Electric resistance water heaters are relatively simple and are therefore one of the most common water heating configurations. Due to constraints on the allowable instantaneous electrical power draw, most electric water heating systems incorporate a sizable thermal storage component. The inherently unsteady storage component therefore has an overwhelming impact on the system behavior. In this investigation, a residential-scale electric storage water heater was tested across a range of flow rates for both powered and nonpowered discharge processes as well as for charge processes with no throughflow. The flow dynamics internal to the storage volume is shown to be strongly multidimensional and transient, especially when the internal heating elements are energized. Comparison of the measured data to the performance limits of a system with a fully mixed or a perfectly stratified storage element reveals that the conventional system operates relatively near to the fully mixed limit. As a result, there appears to be significant potential for improvements in system performance through reductions in the level of thermal mixing internal to the storage volume.

1.
Schultz
,
W. W.
, and
Goldschmidt
,
V. W.
, 1981, “
Energy Performance of a Residential Electric Water Heater
,”
ASHRAE Trans.
0001-2505,
87
, pp.
310
334
.
2.
Fanney
,
A. H.
, and
Dougherty
,
B. P.
, 1996, “
The Thermal Performance of Residential Electric Water Heaters Subjected to Various Off-Peak Schedules
,”
ASME J. Sol. Energy Eng.
0199-6231,
118
, pp.
73
80
.
3.
Ton-That
,
Q. A.
, and
Laperriere
,
A.
, 1991, “
Numerical Simulation of Domestic Multi-Element Electric Water Heaters Using a Dynamic Discretization Technique
,”
ASHRAE Trans.
0001-2505, vol.
97
, pp.
219
225
.
4.
Cook
,
R. E.
, 1980, “
Effects of Stratification in Performance and Control of Residential Electric Water Heaters
,”
ASHRAE Trans.
0001-2505,
86
, pp.
927
937
.
5.
Hiller
,
C. C.
,
Lowenstein
,
A. I.
, and
Merriam
,
R. L.
, 1994, “
Detailed Water Heating Simulation Model
,”
ASHRAE Trans.
0001-2505,
100
, pp.
948
955
.
6.
Farahan
,
E.
, 1977, “
Residential Electric and Gas Water Heaters
,” Tech. Rep. ANL/CES/TE 77-2, Argonne National Laboratory.
7.
Ton-That
,
Q. A.
, and
Laperriere
,
A.
, 1991, “
Temperature Comparison of Experimental Analysis and Numerical Simulation of Electric Water Heaters
,”
ASHRAE Trans.
0001-2505,
97
, pp.
226
230
.
8.
Homan
,
K. O.
, 2001, “
Thermodynamic Optimization of System Configuration for Electric Water Heating with Storage: Fully-Mixed Store
,”
Proceedings of the ASME Advanced Energy Systems Division
.
9.
Homan
,
K. O.
, 2003, “
Integral Solutions for Transient Temperature Profiles in Stably-Stratified Open Enclosures
,”
ASME J. Heat Transfer
0022-1481, vol.
125
, pp.
273
281
.
10.
United States Department of Energy, 1998, “
Test Procedure for Water Heaters; Final Rule
,” Federal Register, 10 CFR Part 430, pp.
25995
26014
.
11.
List
,
E. J.
, 1982, “
Mechanics of Turbulent Buoyant Jets and Plumes
,”
Turbulent Buoyant Jets and Plumes
,
W.
Rodi
, ed.,
Pergamon
, New York, pp.
1
68
.
12.
Homan
,
K. O.
, 2003, “
Internal Entropy Generation Limits for Direct Sensible Thermal Storage
,”
ASME J. Energy Resour. Technol.
0195-0738,
125
, pp.
85
93
.
13.
Homan
,
K. O.
, and
Soo
,
S. L.
, 1998, “
Laminar Flow Efficiency of Stratified Chilled-Water Storage Tanks
,”
Int. J. Heat Fluid Flow
0142-727X,
19
, pp.
69
78
.
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