粉末冶金技术

2022, 40(1): 3-3.

[Abstract](187) [FullText HTML] (147) [PDF 291KB](35)

Abstract:

Effect of Cu‒Fe pre-alloyed powders on the friction and wear properties of Cu-based friction materials

WEI Dong-bin, ZHANG Lin, ZHANG Peng, WU Pei-fang, CAO Jing-wu, SHIJIA Cai-rang, DING Xiang-ying, ZHAO Shang-jie, QU Xuan-hui

2022, 40(1): 4-12. doi: 10.19591/j.cnki.cn11-1974/tf.2020050017

[Abstract](494) [FullText HTML] (135) [PDF 2654KB](163)

Abstract:
Copper-based friction materials containing the Cu‒Fe pre-alloyed powders in different mass fraction were prepared by powder metallurgy method, and the friction properties were tested at different temperatures. The results show that, with the introduction of the Cu‒Fe pre-alloyed powders, the iron participates in the copper matrix and the interface between copper matrix and other components, which hinders the sintering process and reduces the density. The formed pearlite and the participated iron at the interface act as the hard-strengthening phase, which changes the wear mechanism from the adhesive wear of the pure copper matrix to the abrasive wear after adding the Cu‒Fe pre-alloyed powders, resulting in the reduction of friction coefficient at first and then rising. The critical temperature is 200～250 ℃ for maintaining the stable friction coefficient. When the temperature exceeds the critical temperature, the copper on the friction surface softens and its self-lubricating effect leads to the decrease of friction coefficient. 30% Cu‒Fe pre-alloyed powders by mass is the optimum content for the copper-based friction materials, and the copper-based friction materials have the good plasticity of copper and the appropriate amount of the hard phases to strengthen the friction surface.

Effect of two-stage supersolidus liquid phase sintering on microstructure and properties of 15Cr high chromium cast iron

GU Si-min, XIAO Ping-an, GU Jing-hong, LÜ Rong, ZHAO Ji-kang, ZHONG Si-yuan

2022, 40(1): 13-21. doi: 10.19591/j.cnki.cn11-1974/tf.2021040016

[Abstract](394) [FullText HTML] (201) [PDF 3161KB](102)

Abstract:
To solve the problems in the one-stage supersolidus liquid phase sintering (SLPS) that the sintering temperature window is narrow and the mechanical properties of the products are very sensitive to the fluctuation of sintering temperature, the high chromium cast iron (HCCI) was prepared by the two-stage SLPS technique. The effects of process parameters in the high temperature stage (HTS) on the microstructure and mechanical properties of 15Cr high chromium cast iron prepared by the two-stage SLPS were studied, and the alloys prepared by the one-stage SLPS were compared. The results show that the alloys prepared by the two-stage SLPS are composed of M₇C₃-type carbides, martensite, and a small amount of austenite. Efficient densification and the effective control of microstructure can be achieved through the high and low temperature sintering, and the relative density of high performance alloy material is more than 98.96%. The sintering temperature window is 15 ℃ wider than that of one-stage SLPS. The microstructure of the alloys is gradually coarsened with the increase of the sintering temperature and the holding time during the high temperature stage from 1225 ℃ to 1245 ℃ for 5～10 min. However, when the holding time is controlled within 10 min during the high temperature stage, the grain size is less than 26.98 μm, and the coarsening degree is acceptable. The hardness and impact toughness of HCCI prepared by the two-stage SLPS are better than those prepared by the one-stage SLPS, and the impact toughness remains stable within the sintering window with the average value of 12.10 J·cm⁻². Under the impact energy from 1 J·cm⁻² to 3 J·cm⁻², the impact abrasive wear resistance of the samples sintered by the two-stage SLPS is better than that of the samples sintered by the one-stage SLPS. With the increase of impact energy, the improvement of impact abrasive wear resistance of the alloys increases from 9.70% to 19.83%.

