. The main background for this development is the expected increase of efficiency for both, the solar heating system and the heat pump, and further synergetic effects in comparison to separate conventional heating systems due to the mutual synergetic interaction of the components and high system integration. This can lead to high system performances, thus to a decrease of electric power consumption and emission of greenhouse gases like CO2, respectively [Loose, 2010].
Solar and Heat Pump Systems: Status of IEA SHC Task 44 & HPP Annex 38
June 2011 - PDF 2.24MB
Document Number: 2011.009
Over the past few years, systems that combine solar thermal technology and heat pumps have been marketed to heat houses and produce domestic hot water. This new combination of technologies is a welcome advancement, but standards and norms are still required for its long term successful commercialization.
Test System for the Investigation of the Synergy Potential of Solar Collectors and Borehole Heat Exchangers in Heat Pump Systems
June 2011 - PDF 0.83MB
Document Number: 2011.024
The wide variety of solar assisted heat pump systems makes it difficult to assess the energetic behavior and to find optimized solutions. In order to come to a deeper understanding, scientists from different subjects are cooperating with the aim to analyze the synergy effects of solar heat and heat pumps with borehole heat exchangers (BHE).
Combining Heat Pumps With Solar Energy For Domestic Hot Water Production
February 2011 - PDF 0.11MB
Document Number: 2011.008
The knowledge about the reduction of heat demand in dwellings has reached a sophisticated level, especially regarding the building envelope. The next step are net zero energy buildings, where the total amount of yearly energy demand is covered by building integrated generation of energy from renewable sources. The most promising technologies are solar heat panels, photovoltaics and heat pumps. But it is not yet obvious which combination is best.
A PV/T and heat pump based trigeneration system model for residential application
2011 - PDF 0.54MB
Document Number: 2011.013
A solar trigeneration system, based on photovoltaic-thermal (PV/T) collectors, photovoltaic (PV) modules and a heat pump unit for heating and cooling, is modelled to forecast the thermal and electric yields of the system. The aim of the trigeneration system is to provide enough electricity, domestic hot water (DHW), heating and cooling power to meet the typical demand of an urban single family dwelling with limited roof area and allow the household to achieve a positive net energy status. The PV/T collectors and PV modules provide the electricity while the former also powers the DHW component of the trigeneration system. The heating and cooling components rely on a vapour compression cycle heat pump unit powered by electricity. In Fong et al. (2010), solar-powered electric compression refrigeration was found to have the most energy saving potential in subtropical climates. Thus, a heat pump based cooling system is a cost effective solution for residential applications in Lisbon, Portugal. Thus, according to the dwelling's location, construction details and energy demand patterns, the model computes the system's net results by comparing the dwelling demand with the trigeneration system supply. The paper presents a breakdown of the proposed trigeneration system model and describes each component briefly. Preliminary results produced by the model are presented and analysed in order to identify possible ways of improving the overall system performance.
Analysis on the Operating Characteristics of Solar Water Heater in Combination with Air Source Heat Pump Water Heater
2011 - PDF 0.15MB
Document Number: 2011.002
Solar water heater cannot supply hot water in cloudy and raining days alone. It in combination with air source heat pump water heater (ASHPWH) is a good choice. The performance of the two kinds of water heater is affected by the water temperature. It is important that the ASHPWH operate at a right temperature of the water. A solar water heater with 4m2 flat-plate collector assisted by a 1.5kW ASHPWH is studied in this paper. The results show that both the collector efficiency of the solar water heater and the COP of the ASHPWH system decreases as the water temperature increases. The highest and lowest collector efficiency of the solar water heater are 54.4% and 45.6% respectively. The COP of the ASHPWH system ranges from 6.48 to 2.61 as the water temperature increases. Operating sequences of these two kinds of water heater affect solar energy utilization ratio and the power input of the ASHPWH system.
