Research Journal of Recent Sciences _________________________________________________ ISSN 2277-2502 Vol. 1(2), 92-96, Feb. (2012) Res.J.Recent Sci. International Science Congress Association 92 A Finite Element Approach for Analysis of a Multi Leaf Spring using CAE Tools Kumar Krishan and Aggarwal M.L. Department of Mechanical Engineering, YMCA University of Science and Technology, Faridabad, HR, INDIAAvailable online at: www.isca.in (Received 24th January 2012, revised 27th January 2012, accepted 30th January 2012)Abstract This work is carried out on a multi leaf spring having nine leaves used by a commercial vehicle. The finite element modelling and analysis of a multi leaf spring has been carried out. It includes two full length leaves in which one is with eyed ends and seven graduated length leaves. The material of the leaf spring is SUP9.The FE model of the leaf spring has been generated in CATIA V5 R17 and imported in ANSYS-11 for finite element analysis, which are most popular CAE tools. The FE analysis of the leaf spring has been performed by discretization of the model in infinite nodes and elements and refining them under defined boundary condition. Bending stress and deflection are the target results. A comparison of both i.e. experimental and FEA results have been done to conclude. Keywords: Leaf spring, finite element analysis, FEM, CAE tools. Introduction Multi leaf springs used in automotive vehicles normally consists of full length leaves and graduated length leaves. The specimen under this research work consists of nine leaves, two eye pins, centre bolt with nut etc. CAE tools are being used to analyze the robustness and performance of components and assemblies. The finite element analysis (FEA) is a computing technique that is used to obtain approximate solutions to the boundary value problems in engineering. It uses a numerical technique called the finite element method (FEM). Using FEA Multi leaf spring is modeled using the discrete building blocks called elements. Each element has some equations that describe how it responds to certain loads. The sum of the response of all the elements in the model gives the total response of the design. CAE depends upon actual assumptions of the assembly which acts as input data. CAE has become an important technology with benefits such as lower costs and a shortened design cycle. Studies say that any design professional can save approximate 30% of time and cost by using CAE tools. In future CAE system will be major information provider to help design professionals in decision making. I. Rajendran, S. Vijayaranganpresented a formulation and solution technique using genetic algorithms for design optimizationof composite leaf springs. F.N. Ahmad Refngah presents about fatigue life prediction based on finite element analysis and variable amplitude loading (VAL). The finite element method (FEM) was performed on the spring model to observe the distribution stress and damage. The experimental works has been done in order to validate the FEM result. Mouleeswaran Senthil Kumardescribesstatic and fatigue analysis of steel leaf spring and composite multi leaf spring made up of glass fibre reinforced polymer using life data analysis. Static analysis of 2-D model of conventional leaf spring is also performed using ANSYS 7.1 and compared with experimental results. Same dimensions of conventional leaf spring are used to fabricate a composite multi leaf spring using E-glass/Epoxy unidirectional laminates. Gulur Siddaramanna SHIVA SHANKARpresented a low cost fabrication of complete mono composite leaf spring and mono composite leaf spring with bonded end joints. The finite element results using ANSYS software showing stresses and deflections were verified with analytical and experimental results. The design constraints were stresses (Tsai-Wu failure criterion) and displacement. M. M. Patunkar presented modeling and analysis of composite mono leaf spring (GFRP) and compare its results. Modelling is done using Pro-E (Wild Fire) 5.0 and Analysis is carried out by using ANSYS 10.0 software for better understanding. J.P. Hou presents the design evolution process of a composite leaf spring for freight rail applications. Three designs of eye-end attachment for composite leaf springs are described. Static testing and finite element analysis have been carried out to obtain the characteristics of the spring. Load–deflection curves and strain measurement as a function of