Thermal energy storages with thermosyphon natural convection heat exchangers have been used in solar water heating systems as a means of increasing tank stratification and eliminating the need for a second circulation pump. However, if the storage system is not carefully designed, under adverse pressure conditions, reverse thermosyphoning can result in increased thermal losses from the storage and reduced thermal performance of the system. To investigate this phenomenon, tests were conducted on single tank and multitank thermal storages under controlled laboratory conditions. Energy storage rates and temperature profiles were experimentally measured during charge periods, and the effects of reverse thermosyphoning were quantified. Further objectives of this study were to empirically derive performance characteristics, to develop numerical models to predict the performance of the heat exchanger during reverse thermosyphon operation, and to quantify the relative magnitude of these effects on the energy stored during typical daylong charge periods. Results of this study show that the magnitude of the reverse flow rate depends on the pressure drop characteristics of the heat exchange loop, the system temperatures, and the geometry of the heat exchanger and storage tank. In addition, the results show that in the case of a multitank thermal storage, the carryover of energy to the downstream thermal energy storages depends on the effectiveness of the exchangers used in the system.

1.
Cataford
,
R. J.
, 1995, “
Effects of Storage Tank Stratification on Performance of Solar Domestic Hot Water Systems
,” MS thesis, Department of Mechanical Engineering, Queen’s University, Kingston, Ontario, Canada.
2.
Purdy
,
J. M.
,
Harrison
,
S. J.
, and
Oosthuizen
,
P. H.
, 1998, “
Thermal Evaluation of Compact Heat Exchangers in a Natural Convection Application
,”
Proceedings of the 11th International Heat Transfer Conference
, Korea, Vol.
6
, pp.
305
310
.
3.
Cruickshank
,
C. A.
, and
Harrison
,
S. J.
, 2009, “
Characterization of a Thermosyphon Heat Exchanger for Solar Domestic Hot Water Systems
,”
ASME J. Sol. Energy Eng.
0199-6231,
131
(
2
), p.
024502
.
4.
Hollands
,
K. G. T.
, and
Lightstone
,
M. F.
, 1989, “
A Review of Low-Flow, Stratified-Tank Solar Water Heating Systems
,”
Sol. Energy
0038-092X,
43
(
2
), pp.
97
105
.
5.
Morrison
,
G. L.
, 1986, “
Reverse Circulation in Thermosyphon Solar Water Heaters
,”
Sol. Energy
0038-092X,
36
(
4
), pp.
377
379
.
6.
Cruickshank
,
C. A.
, and
Harrison
,
S. J.
, 2008, “
Experimental Evaluation of a Multi-Tank Thermal Storage Under Variable Charge Conditions
,”
Proceedings of the Joint Conference of the Canadian Solar Buildings Research Network and Solar Energy Society of Canada Inc.
, Fredericton, New Brunswick, Canada.
7.
Cruickshank
,
C. A.
, and
Harrison
,
S. J.
, 2008, “
Thermal Response of a Series-Connected Energy Storage to Multi-Day Charge Sequences
,”
Proceedings of EuroSun Conference
, Lisbon, Portugal.
8.
Lin
,
Q.
,
Harrison
,
S. J.
, and
Lagerquist
,
M.
, 2000, “
Analysis and Modeling of Compact Heat Exchangers for Natural Convection Application
,”
Proceedings of EuroSun Conference
, Copenhagen, Denmark.
9.
Parent
,
M. G.
,
Van der Meer
,
Th. H.
, and
Hollands
,
K. G. T.
, 1990, “
Natural Convection Heat Exchangers in Solar Water Heating Systems: Theory and Experiment
,”
Sol. Energy
0038-092X,
45
, pp.
43
52
.
10.
Fraser
,
K. F.
,
Hollands
,
K. G. T.
, and
Brunger
,
A. P.
, 1995, “
An Empirical Model for Natural Convection Heat Exchangers in Solar Heating Systems
,”
Sol. Energy
0038-092X,
55
(
2
), pp.
75
84
.
11.
Dahl
,
S. D.
, and
Davidson
,
J. H.
, 1997, “
Performance and Modeling of Thermosyphon Heat Exchangers for Solar Water Heaters
,”
ASME J. Sol. Energy Eng.
0199-6231,
119
, pp.
193
199
.
12.
Dahl
,
S.
, and
Davidson
,
J. H.
, 1998, “
Mixed Convection Heat Transfer and Pressure Drop Correlations for Tube-in-Shell Thermosyphon Heat Exchangers With Uniform Heat Flux
,”
ASME J. Sol. Energy Eng.
0199-6231,
120
(
4
), pp.
260
269
.
13.
Dahl
,
S. D.
, and
Davidson
,
J. H.
, 1999, “
Applicability of Uniform Heat Flux Nusselt Number Correlations to Thermosyphon Heat Exchangers for Solar Water Heaters
,”
ASME J. Sol. Energy Eng.
0199-6231,
121
(
2
), pp.
85
90
.
14.
Cruickshank
,
C. A.
, and
Harrison
,
S. J.
, 2006, “
An Experimental Test Apparatus for the Evaluation of Multi-Tank Thermal Storage Systems
,”
Proceedings of the Joint Conference of the Canadian Solar Buildings Research Network and Solar Energy Society of Canada Inc.
, Montreal, Quebec, Canada.
15.
TRNSYS: A Transient Simulation Program, Ver. 15, 2000, Solar Energy Laboratory, University of Wisconsin-Madison, Madison, WI.
16.
Cruickshank
,
C. A.
, and
Harrison
,
S. J.
, 2006, “
Simulation and Testing of Stratified Multi-Tank, Thermal Storages for Solar Heating Systems
,”
Proceedings of EuroSun Conference
, Glasgow, Scotland.
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