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Year 2012, Volume: 25 Issue: 2, 519 - 532, 16.04.2012

Abstract

References

  • Hofman D.M.W., Dowling D.R., “Modeling fully- coupled rigid engine dynamics and vibrations”, SAE Noise and Vibration Conference, Traverse City, Michigan, Proceedings, SAE Paper no. 1999-01-1749, 2:747-755, (1999).
  • Cho S.H., Ahn S.T., Kim Y.H, “A simple model to estimate the impact force induced by piston flap”, Journal of Sound and Vibration, 255(2): Chu C.C., “Multiaxial fatigue life prediction method in the ground vehicle industry”, Int. J. Fatigue, 19: 325-330, (1997).
  • Paschold H.W., Sergeev A.V., “Whole-body vibration knowledge survey of U.S. occupational safety and health professionals”, Journal of Safety Research, 40: 171-176, (2009).
  • Hostens I., Roman H., “Descriptive analysis of combined cabin vibrations and their effect on the human body”, Journal of Sound and Vibration, : 453-464, (2003).
  • Boysal A., Rahneja H., “A torsional vibration analysis of a multi-body single cylinder internal combustion engine model”, Applied Mathematical Modelling, 21: 481-493, (1997).
  • Yu Y., Naganathan N.G., Dukkipati R.V., “A literature review of automotive vehicle engine mounting systems”, Mechanism and Machine Theory, 36: 123-142, (2001).
  • Wang R., “A study of vibration isolation of engine mount University, The Department of Mechanical and Industrial Engineering, (2005). Concordia
  • Hoffmann D.M.W., Dowling D.R., “Fully coupled rigid internal combustion engine dynamics and vibration, Part I: Model development", Journal of Engineering for Gas Turbines and Power, 123: 684, (2001).
  • Megahed S. M., Abd El-Razik A. K., “Vibration control of two degrees of freedom system using variable inertia vibration absorbers: Modeling and simulation", Journal of Sound and Vibration, : 4841-4865, (2010).
  • FitzGerald D., “Focused engine isolation systems- the benefits”, 1997 SAE International Off- Highway
  • Exposition, Milwaukee, Wisconsin, SAE paper no. , 1-9, September (1997). Congress &
  • Shangguan W.B., Lu Z-H., “Experimental study and simulation of a hydraulic engine mount with fully coupled fluid–structure interaction finite element Structures, 82:1751-1771, (2004). Computers and Wang L.R., Wang J.C., Hahiwara I., “An integrated characteristic simulation method, for hydraulic rubber mount of vehicle engine”,
  • Journal of Sound and Vibration, 286: 673-696, (2005).
  • Foumani M.S., Khajepour A., M. Durali, “Optimization of engine mount characteristics using experimental/numerical analysis”, Journal of Vibration and Control, 9: 1121-1139, (2003).
  • Winton D.M., Dowling D.R., “Modal content of heavy-duty diesel engine block vibration”, Society of Automotive Engineers, No: 971948, 621-630, (1997).
  • Muller M., Siebler T.W., Gortner H., “Simulation of vibrating vehicle structures as part of the design process of engine mount systems and vibration absorbers”, Society of Automotive Engineers, No: , 1-11, (1995).
  • Tao J.S., Liu G.R., Lam K.Y., “Design optimization of marine engine mount system”, Journal of Sound and Vibration, 235(3): 477-494, (2000).
  • Guzzomi, A.L., Hesterman D.C., Stone B.J., “The effect of piston friction on engine block dynamics”, Proceedings of the Institution of Mechanical Engineers Part K: Journal of Multi Body Dynamics, 221: 277-289, (2007).
  • Ciulli E., Rizzoni G., Dawson J., “Numerical and experimental study of friction on a single cylinder CFR engine”, SAE International Congress and Exposition, Michigan, 960357, 181-188, (1996).
  • Livanos G.A., Kyrtatos N.P., “Friction model of a marine diesel engine piston assembly”, Tribology, : 1441-1453, (2007).
  • Wang Y., Lim T.C., “Effects of viscous friction and non-friction damping mechanism in a reciprocating engine”, Journal of Sound and Vibration, 257(1): 177-188, (2002).
  • Karabulut, H., Öztürk, E. and Çınar, C., ‘‘Tek Silindirli dört zamanlı bir dizel motorunun dinamik modeli ve titreşimlerinin incelenmesi’’, Gazi Üniversitesi Dergisi, 26(1), 173-183, (2011) Fakültesi
  • Karabulut, H., Dynamic model of a two-cylinder four-stroke internal combustion engine and vibration treatment, International Journal of Engine 1177/1468087412442618, 2012 doi:
  • Ye Z., Zhang C., Wang Y., Cheng H.S., Tung S., Wang Q.J., He X., “An experimental investigation of piston skirt scuffing: a piston scuffing apparatus, experiments, and scuffing mechanism analyses”, Wear, 257: 8-31, (2004).
  • Dowson D., Taylor C. M., Yang L., “Friction modeling for internal combustion engines”, Tribology Series, 31: 301-318, (1996).