Current work on performance evaluation of solar thermal and heat pump hybrid systems within IEA SHC Task 44 / HPP Annex 38 and IEE QAiST Project
2011
Document Number: 2011.020
Development of performance test methods for combined solar thermal and heat pump systems
2011
Document Number: 2011.019
Domestic solar/heat pump heating systems with low and high efficiency collectors in Mediterranean areas
2011 - PDF 0.2MB
Document Number: 2011.022
Recently systems that combine solar thermal technology and heat pumps have been marketed to heat houses and produce domestic hot water. This new combination of technologies is a welcome advancement, and need to be improved in the configuration. These systems will be cleaner as long as the electricity will improve the renewable energy fraction and they improve its efficiency. In Mediterranean areas, where there are less months of heating, the solar thermal systems for heating have a several months with overheating; this fact is an obstacle for the designers and the users. The combination of solar-thermal collectors and heat pumps provides interesting possibilities for innovative and energy efficient heating systems with a high fraction of solar energy. Despite is high cost these systems are gaining more and more importance due to the rising cost of the limited fossil resources. Several configurations of solar systems have been studied. Some of them use cheap collectors that make the investment more attractive.
Einfluss der Neigung auf den äusseren konvektiven Wärmeübergang unabgedeckter Absorber
2011
Document Number: 2011.026
Energetic, economical and geographical evaluation of different solar thermally driven heat pump systems for heating and cooling around Europe
2011 - PDF 0.72MB
Document Number: 2011.027
The present work shows an approximation method for solar designers to evaluate the feasibility of solar thermal plants in Europe depending on the type of solar collector used, the coordinates where the system is going to be installed and the types of summer and winter demands to be covered classified by the design temperatures needed for the processes. This method evaluates the maximum amount of energy able to be captured from the sun to satisfy the needs of a residential building in terms of Domestic Hot Water (DHW), heating and cooling demands. The final result of the work is a matrix where it is evaluated the combination among: · Two different technologies of collectors: Flat Plate and evacuated tube collectors · Two different ways of covering heating demands. Thermal collectors combined with thermal back up and thermal collectors combined with Thermally Driven Heat Pumps(TDHP). · Energetic and economical results plotted in maps will permit easy comparisons among the configurations.
Entwicklung von Prüfverfahren für Anlagen mit Kombination aus Wärmepumpen und Solarthermie
2011
Document Number: 2011.12
Monitoring and simulation of a passive house with innovative solar and heat pump system
2011 - PDF 0.22MB
Document Number: 2011.023
The very low energy demand of passive houses, which has been proven by measurement, is in the range of the target of the Nearly-Zero-Energy directive. Hence, the foundation of a development is already laid today which will be introduced in Europe in 9 years (the recast Energy Performance of Buildings Directive, EPBD, Directive 2010/31/EU). Due to the very high level of thermal insulation and the resulting very low heating demand and heating load, passive houses show a well balanced load duration curve. The domestic hot water demand can be covered with a high fraction by solar energy. However, solar heating of passive houses is under most circumstances poorly effective as the heating demand is confined to few months in main winter.
Optimierung der Einbindung eines 28 m3 – Wasserspeichers in die Beheizung und die WW-Versorgung mit WP und Solartermik
2011
Document Number: 2011.015
Parametric analysis of a novel Solar Combi+ configuration for commercialization
2011
Document Number: 2011.006
Performance testing of solar thermal systems combined with heat pumps
2011
Document Number: 2011.021
Progettazione e analisi numerica di un quadro di controllo standardizzato per applicazione Solar Combi+ di piccola taglia
2011
Document Number: 2011.004
Simulation study on the performance of solar and geothermal hybrid R22 heat pump
2011 - PDF 0.48MB
Document Number: 2011.014
A simulation study on the performance of the solar and geothermal hybrid heat pump system by using R22 was carried out with a variation of operating conditions. The system was consisted of solar system (concentric evacuated tube solar collector, heat storage tank) and geothermal heat pump system (double pipe heat exchanger, electric expansion valve and compressor). As a result, the heating capacity is linearly decreased from 13.2 kW to 11 kW as the heat pump operating temperature increases from 40oC to 48oC. Besides, the heating COP decreases by 13.6% from 4.4 to 3.8 when the ground temperature raises 13oC to 17oC. The heating capacity is increased by 4.7% from 11.5 kW to 12.2 kW and the heating COP rises by 19% from 4.7 to 5.6.
