SiC金属-氧化物-半导体场效应晶体管(MOSFET)作为车用电机控制器功率单元的核心器件,其并联不均流问题是影响电机控制器安全稳定运行的关键因素。对于热增强塑料封装(TPAK)SiC MOSFET功率模块实际应用中的不均流问题,首先通过理论推导...SiC金属-氧化物-半导体场效应晶体管(MOSFET)作为车用电机控制器功率单元的核心器件,其并联不均流问题是影响电机控制器安全稳定运行的关键因素。对于热增强塑料封装(TPAK)SiC MOSFET功率模块实际应用中的不均流问题,首先通过理论推导和仿真,对影响SiC并联均流的器件参数、功率回路参数、驱动回路参数进行了全面的分析总结。然后结合仿真结果对电机控制器进行均流优化设计,其中包括对TPAK SiC MOSFET进行测试、筛选和分析,减小器件参数分散性的影响;基于器件开关特性,对功率模块的驱动回路采用单驱动器多推挽结构,减小驱动回路对并联均流的影响;设计了一种叠层母排结构,在ANSYS Q3D中提取到功率回路寄生电感为9.649 nH,采用ANSYS Q3D和Simplorer进行联合双脉冲仿真,电流不均衡度小于3%。最后,进行了电机控制器样机的试制及测试,实际测试结果表明电流不均衡度小于5%,验证了在车用电机控制器应用中TPAK SiC MOSFET模块均流设计的可行性。展开更多
The Al/Si/SiC composites with medium volume fraction for electronic packaging were fabricated by gas pressure infiltration.On the premise of keeping the machinability of the composites,the silicon carbide particles,wh...The Al/Si/SiC composites with medium volume fraction for electronic packaging were fabricated by gas pressure infiltration.On the premise of keeping the machinability of the composites,the silicon carbide particles,which have the similar size with silicon particles(average 13 μm),were added to replace silicon particles of same volume fraction,and microstructure and properties of the composites were investigated.The results show that reinforcing particles are distributed uniformly and no apparent pores are observed in the composites.It is also observed that higher thermal conductivity(TC) and flexural strength will be obtained with the addition of SiC particles.Meanwhile,coefficient of thermal expansion(CTE) changes smaller than TC.Models for predicting thermal properties were also discussed.Equivalent effective conductivity(EEC) was proposed to make H-J model suitable for hybrid particles and multimodal particle size distribution.展开更多
The rapid solidified process and hot press method were performed to produce three hypereutectic 55%Si-Al, 70%Si-Al and 90%Si-Al alloys for heat dissipation materials. The results show that the atomization is an effect...The rapid solidified process and hot press method were performed to produce three hypereutectic 55%Si-Al, 70%Si-Al and 90%Si-Al alloys for heat dissipation materials. The results show that the atomization is an effective rapid solidified method to produce the Si-Al alloy and the size of atomized Si-Al alloy powder is less than 50 μm. The rapid solidified Si-Al alloy powder were hot pressed at 550 ℃ with the pressure of 700 MPa to obtain the relative densities of 99.4%, 99.2% and 94.4% for 55%Si-Al, 70%Si-Al and 90%Si-Al alloys, respectively. The typical physical properties, such as the thermal conductivity, coefficient of thermal expansion (CTE) and electrical conductivity of rapid solidified Si-Al alloys are acceptable as a heat dissipation material for many semiconductor devices. The 55%Si-Al alloy changes greatly (CTE) with the increase of temperature but obtains a good thermal conductivity. The CTE of 90%Si-Al alloy matches with the silicon very well but its thermal conductivity value is less than 100 W/(m.K). Therefore, the 70%Si-Al alloy possesses the best comprehensive properties of CTE and thermal conductivity for using as the heat sink materials.展开更多
The electronic packaging shell of high silicon carbide (54%SiC, volume fraction) aluminum-based composites was produced by liquid-solid separation technique. The characteristics of distribution and morphology of SiC...The electronic packaging shell of high silicon carbide (54%SiC, volume fraction) aluminum-based composites was produced by liquid-solid separation technique. The characteristics of distribution and morphology of SiC as well as the shell’s fracture surface were examined by optical microscopy and scanning electron microscopy, and the thermo-physical and mechanical properties of the shell were also tested. The results show that Al matrix has a net-like structure while SiC is uniformly distributed in the Al matrix. The SiCp/Al composites have a low density of 2.93 g/cm^3, and its relative density is 98.7%. Thermal conductivity of the composites is 175 W/(·K), coefficient of thermal expansion (CTE) is 10.3×10^-6 K-1 (25-400 ℃), compressive strength is 496 MPa, bending strength is 404.5 MPa, and the main fracture mode is brittle fracture of SiC particles accompanied by ductile fracture of Al matrix.Its thermal conductivity is higher than that of Si/Al alloy, and its CTE matches with that of the chip material.展开更多
