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اثر ارتعاش دورانی بر نیروی کششی عملکرد خاکورزی و کارآیی انرژی زیرشکن | ||
| تحقیقات سامانهها و مکانیزاسیون کشاورزی | ||
| مقاله 2، دوره 22، شماره 78، شهریور 1400، صفحه 19-38 اصل مقاله (1.31 M) | ||
| نوع مقاله: مقاله پژوهشی | ||
| شناسه دیجیتال (DOI): 10.22092/erams.2020.342925.1352 | ||
| نویسندگان | ||
| بهروز گودرزی1؛ نواب کاظمی* 2؛ محمد امین آسودار3 | ||
| 1دانشجوی دکتری گروه ماشین های کشاورزی و مکانیزاسیون، دانشکده مهندسی زراعی و عمران روستایی، دانشگاه علوم کشاورزی و منابع طبیعی خوزستان، اهواز، ایران | ||
| 2استادیار دانشکده مهندسی زراعی و عمران روستایی، گروه ماشین های کشاورزی و مکانیزاسیون، دانشگاه کشاورزی و منابع طبیعی خوزستان، اهواز، ایران | ||
| 3استاد دانشکده مهندسی زراعی و عمران روستایی، گروه ماشین های کشاورزی و مکانیزاسیون، دانشگاه کشاورزی و منابع طبیعی خوزستان، اهواز، ایران | ||
| چکیده | ||
| فشردگی خاک موجب عدم نفوذ آب و هوا در خاک و توسعه نا مناسب ریشه میگردد. سریعترین روش مقابله با آن زیرشکنی است. ارتعاش به کار گرفته شده در زیرشکنهای موجود به دلیل استفاده از محور تواندهی به عنوان منبع توان ایجاد ارتعاش، از نوع رفت و برگشتی است. این روش هم توان بالایی نیاز دارد و هم موجب استهلاک در زیرشکن و تراکتور میگردد. در این پژوهش به منظور دستیابی به اهدافی مانند کاهش توان کل (کششی+ ارتعاشی) و افزایش کارآیی انرژی، یک زیرشکن مجهز به سامانه ارتعاش دورانی ساخته شد و برای تأمین توان ارتعاش دورانی، کنترل بسامد ارتعاش و جهت دوران، از توان الکتریکی استفاده شده است. طرح آماری فاکتوریل در قالب کاملاً تصادفی با سرعت پیشروی و بسامد، به عنوان متغیرهای مستقل و عمق خاکورزی، سطح مقطع خاکورزی، میانگین وزنی قطر کلوخه، نیروی کششی و انرژی کل متغیرهای وابسته در نظر گرفته شدند. اثر ارتعاش دورانی با اطمینان 95% بر عمق خاکورزی و با اطمینان 99% بر سطح خاکورزی و میانگین وزنی قطر کلوخه معنیدار شد. بسامد (36-) هرتز بهترین خردکنندگی کلوخه را داشت. تأثیر ارتعاش دورانی بر نیروی کششی، با اطمینان 99 درصد معنیدار شد و بسامد (36+) هرتز کمترین نیروی کششی را داشت. همچنین انرژی مصرف شده برای خاکورزی با اطمینان 99 درصد کاهش یافت و بسامد (36+) هرتز دارای کمترین انرژی مصرفی شد. با در نظر گرفتن میزان خردکنندگی در ازای مصرف انرژی، نشانگری به عنوان کارآیی زیرشکنی تعریف شد و نتیجه نشانگر کارآیی انرژی، به ترتیب اولویت کارآیی زیرشکنی عبارت از تیمارهای با بسامد (36+)، (36-)، (18-)، (18+) و (0) هرتز است. | ||
| کلیدواژهها | ||
| توان الکتریکی؛ خاکورزی؛ زیرشکن ارتعاشی؛ فشردگی خاک | ||
| عنوان مقاله [English] | ||
| Effect of rotary vibration by electric power, on tillage performance and efficiency of subsoiler | ||
| نویسندگان [English] | ||
| Behrooz Goudarzi1؛ navab kazemi2؛ Mohammad Amin Asoodar3 | ||
| 1Department of agricultural machinery and mechanization, Faculty of agricultural engineering and rural development, Agricultural Sciences and Natural Resources University of Khuzestan | ||
| 2عضو هیات علمی رسمی پایه 26 | ||
| 3Department of agricultural machinery and mechanization, Faculty of agricultural engineering and rural development, Agricultural Sciences and Natural Resources University of Khuzestan | ||
| چکیده [English] | ||
| Soil compaction causes the lack of water and oxygen in the soil; therefore, development of the roots is restricted. Therefore, vibrating subsoilers recommended for better soil crushing and for increasing the power transfer efficiency from tractor to soil. The vibration used in the subsoiler is available from the type of sweep and its main reason is the use of the tractor power axis (P.T.O) as the source of vibration creation. In this study a subsoiler, which was equipped with a rotational vibration system, was fabricated and used to provide rotational vibration, the vibration frequency control and the side of rotation, be controlled with electrical power. Factorial statistical design was performed in a completely randomized manner with speed and frequency, as independent variables. The dependent variables were: tillage depth, tillage cross section, clod mean weight diameter, tensile force and total energy. The effect of rotational vibration with confidence of 95% on tillage depth and with confidence of 99% on tillage side and mean weight of the clot was significant. Frequency (-36 Hz) had the best crushing of the soil. The effect of rotational vibration on tensile force was significant with confidence of 99% and the frequency (+36 Hz) had the lowest tensile force. The energy used for tillage was reduced with confidence of 99% and the frequency (+36 Hz) had the lowest energy consumption. By considering the amount of crushing for energy consumption, the marker was defined as the subsoiler efficiency (the amount of energy consumed for the crushing). The result of this marker is the priority of the rippering of the treatments with frequency (+36, -36, -18, +18 and 0 Hz) respectively. | ||
