https://doi.org/10.4081/jae.2024.1557
Structural strength analysis of a rotary drum mower during harvesting
Published: 16 February 2024
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All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article or claim that may be made by its manufacturer is not guaranteed or endorsed by the publisher.
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A rotary drum mower (RDM) is a tractor-mounted mechanism used for harvesting green fodder crops. It faces dynamic forces from rough field surfaces and cutting resistance, posing design challenges and potential failures. This study aims to present a well-designed procedure for analyzing the structural strength of an RDM during harvesting, employing both experimental and engineering simulation methods. A specific harvesting scenario was created to simulate realistic load conditions. Experimental testing and advanced computer-aided engineering (CAE) simulations were conducted. Tractor power take-off torque measurements during harvesting revealed values of 231.07 Nm, 264.44 Nm, and 269.39 Nm at speeds of 8.56 km h-1, 12.6 km h-1, and 16.23 km h-1, respectively. Finite element analysis (FEA) was conducted to determine stress levels in the RDM components (RDM165-A- 004, RDM165-B-003, and RDM165-B-004). The FEA stress results ranged from 5.070 MPa to 20.600 MPa, 13.800 MPa to 28.600 MPa, and 5.400 MPa to 27.550 MPa, respectively. Experimental testing yielded stress results ranging from 2.127 MPa to 18.600 MPa, 14.618 MPa to 33.229 MPa, and 8.838 MPa to 31.248 MPa, respectively. The comparison between experimental and FEA results showed a reasonable correlation. FEA visual outputs provided insights into the maximum equivalent stress and deformation distributions on the RDM, with no indications of failure in the machine’s structure observed in either the experimental or numerical analyses. In conclusion, this study demonstrates that the machine analyzed operates safely under harvesting conditions. Moreover, the combination of experimental and advanced CAE methodologies presented in this research offers a valuable approach for future investigations into the complex stress and deformation evaluations of rotary drum mowers.
ANSYS Product Doc. 2019. ANSYS Meshing User’s Guide: Skewness (Release 2019 R2). ANSYS Inc., USA. Available from: https://ansyshelp.ansys.com/account/secured?returnurl=/Views/Secured/corp/v191/wb2_help/wb2_help.html
Arac I. 2001. A research on comparison of different type mowers’ performances (In Turkish). Yüzüncü Yıl University.
Ariza O., Gilchrist S., Widmer R.P., Guy P., Ferguson S.J., Cripton P.A., Helgason B. 2015. Comparison of explicit finite element and mechanical simulation of the proximal femur during dynamic drop-tower testing. J. Biomech. 48:224-32.
ASAE D497.7. 2011. Agricultural Machinery Management Data, 5. Available from: https://elibrary.asabe.org/abstract.asp?aid=36431&t=2
Bi Z. 2021. Practical Guide to Digital Manufacturing. In Practical Guide to Digital Manufacturing. Springer Int. Pub. Available from: https://doi.org/10.1007/978-3-030-70304-2
Bringas J.E. 2016. Handbook of Comparative World Steel Standards, 5th Edition. In J. E. Bringas (Ed.), Handbook of Comparative World Steel Standards, 5th Edition. ASTM Int. Available from: https://doi.org/10.1520/ds67d-eb
Caliskan K. 2011. The optimisation of cab protective structure with finite element method simulation verified with laboratory tests (Ph.D. Thesis) (In Turkish). Ege University. Available from: https://tez.yok.gov.tr/UlusalTezMerkezi/tezDetay.jsp?id=f_L98Wo9ne6PuW845lYkJA&no=X5TeCmvjv3KhzPYCXMB-IA
Cardarelli F. 2008. Materials Handbook: A Concise Desktop Reference. Materials Handbook (2nd ed.). London: Springer.
Celik H.K., Akinci I. 2015. Analytical and Finite Element Method Based Stress Analysis of the Motion Transmission Axels of A Rotary Drum Mower (in Turkish). J. Agric. Mach. Sci. 11:247-55.
Celik H.K., Akinci I. 2016. Analytical and Finite Element Method Based Stress Analysis of Rotary Elements: Case Study for the Motion Transmission Gears of a Rotary Drum Mower. J. Fail. Anal. Prev. 16:293-301.
Celik H.K., Caglayan N., Çinar R., Ucar M., Ersoy H., Rennie A.E.W. 2012. Stress analysis of a sample marine crane’s boom under static loading condition. Proceeding of 5th International Mechanical Engineering Forum 2012, June 20th 22nd, 246-55.
Celik H.K., Caglayan N., Topakci M., Rennie A.E.W., Akinci I. 2020. Strength-based design analysis of a Para-Plow tillage tool. Comput. Electron. Agric. 169.
Celik H.K., Rennie A.E.W., Akinci I. 2017. Design and structural optimisation of a tractor mounted telescopic boom crane. J. Braz. Soc. Mech. Sci. Eng. 39:909-24.
Chakrabarty B.K. 2022. Integrated CAD by Optimization. In Integrated CAD by Optimization. Springer Int. Pub. Available from: https://doi.org/10.1007/978-3-030-99306-1
Davis J.R. 1998. Metals Handbook. Asm Intl. 2571. Day B., Field L., Jarvis A. 2009. The Wrest Park Story 1924-2006 (Chapter 7 Post harvest processing). Biosyst. Eng. 103:79-89. Degirmencioglu A. 2003. Determination of Stress Under Load on a Three-Bottom Moulboard Plough Research Project: 98ZRF046.
El-Baily M.M. 2022. A study of rotary drum mower blade wear and its effects on forage productivity. Poljoprivredna Tehnika. 47:87-100.
