In family farming, mechanisation, when appropriate to the task and to the size of the property, can be one way of easing tiring and repetitive work, such as garlic harvesting. The present study is based on a model of harvester currently on the market, and proposes several improvements for mechanising the harvest on family farms, with an emphasis on sloping terrain, to reduce costs and increase productivity. Since the equipment currently on the market reduces the operational performance of these producers resulting in the high prices of commercial garlic, the aim of this study was to evaluate, using the Finite Element Method, the von Mises stresses and the displacement of a garlic harvester in different topographies. A structural analysis was carried out, and the vibration modules in the three main parts that make up the structure of the garlic harvester were checked: the structure supporting the scarifier point, the structure of the plant transport system, and the structure at the rear of the harvester. The structural modifications that were implemented corrected the initial high-stress conditions, showing improvements in stress concentration and areas of displacement. As such, the entire structure of the garlic harvester tends to withstand the proposed loads. From the results of the simulations, we conclude that the connecting support may undergo greater response from structural dynamics, and that frequencies greater than 45.7 Hz should be avoided since there are several natural frequencies above this range that might cause interference to the structure.

AMERICAN WELDING SOCIETY (AWS). Código de Soldagem Estrutural – Aço. AWSD 1.1., 22 ed., 2010.

ANSYS, I. Ansys ls-dyna user’s guide. Canonsburg: ANSYS, Inc, 2014.

BELTRAME, T. F.; SCHMIDT, A. S. Development of product and innovation: mechanized system for garlic culture (Allium sativum L.). Revista Espacios, v. 34, n. 6, p. 11, 2013.

CASTRO, R. et al. Projeto conceitual da estrutura mecânica para testes do sistema hidráulico do levante de máquinas agrícolas. Revista Ciência e Tecnologia, v. 19, n. 34, 2016.

CELY, M. et al. Identificación de defectos en soldaduras de acero estructural ASTM A36 mediante ensayos no destructivos según el código AWS D1.1. Revista Puce, n. 106, p. 81-109, 2018.

CRUZ, A. S. et al. Uma abordagem da importância do alho (Allium sativum) no sistema imunológico. Multidisciplinary Scientific Journal, v. 5, n. 4, p. 65-71, 2019.

CUNHA, J. P. A. R.; DUARTE, M. A. V.; RODRIGUES, J. C. Avaliação dos níveis de vibração e ruído emitidos por um trator agrícola em preparo de solo. Pesquisa Agropecuária Tropical, v. 39, n. 4, p. 348-355, 2009.

FERREIRA, L. G. J. et al. Recommendation for Mechanical harvesting of coffee based on vibration behavior settings rods harvester. Ciências Rural, v. 46, p. 273-278, 2016.

FILGUEIRA, F. A. Novo manual de olericultura: Agrotecnologia moderna na produção e comercialização de hortaliças. 3. ed. Viçosa: Editora UFV, 2013.

HIBBELER, R. C. Resistência dos Materiais. 7 ed. São Paulo: Pearson, 2010.

HÖFG, P.; ARAÚJO, C. F. J. Classes de declividade do terreno e potencial para mecanização no estado do Paraná. The Open Mechanical Engineering Journal, v. 10, n. 2, p. 195-203, 2014.

MAAS, L.; MALVESTITI, R.; GONTIJO, L. A. Results of lack of policies to encourage urban organic farming: a case study in two Brazilian cities. Reports in Public Healths, v. 36, n. 8, online, 2020.

MADENCI, E.; GUVEN, I. The finite element method and applications in engineering using ANSYS R. Springer. 1. Ed. London UK: 2015. 657 p.

MION, R. L. et al. Soil tensions from different pressures caused by farm tractor tires. Engenharia Agrícola, v. 36, n. 1, online, 2016.

NIEMCZEWSKI, B. K. et al. Validação de um modelo de cálculo por elementos finitos do chassi de uma semeadora de quatro linhas. Engenharia Agrícola, v. 34, p. 161-170, 2014.

PEGORORO, M.; GOMES, F. A. A.; NOVAK, P.R. Study of modal analysis based on fluid-structure interaction. Ibracon Structures and Materials Journal, v. 11, p. 1391-1417, 2018.

ROZENFELD, N. et al. Gestão de desenvolvimento de produtos: uma referência para a melhoria do processo. Ed. 5. Saraiva: São Paulo (SP), 2010. 576 p.

SILVA, E. P. et al. Structural static and modal frequency simulation in a coffee harvester’s chassis. Revista Brasileira de Engenharia Agrícola e Ambiental, v. 22, n. 7, p. 511-515, 2018.

SOUZA, V. H. S. et al. Evaluation of the interaction between a harvester rod and a coffee branch based on finite element analysis. Computers and Electronics in Agriculture, v. 150, p. 476-483, 2018.

VELLOSO, N. S. et al. Modal properties of coffee plants via numerical simulation. Computer and Electronics in Agriculture, v. 175, e105552, 2020.