{"title":"Effects of Rotary Tine Tool Velocity on Soil Reaction Forces, Power, and Energy Intensity","authors":"Safal Kshetri, B. Steward, M. Tekeste","doi":"10.13031/ja.15377","DOIUrl":null,"url":null,"abstract":"Highlights Draft force and torque on a vertical rotary tine tool were studied for various longitudinal velocities and speed ratios. Draft force increased with longitudinal velocity but decreased with speed ratio, and soil reaction torque increased with both longitudinal velocity and speed ratio. Total power required by the tool increased with speed ratio, and energy intensity increased with speed ratio and longitudinal velocity, with substantial changes observed at higher velocities. Abstract. Studying soil-tool interaction can provide valuable information on the actuation force and energy requirements of a weeding tool operating in soil. Soil-tine interaction was investigated for a vertical rotary tine tool that was intended to be used as a weeding tool for an automated mechanical intra-row weeder. The main objective of the research was to investigate the effects of linear and rotational velocities on soil reaction forces and power associated with actuation of the rotary tine tool in soil. A series of soil bin experiments were conducted in loam soil. Soil horizontal (draft) force and torque on the tool were measured at three longitudinal/travel velocities of 0.09 m s-1, 0.29 m s-1, and 0.5 m s-1 that were used to move the tool linearly across the soil bin length. The speed ratio, defined as the ratio of the longitudinal velocity to the peripheral velocity of the rotary tines, determined the rotational speeds required for the study. The draft force and torque were evaluated at four speed ratio levels (0, 1, 1.5, and 2). An Analysis of Variance (ANOVA) performed for statistical analysis using p < 0.05 showed that both longitudinal velocity and speed ratio had significant main and interaction effects on the draft force and torque. In most cases, the draft force decreased while torque increased with increasing speed ratios for the different longitudinal velocities used in the study. Power and energy intensity were also calculated using draft force and torque measurements for different experimental settings. For increases in speed ratios, the power requirements for tool draft force decreased, whereas the power requirements for rotating the tool increased for each longitudinal velocity. At the highest test travel speed of 0.5 m s-1, the power decreased from 66 W to 28 W for draft and increased from 0 W to 76 W for rotation of the tool at increasing speed ratios. The maximum total power calculated for the tool was 110 W at 0.5 m s-1 and a speed ratio of 2. The study shows the changes in power and energy requirements of a vertical rotary tine tool for different operating parameters for weed control. This information could be valuable for optimizing the physical weeding process. Keywords: Energy intensity, Power, Rotary tool, Soil-tine interaction, Weed control.","PeriodicalId":29714,"journal":{"name":"Journal of the ASABE","volume":"56 1","pages":""},"PeriodicalIF":1.2000,"publicationDate":"2023-01-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Journal of the ASABE","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.13031/ja.15377","RegionNum":4,"RegionCategory":"农林科学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q3","JCRName":"AGRICULTURAL ENGINEERING","Score":null,"Total":0}
引用次数: 0
Abstract
Highlights Draft force and torque on a vertical rotary tine tool were studied for various longitudinal velocities and speed ratios. Draft force increased with longitudinal velocity but decreased with speed ratio, and soil reaction torque increased with both longitudinal velocity and speed ratio. Total power required by the tool increased with speed ratio, and energy intensity increased with speed ratio and longitudinal velocity, with substantial changes observed at higher velocities. Abstract. Studying soil-tool interaction can provide valuable information on the actuation force and energy requirements of a weeding tool operating in soil. Soil-tine interaction was investigated for a vertical rotary tine tool that was intended to be used as a weeding tool for an automated mechanical intra-row weeder. The main objective of the research was to investigate the effects of linear and rotational velocities on soil reaction forces and power associated with actuation of the rotary tine tool in soil. A series of soil bin experiments were conducted in loam soil. Soil horizontal (draft) force and torque on the tool were measured at three longitudinal/travel velocities of 0.09 m s-1, 0.29 m s-1, and 0.5 m s-1 that were used to move the tool linearly across the soil bin length. The speed ratio, defined as the ratio of the longitudinal velocity to the peripheral velocity of the rotary tines, determined the rotational speeds required for the study. The draft force and torque were evaluated at four speed ratio levels (0, 1, 1.5, and 2). An Analysis of Variance (ANOVA) performed for statistical analysis using p < 0.05 showed that both longitudinal velocity and speed ratio had significant main and interaction effects on the draft force and torque. In most cases, the draft force decreased while torque increased with increasing speed ratios for the different longitudinal velocities used in the study. Power and energy intensity were also calculated using draft force and torque measurements for different experimental settings. For increases in speed ratios, the power requirements for tool draft force decreased, whereas the power requirements for rotating the tool increased for each longitudinal velocity. At the highest test travel speed of 0.5 m s-1, the power decreased from 66 W to 28 W for draft and increased from 0 W to 76 W for rotation of the tool at increasing speed ratios. The maximum total power calculated for the tool was 110 W at 0.5 m s-1 and a speed ratio of 2. The study shows the changes in power and energy requirements of a vertical rotary tine tool for different operating parameters for weed control. This information could be valuable for optimizing the physical weeding process. Keywords: Energy intensity, Power, Rotary tool, Soil-tine interaction, Weed control.
在不同的纵向速度和速比下,研究了垂直旋转刀具的牵伸力和扭矩。牵引力随纵速增大而增大,随速比增大而减小,土反力随纵速和速比增大而增大。工具所需的总功率随着速比的增加而增加,能量强度随着速比和纵向速度的增加而增加,在较高的速度下观察到明显的变化。摘要研究土-工具的相互作用可以为除草工具在土壤中工作的驱动力和能量需求提供有价值的信息。研究了一种垂直旋转时间工具的土壤-时间相互作用,该工具打算用作自动机械行内除草机的除草工具。该研究的主要目的是研究线速度和旋转速度对土壤反作用力和与土壤中旋转时间工具驱动相关的功率的影响。在壤土中进行了一系列土仓试验。在0.09 m s-1、0.29 m s-1和0.5 m s-1的三种纵向/行程速度下,测量了工具上的土壤水平(吃水)力和扭矩,这些速度用于将工具线性地移动到土壤桶的长度上。速比,定义为纵向速度与旋转时间的外围速度之比,决定了研究所需的转速。在4个速比水平(0、1、1.5和2)下评估牵伸力和扭矩。采用p < 0.05的方差分析(ANOVA)进行统计分析,结果表明纵向速度和速比对牵伸力和扭矩有显著的主效应和交互效应。在大多数情况下,随着研究中使用的不同纵向速度的速比的增加,吃水力减小而扭矩增大。功率和能量强度也通过不同实验设置下的牵引力和扭矩测量来计算。随着速比的增加,刀具牵伸力的功率要求降低,而旋转刀具的功率要求在每个纵向速度下都增加。在最高测试行程速度为0.5 m s-1时,吃水功率从66 W下降到28 W,随着速度比的增加,刀具的旋转功率从0 W增加到76 W。该工具在0.5 m s-1和2速比下的最大总功率为110 W。该研究显示了不同操作参数下垂直旋转时间工具的功率和能量需求的变化。这些信息对于优化物理除草过程是有价值的。关键词:能量强度,动力,旋转工具,土-时相互作用,杂草控制。