Res. Agr. Eng., 2012, 58(1):24-29 | DOI: 10.17221/11/2010-RAE

Mechanical behaviour of several layers of selected plant seeds under compression loading

D. Herák1, A. Kabutey1, A. Sedláček1, G. Gűrdil2
1 Department of Mechanical Engineering, Faculty of Engineering, Czech University of Life Sciences Prague, Prague, Czech Republic
2 Department of Agricultural Machinery, Faculty of Agriculture, Ondokuz Mayis University Samsun, Samsun, Turkey

This article is focused on the determination of the mechanical behaviour of several layers of plant seeds namely; garden pea (Pisum sativum L.), common bean (Phaseolus vulgaris L.), common sunflower (Helianthus annuus L.) and jatropha (Jatropha curcas L.) seeds under compression loading. The results from the experiment showed that during compression plant seeds may change their mechanical behaviour that is deformation characteristic ceases to be a function of growing and beginning to resemble that of trigonometric functions and this behaviour is called the "wave effect". Also the strain value at which there is no further change of the mechanical behaviour is actually a local maximum of deformation characteristic and this is called the limit deformation. Exceeding this value can cause vibration of the presser including other negative factors which influences the process of pressing. The amounts of the limit deformation, strain energy and volume energy for jatropha, common bean, common sunflower and garden pea were determined in this experiment. From the calculated amounts of the volume energy, garden pea had the best resistance to change in the mechanical behaviour due to the fact that its change in the mechanical behaviour was not discovered. The other plant seeds; common beans, common sunflower and jatropha with respect to resistance to change in the mechanical behaviour followed in that order of magnitude.

Keywords: jatropha; common bean; garden pea; common sunflower; pressing; wave effect

Published: March 31, 2012  Show citation

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Herák D, Kabutey A, Sedláček A, Gűrdil G. Mechanical behaviour of several layers of selected plant seeds under compression loading. Res. Agr. Eng.. 2012;58(1):24-29. doi: 10.17221/11/2010-RAE.
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    References

    1. Addy T.O., Whitney L.F., Chen C.S., 1975. Mechanical parameters in leaf cell Membrane rupture for protein production. St. Joseph, ASAE Paper No. 75-1057.
    2. Blahovec J., Řezníček R., 1980. Frakcionace píce (Fractionation of the Forage). Prague, Czech University of Life Sciences Prague: 370.
    3. Braga G.C., Couto S.M., Hara T., Neto J.T.P.A., 1999. Mechanical behaviour of macadamia nut under compression loading. Journal of Agriculture Engineering Research, 72: 239-245. Go to original source...
    4. Danilov V.I., 1976. Energojomkost I KPD processa ekstruzionnij dězintegraciji zeljonych kormov (Energy performance and efficiency of the extrusion disintegration process of green forage). In: Proceeding Institute of Agriculture Machine. Rostov-on-Don, Izdatelstvo Rostovskovo universiteta: 35.
    5. Faborode M.O., Favier J.F., 1996. Identification and significance of the oil-point in seed-oil expression. Journal of Agriculture Engineering Research, 65: 335-345. Go to original source...
    6. Fomin V.I., 1978. Vlažnoje frakcionirovanije zeljonych kormov (Wet Fractionation of Green Forage). Rostov-on-Don, Izdatelstvo Rostovskovo universiteta: 160.
    7. Herák D., Karanský J., Sedláček A., Dajbych O., 2007. Basic theory of vegetable oils' pressing. Naukovij Visnik, 117: 276- 285.
    8. Herák D., Gurdil G., Sedláček A., Dajbych O., Simanjuntak S., 2010. Energy demands for pressing Jatropha curcas L. seeds. Biosystems Engineering, 106: 527-534. Go to original source...
    9. Herák D., Kabutey A., Sedláček A., Gűrdil G., 2011. Tangent curve utilization for description of mechanical behaviour of pressed mixture. Research in Agricultural Engineering, 57: 13-18. Go to original source...
    10. Isik E., Izli N., 2007. Physical properties of sunflower seeds (Helianthus annuus L.). International Journal of Agricultural Research, 2: 677-686. Go to original source...
    11. Kabutey A., Herák D., Sedláček A., 2011. Behaviour of different moisture contents of Jatropha curcas L. seeds under compression loading. Research in Agricultural Engineering, 57: 72-77. Go to original source...
    12. Koegel R.G., Fomin V.I., Bruhn H.D., 1973. Roller maceration and fractionation of forage. Transactions of the ASAE, 16: 236-240. Go to original source...
    13. Murthy C.T., Bhattacharya S., 1998. Moisture dependent physical and uniaxial compression properties of black pepper. Journal of Food Engineering, 37: 193-205. Go to original source...
    14. Očenášek J., Voldřich J., 2009. Mathematical modeling of a biogenous filter cake and identification of oilseed material parameters. Applied and Computational Mechanics, 3: 1-12.
    15. Olaniyan A.M., Oje K., 2002. Some aspects of the mechanical properties of shea nut. Biosystems Engineering, 81: 413-420. Go to original source...
    16. Ozturk I., Kara M., Elkoca E., Ercisli S., 2009. Physico-chemical grain properties of new common bean cv. 'Elkoca-05'. Scientific Research and Essay, 4: 88-93.
    17. Raji A.O., Favier J.F., 2004. Model for the deformation in agricultural and food particulate materials under bulk compressive loading using discrete element method II: Theory, compression of oilseeds. Journal of Food Engineering, 64: 373-380. Go to original source...
    18. Resende O., Correa P.C., Jarén C., Moure A.J., 2007. Bean moisture diffusivity and drying kinetics: a comparison of the liquid diffusion model when taking into account and neglecting grain shrinkage. Spanish Journal of Agricultural Research, 5: 51-58. Go to original source...
    19. Sirisomboon P., Kitchaiya P., Pholpo T., Romphophak T., 2007. Physical and mechanical properties of Jatropha curcas L. fruits, nuts and kernels. Biosystems Engineering, 97: 201-207. Go to original source...
    20. Tavakoli H., Mohtasebi S.S., Rajabipour A., Tavakoli M., 2009. Effects of moisture content, loading rate, and grain orientation on fracture resistance of barley grain. Research in Agricultural Engineering, 55: 85-93. Go to original source...
    21. Yalcin I., Ozarslan C., Zkvas T., 2007. Physical properties of pea (Pisum sativum) seed. Journal of Food Engineering, 79: 731-735. Go to original source...
    22. Yao W.G., Takahashi K., Koyama K., Dai G.C., 1997. Design of a new type of pin mixing section for a screw extruder based on analysis of flow and distributive mixing performance. Chemical Engineering Science, 52: 13-21. Go to original source...
    23. Zhu L., Narh K.A., Hyun K.S., 2005. Investigation of mixing mechanisms and energy balance in reactive extrusion using three-dimensional numerical simulation Method. International Journal of Heat and Mass Transfer, 48: 3411-3422. Go to original source...

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