There is a growing interest in organic Rankine cycle (ORC) turbogenerators because they are suitable as sustainable energy converters. ORC turbogenerators can efficiently utilize external heat sources at low to medium temperature in the small to medium power range. ORC turbines typically operate at very high pressure ratio and expand the organic working fluid in the dense-gas thermodynamic region, thus requiring computational fluid dynamics (CFD) solvers coupled with accurate thermodynamic models for their performance assessment and design. This article presents a comparative numerical study on the simulated flow field generated by a stator nozzle of an existing high-expansion ratio radial ORC turbine with toluene as working fluid. The analysis covers the influence on the simulated flow fields of the real-gas flow solvers: FLUENT, FINFLO, and ZFLOW, of two turbulence models and of two accurate thermodynamic models of the fluid. The results show that FLUENT is by far the most dissipative flow solver, resulting in large differences in all flow quantities and appreciably lower predictions of the isentropic nozzle efficiency. If the combination of the kω turbulence model and FINFLO solver is adopted, a shock-induced separation bubble appears in the calculated results. The bubble affects, in particular, the variation in the flow velocity and angle along the stator outlet. The accurate thermodynamic models by Lemmon and Span (2006, “Short Fundamental Equations of State for 20 Industrial Fluids,” J. Chem. Eng. Data, 51(3), pp. 785–850) and Goodwin (1989, “Toluene Thermophysical Properties From 178 to 800 K at Pressures to 1000 Bar,” J. Phys. Chem. Ref. Data, 18(4), pp. 1565–1636) lead to small differences in the flow field, especially if compared with the large deviations that would be present if the flow were simulated based on the ideal gas law. However, the older and less accurate thermodynamic model by Goodwin does differ significantly from the more accurate Lemmon–Span thermodynamic model in its prediction of the specific enthalpy difference, which leads to a considerably different value for the specific work and stator isentropic efficiency. The above differences point to a need for experimental validation of flow solvers in real-gas conditions, if CFD tools are to be applied for performance improvements of high-expansion ratio turbines operating partly in the real-gas regime.

Issue Section:
Technical Briefs
Keywords:
computational fluid dynamics, mechanical engineering computing, nozzles, stators, thermodynamics, turbogenerators, turbulence, organic Rankine cycle, real gas, high expansion ratio, radial turbine, CFD simulation
Topics:
Computational fluid dynamics, Flow (Dynamics), Fluids, Nozzles, Organic Rankine cycle, Stators, Turbines, Turbulence, Simulation, Pressure
1.
Bronicki
,
L.
, 2007, “
Organic Rankine Cycles in Geothermal Power Plants—25 Years of Ormat Experience
,”
Proceedings of the GRC 2007 Annual Meeting
, Reno, NV.
2.
Bronicki
,
L. Y.
, 1988, “
Electrical Power From Moderated Temperature Geothermal Sources With Modular Mini-Power Plants
,”
Geothermics
0375-6505,
17
(
1
), pp.
83
92
.
Crossref
Search ADS
 
3.
Bini
,
R.
, and
Manciana
,
E.
, 1996, “
Organic Rankine Cycle Turbogenerators for Combined Heat and Power Production From Biomass
,”
Proceedings of the Third Munich Discussion Meeting on Energy Conversion From Biomass Fuels: Current Trends and Future Systems
, Paper No. 96A00412, pp.
1
8
.
4.
Obernberger
,
I.
,
Thonhofer
,
P.
, and
Reisenhofer
,
E.
, 2002, “
Description and Evaluation of the New 1000 kW ORC Process Integrated in the Biomass CHP Plant in Lienz, Austria
,”
Euroheat and Power
,
10
, pp.
1
17
.
5.
Bini
,
R.
,
Duvia
,
A.
,
Schwarz
,
A.
,
Gaia
,
M.
,
Bertuzzi
,
P.
, and
Righini
,
W.
, 2004, “
Operational Results of the First Biomass CHP Plant in Italy Based on Organic Rankine Cycle Turbogenerator and Overview of a Number of Plants in Operation in Europe Since 1998
,”
Proceedings of the 2nd World Conference on Biomass for Energy, Industry and Climate Protection
, 10–14 May 2004, Rome, Italy, pp.
1716
1721
.
6.
Drescher
,
U.
, and
Brüggemann
,
D.
, 2007, “
Fluid Selection for the Organic Rankine Cycle (ORC) in Biomass Power and Heat Plants
,”
Appl. Therm. Eng.
1359-4311,
27
, pp.
223
228
.
Crossref
Search ADS
 
