THROUGHFLOW THEORY FOR NONAXISYMMETRIC TURBOMACHINERY FLOW .1. FORMULATION

被引：13

作者：

DRING, RP

OATES, GC

机构：

[1] United Technologies Research Center, E. Hartford, CT

[2] University of Washington, Seattle, WA

来源：

JOURNAL OF TURBOMACHINERY-TRANSACTIONS OF THE ASME | 1990年 / 112卷 / 03期

关键词：

D O I：

10.1115/1.2927661

中图分类号：

TH [机械、仪表工业];

学科分类号：

0802 ;

摘要：

Throughflow theory has been limited in its applicability and in its accuracy by the fact that it has not historically been cast in a form that can account for the nonaxisymmetries that naturally arise in turbomachinery flow due to the presence of finite numbers of rotor andstator airfoils. The attempt to circumvent this limitation by the introduction of an aerodynamic blockage factor has been demonstrated in earlier work to produce fundamental inconsistencies in the calculation, which lead to significant errors in the regions of the flow where the nonaxisymmetries are severe. The formulation in Part I of the present work is a derivation of a system of throughflow equations for nonaxisymmetric flow. A benchmark database is used in Part II to provide input to the calculation and to help identify the dominant terms. It is demonstrated that the dominant effect of nonaxisymmetry is contained in two terms that relate the total pressure of the averaged flow to the mass-averaged total pressure. It also is demonstrated that the present formulation produces a result that is more accurate than that obtained with the historical blockage-based formulation. © 1990 by ASME.

引用

页码：320 / 327

页数：8

共 25 条

[1]

Adkins G.G., Smith L.H., Spanwise Mixing in Axial-Flow Turbomachines, ASME Journal of Engineering for Power, 104, 1, pp. 97-110, (1982)

[2]

Propulsion and Energetics Panel Working Group 12 on Through-Flow Calculations in Axial Turbomachines, AGARD Advisory Report No. 175, (1981)

[3]

Dring R.P., Joslyn H.D., An Assessment of Single- and MultiStage Compressor Flow Modeling, Part I—Design Conditions, AD-B102 101, Final Report for Naval Air Systems Command, Contract No. N00014-84-C-0354, (1985)

[4]

Dring R.P., Joslyn H.D., Throughflow Modeling of Axial Turbomachinery, ASME, Journal of Engineering for Gas Turbines and Power, 108, 2, pp. 246-253, (1986)

[5]

Dring R.P., Joslyn H.D., Through-Flow Modeling of a Multistage Compressor: Part I—Aerodynamic Input, ASME Journal of Turbomachinery, 108, 1, pp. 17-22, (1986)

[6]

Dring R.P., Joslyn H.D., Through-Flow Modeling of a Multistage Compressor: Part II—Analytical-Experimental Comparisons, ASME Journal of Turbomachinery, 108, 1, pp. 23-31, (1986)

[7]

Dring R.P., Joslyn H.D., An Assessment of Single- and Multistage Compressor Flow Modeling, Part II—Near-Stall Conditions, Final Report, Naval Air Systems Command, Contract No. N00014-85-C-0657, (1986)

[8]

Dring R.P., Joslyn H.D., Throughflow Analysis of a Multistage Compressor Operating at Near-Stall Conditions, ASME Journal of Turbomachinery, 109, 4, pp. 483-491, (1987)

[9]

Dring R.P., Oates G.C., Through-Flow Theory for Nonaxi-symmetric Turbomachinery Flow, Final Report for Naval Air Systems Command, Contract Nos. N62271-86-M-0272 and N62271-87-M-0200, (1988)

[10]

Dring R.P., Oates G.C., Through flow Theory for Nonaxi-symmetric Turbomachinery Flow: Part II—Assessment, ASME Journal of Turbomachinery, 112, (1990)

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