PARAMETRIC DESIGN ANALYSIS AND FEA SIMULATION OF A CHISEL PLOW FOR AN AGRICULTURE USE
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The document presents a parametric design analysis and finite element analysis simulation of a chisel plow used in agriculture, comparing an old model and a new generation model. Through the use of CAD and FEA software, various parameters such as stress, strain, deformation, and fatigue were analyzed, showing that the new generation model demonstrates significant improvements in performance metrics over the old model. The results highlight the potential for design optimization in agricultural tools to enhance efficiency and reduce failure rates under operational conditions.
![International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015
DOI : 10.14810/ijmech.2015.4404 45
PARAMETRIC DESIGN ANALYSIS AND FEA
SIMULATION OF A CHISEL PLOW FOR AN
AGRICULTURE USE
Pawan Sharma1
and Prof. (Dr.) Manish Bhargava2
1,2
Department of Mechanical Engineering
1,2
Maharishi Arvind Institute of Engineering and Technology, Jaipur, India
ABSTRACT
CAD Software for the structural analysis is basically used for the application of CAD/CAM in design
optimization of tillage tools, which is based on the simulation method and Finite Element Method. The
various components of the tillage tools are simulated with help of actual field performance rating
parameters which are prepared by solid models along with actual boundary conditions. The planned work
outcomes of sufficient tolerance in varying the working parameters of Chisel Plow sections for ejecting the
extra weight in a solid section and also to increase the weight of plow for a consistent potency.
In this paper parametric study of two different kinds of Chisel Plow for an agriculture use in designing
from stress, strain, deformation and fatigue analysis has done. One is Old Chisel Plow & another is New
Generation Chisel Plow. The old working model of Chisel Plow is compared with new design parameters
with change of its geometry for the maximum weed exclusion efficiency by showing its realistic results from
the actual field performance.
KEYWORDS
Stress, Strain, Deformation, Fatigue, Modeling, Analysis & Shape Optimization.
1. INTRODUCTION
The development of field is very costliest process in farming. It includes forest cleaning, soil
aperture using bottomless tillage tools, movements of soil from high to low places, farm road
construction, land leveling etc. These all operations can be performed by using self propelled and
heavy equipments such as crawler tractors, high horsepower tractors, scrapers, ditchers, chisel
ploughs, levelers etc. To gain the required seedbed to provide optimal atmosphere for start
germination and plant development, mechanical exploitation of soil is required, known as tillage
operations and for minimize the design optimization and manufacturing errors of the components,
design analysis and optimization is necessary.
Particularly blades and spread parts must be consistent in field the concert against to working
conditions. Forecasting of Stress Analysis must be required for manufacturers, designers and
researchers. The optimization in design of a chisel plow can be obtained by decreasing its weight,
cost and by improving the weed exclusion rate. In industries, CAD software’s are used for the
designing the desired model and FEA software’s are used for the solid analysis of the model.
Thus after the analysis of stress, strain, safety factor, displacement, fatigue etc. on FEA software,
the simulation results shown in terms of safe results or in terms of breakdown and failure due to
high stresses and deformation.
The planned work shows an experimental way for model testing and validation of agriculture
tools and equipments. The selected model of a chisel plow is measured with actual dimensions
and its solid model is prepared on Autodesk Inventor 2014 and the simulation is done on ANSYS
v14.5. [1]](https://image.slidesharecdn.com/4415ijmech04-151211052507/85/PARAMETRIC-DESIGN-ANALYSIS-AND-FEA-SIMULATION-OF-A-CHISEL-PLOW-FOR-AN-AGRICULTURE-USE-1-320.jpg)
![International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015
47
2.1 Soil Parameters
The properties of the soil related to the desired chisel plow were recognized as types of soil,
wetness, mass concentration and cone index. The measurement and categorization methodologies
are discussed in the subsequent section. Black type of soil is used in this research work for the
chisel plow analysis. The humidity substance of soil performs a significant task for the
development of the crops therefore subsequent Soil resistance and humidity substance of soil are
taken as per the table 2. [6]
3. MODELING AND DESIGNING METHODS
The modeling and designing methods include the number of various parameters, methods and
steps for model construction. The input boundary conditions will be required for the pre
processing stage of the desired chisel plow.