7.
Yamaguchi
,
H.
,
Zhang
,
X. R.
,
Fujima
,
K.
,
Enomoto
,
M.
, and
Sawada
,
N.
, 2006, “
Solar Energy Powered Rankine Cycle Using Supercritical CO2
,”
Appl. Therm. Eng.
1359-4311,
26
(
17–18
), pp.
2345
2354
.
8.
Angelino
,
G.
, and
Colonna
,
P.
, 2000, “
Organic Rankine Cycles for Energy Recovery From Molten Carbonate Fuel Cells
,”
Proceedings of the 35th Intersociety Energy Conversion Engineering Conference (IECEC)
, AIAA Paper No. 2000-3052, pp.
1
11
.
9.
Angelino
,
G.
,
Gaia
,
M.
, and
Macchi
,
E.
, 1984, “
A Review of Italian Activity in the Field of Organic Rankine Cycles
,”
VDI Berichte–Proceedings of the International VDI Seminar
, Vol.
539
,
VDI
,
Zurich
, pp.
465
482
.
10.
Colonna
,
P.
,
Harinck
,
J.
,
Rebay
,
S.
, and
Guardone
,
A.
, 2008, “
Real-Gas Effects in Organic Rankine Cycle Turbine Nozzles
,”
J. Propul. Power
0748-4658,
24
(
2
), pp.
282
294
.
Crossref
Search ADS
 
11.
Larjola
,
J.
, 1995, “
Electricity From Industrial Waste Heat Using High-Speed Organic Rankine Cycle (ORC)
,”
Int. J. Prod. Econ.
0925-5273,
41
(
1–3
), pp.
227
235
.
12.
Angelino
,
G.
, and
Colonna
,
P.
, 1998, “
Multicomponent Working Fluids for Organic Rankine Cycles (ORCs)
,”
Energy
0360-5442,
23
(
6
), pp.
449
463
.
Crossref
Search ADS
 
13.
Verneau
,
A.
, 1987, “
Supersonic Turbines for Organic Fluid Rankine Cycles From 3 to 1300 kW
,”
Proceedings of the Small High Pressure Ratio Turbines
(VKI Lecture Series), Jun. 15–18,
Von Karman Institute
,
Rhode-Saint-Genèse, Belgium
, Paper No. 1987-07.
14.
Colonna
,
P.
,
Rebay
,
S.
, and
Silva
,
P.
, 2002, “
Computer Simulations of Dense Gas Flows Using Complex Equations of State for Pure Fluids and Mixtures and State-of-the-Art Numerical Schemes
,” Scientific report, Università di Brescia, Via Branze, Brescia, Italy, Vol.
38
, pp.
1
68
.
15.
Hoffren
,
J.
, 1997, “
Adaptation of FINFLO for Real Gases
,” Technical Report No. 102.
16.
Hoffren
,
J.
,
Talonpoika
,
T.
,
Larjola
,
J.
, and
Siikonen
,
T.
, 2002, “
Numerical Simulation of Real-Gas Flow in a Supersonic Turbine Nozzle Ring
,”
ASME J. Eng. Gas Turbines Power
0742-4795,
124
(
2
), pp.
395
403
.
Crossref
Search ADS
 
17.
Turunen-Saaresti
,
T.
,
Tang
,
J.
, and
Larjola
,
J.
, 2006, “
A Practical Real Gas Model in CFD
,”
Proceedings of the European Conference on Computational Fluid Dynamics (ECCOMAS CFD 2006)
,
P.
Wesseling
,
E.
Onate
, and
J.
Périau
, eds.
18.
Boncinelli
,
P.
,
Rubechini
,
F.
,
Arnone
,
A.
,
Cecconi
,
M.
, and
Cortese
,
C.
, 2004, “
Real Gas Effects in Turbomachinery Flows—A Computational Fluid Dynamics Model for Fast Computations
,”
J. Turbomach.
0889-504X,
126
(
2
), pp.
268
276
.
Crossref
Search ADS
 