Steigert die Nutzung von Solarkollektoren als Wärmequelle für Wärmepumpen die System-Arbeitzahl?
2011
Document Number: 2011.010
THERMAL PERFORMANCE OF A COMPACT SOLAR ASSISTED HEAT PUMP
2011 - PDF 0.25MB
Document Number: 2011.001
Heat Pumps to supply hot-water for domestic consumption are widely used especially in countries where electric energy is also employed for this purpose. Brazil is a country where most of the domestic hot-water requirements are supplied by electric energy, but basically it is done with electric showers. This solution, although cheap for the user in terms of initial investment, has a strong impact on the generation, transmission and distribution – GTD costs. Electric showers have an average power of more than 5 kW, and are a strong contribution to the residential electric energy end use (around 24% in Brazil (Procel/Eletrobras, 2007)). Also, they are partially responsible by the “peak hour” of the power consumption in the residential sector that occurs from 18:00 to 21:00 hours in Brazil. The consumption growth observed in the last years leads to a lack of reliability of the system, and energy efficiency measures are necessary to avoid risks and to postpone investments in GTD. Solar hot-water systems have been used as an effective way to mitigate the problems caused by the intensive use of electric showers, however, this solution faces some problems when used in low-income housing units: absence of hot-water piping, inadequate structure to install collectors and thermal storage, increase of specific thermal energy costs for small systems, and use of an electric shower as the backup system.
A Transient Model For Radiant Heating And Cooling Terminal Heat Exchangers Applied To Radiant Floors And Ceiling Panels
A Transient Model For Radiant Heating And Cooling Terminal Heat Exchangers Applied To Radiant Floors And Ceiling Panels
January 2011 - PDF 0.08MB

Radiant heating and cooling terminal heat exchangers have become very popular in the last decades because of the thermal comfort they provide and the energy savings potential respect to conventional systems.

Heating and Cooling With Heat Pumps In Swiss Residential Buildings
January 2011 - PDF 0.38MB
Document Number: 2011.007
The energy demand for heating decreases in highly-insulated dwellings. Comfort cooling becomes more important due to higher thermal loads and rising summer thermal comfort demands. Heat pumps can provide space heat and domestic hot water but also may provide cooling. Heat sources of heat pumps often can be used for passive cooling. The aim of the project is to support energy efficient solutions for heating and cooling of residential buildings. First step should always be reducing the heat loads by e.g. shading and night-time ventilation.
Kombination Solarthermie / Wärmepumpe inkl. Abwasser-Wärmerückgewinnung (AWR)
German
January 2011 - PDF 0.13MB
Document Number: 2011.017
In Niedrigenergiehäusern ist der Anteil des Wärmebedarfs für das Warmwasser am Gesamtwärmebedarf relativ hoch und kann bei Passivhäusern sogar größer sein als der Heizwärmebedarf. Zusätzlich sind für das Erreichen des Warmwasserkomforts höhere Temperaturen erforderlich als dies für den Vorlauf z. B. bei einer Fußbodenheizung nötig ist. Dadurch steigt die Relevanz des Energiebedarfs für Warmwasser mit zunehmendem Dämmstandard der Gebäude. Aus diesen Gründen wird auch die Nutzung der im Abwasser vorhandenen Wärme über eine Abwasser-Wärmerückgewinnungsanlage mit sinkendem Heizwärmebedarf interessant.
Solar and Heat Pump Systems
IEA SHC Task 44 & HPP
October 2010 - PDF 0.06MB
Document Number: 2010.004
Over the past few years, systems that combine solar thermal technology and heat pumps have been marketed to heat houses and produce domestic hot water. This new combination of technologies is a welcome advancement, but standards and norms are still required for its long term successful commercialization.