Dynamic Behaviors of a Two-Cylinder Four-Stroke Internal Combustion Engine

Year 2012, Volume: 25 Issue: 2, 519 - 532, 16.04.2012

Abstract

In this study the vibrational aspects of a two-cylinder four-stroke internal combustion engine were studied. A dynamic model has been prepared with four degrees of  freedom which are: the translational vibrations of the engine block in vertical and horizontal directions, the rotational vibration of the engine block around the crankshaft center and the fluctuation of crankshaft angular speed. The model comprises forces and moments caused by inertial effects, hydrodynamic and dry frictions, startup moment, external load, gas pressures and mount forces. Vibrations of the engine block and fluctuation of crankshaft speed were optimized by using practical values. The inertia moment of the flywheel was found to be the dominant factor to minimize the angular speed fluctuation of the crankshaft. The gas force and the mass of the pistons were found to be the prevalent parameters contributing to the rotational and translational vibrations of the block respectively. It is observed that the vertical vibration of the block could be adequately minimized by means of exposing counterweights to the crankshaft, however, the counterweight induces a horizontal vibration while diminishing the vertical vibration. Therefore, in minimization of the translational vibrations of engine block, in addition to exposing counterweights, the piston mass should be very well minimized.  

References

  • Hofman D.M.W., Dowling D.R., “Modeling fully- coupled rigid engine dynamics and vibrations”, SAE Noise and Vibration Conference, Traverse City, Michigan, Proceedings, SAE Paper no. 1999-01-1749, 2:747-755, (1999).
  • Cho S.H., Ahn S.T., Kim Y.H, “A simple model to estimate the impact force induced by piston flap”, Journal of Sound and Vibration, 255(2): Chu C.C., “Multiaxial fatigue life prediction method in the ground vehicle industry”, Int. J. Fatigue, 19: 325-330, (1997).
  • Paschold H.W., Sergeev A.V., “Whole-body vibration knowledge survey of U.S. occupational safety and health professionals”, Journal of Safety Research, 40: 171-176, (2009).
  • Hostens I., Roman H., “Descriptive analysis of combined cabin vibrations and their effect on the human body”, Journal of Sound and Vibration, : 453-464, (2003).
  • Boysal A., Rahneja H., “A torsional vibration analysis of a multi-body single cylinder internal combustion engine model”, Applied Mathematical Modelling, 21: 481-493, (1997).
  • Yu Y., Naganathan N.G., Dukkipati R.V., “A literature review of automotive vehicle engine mounting systems”, Mechanism and Machine Theory, 36: 123-142, (2001).
  • Wang R., “A study of vibration isolation of engine mount University, The Department of Mechanical and Industrial Engineering, (2005). Concordia
  • Hoffmann D.M.W., Dowling D.R., “Fully coupled rigid internal combustion engine dynamics and vibration, Part I: Model development", Journal of Engineering for Gas Turbines and Power, 123: 684, (2001).
  • Megahed S. M., Abd El-Razik A. K., “Vibration control of two degrees of freedom system using variable inertia vibration absorbers: Modeling and simulation", Journal of Sound and Vibration, : 4841-4865, (2010).
  • FitzGerald D., “Focused engine isolation systems- the benefits”, 1997 SAE International Off- Highway
  • Exposition, Milwaukee, Wisconsin, SAE paper no. , 1-9, September (1997). Congress &
  • Shangguan W.B., Lu Z-H., “Experimental study and simulation of a hydraulic engine mount with fully coupled fluid–structure interaction finite element Structures, 82:1751-1771, (2004). Computers and Wang L.R., Wang J.C., Hahiwara I., “An integrated characteristic simulation method, for hydraulic rubber mount of vehicle engine”,
  • Journal of Sound and Vibration, 286: 673-696, (2005).
  • Foumani M.S., Khajepour A., M. Durali, “Optimization of engine mount characteristics using experimental/numerical analysis”, Journal of Vibration and Control, 9: 1121-1139, (2003).
  • Winton D.M., Dowling D.R., “Modal content of heavy-duty diesel engine block vibration”, Society of Automotive Engineers, No: 971948, 621-630, (1997).
  • Muller M., Siebler T.W., Gortner H., “Simulation of vibrating vehicle structures as part of the design process of engine mount systems and vibration absorbers”, Society of Automotive Engineers, No: , 1-11, (1995).
  • Tao J.S., Liu G.R., Lam K.Y., “Design optimization of marine engine mount system”, Journal of Sound and Vibration, 235(3): 477-494, (2000).
  • Guzzomi, A.L., Hesterman D.C., Stone B.J., “The effect of piston friction on engine block dynamics”, Proceedings of the Institution of Mechanical Engineers Part K: Journal of Multi Body Dynamics, 221: 277-289, (2007).
  • Ciulli E., Rizzoni G., Dawson J., “Numerical and experimental study of friction on a single cylinder CFR engine”, SAE International Congress and Exposition, Michigan, 960357, 181-188, (1996).
  • Livanos G.A., Kyrtatos N.P., “Friction model of a marine diesel engine piston assembly”, Tribology, : 1441-1453, (2007).
  • Wang Y., Lim T.C., “Effects of viscous friction and non-friction damping mechanism in a reciprocating engine”, Journal of Sound and Vibration, 257(1): 177-188, (2002).
  • Karabulut, H., Öztürk, E. and Çınar, C., ‘‘Tek Silindirli dört zamanlı bir dizel motorunun dinamik modeli ve titreşimlerinin incelenmesi’’, Gazi Üniversitesi Dergisi, 26(1), 173-183, (2011) Fakültesi
  • Karabulut, H., Dynamic model of a two-cylinder four-stroke internal combustion engine and vibration treatment, International Journal of Engine 1177/1468087412442618, 2012 doi:
  • Ye Z., Zhang C., Wang Y., Cheng H.S., Tung S., Wang Q.J., He X., “An experimental investigation of piston skirt scuffing: a piston scuffing apparatus, experiments, and scuffing mechanism analyses”, Wear, 257: 8-31, (2004).
  • Dowson D., Taylor C. M., Yang L., “Friction modeling for internal combustion engines”, Tribology Series, 31: 301-318, (1996).
There are 25 citations in total.