Eryürük Ş., Nesimioǧlu B.I.S., Altun H.O., Açikgöz H., Yumusąk S., Yildiz H.B., Cąlik A., Ethem Baǧriyanik O.İ. 2019. Research and Development Approaches and Implementation Issues in Agricultural Machinery Sector; Konya Case. Procedia Comput. Sci. 158:235-43.
HBM. 2011a. Datasheet: QuantumX MX840A. Doc. No: B2924-2.0 en (p. 16). Hottinger Baldwin Messtechnik GmbH. Available from: https://www.sensor-hbm.com/upload/productfile/b2924.pdf
HBM. 2011b. Strain Gages and Accessories. Doc. No: S 1265-1.0 en (p. 100). Hottinger Baldwin Messtechnik GmbH. http://www.hbm.ru/pic/pdf/1176378299.pdf
HBM Inc. 2022. DAQ Software, Data Acquisition Software, catman, HBM. Available from: https://www.hbm.com/en/2290/catman-data-acquisition-software/?product_type_no=DAQSoftware
Hoffmann K. 1989. An Introduction to Measurements using Strain Gages. Hottinger Baldwin Messtechnik GmbH. Available from: http://elektron.pol.lublin.pl/users/elekp/MNEQ_english/Hoffmann_An_Introduction_to_Measurements_using_Strain_Gages.pdf
Horrocks R.D., Valentine J.F. 2000. Harvested Forages. 1st ed. Crop Sci. 40.
Krutz G., Thompson L., Claar P. 1984. Design of agricultural machinery. In Design of Agric. Mach. John Wiley and Sons.
Kulaksiz O. 1995. Tables in Metal Profession (Metal Mesleğinde Tablolar). Turkish Republic Ministry of National Education.
Kuna M. 2013. Finite Elements in Fracture Mechanics. Springer Netherlands. 201.
Kurowski P., Szabo B. 1997. How to find errors in finite-element models. Mach. Des. 1:93-8.
Kutay G. 2003. The Machinist’s Guide (1st ed.). Birsen Publication.
Martinez-Valencia L., Camenzind D., Wigmosta M., Garcia-Perez M., Wolcott M. 2021. Biomass supply chain equipment for renewable fuels production: A review. Biomass Bioenergy. 148.
Mesa J.A., Gonzalez-Quiroga A., Aguiar M.F., Jugend D. 2022. Linking product design and durability: A review and research agenda. Heliyon 8:e10734.
MKE. 1978. MKE norm special steel types catalog (1st ed.). Machinery and Chemical Industry Corporation (MKE). Available from: https://books.google.com.tr/books/about/MKE_normu_özel_nitelikte_Çelik_türler.html?id=g6DsxAEACAAJ&redir_esc=y
Paraforos D.S., Griepentrog H.W., Vougioukas S.G. 2016. Methodology for designing accelerated structural durability tests on agricultural machinery. Biosyst. Eng. 149:24-37.
Rembold U., Nnaji B.O., Storr A. 1993. Computer Integrated Manufacturing and Engineering. J. Manuf. Syst. (1st ed.). Addison-Wesley Pub. Co.
Rice R.C., Jackson J.L., Bakuckas J., Thompson S. 2003. Metallic Materials Properties Development and Standardization (MMPDS) (Issue January). U.S. Department of Transportation Federal Aviation Administration.
Ruiz de Galarreta S., Jeffers J.R.T., Ghouse S. 2020. A validated finite element analysis procedure for porous structures. Mater. Des. 189:108546.
Sabanci A., Akinci İ. 2012. Agricultural Tractors ( In Turkish) (1st ed.). Nobel Academic Publication.
Srivastava A.K., Goering C.E., Rohrbach R.P., Buckmaster D.R. 2013. Engineering Principles of Agricultural Machines, Second Edition. Engineering Principles of Agricultural Machines, 2nd Edition.
Theunissen P. 2002. An Economical Approach to Agricultural Machinery Management (1st ed.). Computus Management Information (Pty) Ltd.
Torre R., Brischetto S. 2022. Experimental characterization and finite element validation of orthotropic 3D-printed polymeric parts. Int. J. Mech. Sci. 219:107095.
TRMoFAL. 2001. Measurement of the Agricultural Values - Technical Instruction for Alfalfa Plant (Medicago L. species) (In Turkish). Turkish Republic, Ministry of Food, Agriculture and Livestock.
TRMoNE. 2012. Fodder Plant Cultivation (Agricultural Technologies Lecture Notes) (In Turkish). TRMoNE: Turkish Republic Ministry of National Education. Available from: http://megep.meb.gov.tr/mte_program_modul/moduller_pdf/BaklagilYemBitkileriYetiştiriciliği1.pdf
Turker U. 1992. Determination of Cutting Resistance of Alfalfa plant (In Turkish). Akara University.
Vishay. 2007. M-Bond 200 Adhesive - Material safety datasheet (MSDS#MGM007T/.14027). Available from: https://louisville.edu/micronano/files/documents/safety-data-sheetssds/m-bond-200-adhesive/
Walters R.D. 2021. Technical Note 21. Soil, Draft, and Traction Tillage Tool. Core AgriSystems. Agrosphere Int. Group. 1:1-9.
Yuksel Tarim Inc. 2013. YUKSEL TARIM - Agricultural Machinery Inc. Available from: http://www.yukseltarim.com/
Yurdem H., Degirmencioglu A., Cakir E., Gulsoylu E. 2019. Measurement of strains induced on a three-bottom moldboard plough under load and comparisons with finite element simulations. Measurement. J. Int. Meas. Confed. 136:594-602.
How to Cite
Celik, H. K. (2024) “Structural strength analysis of a rotary drum mower during harvesting”, Journal of Agricultural Engineering, 55(1). doi: 10.4081/jae.2024.1557.
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