Field Investigation of the Static Friction Characteristics of High-Yielding Rice during Harvest

Field Investigation of the Static Friction Characteristics of High-Yielding Rice during Harvest

Background: Following the popularization of high-yielding rice in China, fast and efficient mechanized harvesting proved challenging. In addition, the physical characteristics of rice grains and stems are substantially affected during harvest by the field environment and harvest time. However, the c...

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Bibliographic Details
Published in:Agriculture (Basel) Vol. 12; no. 3; p. 327
Main Authors: Ma, Zheng, Zhu, Yongle, Chen, Shuren, Traore, Souleymane Nfamoussa, Li, Yaoming, Xu, Lizhang, Shi, Maolin, Zhang, Qian
Format: Journal Article
Language:English
Published: Basel MDPI AG 01-03-2022
Subjects:
Agricultural equipment
Agricultural production
Biomedical materials
Climate change
Coefficient of friction
Combine harvesters
Design optimization
Design standards
Designers
Field investigations
field test
Friction
friction characteristics
Grain
Harvest
harvest stage
Harvesting
high-yielding rice
Investigations
Laboratories
Physical characteristics
Physical properties
Rice
Standardization
Static friction
Steel plates
Stems
China
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Summary:Background: Following the popularization of high-yielding rice in China, fast and efficient mechanized harvesting proved challenging. In addition, the physical characteristics of rice grains and stems are substantially affected during harvest by the field environment and harvest time. However, the combine harvester driver is focused on maximizing the outputs and does not consider the adverse effects of these factors during the rice harvest. Methods: We investigated the effects of the harvest time, spatial position, and temperature on the static friction coefficient of rice grains and stems of high-yielding rice using a field experiment. Results: The result difference in the static friction coefficient between the parallel and perpendicular placements of the rice stem on the steel plate was 9%, indicating that the contact configuration had a significant impact. The region, harvest time, and temperature significantly affected the static friction characteristics of the rice grains and stems. The most significant differences were observed in the X-direction. Conclusions: The optimum harvest time was 10:11 a.m.–3:30 p.m. and the optimum temperature was above 16.5 °C. A quantitative analysis of the effects of the harvest time and temperature on the static friction characteristics of rice provides reliable data for machine design optimization and standardization of harvests operations.
ISSN:2077-0472
2077-0472
DOI:10.3390/agriculture12030327