한국정밀공학회지 (Journal of the Korean Society for Precision Engineering)

  • 제21권6호
  • /
  • Pages.102-108
  • /
  • 2004
  • /
  • 1225-9071(pISSN)
  • /
  • 2287-8769(eISSN)
한국정밀공학회 (Korean Society for Precision Engineering)
권호 표지

자동차 연료펌프의 오염민감도 실험 연구

An Experimental Investigation on The Contamination Sensitivity of An Automotive Fuel Pump

  • 이재천 (계명대학교 기계자동차공학부) ;
  • 장지현 (계명대학교 대학원 기계공학) ;
  • 신현명 (계명대학교 기계자동차공학부)
  • 발행 : 2004.06.01
PDF 다운로드
⟨ 이전 논문 다음 논문 ⟩

초록

This study addresses the contamination sensitivity test of a typical fuel pump for automotive vehicle. The objective of the study is to find the contamination sensitivity coefficient of fuel pump on specific contaminant particle sizes so that optimal fuel filter could be selected. To achieve the objective, the degradation of discharge flow rate of fuel pump was measured under the experiments of various contaminants size ranges of ISO test dust up to 80${\mu}{\textrm}{m}$. The fundamental theory of contamination sensitivity was introduced and the contamination sensitivity coefficients were estimated using the experimental data. Maximum contamination sensitivity coefficient of $5{\times}10^{-6}$ L/minㆍEa was found on the contaminant size range of 40${\mu}{\textrm}{m}$∼50${\mu}{\textrm}{m}$. The magnified picture of the surface of vane disc revealed that the abrasive wear was the principal cause of discharge flow rate degradation. Hence, this study revealed that high efficiency filter on the contaminant particle size range of 30${\mu}{\textrm}{m}$∼70${\mu}{\textrm}{m}$ especially should be used to maintain the service lift of the fuel filter.

키워드

참고문헌

  1. Fitch, E. C., Fluid Contamination Control, FES, Inc., Stillwater, OK, 1988
  2. Bensch, L. E., 'A New Theory for the Contamination Sensitivity of Fluid Power Pumps,' Paper No. 72-CC-6, The BFPR Program, Oklahoma State University, 1972
  3. Inoue, R., Fitch, E. C., 'The Omega Pump Rating System,' The BFPR Journal, Vol. 12, pp.141-144, 1979
  4. Fitch, E. C., Hong, I. T., 'Pump Contaminant Sensitivity-Part 1: An Overview of the Omega Theory,' The FRH Journal, Vol.6, pp.83-87, 1986
  5. Lee, J.-C., Kim, S.-H., 'An Experimental Investigation of Particle Impingement Erosion in Hydraulic Systems,' J. KSAE, Vol.10, No.2, pp.117-122, 2002
  6. Lee, G.-H., Lee, C.-H., 'Development of Spray Optimization Technique for a GDI Engine,' Proceeding of 9th Next Generation Vehicle Workshop, KATECH, pp.97-104, 2000
  7. Lee, J.-C., Jang, J.-H., 'Performance Evaluation of an Automotive Fuel Filter by Multi-Pass Filtration Test,' J. KSAE, Vol.10, No.6, pp.219-226, 2002
  8. Lee, J.-C., 'A Study on Filtration System Model and Comparative Performance Tests of Automotive Fuel Filters,' J. KSPE, Vol.20, No.3, pp.194-201, 2003
  9. Lee, J.-C., 'A Study on Hydraulic Drawdown Test Model and Experimental Estimation of Desorption Rate Ratios of Fuel Filters,' J. KSPE, Vol.20, No.9, pp.205-213, 2003
  10. Fitch, E. C., Hong, I. T., Hydraulic System Design for Service Assurance, BarDyne Inc., pp.161-164, 2001
  11. NFPA Standard T3.9.18 R1-1978, Method of Establishing The Flow Degradation of Fixed Displacement Hydraulic Fluid Power Pumps When Exposed to Particulate Contminant, NFPA, Inc., Milwaukee, WI, 1978
  12. White Spirit, Mobil Product Data Sheet, Mobil Oil Australia Ltd., 1997
  13. Laser Net Fines-C, Particle Counter and Particle Shape Classifier, Instruction Manual, Spectro Inc., 2001
  14. ISO 11171, Hydraulic Fluid Power-Calibration of Automatic Particle Counters for Liquids, 1999
  15. Roberts, G. A., 'Quality Control of Sample Container Cleanliness,' The BFPR Journal, Vol.21, pp.129-148, 1988
  16. Lee, J. C., 'A Study on Contamination Sensitivity and Condition Monitoring for a Pump,' Proc. 27th Spring Conference KSTLE, pp.124-130, 1998