Effects of soil mechanical properties on the height and tractive performance of rubber grouser at different moisture contents

Sher Ali Shaikh, Yaoming Li, Zheng Ma, Farman Ali Chandio, Mazhar Hussain Tunio, Fiaz Ahmad, Kashif Ali Solangi

Abstract


Rubber tracked vehicles are commonly used on agricultural machinery that perform agricultural operations such as rice harvesting in soft paddy fields with low bearing capacity. Research was carried out to assess the influence of soil moisture content and mechanical properties on the tractive performance of a rubber grouser with three heights (45 mm, 55 mm, 60 mm). The direct shear test and penetration test were used in this study, which was based on a semi-empirical approach of determining tractive parameters. Direct shear tests were used to measure soil shear strength parameters such as cohesion, adhesion, internal and exterior friction angles. The results of the penetration test were used to determine tractive parameters such as soil thrust, running resistance, and traction, for the penetration test, a device was designed and developed. The experimental results revealed that soil cohesion and adhesion increased linearly with increasing soil moisture content, however adhesion dropped after 30.7%. Similarly, the soil thrust initially increased till 21.5% then decreased. Furthermore, running resistance had a decreasing trend over soil moisture content whereas maximum traction achieved for 45 mm grouser height at 21.5% moisture content. It was concluded that a rubber grouser with 45 mm height had better traction rather than 55 mm and 60 mm, it can be suitably used for designing a track system for a crawler vehicle (e.g., harvester) leading to its greater adoption among the farmers.
Keywords: soil moisture content, traction, rubber grouser, soil mechanical properties, tracked vehicle
DOI: 10.25165/j.ijabe.20221506.7137

Citation: Shaikh S A, Li Y M, Ma Z, Chandio F A, Tunio M H, Ahmad F, et al. Effects of soil mechanical properties on the height and tractive performance of rubber grouser at different moisture contents. Int J Agric & Biol Eng, 2022; 15(6): 31–37.

Keywords


soil moisture content, traction, rubber grouser, soil mechanical properties, tracked vehicle

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References


Bekker M G. Introduction of Terrain Vehicle Systems. Ann Arbor, University of Michigan Press, 1969.

Tsuji T, Nakagawa Y, Matsumoto N, Kadono Y, Takayama T, Tanaka T. 3-D DEM simulation of cohesive soil-pushing behavior by bulldozer blade. J Terramechanics, 2012; 49: 37–47.

Chang B-S, Baker WJ. Soil parameters to predict the performance of off-road vehicles. J Terramechanics, 1973; 9: 13–31.

Soltynski A. The mobility problem in agriculture. J Terramechanics, 1979; 16: 139–419.

Wong J Y. Theory of ground vehicles. John Wiley & Sons; 2008.

ITO N. Method for Determining the specification of rubber track with circular grousers. J Jpn Soc Agric Mach, 1999; 61: 95–102.

Bekker MG. Theory of land locomotion-the mechanics of vehicle mobility. University of Michigan Press, 1956.

Yong RN. Track-soil interaction. J Terramechanics 1984; 21: 133–152.

Wong J Y, Huang W. “Wheels vs. tracks”–A fundamental evaluation from the traction perspective. J Terramechanics, 2006; 43: 27–42.

Alcock R, Wittig V. An empirical method of predicting traction. J Terramechanics, 1992; 29: 381–394.

Asaf Z, Rubinstein D, Shmulevich I. Evaluation of link-track performances using DEM. J Terramechanics 2006; 43: 141–161.

Smith WC. Modeling of Wheel-Soil Interaction for Small Ground Vehicles Operating on Granular Soil. PhD Thesis, 2014.

Station WE. Trafficability of soils development of testing instruments. Tech Mem, 1948.

Yang R, Xu M, Liang X, Zhang S, Cheng Y, Xu H, et al. Experimental study and DEM analysis on rigid driving wheel’s performance for off-road vehicles moving on loose soil. 2011 IEEE Int. Conf. Mechatron. Autom, IEEE, 2011; pp.142–147.

Gill W R, Berg G E V. Soil dynamics in tillage and traction. Agricultural Research Service, US Department of Agriculture, 1967.

Abou-Zeid A S. Distributed soil displacement and pressure associated with surface loading. Doctoral dissertation, University of Saskatchewan, 2004.

Reeb J E, Milota M R, Association W D K. Moisture content by the oven-dry method for industrial testing. Proceedings of Western Dry Kiln Association, Corvallis, USA, 1999. http://hdl.handle.net/1957/5190.

