Study on the Shear and Bending Mechanical Properties of Millet Stem

Wang, Wei; Wang, Zeze; Pan, Ben; Cui, Qingliang; Zhang, Lili; Qiu, Shujin; Zhang, Yanqing

doi:10.3390/agriculture14060923

Agriculture

2024

DOI: 10.3390/agriculture14060923

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Study on the Shear and Bending Mechanical Properties of Millet Stem

Wei Wang,

Zeze Wang,

Ben Pan

et al.

Abstract: To determine the patterns and influencing factors of the mechanical properties of millet stems from different varieties during the maturity period, this study employed a complete block experiment method and conducted shearing and bending tests on millet stems using the INSTRON5544 electronic universal material testing machine. The research investigated the variation in the shear strength, specific shear energy, bending strength, elastic modulus, and bending stiffness at different internode positions of the ste… Show more

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Cited by 2 publications

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Research on the Tensile and Impact Mechanical Properties of Millet Ear Petals

Qiu,

Pan,

Wang

et al. 2024

Agriculture

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In response to the low threshing efficiency of millet ear petals, this study investigated the tensile and impact mechanical properties of millet petals during the millet threshing process. Jingu 21, Zhangza 16, and Changza 466 were used as experimental subjects to study the effects of tensile angle and growth part on fracture strength, and to determine the influence of impulse and growth part on drop and breakage rates. The results indicated that both growth part and tensile angle have a highly significant impact on the tensile fracture strength of the millet petals. The tensile fracture strength decreases with the increase in the tensile angle, and increases with the growth part from top to bottom. The variety, growth part, and impulse significantly affect the impact drop and breakage rates of the millet petals, with the main factors affecting the drop rate being impulse, variety, and growth part, in that order. When the impulse is 2.296 N·s, the threshing effect for Jingu 21 is optimal, with a drop rate of 65.091% and a breakage rate of 13.487%. This research provides theoretical insights into the simulation of the millet ear threshing process and the optimization of the performance of millet threshing equipment.

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Research on the Tensile and Impact Mechanical Properties of Millet Ear Petals

Qiu,

Pan,

Wang

et al. 2024

Agriculture

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Tomato Pedicel Physical Characterization for Fruit-Pedicel Separation Tomato Harvesting Robot

Weng,

He,

Zheng

et al. 2024

Agronomy

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To solve the problem of the lack of physical properties of pedicels and the changing pattern for designing the end-effector of tomato harvesting robot and different harvesting modes, research was conducted on the physical properties of tomato pedicels and their change patterns. Using a Universal TA texture analyzer, tensile, three-point bending, and shearing tests were performed on tomato pedicels in the early firm-ripening stage. The tomato variety used was Syngenta Spectrum, cultivated seasonally with two crops per year. Spring crop tomatoes were used in this study. The experimental results provide a theoretical basis for designing tomato harvesting robots across three harvesting modes. Tensile tests measured the pull-off force and tensile strength of the abscission zone with varying diameters. These results are crucial for designing robots using a tensile harvesting mode. The location of the tomato pedicel significantly affects the shearing force. A one-way test was conducted on the shearing part. The results showed that the shearing force and energy required for the proximal pedicel are significantly greater than for the distal pedicel. To reduce the shearing force and energy needed by the end-effector’s shearing mechanism on distal pedicels, a response surface test was conducted. Three factors were examined: shearing speed, angle, and distal pedicel diameter. Design–Expert software optimized these factors to minimize shearing energy and force, leading to the best shearing parameters for different distal pedicel diameters. From the three-point bending tests, the average maximum bending breaking force, bending modulus, and bending strength of the tomato abscission zone were determined. These findings offer a theoretical basis for designing tomato harvesting robots with a bending-type harvesting mode.

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Study on the Shear and Bending Mechanical Properties of Millet Stem

Cited by 2 publications

References 14 publications

Research on the Tensile and Impact Mechanical Properties of Millet Ear Petals

Research on the Tensile and Impact Mechanical Properties of Millet Ear Petals

Tomato Pedicel Physical Characterization for Fruit-Pedicel Separation Tomato Harvesting Robot

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