Response Characteristics of Harvester Bolts and the Establishment of the Strongest Response Structure’s Kinetic Model

Q2 Agricultural and Biological Sciences

Agriculture Pub Date : 2024-07-18 DOI:10.3390/agriculture14071174

Li Wang, Guoqiang Wang, Xujun Zhai, Zhong Tang, Bangzhui Wang, Pengcheng Li

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引用次数: 0

Abstract

The bolts and connections of each working part of a rice combine harvester can suffer from severe instantaneous impacts and alternating loads, and these strong impacts and loads cause instantaneous fracture and fatigue failure of the bolt face and even the loosening, detachment, and fracture of the bolt. The main vibration directions and the most complex vibration parts of the bolts and connections in the main working parts of a combine harvester under time-variable multiload excitation were obtained through the analysis of response signals in terms of time-domain and frequency–domain characteristics via a vibration response experiment. This study revealed that the random peak value of the vibrating screen is 12.5622, which is the severe impact and collision standard. For the vibrating screen, the local peak in the 4-Y direction was the main load of the destroying bolt connection (the impact reached 60.57 m/s2, 96.91 m/s2) and the vibration energy intensity in the 4-Z direction was mainly concentrated at 12.42 m/s2, which is the maximum vibration energy value in the three directions (the peak vibration value reached 109~115.68 m/s2), so the bolted connections of the vibrating screen are the most vulnerable to destruction. Therefore, a kinetic model and a microscopic response model of a vibrating screen were established via the centralized mass method to explore the kinetic response characteristics of bolted structures subjected to multiple excitation loads, thus providing a mathematical model for identifying the features of bolted connections based on static characteristics.

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收割机螺栓的反应特征和最强反应结构动力学模型的建立

水稻联合收割机各工作部位的螺栓和连接件会受到剧烈的瞬时冲击和交变载荷，这些强烈的冲击和载荷会导致螺栓面的瞬时断裂和疲劳失效，甚至造成螺栓的松动、脱落和断裂。通过振动响应实验分析响应信号的时域和频域特性，获得了联合收割机主要工作部件中螺栓和连接件在时变多负载激励下的主要振动方向和最复杂的振动部位。研究发现，振动筛的随机峰值为 12.5622，属于严重冲击和碰撞标准。对于振动筛而言，4-Y 方向的局部峰值是破坏螺栓连接的主要载荷（冲击力达到 60.57 m/s2、96.91 m/s2），4-Z 方向的振动能量强度主要集中在 12.42 m/s2，是三个方向的最大振动能量值（振动峰值达到 109~115.68 m/s2），因此振动筛的螺栓连接最容易受到破坏。因此，通过集中质量法建立了振动筛的动力学模型和微观响应模型，探讨了螺栓结构在多重激励载荷作用下的动力学响应特性，从而为根据静态特性识别螺栓连接的特征提供了数学模型。

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来源期刊

Agriculture Agricultural and Biological Sciences-Horticulture

CiteScore

1.90

自引率

0.00%

发文量

审稿时长

11 weeks

期刊介绍： The Agriculture (Poľnohospodárstvo) is a peer-reviewed international journal that publishes mainly original research papers. The journal examines various aspects of research and is devoted to the publication of papers dealing with the following subjects: plant nutrition, protection, breeding, genetics and biotechnology, quality of plant products, grassland, mountain agriculture and environment, soil science and conservation, mechanization and economics of plant production and other spheres of plant science. Journal is published 4 times per year.