3.1 Finite Element Method for Chisel Plow
The useful features of finite element methods are as follows [7]
:
• Discretization of the whole model into small elements, which may be square, rectangle,
and triangle or in polygon shapes.
• Derive the governing differential equations for each element of the model.
• Assembly of all elements, based on stability of the solution.
3.2 Mesh Generation
The conversion of whole model into number of small elements is known as Mesh generation. The
meshing is a very important step for the accurate solution. Various kinds of meshing are used in
the pre-processing. We are using the mesh generation with a good number of relevance with fine
mesh. For the Chisel Plow elements are used for meshing.
The elements may be rectangular or triangular. We are using triangular mesh for a high accuracy.
The number of elements represents the solution accuracy of the model. The elements can be
increased by increasing the relevance number. So that the run time is less and also the accuracy is
not much affected.
The mesh view of both the Chisel Plows is given below:
Figure 1. Mesh Pictures of the Old Model of Chisel Plow](https://image.slidesharecdn.com/4415ijmech04-151211052507/85/PARAMETRIC-DESIGN-ANALYSIS-AND-FEA-SIMULATION-OF-A-CHISEL-PLOW-FOR-AN-AGRICULTURE-USE-3-320.jpg)
![International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015
57
Table 8. Fatigue Results on Chisel Plows
Fatigue Results
Old Model of Chisel Plow
New Generation Model of Chisel
Plow
Failure Occurs
at
35,426 Cycles 4,22,440 Cycles
Thus, the Fatigue result shows that at the same magnitude of force, the Failure Occurs in Old
Model of Chisel Plow is at 35,426 Cycles and in New Generation Model of Chisel Plow is at
4,22,440 Cycles.
Thus, the Old Model of Chisel Plow gets failure then New Generation Model of Chisel Plow at
the same magnitude of force & fixed support.
Thus, the Parametric Results on the basis of Stress, Strain, Deformation and Fatigue Results, the
New Generation Model of Chisel Plow is much Safe than the Old Model of Chisel Plow. The
design of New Generation Model of Chisel Plow is much safe design for an agriculture use. Also
the life of New Generation Model of Chisel Plow is greater than Old Model of Chisel Plow.
CONCLUSION
A tillage tool such as Chisel Plow is designed in computer aided design software. The motion of
Chisel Plow and soil surface interaction is considered. The tillage operations introduces a quality
parameters and development scope in obtaining a width of cut , depth of cut, Speed of operation,
field efficiency, field capacity, theoretical draft the rate of work, quality of work, draft
measurement etc. The analysis of stress, strain, deformation and life cycle shows the safe designs
at the same range of input parameters between old model of Chisel Plow and New Generation
Model of Chisel Plow.
REFERENCES
[1] Quirke, S. Scheffler, O. Allen, (1988), “An evaluation of the wear behavior of metallic materials
subjected to soil abrasion” Soil and Till. Res. 11
[2] Gill, W.R., and G.E. Vanden Berg, (1996), “Design of tillage tool in soil dynamics in tillage and
traction”, 211-294, Washington, D.C.,U.S.GPO
[3] Godwin, R.J. (1982), “Force measurement on tillage implements” 9th Conference of the International
soil Tillage Research organization, Osijek
[4] Jain, S.C., and Philip (2003), “Farm machinery an approach, standard publishers distributors Delhi pp.
5-7, 21, 27
[5] Kosutic, S., D Filipovic, and Z Gospodaric. (1996), “Rotary Cultivator Energy Requirement
Influenced by Different Constructional Characteristics”, Velocity and Depth of Tillage.
