Mechanical model for double side self-propelled rolling machine based on rigid and flexible contact dynamics
Keywords:
contact dynamics, solar greenhouse, self-propelled rolling machine, mechanical modelAbstract
The objective of the present research was to establish a mechanical model to study the performance of double side self-propelled rolling machine. There are two key models in the modeling process. The first model is the soft cover dynamics model, which is an important innovation in this study. And the insulation quilt was established based on the Macro-modeling technology. The second model is the double side self-propelled rolling machine virtual prototype model. By specifying multiple contact constraints and loadings between the soft cover dynamics model and the rigid component, the virtual prototype model was built successfully and the double side self-propelled rolling process was completely simulated. Moreover, the interaction mechanisms of the rigid and flexible coupling mechanics were investigated. The virtual rolling processes of different insulation quilt lengths were analyzed under different thickness treatments. The simulated results showed a good agreement with the experiment measurements, which suggested that the established model is an effective approach to evaluate and optimize the rolling machine. The successful establishment of the mechanical model can facilitate the study of the performance of the product and further optimization, and also is of great significance to shorten the development cycle and reduce costs. Keywords: contact dynamics, solar greenhouse, self-propelled rolling machine, mechanical model DOI: 10.25165/j.ijabe.20221506.6485 Citation: Li Y M, Liu Y, Yue X, Li Z Q, Liu X A, Li T L. Mechanical model for double side self-propelled rolling machine based on rigid and flexible contact dynamics. Int J Agric & Biol Eng, 2022; 15(6): 38–43.References
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[3] Wang Y, Liu L, Hou J L, Wei M, Wang X F. Development of intelligent solar greenhouse curtain roller. Shandong Agricultural Science, 2014; 46(5): 21–25. (in Chinese)
[4] Gu J H. Study on the role of curtain roller in facility agriculture. Agricultural Science-Technology and Information, 2017; 12: 45–46. (in Chinese)
[5] Liu M G, Wang Y H, Ye Q N. Application research of curtain rolling machine in Liaoning facility agriculture. Agricultural Science& Technology and Equipment, 2012; 4: 66–67. (in Chinese)
[6] Ding X M. Research and development on exterior cover-rolling machine of solar greenhouse in China. Journal of Agricultural Mechanization Research, 2011; 33(12): 217–222. (in Chinese)
[7] Zhang S Q. Causes and preventive measures of running deviation of curtain roller in solar greenhouse. Farm Machinery, 2019; 2: 95–97. (in Chinese)
[8] Cui Y X, Zhao L, Zhao H F, Pan D F, Yang R. Research on current situation and development of control technology of solar greenhouse shutter machine. Agricultural Technology and Equipment, 2019; 4: 50–51. (in Chinese)
[9] Zhang G X, Fu Z T, Li X X, Yan J, Yang H, Zhang L X. Design and experiment of the rear fixed type rolling shutter device in solar greenhouse. Transaction of the CSAM, 2016; 47(12): 299–308. (in Chinese)
[10] Yuan Y W, Ma Y J, Yi J G, Kong D G, Liu J T, Li S S. Development of seamless curtain rolling machine for solar greenhouse. Journal of Agricultural Mechanization Research, 2017; 39(6): 140–144. (in Chinese)
[11] Yin J J, Gao Q, Chen Y M. Research on virtual knotting method of knotting machine based on rigid and flexible contact dynamics. Transactions of the CSAM, 2016; 47(9): 85–92. (in Chinese)
[12] Ma X F. Modeling and simulation based on ADAMS for elevator wire rope system. Journal of Hunan Institute of Engineering (Natural Science Edition), 2016; 26(3): 32–36. (in Chinese)
[13] Yuan J J, Wang J T, Guo W J. Study on modeling of material conveying machinery based on ADAMS macro programs. Equipment Manufacturing Technology, 2018; 10: 140–144. (in Chinese)
[14] Du Z X, Liu M D. Study on modeling the cable system of bridge tower testing machine based on ADAMS macro programs. Machine Design and Research, 2013; 29(6): 140–143. (in Chinese)
[15] Pu M H, Wu Jiang. Study on multi-body dynamics model of chain drive based on ADAMS. Mechanical Design and Research, 2008; 24(2): 57–59. (in Chinese)
[16] Li Z J, Song S Y. Modeling and simulation of roll film based on ADAMS. Journal of Wuhan University of Light Industry, 2014; 33(4): 54–57, 67. (in Chinese)
[17] Li Z J, Song S Y. Roll film modeling and dynamics simulation based on ANSYS. Packaging Engineering, 2015; 36(7): 31–35. (in Chinese)
[18] Shi M Q. Research on multi-contact problem based on ADAMS. Computer Engineering and Application, 2004; 29: 220–222. (in Chinese)
[19] Shi M Q, Zhang P, Fan S Q, Liu Q. Computational efficiency for dynamic simulation based on multi-contact mechanical system. Journal of Mechanical Engineering, 2010; 46(7): 108–113. (in Chinese)
[20] Fang X F, Wu H T, Liu Y P, Lu Y P, Wang T Y. Calculation of multi-body system dynamics modeling based on the theory of spatial operator algebra. Journal of Mechanical Engineering, 2009; 45(1): 228–234. (in Chinese)
[21] Mocera F, Nicolini A. Multibody simulation of a small size farming tracked vehicle. Procedia Structural Integrity, 2018; 8: 118–125.
[22] Klisch T. Contact mechanics in multibody systems. Mechanism and Machine Theory, 1999; 34(5): 665–675.
[23] Zhang G X, Liu X X, Fu Z T, Stankovski S, Dong Y H, Li X X. Precise measurements and control of the position of the rolling shutter and rolling film in a solar greenhouse. Journal of Cleaner Production, 2019; 228: 645–657.
[24] Meng X Z, Li S L. Theoretical analysis of work load of solar greenhouse curtain roller. Mechanization of Rural Pastoral Areas, 2009; 4: 13–17. (in Chinese)
[25] Sun H, Teng G H, Zhang X F, He G R. Design and test on real-time measurement system of mat roller workload for sunlight greenhouse. Transaction of the CSAE, 2014; 30(1): 138–145. (in Chinese)
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Published
2022-12-27
How to Cite
Li, Y., Liu, Y., Yue, X., Li, Z., Liu, X., & Li, T. (2022). Mechanical model for double side self-propelled rolling machine based on rigid and flexible contact dynamics. International Journal of Agricultural and Biological Engineering, 15(6), 38–43. Retrieved from https://ijabe.migration.pkpps03.publicknowledgeproject.org/index.php/ijabe/article/view/6485
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Animal, Plant and Facility Systems
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