Journal of the Korea Academia-Industrial cooperation Society (한국산학기술학회논문지)

The Korea Academia-Industrial cooperation Society (한국산학기술학회)
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Investigation of Emission Gas by using the Intake Manifold Gasket Blade

흡기 매니폴드 가스켓 블레이드 적용에 따른 배출가스 고찰

  • Lee, Minjung (Graduate school of Mechanical engineering, Chosun University) ;
  • Kim, Taejung (Department of Automobile, Dalseong Campus of Korea Polytechnics) ;
  • Shin, Yunchan (Graduate school of Mechanical engineering, Chosun University) ;
  • Cho, Honghuyn (Department of Mechanical engineering, Chosun University)
  • 이민정 (조선대학교 기계공학과 대학원) ;
  • 김태중 (한국폴리텍대학 달성캠퍼스 자동차과) ;
  • 신윤찬 (조선대학교 기계공학과 대학원) ;
  • 조홍현 (조선대학교 기계공학과)
  • Received : 2018.09.10
  • Accepted : 2018.12.07
  • Published : 2018.12.31
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Abstract

Incomplete combustion in automotive engines is a major cause of harmful exhaust gases. In this study, to prevent incomplete combustion and reduce exhaust gas emissions, a gasket blade for increasing the air velocity was applied to the intake manifold, and the change in exhaust gas was investigated theoretically and experimentally. First, simulation analysis for flow according to the number and angle of the gasket blade was performed using a 3D flow analysis program. As an analysis result, the internal average velocity of the gasket blade was optimum at 6-blade with an angle of $30^{\circ}$. Based on the simulation results, experiments were conducted to verify the effects of the gasket blades on the exhaust gas in a non-load engine simulation system. As the engine speed was increased from 2000 to 4000 rpm, exhaust gases of HC, CO, and NOx decreased by 23.4%, 16.5%, and 3.8%, respectively, and the emission decreasing effect was reduced.

자동차의 엔진에서 불완전 연소는 유해 배기가스 생성의 주요 원인이다. 따라서 본 연구에서는 자동차 엔진에서 불완전 연소를 방지하고 배출되는 배기가스의 양을 줄이기 위하여 흡기 매니폴드에 가스켓 블레이드를 적용하여 유입되는 공기의 유속 증가에 따른 배기가스의 변화를 해석과 실험을 통하여 고찰하였다. 먼저 3D 유동 해석 프로그램을 사용하여 가스켓 블레이드의 개수와 각도에 따른 유동 해석을 수행하였으며, 해석 결과 가스켓 블레이드를 적용한 흡기 매니폴드 출구에서 공기의 평균 유속은 블레이드 개수가 6개와 $30^{\circ}$각도에서 가장 좋게 나타났다. 해석 결과를 기반으로 무부하 엔진 시뮬레이션 시스템에서 가스켓 블레이드가 배기가스에 미치는 영향을 확인하기 위하여 실험을 진행하였으며 엔진 회전수가 2000 rpm에서 4000 rpm으로 증가함에 따라 배기가스인 HC, CO, NOx는 평균적으로 각각 23.4%, 16.5%, 3.8% 감소하였으며 배기가스의 배출량 감소 효과는 점점 줄어드는 것으로 나타났다.

Keywords

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Fig. 1. Intake manifold according to the number of various gasket blades

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Fig. 2. Modeling of intake manifold

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Fig. 3. Photos of manufactured gasket blade and mounted on intake manifold

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Fig. 4. Emission simulation system

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Fig. 5. Maximum air velocity in the intake manifold with the number of gasket blade

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Fig. 6. Turbulence kinetic energy in the intake manifold with the number of gasket blade

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Fig. 7. Maximum air velocity in the intake manifold with the angle of gasket blade

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Fig. 8. Turbulence kinetic energy in the intake manifold with the angle of gasket blade

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Fig. 9. Outlet average air velocity in the intake manifold with the angle of gasket blade

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Fig. 10. Variation of HC according to engine speed

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Fig. 11. Variation of CO according to engine speed

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Fig. 12. Variation of NOx according to engine speed

Table 1. Emission gas regulations of European passenger car

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Table 2. Analysis conditions of intake manifold

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Table 3. Specifications of gasoline engine

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Table 4. Emission measure equipments

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References

  1. G. Greeves, I. M. Khan, C. H. T. Wang, I. Fenne, Origins of Hydrocarbon Emission from Diesel Engines, SAE Technical Paper No. 770259, 1977 DOI: https://dx.doi.org/10.4271/770259
  2. Y. Sato. A. Noda, T. Sakamoto, Combustion and NOx Emission Characteristics in a DI Methanol Engine Using Supercharging with EGR, SAE No. 971647, 1997 DOI: https://dx.doi.org/10.4271/971647
  3. N. Uchida, Combustion Optimization by Means of Common Rail Injection System for Heavy-Duty Diesel Engines, SAE No. 982679, 1987 DOI: https://dx.doi.org/10.4271/982679
  4. Y. H. Cho, S. O. Kim, EU, EURO 6 Enforcement of automobile exhaust gas regulation, BSC Report 359-13-003
  5. Regulation (EC) No 715/2007 of the European Parliament and of the Council of 20 June 2007 on type approval of motor vehicles with respect to emissions from light passenger and commercial vehicles (Euro 5 and Euro 6) and on access to vehicle repair and maintenance information
  6. Compliance in Advance and Supporting system (http://www.compass.or.kr)
  7. J. Kim, The Flow and Distribution Characteristics for Various Configurations of Individual EGR Supply System, KSAE 2005 Fall, KSAE05-F0003, pp. 15-21, 2005
  8. S. Park, The study on Engine Performance and Emission Characteristics with Continuously Variable Valve Lift System in an SI Engine, M. S. thesis, Kookmin University, 2011
  9. C. D. Copeland, X. Gao, P. A. Freeland, J. Neumeister and J. Micalf, Simulation of Exhaust Gas Residuals in a Turbocharged, Spark Ignition Engine, SAE Technical Paper 2013-01-2705, 2013 DOI: https://dx.doi.org/10.4271/2013-01-2705
  10. T. Alger, T. Chauvet and Z. Dimitrova, Synergies between High EGR Operation and GDI Systems, SAE Technical Paper 2008-01-0134, 2008 DOI: https://dx.doi.org/10.4271/2008-01-0134
  11. J. Nan, L. Jifeng, Z. Xueen and C. Xiaojun, Study on Engine Performance Influenced by External Cooled EGR, Proceedings of the FISITA 2012 World Automotive Congress, Vol. 1, pp. 587-598, 2012 DOI: https://dx.doi.org/10.1007/978-3-642-33841-0_45