Poljoprivredna-Znanstvena-Somatra, vol 61,Pg3-4, 1996, p 239
[6] Krutz, G., L. Thompson and C. Poul (1984), “Design of Agricultural machine”, John Willey and
Sons, New Delhi. pp.32-36
[7] Ben Yahia, Logue, and M. Khelifi. (1999), “Optimum settings for rotary tools used for on-the-row
mechanical cultivation in corn”, Transactions of ASAE, 15(6): 615-619
[8] Biswas, H.S. (1993)., “Performance Evaluation and optimization of straight blades for shallow tillage
and weeding in black soils”, Agric. Mech. in Asia, Africa and Latin America, 24(4) 19-22
[9] Block, J.M. (1986), “Performance of power tiller blades”, Agric. Mech. In Asia, Africa and Latin
America, 17 (1): 22-26
[10] Spoor. G., “Design of soil engaging implements”, practice, Farm Machine design Eng J:14-
19,Dec,1969](https://image.slidesharecdn.com/4415ijmech04-151211052507/85/PARAMETRIC-DESIGN-ANALYSIS-AND-FEA-SIMULATION-OF-A-CHISEL-PLOW-FOR-AN-AGRICULTURE-USE-13-320.jpg)
![International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015
58
[11] Thakur T.C., (1991), “Design aspects of soil engaging hand tools”, Agricultural Engineering
Today.21:15-18
[12] Zhang, J., and R.L.K Khuswala, (1996), “Wear and draft of cultivator sweep with hardened edges”,
Canadian Agricultural Engineering, 37(1); 41-47
AUTHORS:
Pawan Sharma has completed his B.Tech in Mechanical Engineering, M.Tech in
Machine Design from RTU (Kota), Rajasthan, INDIA. He has published more than 25
research papers in the refereed International journals and conferences. He has
published three Engineering Books in the field of FEA/FEM. His area of research
includes CAD/CAM, FEA/FEM, Composite Materials, CFD and Vibration Analysis.
Prof. (Dr.) Manish Bhargava holds M.Tech. in Manufacturing System Engineering,
Ph.D. in Mechanical Engineering from MNIT, Jaipur. He has published more than 30
research papers in the refereed International journals and conferences. He has a
teaching and research experience of more than 14 years. Currently, He is working as a
Professor in Mechanical Engineering & Principal with Maharishi Arvind Institute of
Engineering and Technology, Jaipur, Rajasthan, India. His area of research includes
CIMS, CAD/CAM, Reliability & Maintenance, Manufacturing Systems and Material
Science.](https://image.slidesharecdn.com/4415ijmech04-151211052507/85/PARAMETRIC-DESIGN-ANALYSIS-AND-FEA-SIMULATION-OF-A-CHISEL-PLOW-FOR-AN-AGRICULTURE-USE-14-320.jpg)
PARAMETRIC DESIGN ANALYSIS AND FEA SIMULATION OF A CHISEL PLOW FOR AN AGRICULTURE USE
- 1. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 DOI : 10.14810/ijmech.2015.4404 45 PARAMETRIC DESIGN ANALYSIS AND FEA SIMULATION OF A CHISEL PLOW FOR AN AGRICULTURE USE Pawan Sharma1 and Prof. (Dr.) Manish Bhargava2 1,2 Department of Mechanical Engineering 1,2 Maharishi Arvind Institute of Engineering and Technology, Jaipur, India ABSTRACT CAD Software for the structural analysis is basically used for the application of CAD/CAM in design optimization of tillage tools, which is based on the simulation method and Finite Element Method. The various components of the tillage tools are simulated with help of actual field performance rating parameters which are prepared by solid models along with actual boundary conditions. The planned work outcomes of sufficient tolerance in varying the working parameters of Chisel Plow sections for ejecting the extra weight in a solid section and also to increase the weight of plow for a consistent potency. In this paper parametric study of two different kinds of Chisel Plow for an agriculture use in designing from stress, strain, deformation and fatigue analysis has done. One is Old Chisel Plow & another is New Generation Chisel Plow. The old working model of Chisel Plow is compared with new design parameters with change of its geometry for the maximum weed exclusion efficiency by showing its realistic results from the actual field performance. KEYWORDS Stress, Strain, Deformation, Fatigue, Modeling, Analysis & Shape Optimization. 