| کلیدواژهها [English] | ||
| Electrical Power, Soil Compaction, Tillage, Vibrating Subsoiler | ||
| مراجع | ||
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Ahmadi, I. (2017). Effect of soil type, machine geometry, and working conditions on draft force of a moldboard plow and a disk plow. Zist Samane Engineering, 6(1), 1-9. (in Persian) Awad-Allah, M. A., Mahgoub, H. M., Abo-Elnor, M. E., & Shahin, M. A. (2009). Experimental investigation of the effect of vibration during tillage process of multi shank plough blade. Proceeding of 13th International Conference on Aerospace Sciences and Aviation Technology. May 28, Cairo, Egypt. Bandalan, E. P., Salokhe, V. M., Gupta, C. P., & Niyamapa, T. (1999). Performance of an oscillating subsoiler in breaking a hardpan. Journal of Terramechanics, 36, 117-125. Beiranvand, M., & Shahgoli, Gh. (2010). Investigating some oscillatory tillage parameters by dynamic modeling for energy saving. Journal of Agricultural science and Sustainable Production, 20(4), 54- 64. (in Persian) Boyd, R. J., & Nalezny, C. L. (1967). A model vibrating soil cutting, SAE farm, Construction and industrial machinery meeting, Milwaukee. Buckingham, F., & Pauli, A. (2008). Conservation tillage systems. (Translation: Asudar, M. A. & Sabzezar, H.). Agricultural Extension, Education and Research Organization. Deputy for Agricultural Extension and Education. Agricultural Education Pub. (in Persian) Frisby, J. C., & J. D. Summers. (1979). Energy related data for selected implements. Transaction of the ASAE, 22(5), 1010 -1011. Ghanbarian, D., & Shahmirzaei, H. (2010). Basics of tillage machinery engineering. Shahrekord University Pub. (in Persian) Godwin, R. J., & Spoor, G. (1977). Soil failure with narrow tine. Journal of Agricultural Engineering Research, 22, 213-228. Goudarzi, B., Asoodar, A., & Kazemi, N. (2015). Blade vibration impact on the performance of silty clay loam soil cover tillage. Agricultural Engineering Journal, 5(2), 357-367. (in Persian) Hansoon, P. A. (2002). Working space requirement for an agricultural tractor axle suspension. Biosystems Engineering, 81(1), 57-71. Hemmat, A., Sadegh-Nejad, H. R., & Alimardani, R. (2000). Draft of vibrating- share subsoiler in vibrating and non- vibrating modes and its effect on soil physical properties. Iranian Journal of Agricultural and Science, 31(1), 127-146. (in Persian) Hendrick, J. G., & Buchele, W. F. (1963). Tillage energy of a vibrating tillage tool. American Society of Agricultural Engineers (ASAE), 6(3), 207-219. Karoonboonyanan, R., Salokhe, V. M., Niapama, T., & Nakashima, H. (2007). Vibration effects on the performance of a single-shank subsoiler. CIGR Journal, 1, 7-18. Kattenstorth, R., & Hans, H. (2011). Reducing friction in tillage using ultrasonic vibration. Biosystems Engineering, 94, 181-192. Kepner, R. A., Bainer, R., & Barger, E. L. (1978). Principles of farm machinery. Third Ed. AVI publishing Co. Inc., Westport, Connecticut. Khaffaf, A., & Khadr, A. (2008). Effect of some primary tillage implement on soil pulverization and specific energy. Farm machinery and power, 25(3), 731-745. Kheiry, A. N. O., & Xing, Z. D. (2016). Staggered reciprocating subsoiler shanks and tractor forward speed and their influence on power requirement and soil profile. International Journal of Engineering Studies and Technical Approches, 2(8), 12-19. Klenin, N. I., Popov, I. F., & Sakun, V. A. (1986). Agricultural machines: theory of operation, computation of controlling parameters, and the conditions of operation. Rotterdam: A. A. Balkema