Details

Primary Language English
Subjects Engineering
Journal Section Mechanical Engineering
Authors

Halit Karabulut

Hakan Ersoy

Publication Date April 16, 2012
Published in Issue Year 2012 Volume: 25 Issue: 2

Cite

APA Karabulut, H., & Ersoy, H. (2012). Dynamic Behaviors of a Two-Cylinder Four-Stroke Internal Combustion Engine. Gazi University Journal of Science, 25(2), 519-532.
AMA Karabulut H, Ersoy H. Dynamic Behaviors of a Two-Cylinder Four-Stroke Internal Combustion Engine. Gazi University Journal of Science. April 2012;25(2):519-532.
Chicago Karabulut, Halit, and Hakan Ersoy. “Dynamic Behaviors of a Two-Cylinder Four-Stroke Internal Combustion Engine”. Gazi University Journal of Science 25, no. 2 (April 2012): 519-32.
EndNote Karabulut H, Ersoy H (April 1, 2012) Dynamic Behaviors of a Two-Cylinder Four-Stroke Internal Combustion Engine. Gazi University Journal of Science 25 2 519–532.
IEEE H. Karabulut and H. Ersoy, “Dynamic Behaviors of a Two-Cylinder Four-Stroke Internal Combustion Engine”, Gazi University Journal of Science, vol. 25, no. 2, pp. 519–532, 2012.
ISNAD Karabulut, Halit - Ersoy, Hakan. “Dynamic Behaviors of a Two-Cylinder Four-Stroke Internal Combustion Engine”. Gazi University Journal of Science 25/2 (April 2012), 519-532.
JAMA Karabulut H, Ersoy H. Dynamic Behaviors of a Two-Cylinder Four-Stroke Internal Combustion Engine. Gazi University Journal of Science. 2012;25:519–532.
MLA Karabulut, Halit and Hakan Ersoy. “Dynamic Behaviors of a Two-Cylinder Four-Stroke Internal Combustion Engine”. Gazi University Journal of Science, vol. 25, no. 2, 2012, pp. 519-32.
Vancouver Karabulut H, Ersoy H. Dynamic Behaviors of a Two-Cylinder Four-Stroke Internal Combustion Engine. Gazi University Journal of Science. 2012;25(2):519-32.