1. INTRODUCTION The development of field is very costliest process in farming. It includes forest cleaning, soil aperture using bottomless tillage tools, movements of soil from high to low places, farm road construction, land leveling etc. These all operations can be performed by using self propelled and heavy equipments such as crawler tractors, high horsepower tractors, scrapers, ditchers, chisel ploughs, levelers etc. To gain the required seedbed to provide optimal atmosphere for start germination and plant development, mechanical exploitation of soil is required, known as tillage operations and for minimize the design optimization and manufacturing errors of the components, design analysis and optimization is necessary. Particularly blades and spread parts must be consistent in field the concert against to working conditions. Forecasting of Stress Analysis must be required for manufacturers, designers and researchers. The optimization in design of a chisel plow can be obtained by decreasing its weight, cost and by improving the weed exclusion rate. In industries, CAD software’s are used for the designing the desired model and FEA software’s are used for the solid analysis of the model. Thus after the analysis of stress, strain, safety factor, displacement, fatigue etc. on FEA software, the simulation results shown in terms of safe results or in terms of breakdown and failure due to high stresses and deformation. The planned work shows an experimental way for model testing and validation of agriculture tools and equipments. The selected model of a chisel plow is measured with actual dimensions and its solid model is prepared on Autodesk Inventor 2014 and the simulation is done on ANSYS v14.5. [1]
- 2. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 46 1.1 Types of Chisel Plows • Animal Drawn Mouldboard • Melur • Improved Iron • Animal Drawn Bose • Khargaon • Dabra • Rau • Chisel • MP Iron Wedge • Birsa Animal Drawn Ridger • Kapas Ridger • Bullock Drawn Ridger • Bullock Drawn Disc Harrow • Disc Harrow • Blade Harrow • Bullock Drawn Puddler • Animal Drawn Puddler • Animal Drawn Helical Blade Puddler • Bullock Drawn Land Leveler • Bullock Drawn Cultivator • Tractor Mounted Mouldboard • Tractor Drawn Disc These are the various types of Chisel Plows used in agriculture field for different types of soils. 2. MATERIALS The materials are taken from the engineering database of Chisel Plow production system specification drawn by Industry. The properties of Material and Soil are taken as per the following data: Table 1. Material Properties Material Name Stainless Steel Material Properties Density 7750 Kg/m3 Young’s Modulus 1.93 X 1011 Poisson Ratio 0.31 Bulk Modulus 1.693 X 1011 Shear Modulus 7.3664 X 1010 Tensile Yield Strength 207 MPa Compressive Yield Strength 207 MPa Tensile Ultimate Strength 586 Mpa Table 2. Soil Properties S. No. Type of Soil Soil Resistance (Kg/m2 ) Optimum Moisture Content (%) 1 Sandy Soil 2000 3.5 2 Sandy Loam 3000 5.8 3 Silt Loam 3500-5000 5.8 4 Clay 4000-5600 7.18 5 Heavy Loam 5000-7000 13.30
- 3. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 47 2.1 Soil Parameters The properties of the soil related to the desired chisel plow were recognized as types of soil, wetness, mass concentration and cone index. The measurement and categorization methodologies are discussed in the subsequent section. Black type of soil is used in this research work for the chisel plow analysis. The humidity substance of soil performs a significant task for the development of the crops therefore subsequent Soil resistance and humidity substance of soil are taken as per the table 2. [6] 3. MODELING AND DESIGNING METHODS The modeling and designing methods include the number of various parameters, methods and steps for model construction. The input boundary conditions will be required for the pre processing stage of the desired chisel plow. 3.1 Finite Element Method for Chisel Plow The useful features of finite element methods are as follows [7] : • Discretization of the whole model into small elements, which may be square, rectangle, and triangle or in polygon shapes. • Derive the governing differential equations for each element of the model. • Assembly of all elements, based on stability of the solution. 3.2 Mesh Generation The conversion of whole model into number of small elements is known as Mesh generation. The meshing is a very important step for the accurate solution. Various kinds of meshing are used in the pre-processing. We are using the mesh generation with a good number of relevance with fine mesh. For the Chisel Plow elements are used for meshing. The elements may be rectangular or triangular. We are using triangular mesh for a high accuracy. The number of elements represents the solution accuracy of the model. The elements can be increased by increasing the relevance number. So that the run time is less and also the accuracy is not much affected. The mesh view of both the Chisel Plows is given below: Figure 1. Mesh Pictures of the Old Model of Chisel Plow