load for the three designs tested have been plotted for comparison with FEA predicted values. M.L. Aggarwal calculated fatigue strength of shot peened leaf springs from laboratory samples. The axial fatigue strength of EN45A spring steel specimen is evaluated experimentally as a function of shot peening in the conditions used for full-scale leaf springs testing in industries. Andrea Corvi demonstrated the feasibility of using the program as a tool in establishing the initial design considerations and in developing preliminary designs. W.J. Yu investigatedfundamental properties of dimensioning of double tapered FRP leaf Research Journal of Recent Sciences ______ _ Vol. 1(2), 92-96, Feb. (2012) International Science Congress Association Spring made from glass fibre and epoxy to replace four leaf steel springs . GRP leaf springs showed a superior and fail-safe characteristics. M.L. Aggarwal improvement in fatigue and fretting fatigue performance of leaf springs used in automotive vehicles. Th e fatigue strength of 65Si7 spring steel has been evaluated experimentally as a function of shot peening parameters for application in automotive vehicles10 . The main objective of this work is to perform finite element analysis of multi leaf spring. ex perimental results have been taken on a full scale static load testing machine, in which leaf spring is held under an axial load at centre till maximum deflection. These experimental results will be compared with FEA results for validation. Material and Methods Material properties and Design parameters below is showing the different parameters related to material properties; Table-1 Material Properties Parameter Value Material selected- steel 65Si7/SUP9 Young’s Modulus, E 2.1* 10 5 N/mm Poisson’s Ratio 0.266 BHN 400-425 Tensile strength Ultimate 1272 MPa Tensile strength Yield 1158 MPa Spring stiffness 221.5 N/mm Mass 54.165 kg Normal Static loading 35000 N Density 0.00000785 Kg/mm Behavior Isotropic Design parameters of the multi leaf spring used in this work are: Total span length (eye to eye): 1450mm Number of full length leaves: 02 Length of full length leaves (L-1 and L-2): 1450 mm each Width of all leaves: 70mm Thickness of all leaves: 12mm Number of graduated length leaves: 07 Length of graduated length leaves; (L-3, L-4, L-5, L-6, L-7, L-8 and L- 9): 1320mm, 1140mm, 940mm, 800mm, 640mm, 464mm & 244mm respectively. Multi Leaf Spring Geometery and Boundary Conditions The two dimensional drawing of the multi leaf spring is shown in the figure-1 below; _ ________________________________ ______________ International Science Congress Association fibre and epoxy to replace four leaf . GRP leaf springs showed a superior endurance M.L. Aggarwal described improvement in fatigue and fretting fatigue performance of e fatigue strength of 65Si7 spring steel has been evaluated experimentally as a function of shot peening parameters for application in . The main objective of this work is to perform finite element analysis of multi leaf spring. The perimental results have been taken on a full scale static load testing machine, in which leaf spring is held under an axial load at centre till maximum deflection. These experimental results will be compared with FEA results for Design parameters : The table-1 below is showing the different parameters related to material 65Si7/SUP9 N/mm 2 MPa MPa 221.5 N/mm 54.165 kg 0.00000785 Kg/mm 3 Design parameters of the multi leaf spring used in this work 1450mm 1450 mm each 70mm 12mm 9): 1320mm, 1140mm, 940mm, 800mm, 640mm, 464mm & 244mm Boundary Conditions : The two dimensional drawing of the multi leaf spring is Figure Drawing of Multi Leaf Spring The multi leaf spring is modelled maximum deflection i.e. flat position reverse direction to attain its original shape i.e. semi elliptical. The boundary condition is the collection of different forces, pressure, velocity, supports, constraints an required for complete analysis. As per specifications the spring is drawn at flat condition, therefore the load is applied in downward direction to achieve initial no load condition. As no load camber is 153°, a joint rotation of 27° is c onsidered for both revolute joints, during static analysis. The boundary conditions for the experimental results are shown in the figure-2 below; Figure Experimental Boundary Conditions Modeling & Finite Element Analysis CAD modeling so ftware is dedicated for the specialized job of 3D- modeling. The model of the