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Abstract

The one-dimensional design approaches of radial inflow turbine volutes can be catalogued into incompressible and compressible. This paper investigates the degree to which they differ from each other in terms of design parameters, such as the distribution of ratio of area to radius A/r and radius r, and in terms of flow deviation from the free vortex pattern. Theoretical analysis proves that the incompressible approaches failed to provide free vortex and uniform flow for the wheel in compressible flow regimes. A numerical simulation on a previously designed and tested volute shows that the wake flow of the tongue and the boundary layer on the wall cause the tangential velocity of the volute flow to deflect from the free vortex design downstream and upsteam respectively of the tongue. The radial velocity component is higher at first, then lower than the free vortex design, owing to the significant pressure gradient around the tongue.

Keywords

volute radial turbine incompressible flow compressible flow free vortex flow

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References

Whitfield

Noor

Mohd A. B.

Design and performance of vaneless volutes for radial inflow turbines. Part 1: Non-dimensional conceptual design considerations. Proc. Instn Mech. Engrs, Part A, Journal of Power and Energy, 1994, 208(A3), 199–211.

Whitfield

MacGregor

S. A.

Noor

Mohd A. B.

Design and performance of vaneless volutes for radial inflow turbines. Part 2: Experimental investigation of the mean line performance-assessment of empirical design parameters. Proc. Instn Mech. Engrs, Part A, Journal of Power and Energy, 1994, 208(A3), 213–224.

Hussain

Ilyas

Bhinder

F. S.

A contribution to designing a nozzle-less volute casing for the inward flow radial gas turbine. In IMechE Conference, 1982, paper C35/82.

Chapple

P. M.

Flynn

P. F.

Mulloy

J. M.

Aerodynamic design of fixed and variable geometry nozzleless turbine casing. Trans. ASME, J. Engng Pwr, 1980, 102, 141–147.

Chen

Design methods of volute casings for turbo-charger turbine applications. Proc. Instn Mech. Engrs, Part A, Journal of Power and Energy, 1996, 210(A2), 149–156.

Owarish

H. O.

Ilyas

Bhinder

F. S.

A two-dimensional flow analysis model for designing a nozzle-less volute casing for radial flow gas turbines. Trans. ASME, J. Turbomachinery, 1992, 114, 402–410.

Tabakoff

Sheoran

Kroll

Flow measurements in a turbine scroll. Trans. ASME, J. Fluids Engng, 1980, 102, 290–296.

MacGregor

S. A.

Whitfield

Noor

Mohd A. B.

Design and performance of vaneless volutes for radial inflow turbines. Part 3: Experimental investigation of the internal flow structure. Proc. Instn Mech. Engrs, Part A, Journal of Power and Energy, 1994, 208(A4), 295–302.

Miller

E. C.

L'Ecuyer

M. R.

Benisek

E. F.

Flowfield surveys at the rotor inlet of a radial inflow turbine. ASME paper 87-ICE-52, 1987.

10.

Benisek

E. F.

Laser velocimeter measurements at the rotor inlet of a turbocharger radial inflow turbine. ASME FED-Vol. 55, 1987.

11.

Flathers

M. B.

Bache

G. E.

Rainsberger

An experimental and computational investigation of flow in a radial inlet of an industrial pipeline centrifugal compressor. ASME paper 94-GT-134, 1994.

12.

Schlichting

Boundary-Layer Theory, 1979 (McGraw-Hill, New York).

A comparative study of incompressible and compressible design approaches of radial inflow turbine volutes

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