基于ADAMS和ABAQUS热磨机研磨木片断裂过程数值模拟

doi:10.11707/j.1001-7488.20181217

摘要/Abstract

摘要： [目的]基于ADAMS和ABAQUS软件对热磨机研磨木片的断裂过程进行数值模拟，研究当动、静盘磨齿间的夹角α一定、木片到主轴中心的距离R变化时的场变量输出，从理论上分析磨片破碎区域面积对纤维分离能耗的影响，指导热磨机磨片的优化设计。[方法]结合断裂力学理论，基于数值模拟方法，取动、静盘磨齿间的夹角α=15°，运用ADAMS软件求解木片到主轴中心的距离R分别为370、390、410、430、450 mm 5种情况时木片所受的研磨压力F_m和剪切力F_r，并利用ABAQUS软件将所求得的力加载在木片上进一步模拟木片断裂过程。[结果]1）在热磨机动、静磨齿研磨压力F_m和剪切力F_r的作用下，木片发生断裂破坏，α=15°、R=450 mm时木片的Mises应力变化范围为9.846×10^-2~7.493 MPa，第一主应变变化范围为1.235×10^-5~2.546×10^-2，第三主应变变化范围为-1.231×10^-4~-1.853×10^-2，应变E₂₃变化范围为-3.481×10^-2~3.756×10^-3，较大的应力应变主要分布在裂纹附近，木片左右两侧的应力应变逐渐减小。α=15°、R=450 mm时木片节点位移U₁的变化范围为-7.605×10^-4~1.693×10^-3mm，节点位移U₃的变化范围为-3.334×10^-2~1.966×10^-2mm，U₃的变化范围大于U₁的变化范围，木片主要沿U₃方向被撕裂，即木片在被研磨过程中主要在剪切力F_r的作用下沿木片横纹方向被分离。2）在磨片破碎区，当动、静盘磨齿间的夹角α一定时，木片到主轴中心的距离R增大，木片的Mises应力、正应力、Magnitude、节点位移呈增大趋势。当木片到主轴中心的距离R越大，即破碎区面积越大时，木片所受应力应变增大，木片断裂越容易。[结论]1）木片被研磨过程中主要在剪切力F_r的作用下沿木片横纹方向被分离，对磨片进行结构设计和优化分析时应尽可能增加磨齿对木片的剪切力F_r，使磨片破碎区木片的断裂程度更充分，降低粗磨区和精磨区的纤维分离能耗。2）热磨机研磨木片时木片到主轴中心的距离R越大，即破碎区面积越大，木片断裂就越容易，合理设计磨片破碎区域面积可以降低纤维分离能耗。3）运用ABAQUS软件模拟木片到主轴中心的距离R不等时的场变量输出，从理论上分析磨片破碎区域面积对纤维分离能耗的影响，可以指导热磨机磨片的优化设计。

关键词: 热磨机, 木片断裂, 纤维分离, 数值模拟

Abstract: [Objective] In order to improve the design of the mill grinding disc, the fracture process of grinding the wood chips into fibers by the hot mill was studied in this paper. Based on ADAMS and ABAQUS, the process of grinding the wood chips by the hot mill was numerically simulated, and the process of gradual fracture of the wood chips with the force was explored. When the angle between the grinding and grinding teeth of the moving and stationary discs is constant, the amount of field change was recorded for the distance R from the wood piece to the center of the spindle. The influence of broken area size of the grinding piece on the energy consumption of fiber separation was theoretically analyzed.[Method] Combined with the theory of fracture mechanics, the method of numerical simulation is used. When the angle between the teeth of the moving and stationary discs α is 15°,the numerical simulation method is applied to solve the distance R between the wood chips and the spindle center by using ADAMS software to obtain R=370, 390, 410, 430, 450 mm in five cases, the size of the grinding pressure F_m and the shear force F_r. Then use ABAQUS software to load it on the wood chip and numerically simulate the fracture process.[Result] The ADAMS software was used to simulate the working process of grinding the wood chips by the hot mill, and the simulation result of the grinding pressure F_m and the shearing force F_r of the wood chips α=15° and R=450 mm were obtained. The field variable output result of α=15° and R=450 mm were obtained by using ABAQUS software. The variation trend of Mises stress, normal stress, Magnitude and node displacement of wood chips under different conditions was studied by using Excel scatter plot and regression analysis chart.[Conclusion] 1) The damage form of the wood chips during the grinding process is mainly separated by the shear force F_r along the transverse direction of the wood chips. Therefore, during the structural design and optimization analysis of the grinding plates, the grinding teeth should be increased as much as possible. The force of the cutting force F_r makes the fracture degree of the wood chip in the crushing zone more complete, and reduces the energy consumption of fiber separation in the rough grinding zone and the fine grinding zone. 2) When the hot mill grinds the wood chips, the larger the distance R from the wood chips to the center of the main shaft, the larger the area of the crushing area, the easier the fracture of the wood chips is. The reasonable design of the area of the crushing area of the grinding plate can reduce the energy consumption of fiber separation. 3) Using ABAQUS to simulate the field variable output when the distance from the wood chip to the center of the spindle is not equal, the influence of the area of the crushed area on the fiber separation energy consumption is theoretically analyzed, which can guide the optimized design of the grinding piece.