multi leaf spring structures also includes many complicated parts, which are difficult to make by any of other CAD modeling as well as Finite Element software. CAD modeling of the Multi Leaf Spring structure is performed by using CATIA V5 R17 software. CATIA is having special tools in ______________ _______ ISSN 2277-2502 Res. J. Recent Sci. 93 Figure -1 Drawing of Multi Leaf Spring The multi leaf spring is modelled in position having maximum deflection i.e. flat position 11 & will be loaded in reverse direction to attain its original shape i.e. semi - The boundary condition is the collection of different forces, pressure, velocity, supports, constraints an d every condition required for complete analysis. As per specifications the spring is drawn at flat condition, therefore the load is applied in downward direction to achieve initial no load condition. As no load camber is 153°, a joint rotation of 27° is onsidered for both revolute joints, during static analysis. The boundary conditions for the experimental results are Figure -2 Experimental Boundary Conditions Modeling & Finite Element Analysis : CAD Modeling: ftware is dedicated for the specialized job modeling. The model of the multi leaf spring structures also includes many complicated parts, which are difficult to make by any of other CAD modeling as well as Finite Element software. CAD modeling of the complete Multi Leaf Spring structure is performed by using CATIA V5 R17 software. CATIA is having special tools in Research Journal of Recent Sciences ____________________________________________________________ ISSN 2277-2502Vol. 1(2), 92-96, Feb. (2012) Res. J. Recent Sci. International Science Congress Association 94 generating surface design to construct typical surfaces, which are later converted into solid models. Solid model of all parts of the structures are then assembled to make a complete structure. The process of assembly is very much analogous to general process of fabricating structures while real production. The CAD model of multi leaf spring used for FE Analysis during assembly is shown in figure-3 and figure-4. The assembled CAD model has been prepared from various part modeling drawings. Figure-3 Assembly Design in CATIAFigure-4 Assembly Design in CATIA Finite Element Analysis: A stress-deflection analysis is performed using finite element analysis (FEA). The complete procedure of analysis has been done using ANSYS-11. To conduct finite element analysis, the general process of FEA is divided into three main phases, preprocessor, solution, and postprocessor. Preprocessor: The preprocessor is a program that processes the input data to produce the output that is used as input to the subsequent phase (solution). Following are the input data that needs to be given to the preprocessor: i. Type of analysis ii. Element type iii. Real constants iv. Material properties v. Geometric model vi. Meshed model vii. Loading and boundary conditions. Solution: Solution phase is completely automatic. The FEA software generates the element matrices, computes nodal values and derivatives, and stores the result data in files. These files are further used by the subsequent phase (postprocessor) to review and analyze the results through the graphic display and tabular listings. Postprocessor: The output from the solution phase is in the numerical form and consists of nodal values of the field variable and its derivatives. For example, in structural analysis, the output is nodal displacement and stress in the elements. The postprocessor processes the result data and displays them in graphical form to check or analyze the result. The graphical output gives the detailed information about the required result data. The multi leaf spring with all boundary conditions and material properties is imported in ANSYS-11, showing in figure-5, figure-6, figure-7 and figure-8. The material used for the leaf spring for analysis is structural steel, which has approximately similar isotropic behavior and properties as compared to SUP9. Figure-5 Multi Leaf Spring Assembly Figure-6 Eye end with pin Research Journal of Recent Sciences ____________________________________________________________ ISSN 2277-2502Vol. 1(2), 92-96, Feb. (2012) Res. J. Recent Sci. International Science Congress Association 95 Figure-7 Meshing of Assembly Figure-8 Boundary Conditions in ANSYS-11Result and Discussions As the finite element analysis of multi leaf spring is performed using ANSYS-11 