Source froide solaire pour pompe à chaleur avec un COP annuel de 5 généralisable dans le neuf et la rénovation
Swiss
October 2010 - PDF 2.97MB
Le projet Solarcity, basé à Satigny (GE), est un nouveau complexe immobilier de 9550 m², comprenant 78 logements répartis dans 4 bâtiments divisés en 10 immeubles. L’enveloppe énergétique a été conçue pour respecter le standard Minergie, et le système de chauffage est basé sur une pompe à chaleur par immeuble utilisant comment source froide 1160 m² de capteurs solaires non couverts.
COP5 : Source froide solaire pour pompe à chaleur avec un COP annuel de 5 généralisable dans le neuf et la rénovation
July 2010 - PDF 2.97MB
Document Number: 2010.008
Le projet Solarcity, basé à Satigny (GE), est un nouveau complexe immobilier de 9550 m², comprenant 78 logements répartis dans 4 bâtiments divisés en 10 immeubles. L’enveloppe énergétique a été conçue pour respecter le standard Minergie, et le système de chauffage est basé sur une pompe à chaleur par immeuble utilisant comment source froide 1160 m² de capteurs solaires non couverts.
Solarthermie und Wärmepumpe Erfahrungen aus 3 Heizperioden Entwicklung einer solaren Systemarbeitszahl
2010 - PDF 0.15MB
Document Number: 2010.007
Solarthermieanlagen und Wärmepumpen sind mittlerweile als regenerative Energieerzeuger in der Politik, in den Förderprogrammen und Markt aktzeptiert und angekommen. Auch die Kombination findet immer mehr Anhänger, wobei die unterschiedlichsten Konzepte angeboten werden. Insbesondere die hydraulische und regelungstechnische Kombination auf der kalten Quellenseite der Wärmepumpe lassen Effizienzsprünge erwarten. Seit 3 Jahren wird von der Fa. Schüco International KG ein umfangreicher Feldtest einer Solarthermie – Wärmepumpenkombination getestet. Nach Konzeptstudien und umfangreichen Simulationen mit Parametervariationen kristallisierte sich ein Erfolgsversprechendes System heraus. Aufbauend auf eine heizungsunterstützende Solarthermieanlage mit Kombispeicher wurde die Erdsonde einer Sole-Wasserwärmepumpe wie ein zweiter Speicher an die Kollektoranlagen angeschlossen. Auf der Wärmesenkenseite wurde die Kombination zwischen Solarkombispeicher und Wärmepumpe nach einer bivalent-regenerativen Betriebsweise gesteuert. Bei Vorliegen von ausreichend Solarwärme wird die Wärmepumpe gesperrt und die Solarwärme vorrangig in das Heizsystem geleitet. Damit werden die Laufzeiten der Wärmepumpe gering gehalten und gleichzeitig stehen die niedrigen Rücklauftemperaturen jederzeit sowohl dem Solarspeicher als auch der Wärmepumpe zur Verfügung. Für eine Absicherung dieses Konzeptes über eine Simulation hinaus sicherzustellen wurde ein umfangreicher Feldtest durchgeführt. Nach mittlerweile 3 Heizperioden kann nun hiermit dokumentiert werden, dass die hohen Erwartungen in die Vorteile dieser Kombination voll erfüllt wurden.
Condensation Heat Gains on Unglazed Solar Collectors in Heat Pump Systems
January 2010 - PDF 0.28MB
Document Number: 2010.001
The performance of ground coupled heat pump systems with borehole heat exchangers can be significantly improved by unglazed solar collectors. In this combination, collector operation temperatures below the ambient air level and hence additional condensation heat gains occur. For an investigated and monitored system in Limburg, Germany, the condensation yield was determined to 3.7% or 19 kWh/(a m²). Thereby, condensation shows a significant dependency on the season. During the summer months, only 0.8% of the total collector yield is induced by condensation, while in winter it increases to 13%. The implementation of an established condensation model to the collector model according to EN 12975 is demonstrated. As main result the investigated the heat pump system performance is only marginally improved due to the condensation heat gains.