19.
Cinnella
,
P.
, and
Congedo
,
P.
, 2004, “
A Numerical Solver for Dense Gas Flows
,”
Proceedings of the 34th AIAA Fluid Dynamics Conference and Exhibit
, AIAA Paper No. 2004-2137, pp.
1
12
.
20.
Cinnella
,
P.
, and
Congedo
,
P.
, 2007, “
Inviscid and Viscous Aerodynamics of Dense Gases
,”
J. Fluid Mech.
0022-1120,
580
, pp.
179
217
.
Crossref
Search ADS
 
21.
Colonna
,
P.
, and
Rebay
,
S.
, 2004, “
Numerical Simulation of Dense Gas Flows on Unstructured Grids With an Implicit High Resolution Upwind Euler Solver
,”
Int. J. Numer. Methods Fluids
0271-2091,
46
(
7
), pp.
735
765
.
Crossref
Search ADS
 
22.
Harinck
,
J.
,
Colonna
,
P.
,
Guardone
,
A.
, and
Rebay
,
S.
, 2010, “
Influence of Thermodynamic Models in Two-Dimensional Flow Simulations of Turboexpanders
,”
J. Turbomach.
0889-504X,
132
, p.
011001
.
Crossref
Search ADS
 
23.
Van Buijtenen
,
J.
,
Larjola
,
J.
,
Turunen-Saaresti
,
T.
,
Honkatukia
,
J.
,
Esa
,
H.
,
Backman
,
J.
, and
Reunanen
,
A.
, 2003, “
Design and Validation of a New High Expansion Ratio Radial Turbine for ORC Applications
,”
Proceedings of the Fifth European Conference on Turbomachinery
, pp.
1
14
.
24.
Colonna
,
P.
,
Rebay
,
S.
,
Harinck
,
J.
, and
Guardone
,
A.
, 2006, “
Real-Gas Effects in ORC Turbine Flow Simulations: Influence of Thermodynamic Models on Flow Fields and Performance Parameters
,”
Proceedings of the European Conference on Computational Fluid Dynamics (ECCOMAS CFD 2006)
,
P.
Wesseling
,
E.
Onate
, and
J.
Périau
, eds., pp.
1
18
.
25.
FLUENT Inc.
, 2006, FLUENT 6.3 documentation, Lebanon, NH.
26.
Pan
,
H.
, 1993, “
Two-Dimensional Navier-Stokes Computations of Subsonic and Supersonic Flows Through Turbine Cascades
,” Technical Report No. B-40.
27.
Rautaheimo
,
P.
,
Salminen
,
E.
, and
Siikonen
,
T.
, 1995, “
Numerical Simulation of the Flow in the NASA Low-Speed Centrifugal Compressor
,” Technical Report No. 119.
28.
Pitkänen
,
H.
, and
Siikonen
,
T.
, 1995, “
Simulation of Viscous Flow in a Centrifugal Compressor
,” Technical Report No. B-46.
29.
Goodwin
,
R.
, 1989, “
Toluene Thermophysical Properties From 178 to 800 K at Pressures to 1000 Bar
,”
J. Phys. Chem. Ref. Data
0047-2689,
18
(
4
), pp.
1565
1636
.
Crossref
Search ADS
 
30.
Lemmon
,
E.
, and
Span
,
R.
, 2006, “
Short Fundamental Equations of State for 20 Industrial Fluids
,”
J. Chem. Eng. Data
0021-9568,
51
(
3
), pp.
785
850
.
Crossref
Search ADS
 
31.
Harinck
,
J.
,
Turunen-Saaresti
,
T.
, and
Colonna
,
P.
, 2007, “
Performance and CFD Analyses of a High-Expansion Ratio Radial ORC Turbine
,” Scientific Report No. ET-2262.
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