Both solar and heat pump heating systems are innovative technologies for sustaining ecological heat generation. They are gaining more and more importance due to the accelerating pace of climate change and the rising cost of limited fossil resources. Against this background, a heating system combining solar thermal collectors, heat pump, stratified thermal storage, and water/ice latent heat storage has been investigated. The major advantages of the proposed solar/heat pump heating system are considered to be its flexible application (suitable for new and existing buildings because of acceptable space demand), as well as the improvement of solar fraction (extended solar collector utilization time, enhanced collector efficiency), i.e., the reduction of electric energy demand for the heat pump by management of the source and sink temperatures. In order to investigate and optimize the heating system, a dynamic system simulation model was developed. On this basis, a fundamental control strategy was derived for the overall co-ordination of the heating system with particular regard to the performance of the two storage tanks. In a simulation study, a fundamental investigation of the heating system configuration was carried out and an optimization was derived for the system control, as well as the selection of components and their dimensioning. The influence of different parameters on the system performance was identified, where the collector area and the latent heat storage volume were found to be the predominant parameters for system dimensioning. For a modern one-family house of 120m2 living area with a specific annual heat demand of 60kWh/(m2a) for both heating and domestic hot water, a solar collector area of 30m2, and a latent heat store volume of 12.5m3 are proposed for the location of Wuerzburg (Germany). In this configuration, the heating system reaches a seasonal performance factor of 4.6, meaning that 78% of the building’s and users’ heat demand are delivered by solar energy. The results show that the solar/heat pump heating system can give an acceptable performance using up-to-date components in a state-of-the-art building.

1.
Freeman
,
T. L.
,
Mitchell
,
J. W.
, and
Audit
,
T. E.
, 1979, “
Performance of Combined Solar-Heat Pump Systems
,”
Sol. Energy
0038-092X,
22
, pp.
125
135
.
2.
Ziegenbein
,
B.
, 1984, “
Experimental and Computer Simulation Results From a Heat Pump Assisted Solar Heating System With Latent Heat Storage
,”
Proceedings of the IEA-Workshop on Latent Heat Stores—Technology and Application
,
International Energy Agency (IEA)
,
Stuttgart, Germany
.
3.
Çomakli
,
O.
,
Kaygusuz
,
K.
,
Ayhan
,
T.
, and
Arslan
,
F.
, 1993, “
Experimental Investigation and a Dynamic Simulation of the Solar-Assisted Energy-Storaged Heat Pump System
,”
Sol. Energy
0038-092X,
51
(
2
), pp.
147
158
.
4.
Weik
,
H.
, 1988,
Das Solarhaus-Experiment der Fachhochschule Lübeck
,
Lübeck University of Applied Sciences
,
Lübeck, Germany
.
5.
Holman
,
A. S.
, and
Brantley
,
V. R.
, 1978, “
ACES Demonstration: Construction, Startup and Performance Report
,” Oak Ridge National Laboratory, Oak Ridge, TN, Technical Report No. ORNL/CON-26.
6.
Trinkl
,
C.
,
Zörner
,
W.
, and
Hanby
,
V.
, 2004, “
A Review on Solar-Assisted Heat Pump Systems for Domestic Heating
,”
Fifth ISES Europe Solar Conference (EuroSun2004)
, Freiburg, Germany.
7.
Fellner
,
A.
,
Trinkl
,
C.
,
Kruck
,
A.
,
Weidinger
,
A.
, and
Zörner
,
W.
, 2003, “
New Technology for Solar Heating: Concept and Application of a Fuel-Free, Solar-Based Heating System for Family Houses
,”
European Solar Thermal Energy Conference 2003 (Estec2003)
, Freiburg, Germany.
8.
Trinkl
,
C.
,
Zörner
,
W.
, and
Hanby
,
V.
, 2005, “
Solar-Assisted Domestic Heating With Heat Pump and Latent Heat Storage
,”
Second European Solar Thermal Energy Conference 2005 (Estec2005)
, Freiburg, Germany.
9.
Matlab/Simulink User Manuals
,” 2002, The Mathworks Inc., Natick, MA, http://www.mathworks.comhttp://www.mathworks.com.
10.
Hafner
,
B.
,
Plettner
,
J.
, and
Wemhöner
,
C.
, 1999, “
CARNOT Blockset: Conventional and Renewable Energy Systems Optimization Blockset—User’s Guide
,” Solar-Institut Jülich, Aachen University of Applied Sciences, Germany.
11.
Isakson
,
P.
, 1991, “
Matched Flow Solar Collector Model for TRNSYS
,” TRNSYS Users and Programmers Manual.
12.
Duffie
,
J. A.
, and
Beckman
,
W. A.
, 2006,
Solar Engineering of Thermal Processes
, 3rd ed.,
Wiley
,
Hoboken, NJ
.
13.
Feist
,
W.
, 1994,
Thermische Gebäudesimulation—Kritische Prüfung unterschiedlicher Modellansätze
,
Verlag C.F. Müller
,
Heidelberg, Germany
.
14.
Schwamberger
,
K.
, 1991, “
Modellbildung und Regelung von Gebäudeheizungsanlagen mit Wärmepumpen
,” VDI-Verlag GmbH, Düsseldorf, Germany, VDI Technical Report No. 263.
15.
Dincer
,
I.
, and
Rosen
,
M. A.
, 2002,
Thermal Energy Storage
,
Wiley
,
Chichester, UK
.
16.
Zalba
,
B.
,
Marin
,
J. M.
,
Cabeza
,
L. F.
, and
Mehling
,
H.
, 2003, “
Review on Thermal Energy Storage With Phase Change: Materials, Heat Transfer Analysis and Applications
,”
Appl. Therm. Eng.
1359-4311,
23
, pp.
251
283
.
17.
Trinkl
,
C.
, 2006, “
A Domestic Solar/Heat Pump Heating System Incorporating Latent and Stratified Thermal Storage
,” Ph.D. thesis, De Montfort University, Leicester, UK.
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