Systematic Classification of Combined Solar Thermal and Heat Pump Systems
January 2010 - PDF 0.48MB
Document Number: 2010.003
In this paper several approaches are discussed for the analysis and comparison of combined solar thermal and heat pump systems. The discussion is based on a detailed literature review and investigations on market available systems. Based on this, an approach to describe and systematically classify combined solar thermal and heat pump systems is presented.
Unglazed Photovoltaic Thermal Collectors in Heat Pump Systems
January 2010 - PDF 0.34MB
Document Number: 2010.002
Unglazed Photovoltaic Thermal (PVT) collectors provide very high efficiency for heat and electricity generation at low temperatures. Therefore they are particularly suitable to support the heat source of heat pump systems, where low temperature heat is required. In this combination the PVT collector improves efficiency in two ways- of the heat pump by additional low temperature heat and of the photovoltaic module by lower cell temperatures. An increase of 4% of the annual and up to 9% for the daily photovoltaic electricity production and a high collector yield of 450 kWh/(m² a) was measured at a pilot system between April 2009 and April 2010. As the improvement of the PV and heat pump efficiency depends strongly on the thermal PVT collector performance, efficiency measurements of five different unglazed PVT collectors have been carried out. They showed significant differences, e.g. the conversion factor 0 without electricity production varies from 0.33 to 0.73. Further, a simulation model for unglazed PVT -collectors is presented. It is based on thermal performance parameters of EN 12975 and PV performance data at standard test conditions and it further includes thermal collector capacity and condensation effects.
Kombination Solarthermi und Warmepumpe - Losungsan-satze, Chancen and Grezen
in German
October 2009 - PDF 0.72MB
Document Number: 2009.003
Soil Regeneration by Unglazed Solar Collectors in Heat Pump Systems
October 2009 - PDF 0.86MB
Document Number: 2009.001
Heat pump systems with borehole heat exchanger and unglazed solar thermal collector have been analysed in two pilot systems and assisting TRNSYS-Simulations. Measurements carreid out and simulations demonstrate that the borehole heat exchange is annually regenerated by the solar collector. This results in a a different behaviour compared to systems without a solar collector. As one effect of the changed system behaviour, the results of one investigated system, e.g. a simulation reference system, become transferable to other buildings by normalization to the total heat demand. Furthermore the influence of significant parameter on the annual performance factor and a correction function to characterize the heat sink side of the heat pump is presented.
Performance Analysis of a Solar Heating System Coupled to a Heat Pump for Building Renovation Purposes
June 2009 - PDF 0.16MB
Document Number: 2009.002
The aim of this study is to analyse the energy and economic performances of different types of facilities coupling a ground/water heat pump with an air-heater equipped with solar thermal collectors.
Optimization of systems with the combination of ground-source heat pump and solar collectors in dwellings
April 2009 - PDF 0.45MB
The use of ground-source heat pumps for heating and domestic hot water in dwellings is common in Sweden. The combination with solar collectors has been introduced to reduce the electricity demand in the system.
235 - Unglazed Solar Collectors in Heat Pump Systems: Measurement, Simulation and Dimensioning
October 2008 - PDF 0.22MB
Document Number: 2008.001
Two heat pump-systems with borehole and unglazed solar thermal collector are measured and simulated in TRNSYS as part of a research project. Compared to systems without collector the collector yield increases the average temperature level of the heat pump system on the evaporator side. A collector model is developed and evaluated considering the longwave radiation exchange and the condensation heat gains. The annual collector yield is measured as 545 kWh/m²a, of which 4% are determined as heat gains through condensation. Further simulations in TRNSYS show the interdependency of collector area, borehole length and heat pump system performance. The additional heat source component collector reduces the required borehole length and simultaneously improves the heat pump system performance in comparison to a solely borehole supported heat pump. In addition the system sensitivity for the heat source parameters is reduced significantly, thus resulting in a more certain system planning and operation.
Sol-Pac. Analyse des performances du couplage d’une pompe à chaleur avec une installation solaire thermique pour la renovation
2008
Document Number: 2008.002
Systemoptimierung der Kombination von Solarkollektoren mit Wärmepumpenanlgen
2008
Document Number: 2008.004