Study on the coolant pressure of internal combustion engines through vibro-acoustical analysis of a real cylinder block structure

Wang, Xiaoyu; Zhang, Zheng; Chen, Yu; Li, Yinglong

doi:10.1007/s40430-020-2204-y

Cited by 2 publications

(2 citation statements)

References 18 publications

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“…Alshwawra et al [3] quantitatively ensured whether the coolant flow rate met the needs of the power drive unit. Wang et al [4] proposed the "motor and motor driver integration system" concept. The purpose is to improve the cooling effect of the motor and driver cooling system.…”

Section: Introductionmentioning

confidence: 99%

Simulation Analysis of New Energy Vehicle Engine Cooling System Based on K-E Turbulent Flow Mathematical Model

Mu,

Wang,

Yang

et al. 2023

Energy Engineering

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New energy vehicles have better clean and environmental protection characteristics than traditional fuel vehicles. The new energy engine cooling technology is critical in the design of new energy vehicles. This paper used oneand three-way joint simulation methods to simulate the refrigeration system of new energy vehicles. Firstly, a k-ε turbulent flow model for the cooling pump flow field is established based on the principle of computational fluid dynamics. Then, the CFD commercial fluid analysis software FLUENT is used to simulate the flow field of the cooling pump under different inlet flow conditions. This paper proposes an optimization scheme for new energy vehicle engines' "boiling" phenomenon under high temperatures and long-time climbing conditions. The simulation results show that changing the radiator's structure and adjusting the thermostat's parameters can solve the problem of a "boiling pot." The optimized new energy vehicle engine can maintain a better operating temperature range. The algorithm model can reference each cryogenic system component hardware selection and control strategy in the new energy vehicle's engine.

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Section: Introductionmentioning

confidence: 99%

Simulation Analysis of New Energy Vehicle Engine Cooling System Based on K-E Turbulent Flow Mathematical Model

Mu,

Wang,

Yang

et al. 2023

Energy Engineering

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“…The severity of liner deformation, wear, and cavitation determines the durability life of the cylinder liner. By using a numerical method, Wang et al [8] predicted the pressure fluctuation of the coolant in an internal combustion engine so that the potential locations of cavitation could be identified. Suzuki and Yaguchi [9] found that piston ring conformability was affected by a deformed bore, which generated a gap between the piston ring and the liner, resulting in gas leakage from the combustion chamber and engine performance degradation.…”

Section: Introductionmentioning

confidence: 99%

Analysis of out-of-round deformation of a dry cylinder liner of a non-road high-pressure common-rail diesel engine based on multi-field coupling

Wang

Luo

et al. 2021

J Braz. Soc. Mech. Sci. Eng.

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The deformation of cylinder liner directly affects the sealing performance of the friction components in internal combustion engines, resulting in high oil consumption, engine power loss, and high-particulate matter emissions. Previous research works focused more on deformation of the wet vehicular cylinder liners, however, the effects of different loads on the dry liner deformation is not clear yet. A non-road high-pressure common-rail diesel engine was selected as the research object, and a coupled model of the engine was developed based on fluid-solid coupled heat transfer theory. After the accuracy of the model was verified by temperature measurement of the cylinder head and cylinder liner, deformation of the dry cylinder liner was studied. The results show that the axial and radial deformations of the cylinder liner are not uniform under the bolt preload condition. Large deformation occurs at the first liner and fourth liner, with the maximum deformation occurring at the top of fourth liner for 10.14 μm. Under the condition of thermal load, the temperature of cylinder liner exhibits a distribution of three-segments from the top to bottom. The liner deformation is not uniform, and the maximum deformation occurs at the top of the fourth liner for 304 μm. The radial deformations of all four cylinder liners present a symmetrical structure of a "heart" shape with respect to the centerline of the second and third cylinders. The axial deformation of each liner exhibits a "barrel" shape which is convex in the middle and narrow at the two ends.

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Study on the coolant pressure of internal combustion engines through vibro-acoustical analysis of a real cylinder block structure

Cited by 2 publications

References 18 publications

Simulation Analysis of New Energy Vehicle Engine Cooling System Based on K-E Turbulent Flow Mathematical Model

Simulation Analysis of New Energy Vehicle Engine Cooling System Based on K-E Turbulent Flow Mathematical Model

Analysis of out-of-round deformation of a dry cylinder liner of a non-road high-pressure common-rail diesel engine based on multi-field coupling

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