Optimization analysis and discrete element simulation of soilstraw mixed accumulation in smokeless wood ash furnace

doi:10.13733/j.jcam.issn.2095-5553.2025.05.032

Abstract

Abstract: Aiming at the problem of uneven accumulation of soilstraw in smokeless wood ash furnace, an optimization model of shovelloaded mixed accumulation based on discrete element was proposed. The loading and accumulation process of soilbroken straw in smokeless wood ash furnace was studied by shovelloaded operation. Taking the bucket height, the bucket attitude angle and the shovel tip speed as the test factors, and the flatness of the accumulation profile as the test index, the threefactor and threelevel orthogonal test was designed, and the regression model of the flatness of the accumulation profile was established to obtain the influence of the test factors on the test index. The results showed that the influence of shovel tip speed, bucket attitude angle and bucket height on the flatness of stacking profile was extremely significant (P<0.01), significant (0.01<P<0.05) and not significant (P>0.05), respectively. The three test factors were optimized, and the optimal parameter combination was obtained as follows: bucket height 0.549 m, bucket attitude angle 122.1°, bucket speed 0.598 m/s, and the optimal stacking profile flatness 236.742 mm. Using EDEM to validate the optimal parameter combination, the actual stacking contour flatness of the optimal parameter combination was 223.859 mm, with a relative error of 5.442% compared to the predicted value. This study can provide reference for the optimal design of linkage shovel loading mechanism.

Key words: smokeless wood ash furnace, soilstraw, discrete element, packing flatness, shovel loading, orthogonal test

摘要： 针对无烟草木灰炉内土壤—秸秆堆积不平整问题，构建基于离散元的铲装混合堆积优化模型，通过铲装作业方式研究土壤—碎秸秆在无烟草木灰炉中的装填堆积过程。以铲斗高度、铲斗姿态角和铲尖速度为试验因素，堆积轮廓平整度为试验指标，设计三因素三水平正交试验，建立堆积轮廓平整度回归模型得出试验因素对试验指标的影响情况。结果表明，铲尖速度、铲斗姿态角、铲斗高度对堆积轮廓平整度的影响分别为极显著（P<0.01）、显著（0.01<P<0.05）、不显著（P>0.05）。对3个试验因素进行优化设计，得到最优参数组合：铲斗高度为0.549 m，铲斗姿态角为122.1°，铲尖速度为0.598 m/s，最优堆积轮廓平整度为236.742 mm。利用EDEM对最优参数组合进行验证，得出在最优参数组合时实际堆积轮廓平整度为223.859 mm，与预测值相对误差为5.442%。为连杆式铲装机构的优化设计提供参考。

关键词: 无烟草木灰炉, 土壤—秸秆, 离散元, 堆积平整度, 铲装, 正交试验

CLC Number:

S226.5

Jiang Yunsheng, He Bowei, Lü Qundan, Zhang Lei, , Liu Yang, Zhou Heng. Optimization analysis and discrete element simulation of soilstraw mixed accumulation in smokeless wood ash furnace [J]. Journal of Chinese Agricultural Mechanization, 2025, 46(5): 235-241.

蒋云胜, 何伯伟, 吕群丹, 张雷, , 刘洋, 周恒. 无烟草木灰炉土壤—秸秆混合堆积优化分析与离散元仿真[J]. 中国农机化学报, 2025, 46(5): 235-241.