Pub. Kofoed, S. S. (1969). Kinematics and power requirement of oscillating tillage-tool. Journal of Agricultural Engineering, 14(1), 54-73. Martinez, E., Fuents, J. P., & Silva, P. (2008). Soil physical and wheat root growth as affected by no tillage and conventional tillage systems in a Mediterranean environment of chile. Soil and Tillage Research, 99, 22-244. Modaress Razavi, M. (2010). Farm machinery management. Mashhad Ferdowsi University Pub. (in Persian) Moeenifar, A., Mousavi-seyedi, S. R., & Kalantari, D. (2014). Influence of tillage depth, penetration angle and forward speed on the soil/thin-blade interaction force. Agricultural Engineering International: CIGR Journal, 16(1), 69-74. Niapama, T., & Salokhe, V. M. (1993). Laboratory investigations into soil failure under vibratory tillage tools. Journal of Terramechanics, 30(6), 395-403. Niapama, T., & Salokhe, V.M. (2000b). Force and pressure distribution under vibratory tillage tool. Journal of Terramechanics, 37(2), 139-150. Ogbeche, O. S., & Idowu, M. S. (2016). Design steps of narrow tillage tools for draught reduction and increased soil disruption – A review. Agricultural Engineering International: CIGR Journal, 18(1), 91-102. Radite, P. A. S., Hermawan Mulyana, W., Rizkianda, A. B., & Crosby, H. B. (2010). Experimental investigation on the application of vibration to reduce draft requirement of subsoiler. International Agricultural Engineering Journal, 19(1), 31-38. Reshad Sedghi, A., & Loghavi, M. (2009). The effect of soil moisture content (in primery tillage) and travel speed during disking operation on performance of dick harrow as a secondary tillage tool. Biosystms Engineering, 40(2), 131-138. (in Persian) Reynolds Chávez, A., Campos Magana, G., Cadena Zapata, M., López, A., & Cuervo Pina, N. (2015). Vertical tillage parameters to optimize energy consumption. CIGR Journal, 17(4), 130-140. Sadaghi, R., & Abbaspour, Y. (2014). Prediction of soil fragmentation during tillage operations using fuzzy-neural inference system (ANFIS). Journal of Agricultural Machinery, 4(2), 387-398. (in Persian) Sahaya, C. S., Thomasb, E. V., & Satapathyc, K. K. (2009). Performance evaluation of a novel power-tiller-operated oscillatory tillage implement for dry land tillage. Biosystms Engineering, 102(4), 385-391. Shahgoli, G., Fielke, J., Dcsbiolles, J., & Saunders, C. (2010). Optimising oscillation frequency in oscillatory tillage. Soil and Tillage Research, 106(2), 202-210. Shahidy, K., & Ahmadi Moghaddam, P. (2006). Soil and machine. Oroumie University Pub. (in Persian) Soehne, W. H. (1963). Aspects of tillage. Canadian Agricultural Engineering, 5(1), 2-3. Soeharsono, P., & Setiawan, R. A. (2010). Analytical study of self-excited vibration on single degree of freedom vibratory-tillage. Journal of Engineering and Applied Sciences, 5(6), 61-66. Solhjou, A., & Alavimanesh, S. M. (2020). Effect of soil moisture content, forward speed and bent leg blade spaces on soil pulverization. Agricultural Mechanization and Systems Research, 20(73), 83-92. Szabo, B., Barnes, F., Sture, S., & Ko, J. H. (1998). Effectiveness of vibrating bulldozer and plow blades on draft force reduction. American Society of Agricultural Engineering (ASAE), 41(2), 283-290. Teschke, K. Nicol, A. M., Davies, H., & Ju, S. (1999). Whole body vibration and back disorders among motor vehicle drivers and heavy equipment operators: A review of the scientific evidence, Vacouver, British Columbia. Biosystms Engineering, 65, 375-383. Upadhyaya, S. K., Williams, T. H., Kemble, L. J., & Collins, N. E. (1984). Energy requirements for chiseling in Coastal Plain soils. Transaction of the American Society of Agricultural Engineering (ASAE), 27, 1643-1649. Wolf, D., Garner. T. H., & Davis, J. W. (1981). Tillage mechanical energy input and soil – crop response. Transaction of the American Society of Agricultural Engineering (ASAE), 24, 1412-1419. Xin, L., Liang, J., & Qiu, L. (2013). Dynamic analysis and experimental research of vibratory subsoiler system. Journal of Theoretical and Applied Information Technology, 48(2), 1195-1201. | ||
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