Key words: hot grinding, wood fracture, fiber separation, the numerical simulation

中图分类号:

TS642

张绍群, 颜家雄, 曹雷, 王海涛. 基于ADAMS和ABAQUS热磨机研磨木片断裂过程数值模拟[J]. 林业科学, 2018, 54(12): 149-156.

Zhang Shaoqun, Yan Jiaxiong, Cao Lei, Wang Haitao. Crack Propagation Simulation of Hot Mill Grinding with Wood Based on ADAMS and ABAQUS[J]. Scientia Silvae Sinicae, 2018, 54(12): 149-156.

参考文献

陈光伟, 花军, 纪伟, 等. 2010. 磨片结构对纤维分离过程中能量转换机理的影响.东北林业大学学报,38(8):109-110,114.
(Chen G W, Hua J, Ji W, et al. 2010. Effects of abrasive disc- structure on energy transformation during fiber separation. Journal of Northeast Forestry University,38(8):109-110,114. [in Chinese])
陈光伟. 2012. 热磨法磨片纤维分离机理的模型分析与实验研究. 哈尔滨:东北林业大学博士学位论文,22-30.
(Chen G W. 2012. Model analysis and experimental study on mechanism of thermomechanical refining plate separating fiber.Harbin: PhD thesis of Northeast Forestry University, 22-30. [in Chinese])
李艳丽, 高秀华, 陈淑清. 2008. 扇块分区热磨机磨片的热应力分析与优化设计. 林业机械与木工设备,36(1):29-31.
(Li Y L, Gao X H, Chen S Q. 2008. Thermal stress analysis and optimization design of fan block to zone grinding mill. Forestry Machinery & Woodworking Equipment,36(1):29-31. [in Chinese])
邵贤林, 王平. 2013. 盘磨机磨盘间隙的调整方式与分析.纸和造纸,32(3):21-25.
(Shao X L, Wang P. 2013. Adjustment and analysis of disc gap in disc refiner. Paper and Paper Making,32(3):21-25. [in Chinese])
沈立新. 1999. 浅谈盘磨磨片齿型的设计与选择. 上海造纸,(1):27-30,33.
(Shen L X. 1999. Discussion on the design and selection of disc grinding die. Shanghai Paper Making,(1):27-30,33. [in Chinese])
徐大鹏. 2012. MDF纤维分离机理及磨片齿形结构参数优化设计的研究. 哈尔滨: 东北林业大学硕士学位论文,4-15.
(Xu D P. 2012. Study on the fiber separation mechanism of MDF and the optimization design of plate-bar structural parameters. Harbin: MS thesis of Northeast Forestry University, 4-15.[in Chinese])
Berg J E. 2001. Effect of impact velocity on the fracture of wood as related to the mechanical pulping process. Wood Science and Technology,35(4):343-351.
Chen G W, Hua J. 2008. Test analysis and deduction of factors affecting fiber separating quality and mechanism refiner-disc working.International Association of Wood Products Societies, 227-228.
Fan K, Hatzikifiakos S G, Avramidis S. 1999. Determination of the surface fractal dimension from sorption isotherms of five softwoods. Wood Science and Technology, 33(2):139-149.
Hua J, Chen G W. 2008. Theoretic deduction and computation of material movement track in parting fiber. International Association of Wood Products Societies(IAWPS2008),235-236.
Holmberg S, Persson K, Petersson H. 2009. Nonlinear mechanical behavior and analysis of wood and fibre materials. Computers & Structures,72(4/5): 459-480.
Li J G, Pang S S, Scharpf E W. 2007. Modeling of thermal energy demand in MDF production. Forest Products Journal,57(9):97-104.
Olson J A, Drozdiak J, Martinez M, et al. 2013. Characterizing fiber shortening in low-consistency refining using a comminution model. Powder Technology,129(1/3): 122-129.
May W D. 1973. A theory of chip refining the origin of fibre length. Pulp and Paper Research Institude of Canada,24:245-253.
Pelletier A L,Zhao Y,Lei X, et al. 2013. Improved fiber separation and energy reduction in thermomechanical pulp refining using enzyme-pretreated wood. BioResources,8(3):3385-3398.
Qin D C,Guan N,Jiang X M. 1999. Morphology of wood failure in relation to the variation in tensile strength parallel to grain of three hard pines. Journal of the Institute of Wood Science,15(1):1-5.
Resch E, Kaliske M. 2012. Numerical analysis and design of double-shear dowel-type connections of wood. Engineering Structures,41:234-241.
Roux J C, Mayade T L. 2009. Modeling of the particle breakage kinetics in the wet mills for the paper industry. Powder Technology,105(1/3): 237-242.
Santos C L, De Jesus A M P, Morais J J L, et al. 2009. Quasi-static mechanical behaviour of a double-shear single dowel wood connection.Construction and Building Materials,23(1):171-182.
Shida S, Hiziroglu S. 2010. Evaluation of shear strength of Japanese wood species as a function of surface roughness. Forest Products Journal,60(4):400-404.

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[3]	张志强王礼先余新晓李亚光 E.Klaghofer. 渗透坡面林地地表径流运动的有效糙率研究[J]. 林业科学, 2000, 36(5): 22-27.