References

［1］　王颖洁, 张朋, 宋晨愿, 等. 秸秆生物质综合利用的现状分析［J］. 现代农业, 2023, 48（4）: 108-112.
Wang Yingjie, Zhang Peng, Song Chenyuan, et al. Analysis on the current situation of comprehensive utilization of straw biomass ［J］. Modern Agriculture, 2023, 48（4）: 108-112.
［2］　王毅, 张俊清, 况帅, 等. 施用小麦秸秆或其生物炭对烟田土壤理化特性及有机碳组分的影响［J］. 植物营养与肥料学报, 2020, 26（2）: 285-294.
Wang Yi, Zhang Junqing, Kuang Shuai, et al. Effects of wheat straw and its biochar application on soil physiochemical properties and organic carbon fractions in fluecured tobacco field ［J］. Journal of Plant Nutrition and Fertilizers, 2020, 26（2）: 285-294.
［3］　刘长涛, 侯建伟, 索全义, 等. 玉米秸秆生物质炭基肥的结构与性质表征［J］. 土壤, 2019, 51（3）: 465-469.
Liu Changtao, Hou Jianwei, Suo Quanyi, et al. Structure and performance characterization of maize straw biocharbased fertilizer ［J］. Soils, 2019, 51（3）: 465-469.
［4］　Liu B, Zhou Z, Gan J, et al. Investigation of performance of hydraulic excavators by cosimulation of multibody dynamics and discrete element method ［J］. Powder Technology, 2023, 414: 118088.
［5］　吴超, 吴努, 胡志超, 等. 基于DEM的螺旋输送机模拟仿真［J］. 中国农机化学报, 2015, 36（2）: 92-94, 115.
Wu Chao, Wu Nu, Hu Zhichao, et al. Simulation of the screw conveyor based on the DEM ［J］. Journal of Chinese Agricultural Mechanization, 2015, 36（2）: 92-94, 115.
［6］　Wang X, Li B, Yang Z. Analysis of the bulk coal transport state of a scraper conveyor using the discrete element method ［J］. Journal of Mechanical Engineering/Strojniki Vestnik, 2018, 64（1）.
［7］　张元清, 郭鑫, 赵晓燕, 等. 地下铲运机不同铲装方式下的离散元仿真研究［J］. 有色金属（矿山部分）, 2021, 73（6）: 72-78, 85.
Zhang Yuanqing, Guo Xin, Zhao Xiaoyan, et al. Discrete element simulation analysis of different shoveling methods for underground LHD ［J］. Nonferrous Metal （Mining Section）, 2021, 73（6）: 72-78, 85.
［8］　庞立志. 基于离散元法的斗轮堆取料机铲斗与物料相互作用机理研究［D］. 长春: 吉林大学, 2023.
Pang Lizhi. Research on the interaction mechanism between bucket and material of bucket wheel stacker and reclaimer based on discrete element method ［D］. Changchun: Jilin University, 2023.
［9］　袁建明, 郭城, 叶方平, 等. 新型卸料斗及落料平整堆积仿真分析［J］. 机械设计, 2020, 37（7）: 45-50.
Yuan Jianming, Guo Cheng, Ye Fangping, et al. Simulation analysis on the new discharge hopper and the process of blanking, leveling and accumulating ［J］. Journal of Machine Design, 2020, 37（7）: 45-50.
［10］　朱君伟, 金浩, 曹银平, 等. 焦炉装平煤过程的离散元模拟优化［J］. 科学技术与工程, 2020, 20（32）: 13327-13332.
Zhu Junwei, Jin Hao, Cao Yinping, et al. Optimization of coal loading and leveling process in coke oven based on the simulation with discrete element method ［J］. Science Technology and Engineering, 2020, 20（32）: 13327-13332.
［11］　马志奇, 杨小彬, 刘腾辉, 等. 粒径大小对颗粒堆积体Burgers模型蠕变参数相似试验研究［J］. 矿业科学学报, 2022, 7（6）: 730-737.
Ma Zhiqi, Yang Xiaobin, Liu Tenghui, et al. Similar experimental study on the effect of particle size on the creep parameters of Burgers model of granular accumulation ［J］. Journal of Mining Science and Technology, 2022, 7（6）: 730-737.
［12］　Wang X, Zhang S, Pan H, et al. Effect of soil particle size on soilsubsoiler interactions using the discreteelement method simulations ［J］. Biosystems Engineering, 2019, 182: 138-150.
［13］　Wang Y, Zhang D, Yang L, et al. Modeling the interaction of soil and a vibrating subsoiler using the discrete element method ［J］. Computers and Electronics in Agriculture, 2020, 174: 105518.
［14］　Zhang L, Zhai Y, Chen J, et al. Optimization design and performance study of a subsoiler underlying the tea garden subsoiling mechanism based on bionics and EDEM ［J］. Soil and Tillage Research, 2022, 220: 105375.
［15］　丁启朔, 任骏, BELAL Eisa Ada, 等. 湿粘水稻土深松过程离散元分析［J］. 农业机械学报, 2017, 48（3）: 38-48.
Ding Qishuo, Ren Jun, BELAL Eisa Ada, et al. DEM analysis of subsoiling process in wet clayey paddy soil ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2017, 48（3）: 38-48.
［16］　施丽莉, 顾峰玮, 胡志超, 等. 稻茬麦覆秸还田播种机均匀抛撒机理分析与机构优化［J］. 农业机械学报, 2022, 53（7）: 74-83.
Shi Lili, Gu Fengwei, Hu Zhichao, et al. Analysis and optimization of uniform throwing device by notillage planter of wheat after rice ［J］. Transactions of the Chinese Society for Agricultural Machinery, 2022, 53（7）: 74-83.

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