- 4. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 48 Figure 2. Mesh Pictures of the New Generation Model of Chisel Plow The fine triangular mesh is showing with scale in the above figures shows the accuracy of mesh at small and large surface areas. 3.3 Model Description The Model Description for the Chisel Plow is given below: Table 3. Model Description Old Model of Chisel Plow New Generation Model of Chisel Plow Length X 0.24281 m Length X 0.10152 m Length Y 0.55658 m Length Y 0.23556 m Length Z 0.25 m Length Z 0.33916 m Volume 1.0423e-003 m³ Volume 2.1013e-004 m³ Mass 8.1817 kg Mass 1.6495 kg Scale Factor Value 1 Scale Factor Value 1 No. of Nodes 32105 No. of Nodes 1751 No. of Elements 16472 No. of Elements 693 The model description shows in the above table number 3. The model description shows the exact location and orientation of the model with respect to the global coordinate system. The model description includes the model length in X, Y & Z direction, Volume & Mass of model, No. of Nodes & Elements in the model of Chisel Plow after meshing. 4. ANALYSIS OF CHISEL PLOW BY USING ANSYS The Analysis of the model can be done by using boundary conditions. After applying the boundary conditions, we can get the required results. Analysis can be done by using the analysis tool. The Modeling tool is Autodesk Inventor 14 and Analysis tool is ANSYS Workbench 14.5. There are three steps in ANSYS working procedure used for the analysis are: • Preprocessing • Solution • Post processing
- 5. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 49 After preparing a solid geometry of Chisel Plow in Autodesk Inventor 14 the important steps are meshing (that we have already done) and applying load on inclined face of the Chisel Plow by the soil and boundary conditions in the preprocessor, so that simulation can be run to get a solution and generate results in the post-processor. Figure 3(a). Old Model of Chisel Plow Figure 3(b). New Model of Chisel Plow The above figure shows the modeled view of Chisel Plow on the modeling tool Autodesk Inventor 14. Figure 3(a) showing the Old Model of Chisel Plow and Figure 3(b) showing New Generation Model of Chisel Plow. 4.1 Boundary Conditions and Input Parameters The boundary conditions are type of supports and forces on various faces, also various supports & forces are the input parameters for the Chisel Plow. 4.1.1 Type of Support Fixed Support will be applied on the face on which the body experiences the resisting force. Thus, Fixed Support will be applied at the handle of ploughs of both Old Plough & New Generation Plough. 4.1.2 Force The Force will be applied by the soil in the opposite direction of motion. Thus, the force will be applied on the inclined face of both Old Plough & New Generation Plough. Table 4. Force Description X Component 500 N Y Component 0 N Z Component 500 N The above boundary conditions are used for modeling and analysis of the Chisel Plow.
- 6. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 50 4.2 Types of Analysis We will use total three types of Analysis for both the Chisel Plows under the fix ranges: 4.2.1 Stress Analysis At the same magnitude of force and fixed support, the stress analysis is: Figure 4(a). Old Model of Chisel Plow Figure 4(b). New Generation Model of Chisel Plow Above Figure 4(a) shows Old Model of Chisel Plow, in which under the action of the force of 500 N, the maximum stress is 1995.6 MPa and Figure 4(b) shows New Generation Model of Chisel Plow in which the maximum stress is 797.54 MPa. Thus at the same magnitude of force the lower stress developed in the New Generation Model of Chisel Plow, hence it is safe then the Old Model of Chisel Plow.
- 7. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 51 4.2.2 Strain Analysis At the same magnitude of force and fixed support, the strain analysis is: Figure 5(a). Old Model of Chisel Plow Figure 5(b). New Generation Model of Chisel Plow Above Figure 5(a) shows Old Model of Chisel Plow, in which under the action of the force of 500 N, the maximum strain is 0.010801 and Figure 5(b) shows New Generation Model of Chisel Plow in which the maximum strain is 0.0040332. Thus at the same magnitude of force the lower strain developed in the New Generation Model of Chisel Plow, hence it is safe then the Old Model of Chisel Plow.
- 8. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 52 4.2.3 Deformational Analysis At the same magnitude of force and fixed support, the deformation analysis is: Figure 6(a). Old Model of Chisel Plow Figure 6(b). New Generation Model of Chisel Plow Above Figure 6(a) shows Old Model of Chisel Plow, in which under the action of the force of 500 N, the maximum deformation is 31.847 mm and Figure 6(b) shows New Generation Model of Chisel Plow in which the maximum deformation is 26.935 mm. Thus at the same magnitude of force the lower deformation developed in the New Generation Model of Chisel Plow, hence it is safe then the Old Model of Chisel Plow.
