The prospect of the application of the magnetic field quenching was also put forward.
展望了磁场淬火工艺的应用前景。
The distribution of the temperature field during magnetic field quenching is a kind of new research.
外加磁场淬火的温度场分布模拟是一个新的领域。
Through the results and analysis, we can discover that utilizing heat transfer theory and computer technology to simulate magnetic field quenching process is feasible.
分析结果表明,运用热传导理论和计算机技术来模拟外加磁场淬火过程在理论上是可行的。
The tensile strength, elongation and hardness of T10 steel subjected to magnetic field quenching and to high temperature tempering were separately increased by 28%, by 8.
与经普通淬火和高温回火的相比,经磁场淬火和高温回火的T10钢的抗拉强度提高了28%,断后伸长率提高了8。
In addition, the magnetic field quenching will increase the resistance of the T10 steel to tempering because of a large amount of dispersed carbides in the steel after magnetic field quenching.
此外,磁场淬火还提高了T10钢的抗回火能力,这是由于磁场淬火后的钢中含有大量弥散碳化物所致。
The three dimensional non linear finite element analysis of the transient temperature field during intermediate frequency quenching of diesel crankshaft was simulated by using of ANSYS.
利用ANSYS有限元分析软件,采用三维非线性有限元方法对柴油机曲轴中频淬火瞬态温度场进行了模拟计算;
This paper simulates the temperature field associated with laser surface quenching using ANSYS - a finite element analysis software, and a series of studies are carried out based on this simulation.
本文结合先进的大型有限元分析软件ANSYS,对激光表面淬火的温度场进行有限元模拟,并在此基础上,对此展开一系列研究。
The temperature field of workpiece was analyzed, and the influence on surface quenching of technological parameters was primary studied.
分析了工件的温度场,初步探讨了搓滚工艺参数对表面淬火的影响。
The effects of variation of temperature field of T8 steel quenching heat treatment on quenching microstructure were studied.
利用有限差分法计算了T8钢二维温度场,研究了T8钢淬火热处理温度场的变化对组织的影响。
The current industrial situation of amorphous & nanocrystalline alloy made by rapidly quenching technology is introduced, including the recent research, development and application in this field.
介绍了国内外利用快淬技术制备非晶纳米晶合金材料的产业现状以及这一领域材料工艺技术的研究开发动态和非晶纳米晶材料的应用情况。
Hardening depth related to the technical parameters and the quenching temperature field is an important target by plasma surface quenching.
硬化层深度是等离子弧表面淬火效果的重要指标之一,而硬化层深度与工艺参数、淬火过程中温度场的变化密切相关。
The structure and performance of steel materials is analyzed after laser quenching , and the research situation of laser transformation hardening in the field of materials science in future.
分析了钢铁材料激光相变硬化后的组织与性能,及近年来激光相变硬化技术在材料科学领域的研究状况。
Quenching in magnetic field can increase the strength and the elongation of the alloy after ageing.
淬火时施加磁场,使合金时效后的强度和塑性有所提高。
The temperature field with phase transformation and non-linear surface heat-transfer coefficient of steel 1045 during quenching is calculated with ANSYS program.
应用有限元分析软件ANSYS计算了1045钢淬火时具有相变和非线性表面换热系数的温度场。
Calculations by using ANSYS software were carried out to simulate the 3d temperature field of T8 steel with the shape of cylinder during quenching.
用有限元软件ANSYS模拟计算了T8钢圆柱体水淬过程中三维温度场的变化。
According to the simulated results, the flow-equalizing equipment is improved in order to make the medium flow field in a quenching tank more homogeneous.
根据数值模拟结果,改进了淬火槽的均流装置,使淬火槽内介质流场更加趋于均匀。
The new technics of 45 steel quenching under pulse electric field was studied.
研究了45钢在脉冲电场作用下淬火的新工艺。
The influence of variation of inlet speed, oil temperature and concentration of polymer solution on the distribution of flow field in the quenching tank was also analyzed.
并研究了淬火槽进口速度、光亮淬火油的使用温度、聚合物浓度对于流场分布的影响。
Three dimensional nonlinear and isoparameter FEM has been successfully used to simulate the transient temperature field, phase transformation, stress and strain of complex components during quenching.
采用非线性等参元三维有限元算法(FEM)成功地模拟了形状复杂的零件淬火过程中瞬态温度场、相变、应力和应变,获得直观的立体图象。
Temperature-floating martensitic transformation is an important transformation during the quenching treatment process. The calculation of temperature field is the key to the transformation simulation.
变温马氏体相变是重要的相变,其温度场的计算是相变模拟关键环节。
Computer simulation on complicate shaped parts during quenching process has been realized by using FEM analysis of temperature field phase transformation-stress and strain.
籍助于温度场-相变-应力和应变的有限元分析方法(FEM),实现了复杂形状工件淬火过程的计算机模拟。
Computer simulation on complicate shaped parts during quenching process has been realized by using FEM analysis of temperature field phase transformation-stress and strain.
籍助于温度场-相变-应力和应变的有限元分析方法(FEM),实现了复杂形状工件淬火过程的计算机模拟。
应用推荐