Al?50%SiC (volume fraction) composites containing different sizesofSiC particles (average sizesof 23, 38 and 75 μm) were prepared by powder metallurgy. The influences of SiC particle sizes and annealing on the p...Al?50%SiC (volume fraction) composites containing different sizesofSiC particles (average sizesof 23, 38 and 75 μm) were prepared by powder metallurgy. The influences of SiC particle sizes and annealing on the propertiesof the compositeswere investigated. The results show that SiC particles are distributed uniformly in the Al matrix. The coarse SiC particles result in higher coefficient of thermal expansion (CTE) and higher thermal conductivity (TC), while fine SiC particles decrease CTE and improve flexural strength of the composites. The morphology and size of SiC particles in the composite are not influenced by the annealing treatment at 400℃for 6h. However, the CTE and the flexural strength of annealed composites are decreased slightly, and the TCis improved. The TC, CTE and flexural strength of the Al/SiC composite with averageSiC particlesize of75 μm are 156 W/(m·K), 11.6×10^-6K^-1 and 229 MPa, respectively.展开更多
The electronic packaging box with high silicon aluminum-base alloy was prepared by semi-solid thixoforming technique.The flow characteristic of the Si phase was analyzed.The microstructures of different parts of the b...The electronic packaging box with high silicon aluminum-base alloy was prepared by semi-solid thixoforming technique.The flow characteristic of the Si phase was analyzed.The microstructures of different parts of the box were observed by optical microscopy and scanning electron microscopy,and the thermophysical and mechanical properties of the box were tested.The results show that there exists the segregation phenomenon between the primary Si phase and the liquid phase during thixoforming,the liquid phase flows from the box,and the primary Si phase accumulates at the bottom of the box.The volume fraction of primary Si phase decreases gradually from the bottom to the walls.Accordingly,the thermal conductivities of bottom center and walls are 107.6 and 131.5 W/(m·K),the coefficients of thermal expansion(CTE) are 7.9×10-6 and 10.6×10-6 K-1,respectively.The flexural strength increases slightly from 167 to 180 MPa.The microstructures and properties of the box show gradient distribution overall.展开更多
文摘SiC金属-氧化物-半导体场效应晶体管(MOSFET)作为车用电机控制器功率单元的核心器件,其并联不均流问题是影响电机控制器安全稳定运行的关键因素。对于热增强塑料封装(TPAK)SiC MOSFET功率模块实际应用中的不均流问题,首先通过理论推导和仿真,对影响SiC并联均流的器件参数、功率回路参数、驱动回路参数进行了全面的分析总结。然后结合仿真结果对电机控制器进行均流优化设计,其中包括对TPAK SiC MOSFET进行测试、筛选和分析,减小器件参数分散性的影响;基于器件开关特性,对功率模块的驱动回路采用单驱动器多推挽结构,减小驱动回路对并联均流的影响;设计了一种叠层母排结构,在ANSYS Q3D中提取到功率回路寄生电感为9.649 nH,采用ANSYS Q3D和Simplorer进行联合双脉冲仿真,电流不均衡度小于3%。最后,进行了电机控制器样机的试制及测试,实际测试结果表明电流不均衡度小于5%,验证了在车用电机控制器应用中TPAK SiC MOSFET模块均流设计的可行性。
基金Project (60776019) supported by the National Natural Science Foundation of ChinaProject (61-TP-2010) supported by the Research Fund of the State Key Laboratory of Solidification Processing (NWPU),China
文摘The Al/Si/SiC composites with medium volume fraction for electronic packaging were fabricated by gas pressure infiltration.On the premise of keeping the machinability of the composites,the silicon carbide particles,which have the similar size with silicon particles(average 13 μm),were added to replace silicon particles of same volume fraction,and microstructure and properties of the composites were investigated.The results show that reinforcing particles are distributed uniformly and no apparent pores are observed in the composites.It is also observed that higher thermal conductivity(TC) and flexural strength will be obtained with the addition of SiC particles.Meanwhile,coefficient of thermal expansion(CTE) changes smaller than TC.Models for predicting thermal properties were also discussed.Equivalent effective conductivity(EEC) was proposed to make H-J model suitable for hybrid particles and multimodal particle size distribution.
