Enhancing the Durability of Connecting Rod of a Heavy-Duty Diesel Engine

Islam Ismail,Ahmed Emara,Elsayed Abdelrazek,Mostafa Ismail

doi:10.15282/ijame.18.2.2021.10.0666

Islam Ismail, Ahmed Emara + Show 2 more

Open Access

https://doi.org/10.15282/ijame.18.2.2021.10.0666

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Abstract

This paper investigates the mechanical loads resulting from the combustion pressure and dynamic inertia and their effects on the connecting rod of a direct injection turbocharged diesel engine. The main purpose is to enhance the durability of the connecting rod in order to withstand more engine power increase. The distribution of the axial (compressive/tensile) stress, deformation, and safety factors are calculated in order to predict any possible mechanical failure. The finite element routine is used by ANSYS Workbench to analyse the loading on the connecting rod model. The current study is applied to the connecting rod of a 300 hp diesel engine in order to increase the engine power by 17%. The connecting rod operates safely and withstands the applied loads until the power increase reaches 72%. The most stressed points are at the connecting rod shank, while less stressed are experienced at the big end. Calculations show that introducing some changes to the connecting rod geometry may result in decreasing the excessive stresses. These changes include increasing the thickness of the shank cross-section, increasing the fillets radii and slightly reducing the dimensions of the big end in order to maintain the same mass. The new geometry could significantly reduce the maximum stress by 25.5% with an insignificant reduction in the total mass of the connecting rod.

Highlights

The connecting rod of a diesel engine is subjected to high cyclic loads, changing from the extreme compression to the highest tension, all at high frequencies
The results showed that the bending load has a great effect on the connecting rod strength, in addition to the effects of typical axial compression and tension loads
The results showed that the contact pressures between the connecting rod big end, roller bearing, and crankpin are excessively high

Summary

INTRODUCTION

The connecting rod of a diesel engine is subjected to high cyclic loads, changing from the extreme compression (due to the maximum pressure of the combustion gases) to the highest tension (due to the inertia of the reciprocating masses), all at high frequencies. Alam et al [12] presented a detailed investigation for a connecting rod failure during a fatigue test They studied the different factors of failure such as the structural design, material strength, and machining processes by using finite element analysis, visual observation, dimensional inspection, metallurgical, fractography analysis, hardness testing, and residual stresses analysis. The base design of the connecting rod was analysed under fatigue loading using ANSYS software to evaluate the critical regions This analysis revealed that the maximum stress occurred at the shank near the piston pin end. These results were used to modify the connecting rod design, which led to reduce the weight, inertia force and cost of the material. Parameters Type No of cylinders Aspiration type Bore x Stroke (mm) Displacement (cm3) Crank shaft radius (mm) Connecting rod length (mm) Compression ratio Pressure ratio (boost) Rated power (hp) Max. torque (N.m)

Inline turbocharged

RESULTS AND DISCUSSION

CONCLUSION