Dynamic Behavior of Coffee Branches: an Analysis Using the Finite Element Method

Melo Junior, Wellington Washington Andrade de; Santos, Fábio Lúcio; Scinocca, Francisco; Rosa, Pablo Antunes da; Magalhães, Ricardo Rodrigues

doi:10.1590/1678-4324-2024220331

Braz. arch. biol. technol.

2024

DOI: 10.1590/1678-4324-2024220331

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Dynamic Behavior of Coffee Branches: an Analysis Using the Finite Element Method

Wellington Washington Andrade de Melo Junior,

Fábio Lúcio Santos,

Francisco Scinocca

et al.

Abstract: The use of computational simulation techniques is an important tool for the coffee harvesting issues, particularly the finite element method. The method is widely used in the structural analysis of agricultural machinery, as well as in the analysis of the stresses and vibrations of coffee branches and peduncles during the harvesting process. The present study aimed to develop three-dimensional finite element models of the plagiotropic branches of the Catuaí Vermelho variety of Arabica coffee in different posit… Show more

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Tool–Branch Interaction Mechanism of Impact-Pruning Process Based on Finite Element Method

Liu,

Ban,

Zhang

et al. 2024

Forests

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This study addresses the necessity for a more profound comprehension of the mechanical behavior and fracture mechanisms of tree branches during impact pruning. The methodologies of the research are to develop a failure model of impact-cutting mechanics and a tool–branch interaction model using the finite element method (FEM). The validation of the model was conducted through the measurement of cutting forces and cross-sectional morphology in the field. A comparative analysis between experimental and simulation data revealed an average relative error below 15% for cutting force and below 10% for the cross-sectional ratio, thereby confirming the accuracy of the model. The findings indicate the presence of plastic deformation within the cutting zone, with elastic deformation prevailing in the surrounding region. As the branch approaches the yield point, the phenomenon of plastic deformation intensifies, resulting in a notable increase in internal energy demands, particularly in larger branches. The optimal pruning diameter was identified as 15 mm. An increase in cutting velocity raises the peak cutting force by 460.9 N per m/s, while a 1° increase in the blade wedge angle adds 34.9 N. A reduction in normal stress by increasing the tool back angle improves energy efficiency. This study provides insights to optimize pruning practices, enhancing efficiency and precision.

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Tool–Branch Interaction Mechanism of Impact-Pruning Process Based on Finite Element Method

Liu,

Ban,

Zhang

et al. 2024

Forests

View full text Add to dashboard Cite

show abstract

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Dynamic Behavior of Coffee Branches: an Analysis Using the Finite Element Method

Cited by 1 publication

References 27 publications

Tool–Branch Interaction Mechanism of Impact-Pruning Process Based on Finite Element Method

Tool–Branch Interaction Mechanism of Impact-Pruning Process Based on Finite Element Method

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