Nagaoka K, Sawada K, Yoshida K. Shape effects of wheel grousers on traction performance on sandy terrain. J Terramechanics, 2020; 90: 23–30.

Density B. Soils - Part 2: Physical properties of soil and soil water. Plant & Soil Sciences eLibrary. https://passel2.unl.edu/view/lesson/0cff7943f577/6. Accessed on [2021-08-29]

Shaikh S A, Li Y, Zheng M, Chandio F A, Ahmad F, Tunio M H, et al. Effect of grouser height on the tractive performance of single grouser shoe under different soil moisture contents in clay loam terrain. Sustainability, 2021; 13: 1156. https://doi.org/10.3390/su13031156

Rajaram G, Erbach D C. Effect of wetting and drying on soil physical properties. J Terramechanics, 1999; 36: 39–49.

Abbaspour-Gilandeh Y, Hasankhani-Ghavam F, Shahgoli G, Shrabian V R, Abbaspour-Gilandeh M. Investigation of the effect of soil moisture content, contact surface material and soil texture on soil friction and soil adhesion coefficients. Acta Technol Agric, 2018; 21: 44–50.

Gill W R, Berg G E V. Assessment of the dynamic properties of soils. Chapter 3. In Soil dynamics in tillage and traction. Vol. 316. Washington, D.C. USA. Government Printing Office: Agricultural Research Service, US Department of Agriculture, 1967.

Neal M S. Friction and adhesion between soil and rubber. J Agric Eng Res, 1966; 11: 108–112.

Ren L Q, Tong J, Li J Q, Chen B C. SW—soil and water: soil adhesion and biomimetics of soil-engaging components: a review. J Agric Eng Res, 2001; 79: 239–263.

Pezowicz P, Choma-Moryl K. Moisture content impact on mechanical properties of selected cohesive soils from the wielkopolskie voivodeship southern part. Stud Geotech Mech, 2015; 37: 37–46.

Gan J K M, Fredlund D G, Rahardjo H. Determination of the shear strength parameters of an unsaturated soil using the direct shear test. Can Geotech J, 1988; 25: 500–510.

Pawlak K, Chudy K. Strength parameters of cohesive soils from the region of Ostrów Wielkopolski, glacitectonically disturbed - new possibilities and problems of interpretation. Cuprum: ore mining science and technology journal, 2013 (1): 87–99.

Baek S-H, Shin G-B, Lee S-H, Yoo M, Chung C-K. Evaluation of the slip sinkage and its effect on the compaction resistance of an off-road tracked vehicle. Appl Sci, 2020; 10: 3175. doi: 10.3390/app10093175.

Gotteland P, Benoit O. Sinkage tests for mobility study, modelling and experimental validation. J Terramechanics, 2006; 43: 451–467.

Liu K, Ayers P, Howard H, Anderson A. Lateral slide sinkage tests for a tire and a track shoe. J Terramechanics, 2010; 47: 407–414.

Malý V, Kučera M. Determination of mechanical properties of soil under laboratory conditions. Res Agric Eng, 2014; 60: 66–69.

Rashidi M, Fakhri M, Sheikhi M, Azadeh S, Razavi S. Evaluation of Bekker model in predicting soil pressure-sinkage behaviour under field conditions. Middle-East J Sci Res, 2012; 12: 1364–1369.

Van NN, Matsuo T, Koumoto T, Inaba S. Experimental device for measuring sandy soil sinkage parameters. Bull Fac Agric Saga Univ 2008; 93: 91–99.

Ge J, Wang X L, Kito K. Comparing tractive performance of steel and rubber single grouser shoe under different soil moisture contents. Int J Agric & Biol Eng, 2016; 9(2): 11–20.

Yong RN, Youssef A F, El-Mamlouk H. Soil deformation and slip relative to grouser shape and spacing. J Terramechanics, 1978; 15: 129–44.

Rasool S, Raheman H. Improving the tractive performance of walking tractors using rubber tracks. Biosyst Eng, 2018; 167: 51–62.

Liu J, Gao H, Deng Z. Effect of straight grousers parameters on motion performance of small rigid wheel on loose sand. Inf Technol J, 2008; 7: 1125–1132.

Li J, Zhang Y, Jingkai Z, Gong C. Study on prediction method of the sinkage of track with big shoes. Agric Equip Veh Eng, 2013; 51: 33–36.

Li J, Liu S, Dai Y. Effect of grouser height on tractive performance of tracked mining vehicle. J Braz Soc Mech Sci Eng, 2017; 39: 2459–2466.




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