detailed above, in which all conditions are considered which were also considered for results taken by experimental testing. The multi leaf spring showing deflections under full & half rated loads are shown in figure-9 and figure-10, as well as in tabular form taken from ANSYS-11. Figure-9 Deformation at Full Load Figure-10 Deformation at Half Load Result Comparison & Discussions: Table-2 Result Comparison at Full Load Parameters Experiment Results FEA Results Variation Normal Static Load 35000 N35000 NNil Deflection158 mm157 mm0.632 % Spring Rate 221.5 N/mm 222.92 N/mm 0.641 % Bending Stress 101.8 Kgf/mm113.25 Kgf/mm10.11 % As shown in the above table-2 deflection and the bending stress are compared for experimental and FEA results. The experimental deflection value is 158 mm and the FEA value is 157 mm i.e. a negligible difference is detected. On the other hand the bending stress is increased from 101.8 Kgf/mm to 113.25 Kgf/mm i.e. again a negligible difference is detected. Table-3 Result Comparison at Half LoadParametersExperimental Results FEA Results Variation Normal Static Load 17500 N 17500 N Nil Deflection 79 mm 78.5 mm 0.632 % Spring Rate 221.5 N/mm 222.92N/mm 0.641 % Bending Stress 48 Kgf/mm 2 56.62 Kgf/mm17.95 % As shown in the above table-3 the deflection and the bending stress with half rated load are compared for experimental and FEA results. The experimental deflection value is 79 mm and the FEA value is 78.5 mm i.e. a negligible difference in Experimental and FEA value. On the other hand the bending stress is increased from 48 Kgf/mm to 56.62 Kgf/mm i.e. the experimental value is lower than the FEA value but not far away . Research Journal of Recent Sciences ______ _ Vol. 1(2), 92-96, Feb. (2012) International Science Congress Association The load vs deflection curve is also plotted here for FEA results. Figure-11 Load- Deflection curve for FEA Results Conclusion Design and stress- deflection analysis of a multi leaf spring is carried out by finite element approach using CAE tools (i.e CATIA, ANSYS). When the leaf spring is fully loaded, a variation of 0.632 % in def lection is observed between the experimental and FEA result, and same in case of half load, which validates the model and analysis. On the other hand, bending stress in both the cases is also close to the experimental results. The maximum value of equivalent stresses is below the Yield Stress of the material that the design is safe from failure.References 1. Rajendran I. and Vijayarangan S., Design and Analysi s of a Composite Leaf Spring, Institute of Engineers, India, 82,180– 187 2. Ahmad Refngah F.N., Abdullah S., Jalar A. and Chua L.B., Life Assessment of a Parabolic Spring Under Cyclic Strain Loading, European Journal of Scientific Research, 28(3), 351-363 (2009)3. Mouleeswaran Senthil Kumar and Vijayarangan Sabapathy, Analytical and Experimental Studies on Fatigue Life Prediction of Steel and Composite Multi leaf Spring for Light Passenger Vehicles Using Life _ ________________________________ ______________ International Science Congress Association The load vs deflection curve is also plotted here for FEA Deflection curve for FEA Results deflection analysis of a multi leaf spring is carried out by finite element approach using CAE tools (i.e CATIA, ANSYS). When the leaf spring is fully loaded, a lection is observed between the FEA result, and same in case of half load, which validates the model and analysis. On the other hand, bending stress in both the cases is also close to the experimental results. The maximum value of equivalent of the material indicating Rajendran I. and Vijayarangan S., Design and s of a Composite Leaf Spring, Journal of 187 (2002) Abdullah S., Jalar A. and Chua L.B., Life Assessment of a Parabolic Spring Under European Journal of Scientific Mouleeswaran Senthil Kumar and Vijayarangan Sabapathy, Analytical and Experimental Studies on Fatigue Life Prediction of Steel and Composite Multi - leaf Spring for Light Passenger Vehicles Using Life Data Analysis, ISSN 1 392 13(2), 141-146 (2007)4. Shiva Shankar Gulur Siddaramann and Vijayarangan Sambagam, Mono Composite Leaf Spring for Light Weight Vehicle– Design, End Joint Analysis and Testing, ISSN 1392– 1320 220-225( 2007)5. Patunkar M.M. and Dolas D.R., Modelling and Analysis of Composite Leaf Spring under the Static Load Condition by using FEA, of Mechanical and Industrial Engineering, (2011) 6. 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