International Research Journal of Engineering and Technology (IRJET)
e-ISSN: 2395-0056
Volume: 05 Issue: 03 | Mar-2018
p-ISSN: 2395-0072
www.irjet.net
To Design a New Cross Section for Connecting Rod with a Target of 10% Weight Reduction Priyanka Inderchandji Mutha1 1Student,
Dept. of Mechanical Engineering, Govt. College of Engineering, Aurangabad ---------------------------------------------------------------------***---------------------------------------------------------------------
Abstract - The connecting rod is an intermediate member
between the piston and the Crankshaft. Its function is to transmit the push and pull forces from the piston pin to the crank pin, converting the reciprocating motion of the piston into rotary motion of the crank. Traditionally, I cross-section has been used to design the connecting rod. This paper describes design and analysis of alternate cross sections evaluated to achieve weight reduction for cost benefits. Alternate designs were modelled in Creo2.0 and were analyzed using ANSYS 18.2. Through concept selection study, the C section was selected and further was further optimized for a minimum weight considering FOS of 2 using Response Surface Methodology (RSM) in Minitab 17.
Designed concepts were compared using a decision matrix to select the one best concept. The selected C cross-section design was further optimized for weight reduction using Response Surface Methodology. An overall 14% weight reduction is achieved in C cross-section design as compared to the original I section design. 1.1 THEORETICAL CALCULATION OF FORCES ACTING ON CONNECTING ROD Bajaj Pulsar 220 CC Engine connecting rod was considered for the study purpose. A reversed engineered model of connecting rod was created using CREO 2.0. a. Pressure calculation:
Key Words: Connecting rod, Static Analysis, I section, C section, Fatigue Analysis, CREO 2.0R, ANSYS 18.2R, MINITAB 17R and Finite Element Analysis, Response Surface Methodology (RSM).
1. INTRODUCTION In a reciprocating piston engine, the connecting rod connects the piston to the crank or crankshaft. The major stresses induced in the connecting rod are combination of axial and bending stresses in operation. The axial stresses are produced due to cylinder gas pressure (compressive only) and the inertia force arising in account of reciprocating action (both tensile and compressive), whereas bending stresses are caused due to the centrifugal effects. The connecting rods are made traditionally with I cross section. This is due to the rigidity provided by the I-section which proves to be good in taking bending moment and provide effective fatigue life. But a trade-off can been seen between the stress carrying capacity v/s weight of connecting rod due to the use of I-Section. Different cross section like H Section, Circular Section, Hollow circular section etc. are presently been used in Industry as an alternative to the I section, where weight of component is critical factor for design. The objective of this study is to design and optimize a new cross section of connecting rod for its weight. To achieve this three cross sections, T Section, C section and hollow C section were designed. Bending stresses and fatigue life were calculated using theoretical calculations. The equivalent stress and principal stresses were evaluated using ANSYS. Š 2018, IRJET
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Impact Factor value: 6.171
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Below engine specifications were considered: Engine type air cooled 4-stroke Bore Ă— Stroke (mm) = 67 x 62.4 Displacement = 220 CC Maximum Power = 21.05 @ 8500 (Ps @ RPM) Maximum Torque = 19.12 @ 7000 (Nm @ RPM) Compression Ratio = 9.5/1 Density of petrol at 288.855 K = 737.22*10-9 kg/mm3 Molecular weight M = 114.228 g/mole Ideal gas constant R = 8.3143 J/mol.k From gas equation, PV=m*R specific*T Where, P = Pressure V = Volume m = Mass R specific = Specific gas constant T = Temperature But, Mass of air = Density * Volume Density for Grey Cast Iron = 737.22 E-9 kg/mm3 m =737.22E-9*220E3 m = 0.16 kg R specific = R/M R specific = 8.3143/0.114228 R specific = 72.79 P = m* R specific* T/V P = 0.16*72.79*288.85/200E3 P = 15.5 MPa P ~ 16 MPA.
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