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Deep tillage tool optimization by means of finite element method: Case study for a subsoiler tine

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Deep tillage tool optimization by means of finite element method: Case study for a subsoiler tine. / Topakci, Mehmet; Celik, H Kursat; Canakci, Murad et al.
In: Journal of Food, Agriculture and Environment, Vol. 8, No. 2, 04.2010, p. 531-536.

Research output: Contribution to Journal/MagazineJournal articlepeer-review

Harvard

Topakci, M, Celik, HK, Canakci, M, Rennie, A, Akinci, I & Karayel, D 2010, 'Deep tillage tool optimization by means of finite element method: Case study for a subsoiler tine', Journal of Food, Agriculture and Environment, vol. 8, no. 2, pp. 531-536. <http://www.world-food.net/scientficjournal/2010/issue2.php>

APA

Topakci, M., Celik, H. K., Canakci, M., Rennie, A., Akinci, I., & Karayel, D. (2010). Deep tillage tool optimization by means of finite element method: Case study for a subsoiler tine. Journal of Food, Agriculture and Environment, 8(2), 531-536. http://www.world-food.net/scientficjournal/2010/issue2.php

Vancouver

Topakci M, Celik HK, Canakci M, Rennie A, Akinci I, Karayel D. Deep tillage tool optimization by means of finite element method: Case study for a subsoiler tine. Journal of Food, Agriculture and Environment. 2010 Apr;8(2):531-536.

Author

Topakci, Mehmet ; Celik, H Kursat ; Canakci, Murad et al. / Deep tillage tool optimization by means of finite element method: Case study for a subsoiler tine. In: Journal of Food, Agriculture and Environment. 2010 ; Vol. 8, No. 2. pp. 531-536.

Bibtex

@article{6bff96ae98314f7fa9632256bd0f8654,
title = "Deep tillage tool optimization by means of finite element method: Case study for a subsoiler tine",
abstract = "Technologies and computer capacity currently available allow us to employ design software and numerical methods to solve complicated problems in very wide disciplines of engineering. It is also important for researches in agriculture. This study focused on obtaining optimum geometry parameters of a subsoiler tine by using computer aided engineering (CAE) applications. A field experiment was conducted to determine draft force of the subsoiler. The results from the experimental study were used in the finite element analysis (FEA) to simulate stress distributions on the subsoiler tine. The maximum equivalent stress of 432.49 MPa was obtained in the FEA. Visual investigations and FEA results showed that according to the tine{\textquoteright}s material yield stress point of 355 MPa, plastic deformation was evident. Based on the FEA results, an optimization study was undertaken to obtain optimum geometry parameters without the occurrence of plastic deformation. According to the optimization study results, the optimum parameters of the tine geometry and maximum equivalent stress of 346.61 MPa were obtained. In addition to this, the total mass of the tine was reduced by about 0.367 kg.",
keywords = "Subsoiler, Optimization, finite element method, Agricultural Machinery Design",
author = "Mehmet Topakci and Celik, {H Kursat} and Murad Canakci and Allan Rennie and Ibrahim Akinci and Davut Karayel",
year = "2010",
month = apr,
language = "English",
volume = "8",
pages = "531--536",
journal = "Journal of Food, Agriculture and Environment",
issn = "1459-0255",
publisher = "World Food Ltd. and WFL Publishers",
number = "2",

}

RIS

TY - JOUR

T1 - Deep tillage tool optimization by means of finite element method: Case study for a subsoiler tine

AU - Topakci, Mehmet

AU - Celik, H Kursat

AU - Canakci, Murad

AU - Rennie, Allan

AU - Akinci, Ibrahim

AU - Karayel, Davut

PY - 2010/4

Y1 - 2010/4

N2 - Technologies and computer capacity currently available allow us to employ design software and numerical methods to solve complicated problems in very wide disciplines of engineering. It is also important for researches in agriculture. This study focused on obtaining optimum geometry parameters of a subsoiler tine by using computer aided engineering (CAE) applications. A field experiment was conducted to determine draft force of the subsoiler. The results from the experimental study were used in the finite element analysis (FEA) to simulate stress distributions on the subsoiler tine. The maximum equivalent stress of 432.49 MPa was obtained in the FEA. Visual investigations and FEA results showed that according to the tine’s material yield stress point of 355 MPa, plastic deformation was evident. Based on the FEA results, an optimization study was undertaken to obtain optimum geometry parameters without the occurrence of plastic deformation. According to the optimization study results, the optimum parameters of the tine geometry and maximum equivalent stress of 346.61 MPa were obtained. In addition to this, the total mass of the tine was reduced by about 0.367 kg.

AB - Technologies and computer capacity currently available allow us to employ design software and numerical methods to solve complicated problems in very wide disciplines of engineering. It is also important for researches in agriculture. This study focused on obtaining optimum geometry parameters of a subsoiler tine by using computer aided engineering (CAE) applications. A field experiment was conducted to determine draft force of the subsoiler. The results from the experimental study were used in the finite element analysis (FEA) to simulate stress distributions on the subsoiler tine. The maximum equivalent stress of 432.49 MPa was obtained in the FEA. Visual investigations and FEA results showed that according to the tine’s material yield stress point of 355 MPa, plastic deformation was evident. Based on the FEA results, an optimization study was undertaken to obtain optimum geometry parameters without the occurrence of plastic deformation. According to the optimization study results, the optimum parameters of the tine geometry and maximum equivalent stress of 346.61 MPa were obtained. In addition to this, the total mass of the tine was reduced by about 0.367 kg.

KW - Subsoiler

KW - Optimization

KW - finite element method

KW - Agricultural Machinery Design

M3 - Journal article

VL - 8

SP - 531

EP - 536

JO - Journal of Food, Agriculture and Environment

JF - Journal of Food, Agriculture and Environment

SN - 1459-0255

IS - 2

ER -