Structure Optimization Design of Vane Steering Pump

Lian Fu Yang

doi:10.4028/www.scientific.net/AMM.496-500.904

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HomeApplied Mechanics and MaterialsApplied Mechanics and Materials Vols. 496-500Structure Optimization Design of Vane Steering...

Structure Optimization Design of Vane Steering Pump

Abstract:

How to reduce or eliminate the noise of the vane steering pump is a key problem to use hydraulic power steering car to solve. After a lot of experiments and demonstration, the methods of adopting correct transition curve, and a large circular arc method, adopting low noise impact curve of eight times optimization design, and the advanced stator curve fitting method, are to be good solutions to the problem of the vane steering pump noise.

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Periodical:

Applied Mechanics and Materials (Volumes 496-500)

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904-907

DOI:

https://doi.org/10.4028/www.scientific.net/AMM.496-500.904

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Online since:

January 2014

Authors:

Lian Fu Yang

Keywords:

Design, Optimization, Structure, Vane Steering Pump

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References

[1] Barer A. Handbook of Noise & Vibration Control. Elsevier Science Pub Co., (1993).

Google Scholar

[2] Harris C M, Piersol A G. Harris Shock and Vibration Handbook. Mcgraw-Hill Professional, 5th edition , (2001).

Google Scholar

[3] ALY.S. Performance Prediction Method for Centrifugal Pumps. SAE Technical, Paper Series 1992: 62-73.

DOI: 10.4271/921731

Google Scholar

[4] A.W. NEASE,A.C. MORSE，A Solution to pump ripple in the space shuttle flight control system，PaP. Am. Soc. Mech. Eng, [80-C2-AERO-5], (1980).

Google Scholar

[5] BECKA ，Hydraulic mufflers for noise and vibration control，Proc. natl. conf. Fluid power, vol. 36，(1982).

Google Scholar

[6] KOJI MA E, SHI NADN M, YOSHINO T. Characteristic of fluidebore noise generated by fluid power pump (2nd Report, Pressure pulsation in balanced vane Pump)[J]. Bulletin of JSME, 1984, 27(225): 475-482.

DOI: 10.1299/jsme1958.27.475

Google Scholar

[7] Young M.Y. Digital Simulation of Hydraulic Contral Systems.M. Eng. sc. Thesis, Monash University, Australia, 1978: 154-162.

Google Scholar

[8] Zhang Kewei etal. Optimization Desion of The Mixed Flow Pump, Proceedings of Second International Conference on Pumps Using Jet-Wake Model, Second ASME Pumping Machinery Symposium Washington D.C.U.S. A: June 1993: 12.

Google Scholar

[9] T. Takagi. Performance Prediction of Single-Suction Centrifugal Pump of Different Specific Speeds. ASME, 1979: 20-26.

Google Scholar

[10] C Weissgerber. Comparisions of Hydraulic Performance Predictions and Test Datafor a Range of Pump, ASME, 1979: 1123-1450.

Google Scholar

[11] Gopala Krishnan S. Computer Based Hydraulic Design of Pumps. 7th Tech. Conf ofthe BPMA 31st.

Google Scholar