Design and experimental verification of the picking cam mechanism for safflower filaments

Design and experimental verification of the picking cam mechanism for safflower filaments

A picking head for automated harvesting of safflower filaments is designed to address the low manual harvesting efficiency and scarce automatic harvesting machinery. Based on the cluster growth characteristics of safflower filaments and the requirements for filament harvesting, the key structures an...

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Bibliographic Details
Main Authors: Chen Bangbang, Ding Feng, Ma Baojian, Liu Xiangdong, Ning Shanping
Format: Article
Language:English
Published: EDP Sciences 2024-01-01
Series:Mechanics & Industry
Subjects:
safflower filaments
cam
picking head
cutting
design experiment
Online Access:https://www.mechanics-industry.org/articles/meca/full_html/2024/01/mi240031/mi240031.html
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Summary:A picking head for automated harvesting of safflower filaments is designed to address the low manual harvesting efficiency and scarce automatic harvesting machinery. Based on the cluster growth characteristics of safflower filaments and the requirements for filament harvesting, the key structures and parameter ranges of the “∞”-shaped cam and cutting tools are established. Using ANSYS/LS-DYNA simulation analysis, the effects of the blade edge angle, cutting inclination, and cutting speed on the mechanical properties during filament cutting are explored. After that, a safflower filament picking head cutting test bench is built. Using the Central Composite Design method, a regression model between different test factors and indicators is established, and the response surface analysis and parameter optimization are performed for the interacting factors. The optimal parameters are a cam rotational speed of 32.6 r/min, a blade edge angle of 22.5°, and a cutting inclination of 19.6°. Five repeated bench tests are conducted using these parameters for verification. The experiments show that the average success rate of cutting filaments is 90.5%, and the error between the experimental and theoretical optimal values does not exceed 2.5%. The optimization model is reasonable and feasible, meeting the design requirements of the cutting of the safflower filament picking head. The results can provide a reference for the design and development of automated safflower harvesting devices.
ISSN:2257-7777
2257-7750

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