Authors: A. Armin, R. Fotouhi, W. Szyszkowski

Abstract:

In this paper a 3-D finite element (FE) investigation of soil-blade interaction is described. The effects of blade’s shape and rake angle are examined both numerically and experimentally. The soil is considered as an elastic-plastic granular material with non-associated Drucker-Prager material model. Contact elements with different properties are used to mimic soil-blade sliding and soil-soil cutting phenomena. A separation criterion is presented and a procedure to evaluate the forces acting on the blade is given and discussed in detail. Experimental results were derived from tests using soil bin facility and instruments at the University of Saskatchewan. During motion of the blade, load cells collect data and send them to a computer. The measured forces using load cells had noisy signals which are needed to be filtered. The FE results are compared with experimental results for verification. This technique can be used in blade shape optimization and design of more complicated blade’s shape.

Keywords: Finite element analysis, soil-blade contact modeling, blade force, experimental results.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1130067

Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1112

References:

[1] Zhang, J., and Kushwaha, R.L. 1998, “Dynamic analysis of tillage tool: Part I – Finite element method”, Canadian Agriculture Engineering; Vol (40), pp. 287-292.
[2] Ashrafi Zadeh, S.R, 2006. “Modeling of energy requirements by a narrow tillage tool’. Unpublished Doctoral Thesis at the University of Saskatchewan, Saskatoon, Canada.
[3] S.Karmakar, 2008, “Modeling of soil-tool interaction in tillage”. Transworld research network, India.
[4] M. Abo-Elnor, R. Hamilton, J.T. Boyle, 2004, “Simulation of soil-blade interaction for sandy soil using advanced 3D finite element analysis”, Soil & Tillage Research. Vol(75), pp. 61-73.
[5] J. Wang, and D. Gee-Clough, 1991, “Deformation and failure in wet clay soil. Simulation of tine soil cutting”. Proc IAMC Conference Beijing, China. Pp. 219-226.
[6] L. Chi, and R.L. Kushwaha, 1989, “Finite element analysis of force on a plane soil blade”. Canadian Agriculture Engineering, Vol(31), pp. 135-140.
[7] J. Shen, and R. L. Kushwaha, 1998, “Soil-Machine Interactions-A Finite Element Perspective”, Marcel Dekker Inc. Publishers,.
[8] S.K. Upadhyaya, U.A. Rosa, and D. Wulfsohn, 2002, “Application of the finite element method in agricultural soil mechanics”, Advances in soil Dynamics, PP. 117-153.
[9] D.R.P. Hettiaratchi, A.R., Reece, The calculation of passive soil resistance. Computers and Geotechnique. 24 (1974) 280-310.
[10] E. McKyes, O.S. Ali, The cutting of soil by a narrow blade. Journal of Terramechanics. 14 (1977) 43-58.J. Shen, and R. L. Kushwaha, 1998, “Soil-Machine Interactions-A Finite Element Perspective”, Marcel Dekker Inc. Publishers,.
[11] Y. Chen, L. J. Munkholm, T. A. Nyord, Discrete element model for soil-sweep interaction in three different soils. Soil & Tillage Research. 126 (2013) 34-41.
[12] E. McKeyes, Soil cutting and tillage. Elsevier Science Publishing Company, New York, 1985.
[13] A. Armin, R. Fotouhi, W. Szyszkowski, On the FE modeling of soil–blade interaction in tillage operations, Finite elements in analysis and design 92(2014)1-11.
[14] A. Bankole, Critical State Behaviour Of An Agricultural Soil. Doctoral Thesis at the University of Saskatchewan, Saskatoon, Canada, 1996.
[15] Godwin, R.J., O’Dogherty, M.J. Integrated soil tillage force prediction models. Journal of Terramechanics; 44(2007) 3-14