基金Project (2011) supported by the Hunan Nonferrous Research Funding of Hunan Nonferrous Metals Holding Group Co.,Ltd.,China
文摘The rapid solidified process and hot press method were performed to produce three hypereutectic 55%Si-Al, 70%Si-Al and 90%Si-Al alloys for heat dissipation materials. The results show that the atomization is an effective rapid solidified method to produce the Si-Al alloy and the size of atomized Si-Al alloy powder is less than 50 μm. The rapid solidified Si-Al alloy powder were hot pressed at 550 ℃ with the pressure of 700 MPa to obtain the relative densities of 99.4%, 99.2% and 94.4% for 55%Si-Al, 70%Si-Al and 90%Si-Al alloys, respectively. The typical physical properties, such as the thermal conductivity, coefficient of thermal expansion (CTE) and electrical conductivity of rapid solidified Si-Al alloys are acceptable as a heat dissipation material for many semiconductor devices. The 55%Si-Al alloy changes greatly (CTE) with the increase of temperature but obtains a good thermal conductivity. The CTE of 90%Si-Al alloy matches with the silicon very well but its thermal conductivity value is less than 100 W/(m.K). Therefore, the 70%Si-Al alloy possesses the best comprehensive properties of CTE and thermal conductivity for using as the heat sink materials.
文摘The electronic packaging shell of high silicon carbide (54%SiC, volume fraction) aluminum-based composites was produced by liquid-solid separation technique. The characteristics of distribution and morphology of SiC as well as the shell’s fracture surface were examined by optical microscopy and scanning electron microscopy, and the thermo-physical and mechanical properties of the shell were also tested. The results show that Al matrix has a net-like structure while SiC is uniformly distributed in the Al matrix. The SiCp/Al composites have a low density of 2.93 g/cm^3, and its relative density is 98.7%. Thermal conductivity of the composites is 175 W/(·K), coefficient of thermal expansion (CTE) is 10.3×10^-6 K-1 (25-400 ℃), compressive strength is 496 MPa, bending strength is 404.5 MPa, and the main fracture mode is brittle fracture of SiC particles accompanied by ductile fracture of Al matrix.Its thermal conductivity is higher than that of Si/Al alloy, and its CTE matches with that of the chip material.
基金Project support by the 2015 Shandong Province Project for Outstanding Subject Talent Group,China
文摘Al?50%SiC (volume fraction) composites containing different sizesofSiC particles (average sizesof 23, 38 and 75 μm) were prepared by powder metallurgy. The influences of SiC particle sizes and annealing on the propertiesof the compositeswere investigated. The results show that SiC particles are distributed uniformly in the Al matrix. The coarse SiC particles result in higher coefficient of thermal expansion (CTE) and higher thermal conductivity (TC), while fine SiC particles decrease CTE and improve flexural strength of the composites. The morphology and size of SiC particles in the composite are not influenced by the annealing treatment at 400℃for 6h. However, the CTE and the flexural strength of annealed composites are decreased slightly, and the TCis improved. The TC, CTE and flexural strength of the Al/SiC composite with averageSiC particlesize of75 μm are 156 W/(m·K), 11.6×10^-6K^-1 and 229 MPa, respectively.
文摘The electronic packaging box with high silicon aluminum-base alloy was prepared by semi-solid thixoforming technique.The flow characteristic of the Si phase was analyzed.The microstructures of different parts of the box were observed by optical microscopy and scanning electron microscopy,and the thermophysical and mechanical properties of the box were tested.The results show that there exists the segregation phenomenon between the primary Si phase and the liquid phase during thixoforming,the liquid phase flows from the box,and the primary Si phase accumulates at the bottom of the box.The volume fraction of primary Si phase decreases gradually from the bottom to the walls.Accordingly,the thermal conductivities of bottom center and walls are 107.6 and 131.5 W/(m·K),the coefficients of thermal expansion(CTE) are 7.9×10-6 and 10.6×10-6 K-1,respectively.The flexural strength increases slightly from 167 to 180 MPa.The microstructures and properties of the box show gradient distribution overall.
