This paper presents the experimental testing of relatively cost-effective expanders in an organic Rankine cycle (ORC) to produce power from low-grade energy. Gerotor and scroll expanders were the two types of expanders tested to determine their applicability in producing power from low-grade energy. The results of the experimental testing showed that both types of expanders were good candidates to be used in an ORC. The gerotor and scroll expanders tested produced 2.07 kW and 2.96 kW, and had isentropic efficiencies of 0.85 and 0.83, respectively. Also the paper presents results of an analytical model produced that predicted improved cycle efficiency with certain changes. One change was the flow rate of the working fluid in the cycle was properly matched with the inlet pocket volume and rotational speed of the expander. Also, the volumetric expansion ratio of the expander was matched to the specific volume ratio of the working fluid (R-123) across the expander. The model incorporated the efficiencies of the expanders and pump obtained during experimental testing, and combined two expanders in series to match the specific volume ratio of the working fluid. The model determined the power produced by the expanders, and subtracted the power required by the working fluid pump and the condenser fan. From that, the model calculated the net power produced to be 6271 W and the overall energy efficiency of the cycle to be 7.7%. When the ORC was simulated to be integrated with the exhaust of a stationary engine, the exergetic efficiency, exergy destroyed, and reduction in diesel fuel while still producing the same amount of power during 2500 h of operation were 22.1%, 22,169 W, and 4,012 L (1060 U.S. gal), respectively. Consequently, the model presents a very realistic design based on results from experimental testing to cost-effectively use low-grade energy.

1.
Hung
,
T. C.
,
Shai
,
T. Y.
, and
Wang
,
S. K.
, 1997, “
A Review of Organic Rankine Cycles (ORCs) for the Recovery of Low-Grade Waste Heat
,”
Energy
0360-5442,
22
(
7
), pp.
661
667
.
2.
Moran
,
M. J.
, and
Shapiro
,
H. N.
, 2004,
Fundamentals of Engineering Thermodynamics
, 5th ed.,
Wiley
,
Hoboken, NJ
.
3.
Badr
,
O.
,
O’Callaghan
,
P. W.
, and
Probert
,
S. D.
, 1985, “
Selecting a Working Fluid for a Rankine Cycle Heat Engine
,”
Appl. Energy
,
21
(
4
), pp.
1
42
. 0306-2619
4.
Yamamoto
,
T.
,
Furuhata
,
T.
,
Arai
,
N.
, and
Mori
,
K.
, 2001, “
Design and Testing of the Organic Rankine Cycle
,”
Energy
0360-5442,
26
(
3
), pp.
239
251
.
5.
Badr
,
O.
,
Probert
,
D.
, and
O’Callaghan
,
P.
, 1986, “
Multi-Vane Expanders as Prime Movers in Low-Grade Energy Engines
,”
Proc. Inst. Mech. Eng., Part A
0957-6509,
200
(
A2
), pp.
117
125
.
6.
Baatz
,
E.
, and
Heidt
,
G.
, 2000, “
First Waste Heat Power Generating Plant Using the Organic Rankine Cycle Process for Utilizing Residual Clinker Cooler Exhaust Air
,”
ZKG Int.
0722-4397,
53
(
8
), pp.
425
436
.
7.
Jaffe
,
L. D.
, 1988, “
A Review of Test Results on Parabolic Dish Solar Thermal Power Modules With Dish-Mounted Rankine Engines and for Production of Process Steam
,”
Sol. Eng.
0363-6003,
110
, pp.
275
281
.
8.
Wali
,
E.
, 1980, “
Optimum Working Fluids for Solar-Powered Rankine Cycle Cooling of Buildings
,”
Sol. Energy
,
25
, pp.
235
241
. 0038-092X
9.
Fontanez
,
J. R.
, 1993, “
Materials Compatibility Analysis for Gas Fired Heat Pump Diaphragms
,” MS thesis, The Ohio State University, Columbus, OH.
10.
Johnston
,
J. R.
, 2001, “
Evaluation of Expanders for Use in a Solar-Powered Rankine Cycle Heat Engine
,” MS thesis, The Ohio State University, Columbus, OH.
11.
Krieder
,
J. F.
, 1979,
Medium and High Temperature Solar Processes
,
Academic
,
New York
, pp.
193
198
.
12.
Sundar
,
S.
, and
Smith
,
J. L.
, 1997, “
Lumped Parameter Thermodynamic and Heat Transfer Modeling of a Scroll Pump
,”
Advanced Energy Systems Division Proceedings of the 1997 ASME International Mechanical Engineering Congress and Exposition
,
ASME
,
Fairfield, NJ
, Vol.
37
, pp.
417
427
.
13.
Moffat
,
R. J.
, 1985, “
Using Uncertainty Analysis in the Planning of an Experiment
,”
ASME J. Fluids Eng.
,
107
, pp.
173
178
. 0098-2202
14.
Çengel
,
Y. A.
, and
Boles
,
M. A.
, 2006,
Thermodynamics: An Engineering Approach
,
McGraw-Hill
,
New York
.
15.
Dincer
,
I.
, and
Rosen
,
M. A.
, 2000, “
Exergy Efficiencies of Sensible, Mixed Thermal Energy Storage Systems
,”
ASHRAE Trans.
0001-2505,
106
(
2
), pp.
260
266
.
16.
Rosen
,
M. A.
, and
Dincer
,
I.
, 2004, “
Exergetic Analysis of Cogeneration-Based District Energy Systems
,”
Proc. Inst. Mech. Eng., Part A
0957-6509,
218
(
6
) pp.
369
375
.
17.
Rosen
,
M. A.
, and
Dincer
,
I.
, 2004, “
A Study of Industrial Steam Process Heating Through Exergy Analysis
,”
Int. J. Energy Res.
,
28
(
10
), pp.
917
930
. 0363-907X
18.
Klein
,
S. A.
, 1992, EES Manual for Commercial and Professional Versions, F-CHART software.
19.
Al-Khafaji
,
A. W.
, and
Tooley
,
J. R.
, 1986,
Numerical Methods in Engineering Practice
,
Holt, Rinehart and Winston
,
New York
, p.
190
ff.
20.
Ferziger
,
J. H.
, 1981,
Numerical Methods for Engineering Application
,
Wiley-Interscience
,
New York
, Appendix B.
21.
Tillner-Roth
,
R.
, 1998,
Fundamental Equations of State
,
Shaker
,
Aachen
,
Germany
.
You do not currently have access to this content.