- 9. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 53 4.2.4 Fatigue Analysis At the same magnitude of force and fixed support, the life analysis is: Figure 7(a). Old Model of Chisel Plow Figure 7(b). New Generation Model of Chisel Plow Above Figure 7(a) shows Old Model of Chisel Plow, in which under the action of the force of 500 N, the maximum life cycles are 35,426 Cycles and Figure 7(b) shows New Generation Model of Chisel Plow in which the maximum life cycles are 4,22,440 Cycles. Thus at the same magnitude of force the maximum life cycles are in the New Generation Model of Chisel Plow, hence it is safe then the Old Model of Chisel Plow. Thus the above Stress, Strain, Deformation and fatigue analysis of Chisel Plow shows that under the same magnitude of force and fixed constraint the Design of Old Model of Chisel Plow get failed and the Design of New Generation Model of Chisel Plow will safe.
- 10. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 54 5. PARAMETRIC RESULTS The parametric results shows the stress, strain, deformation & fatigue results for old model & new generation model of Chisel Plow. 5.1 Stress Results on Chisel Plows The Stress result shows in the comparison of Old Model of Chisel Plow and New Generation Model of Chisel Plow. Figure 8. Comparative Stress Results of Both Chisel Plows Table 5. Stress Results on Chisel Plows Von Mises Stresses Results Old Model of Chisel Plow New Generation Model of Chisel Plow Maximum Stress (MPa) 1995.6 797.54 Minimum Stress (MPa) 4.0034 x 10-10 5.5616 x 10-16 Thus, the stress result shows that at the same magnitude of force, the maximum von mises stress developed in Old Model of Chisel Plow is 1995.6 MPa and in New Generation Model of Chisel Plow is 797.54 MPa. Thus, the Old Model of Chisel Plow get failure and New Generation Model of Chisel Plow get safe at the same magnitude of force & fixed support.
- 11. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 55 5.2 Strain Results on Chisel Plows The Strain result shows in the comparison of Old Model of Chisel Plow and New Generation Model of Chisel Plow. Figure 9. Comparative Strain Results of Both Chisel Plows Table 6. Strain Results on Chisel Plows Elastic Equivalent Strain Results Old Model of Chisel Plow New Generation Model of Chisel Plow Maximum Strain (mm) 0.0108 0.0040 Minimum Strain (mm) 3.7627 x 10-15 6.514 x 10-21 Thus, the strain result shows that at the same magnitude of force, the maximum strain developed in Old Model of Chisel Plow is 0.0108 mm and in New Generation Model of Chisel Plow is 0.0040 mm. Thus, the Old Model of Chisel Plow gets more deformation then New Generation Model of Chisel Plow at the same magnitude of force & fixed support. 5.3 Deformation Results on Chisel Plows The Deformation result shows in the comparison of Old Model of Chisel Plow and New Generation Model of Chisel Plow.
