激光模具表面抗裂仿生单元体模型

目的针对企业模具寿命短、资源浪费、生产成本上升的问题,建立模具表面激光熔凝抗裂仿生单元体模型。方法在研究了植物叶片抗开裂生物原型结构的基础上,提炼针对模具的抗裂要素,形成单体模型,与实际影响模具循环寿命的因素相结合,分析寿命影响因素,然后基于获取到的数学模型构型,对激光熔凝单元体参数进行正交试验设计与优化。结果通过优化单元体的微观组织结构分析,在模具易出现疲劳裂纹位置,进行激光局部熔凝仿生抗开裂单元体制备,熔凝抗开裂单元体起到良好模具裂纹阻断作用,提高模具使用寿命50%以上。结论为提高模具寿命提供了一种新的方法。

H13钢激光仿生强化单元工艺研究

用均匀设计试验和逐步回归统计学方法研究了H13钢激光仿生强化中激光功率、扫描速度、激光密度对仿生单元截面形貌参数、表面粗糙度的影响规律。研究表明:激光密度对仿生单元截面形貌参数影响最为显著,与熔融区的熔深、截面面积、热影响区宽度、热影响区深度、熔融区和热影响区综合截面面积成简单线性递增关系;单元表面粗糙度与扫描速度呈开口下的抛物线关系,而表面粗糙度与激光功率呈开口向上的抛物线关系。

仿生耦合孕镶金刚石钻头底唇面非光滑形态的优化

基于仿生耦合理论研制的仿生耦合孕镶金刚石钻头,在工作过程中,仿生单元的提前磨损,会在其底唇面上形成一定的非光滑表面形态,因此其具有钻进效率高和使用寿命长的优点。探讨了仿生单元的同心圆排列方式,即通过改变仿生单元之间的径向和周向距离,来形成一系列非光滑表面形态,然后加工相应的仿生耦合钻头,并进行室内钻进实验,结果表明,径向距离为1.5d(d为仿生单元直径)、周向距离为3.0d和径向距离为2.0d、周向距离为3.5d两种排列方式更能体现仿生耦合钻头高效率、长寿命的优点,相对普通钻头,其效率和寿命分别提高16%、100%和15%、125%。为以后仿生钻头的设计提供了重要依据。

仿生非光滑耦合模具的耐磨损和热疲劳性能研究

采用激光仿生数控制备系统,在H13热锻模具表面进行仿生非光滑耦合处理,并研究了仿生非光滑耦合处理对模具表面硬度、耐磨损性能和热疲劳性能的影响。结果表明,适当的激光工艺参数可制备出网格状的仿生非光滑耦合单元体,单元体横截面为凸包状单元体结构;与未进行表面处理的H13钢热锻模具相比,仿生非光滑耦合处理使模具的表面平均硬度增加19%,800℃磨损体积减小81.7%;1000次20~800℃冷热循环后模具的主裂纹平均宽度减小91.2%,平均深度减小87.3%。

仿生金刚石钻头非光滑表面优化研究

对仿生单元的直径和排列方式进行研究,探求合理的非光滑表面形态。通过加工四个仿生试样并进行磨耗比测试,实验结果显示:仿生试样B2和B3明显高于B1和B4,其中B3仿生试样最高,比B2高出2%,由此可知,最佳的仿生单元直径为2.0mm;然后加工小口径仿生金刚石钻头,将数个2.0mm仿生单元材料均匀排布于钻头底唇面上,并进行钻进试验,结果显示:仿生单元在合理范围内排布时,仿生金刚石钻头具有较高的钻进效率和较长的使用寿命,否则其性能并不比普通钻头优越。由实验可知,仿生单元均匀排布时,径向角度为24°和30°的仿生单元排布方式比较合理,明显提高了仿生金刚石钻头性能。

仿驯鹿足底形貌胎面单元对轮胎防滑性能影响分析

轮胎胎面单元形貌结构对冬季轮胎防滑性能提升至关重要。为提高轮胎防滑性能,基于驯鹿足部特征,运用工程仿生技术,设计了有棱纹和无棱纹仿生防滑胎面单元。采用冰面附着试验和有限元数值模拟,与同尺寸常规人字形胎面单元比较,对仿生防滑胎面单元的防滑性能进行了分析。在试验低压状态下(压强≤0.02MPa)通过冰面与3种胎面单元的附着试验,结果表明在相同的速度、温度和压力条件下无棱纹仿生胎面单元摩擦系数最高,是人字形胎面单元的1.04～1.26倍。通过有限元数值分析,在低压0.02 MPa作用下,有棱纹仿生胎面单元、无棱纹仿生胎面单元和人字形胎面单元下的冰表面温度相对于初始温度分别升高了0.21、0.66和0.54℃,无棱纹仿生胎面单元温度升高最大,表明在低压条件下,无棱纹仿生胎面单元防滑性能最好。在高压状态(压强=2 MPa),有限元分析发现有棱纹仿生胎面单元、无棱纹仿生胎面单元和人字形胎面单元下的冰表面温度相对于初始温度分别升高了7.76、4.07和3.39℃,有棱纹仿生胎面单元升高温度最大,表明在高压状态下,有棱纹仿生胎面单元防滑性能最好。无棱纹仿生胎面单元和有棱纹仿生胎面单元分别在低压和高压状态下具有优良的防滑特性。该研究可为轮胎胎面单元的冰面防滑设计提供参考。

Bionic structure of shark's gill jet orifice based on artificial muscle

Based on the biological prototype characteristics of shark’s gill jet orifice,the flexible driving characteristics of ionic exchange polymer metal composites(IPMC)artificial muscle materials and the use of sleeve flexible connector,the IPMC linear driving unit simulation model is built and the IPMC material-driving dynamic control structure of bionic gill unit is developed.Meanwhile,through the stress analysis of bionic gill plate and the motion simulation of bionic gill unit,it is verified that various dynamic control and active control of the jet orifice under the condition of different mainstream field velocities will be taken by using IPMC material-driving.Moreover,the large-deflection deformation of bionic gill plate under dynamic pressure and the comparative analysis with that of a rigid gill plate is studied,leading to the achievement of approximate revised modifier from real value to theoretical value of the displacement control of IPMC.

Computer aided modeling and pore distribution of bionic porous bone structure

Artificial bone with porous structure is crucial for tissue scaffold and clinic implants.Scaffold provides structure support for cells and guides tissues regeneration for final tissue structure.A computational aided process of porous bone modeling was developed which described the design and fabrication of tissue scaffolds by considering intricate architecture,porosity and pore size.To simulate intricate bone structure,different constructive units were presented.In modeling process,bone contour was gotten from computed tomography(CT)images and was divided into two levels.Each level was represented by relatively reconstructive process.Pore size distribution was controlled by using mesh generation.The whole hexahedral mesh was reduced by unit structure,when a 3D mesh with various hexahedral elements was provided.The simulation results show that constructive structure of porous scaffold can meet the needs of clinic implants in accurate and controlled way.