- 12. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 56 Figure 10. Comparative Deformation Results of Both Chisel Plows Table 7. Deformation Results on Chisel Plows Deformation Results Old Model of Chisel Plow New Generation Model of Chisel Plow Maximum Deformation 31.847 mm 26.935 mm Minimum Deformation 0 0 Thus, the Deformation result shows that at the same magnitude of force, the maximum strain developed in Old Model of Chisel Plow is 31.847 mm and in New Generation Model of Chisel Plow is 26.935 mm. Thus, the Old Model of Chisel Plow gets more deformation then New Generation Model of Chisel Plow at the same magnitude of force & fixed support. 5.4 Fatigue Results on Chisel Plows The Fatigue result shows in the comparison of Old Model of Chisel Plow and New Generation Model of Chisel Plow. Figure 11. Comparative Fatigue Results of Both Chisel Plows
- 13. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 57 Table 8. Fatigue Results on Chisel Plows Fatigue Results Old Model of Chisel Plow New Generation Model of Chisel Plow Failure Occurs at 35,426 Cycles 4,22,440 Cycles Thus, the Fatigue result shows that at the same magnitude of force, the Failure Occurs in Old Model of Chisel Plow is at 35,426 Cycles and in New Generation Model of Chisel Plow is at 4,22,440 Cycles. Thus, the Old Model of Chisel Plow gets failure then New Generation Model of Chisel Plow at the same magnitude of force & fixed support. Thus, the Parametric Results on the basis of Stress, Strain, Deformation and Fatigue Results, the New Generation Model of Chisel Plow is much Safe than the Old Model of Chisel Plow. The design of New Generation Model of Chisel Plow is much safe design for an agriculture use. Also the life of New Generation Model of Chisel Plow is greater than Old Model of Chisel Plow. CONCLUSION A tillage tool such as Chisel Plow is designed in computer aided design software. The motion of Chisel Plow and soil surface interaction is considered. The tillage operations introduces a quality parameters and development scope in obtaining a width of cut , depth of cut, Speed of operation, field efficiency, field capacity, theoretical draft the rate of work, quality of work, draft measurement etc. The analysis of stress, strain, deformation and life cycle shows the safe designs at the same range of input parameters between old model of Chisel Plow and New Generation Model of Chisel Plow. REFERENCES [1] Quirke, S. Scheffler, O. Allen, (1988), “An evaluation of the wear behavior of metallic materials subjected to soil abrasion” Soil and Till. Res. 11 [2] Gill, W.R., and G.E. Vanden Berg, (1996), “Design of tillage tool in soil dynamics in tillage and traction”, 211-294, Washington, D.C.,U.S.GPO [3] Godwin, R.J. (1982), “Force measurement on tillage implements” 9th Conference of the International soil Tillage Research organization, Osijek [4] Jain, S.C., and Philip (2003), “Farm machinery an approach, standard publishers distributors Delhi pp. 5-7, 21, 27 [5] Kosutic, S., D Filipovic, and Z Gospodaric. (1996), “Rotary Cultivator Energy Requirement Influenced by Different Constructional Characteristics”, Velocity and Depth of Tillage. Poljoprivredna-Znanstvena-Somatra, vol 61,Pg3-4, 1996, p 239 [6] Krutz, G., L. Thompson and C. Poul (1984), “Design of Agricultural machine”, John Willey and Sons, New Delhi. pp.32-36 [7] Ben Yahia, Logue, and M. Khelifi. (1999), “Optimum settings for rotary tools used for on-the-row mechanical cultivation in corn”, Transactions of ASAE, 15(6): 615-619 [8] Biswas, H.S. (1993)., “Performance Evaluation and optimization of straight blades for shallow tillage and weeding in black soils”, Agric. Mech. in Asia, Africa and Latin America, 24(4) 19-22 [9] Block, J.M. (1986), “Performance of power tiller blades”, Agric. Mech. In Asia, Africa and Latin America, 17 (1): 22-26 [10] Spoor. G., “Design of soil engaging implements”, practice, Farm Machine design Eng J:14- 19,Dec,1969
- 14. International Journal of Recent advances in Mechanical Engineering (IJMECH) Vol.4, No.4, November 2015 58 [11] Thakur T.C., (1991), “Design aspects of soil engaging hand tools”, Agricultural Engineering Today.21:15-18 [12] Zhang, J., and R.L.K Khuswala, (1996), “Wear and draft of cultivator sweep with hardened edges”, Canadian Agricultural Engineering, 37(1); 41-47 AUTHORS: Pawan Sharma has completed his B.Tech in Mechanical Engineering, M.Tech in Machine Design from RTU (Kota), Rajasthan, INDIA. He has published more than 25 research papers in the refereed International journals and conferences. He has published three Engineering Books in the field of FEA/FEM. His area of research includes CAD/CAM, FEA/FEM, Composite Materials, CFD and Vibration Analysis. Prof. (Dr.) Manish Bhargava holds M.Tech. in Manufacturing System Engineering, Ph.D. in Mechanical Engineering from MNIT, Jaipur. He has published more than 30 research papers in the refereed International journals and conferences. He has a teaching and research experience of more than 14 years. Currently, He is working as a Professor in Mechanical Engineering & Principal with Maharishi Arvind Institute of Engineering and Technology, Jaipur, Rajasthan, India. His area of research includes CIMS, CAD/CAM, Reliability & Maintenance, Manufacturing Systems and Material Science.