Research progress on FeCrAl alloys used for nuclear fuel cladding prepared by powder metallurgy

JIA Wen-qing, LIU Xiang-bing, XU Chao-liang, LI Yuan-fei, QIAN Wang-jie, QUAN Qi-wei, YIN Jian

2022, 40(1): 22-32. doi: 10.19591/j.cnki.cn11-1974/tf.2021060010

[Abstract](1835) [FullText HTML] (294) [PDF 3979KB](218)

Abstract:
The fuel cladding plays an important role for the safe operation of the nuclear reactors. After the Fukushima nuclear accident, a large number of new types of the accident-tolerant fuel cladding have been developed. FeCrAl alloys have become one of the important candidate materials for the new generation of the accident-tolerant fuel cladding due to the excellent comprehensive properties, such as the high temperature oxidation resistance and the high strength. After years of research and development, some progress has been made in the design and preparation of FeCrAl alloys used for the nuclear fuel cladding. As one of the main research directions, the preparation of the oxide dispersion strengthened FeCrAl alloys with the better performance by powder metallurgy shows a broad prospect and has attracted the extensive attention from scholars at home and abroad. In this paper, the research status of the composition design, smelting, and powder metallurgy for the FeCrAl alloys used for the nuclear fuel cladding were reviewed. The microstructure, properties, and the existing problems of the FeCrAl alloys prepared by the different methods were analyzed. The future design and preparation of the FeCrAl alloys used for the nuclear fuel cladding were prospected.

Preparation and microstructure evolution of TiB₂/Al composite powders by gas atomization method

JIANG Hong-xiang, SONG Yan, ZHAO Lei, HE Jie, ZHAO Jiu-zhou, ZHANG Li-li

2022, 40(1): 33-39. doi: 10.19591/j.cnki.cn11-1974/tf.2021030039

[Abstract](385) [FullText HTML] (148) [PDF 2982KB](59)

Abstract:
The TiB₂/Al composite ingot was prepared by the fluoride salt reaction method, and the TiB₂/Al composite powders were prepared by the high pressure gas atomization. The structures and properties of the composite ingot and powders were characterized by metallographic microscope, scanning electron microscope, X-ray diffractometer, and particle size distribution instrument. The results demonstrate that, the solubility product of TiB₂ in Al melt is much smaller than that of the TiAl₃ and AlB₂ phases in the experiment condition, the change of Gibbs free energy caused by the precipitation of TiB₂ from Al melt is more negative than that caused by the precipitation of TiAl₃ or AlB₂ from Al melt. The TiB₂/Al composite ingot and powders are mainly composed of α-Al matrix and TiB₂ phase. The TiB₂ particles in the TiB₂/Al composite powders prepared by gas atomization have nano-scale, and uniformly disperse in the Al matrix, no obvious segregation phenomenon is observed. The size distribution of the TiB₂/Al composite powders exhibits a normal state in the range of 10~100 μm. The powder yield with the particle size between 10~70 μm is 81.1%, the yield for the particle larger than 70 μm is 12.6%, and that less than 10 μm is 6.3%.

Preparation and research process of high thermal conductivity metal matrix composites

CHEN Zhen-rui, LIU Chao, XIE Yan-chong, PAN Zhi-zhong, REN Shu-bin, QU Xuan-hui

2022, 40(1): 40-52. doi: 10.19591/j.cnki.cn11-1974/tf.2021040002

[Abstract](2067) [FullText HTML] (425) [PDF 3067KB](201)

Abstract:
With the increasing power of the electronic device chip, the higher requirements are put forward for the thermophysical properties of the heat dissipation materials. The metal matrix composites as the ideal heat dissipation material, which are composed of the high thermal conductivity and low thermal expansion reinforcement phase and the high thermal conductivity metal, show the high thermal conductivity and the adjustable coefficient of thermal expansion. The research progress of the copper matrix and aluminum matrix composites reinforced by Si, SiC_p, diamond, and flake graphite in recent years was summarized in this paper, and the existing problems and future research direction of the metal matrix composites were prospected.

Effect of SiC on thermoelectric properties of P-type Bi_0.5Sb_1.5Te₃ alloy prepared by pulverizing and sintering method

WANG Xiao-yu, JIANG Wei, ZHU Bing, SUN Yuan-tao, XIANG Bo, HUANG Zhong-yue, YANG Shuang-gen, ZU Fang-qiu

2022, 40(1): 53-59. doi: 10.19591/j.cnki.cn11-1974/tf.2020010008

[Abstract](359) [FullText HTML] (191) [PDF 2615KB](161)

Abstract:
SiC particles in the different volume fraction were mixed into Bi_0.5Sb_1.5Te₃+5%Te alloy powders (mass fraction) prepared by the pulverizing method. The mixed powders were sintered into the blocks by spark plasma sintering (SPS) method. The microstructure and thermoelectric properties of these block samples were investigated. The results show that, with the increase of SiC volume fraction, the orientation of the bulks is weakened, the microstructure is refined, the carrier concentration increases, and the mobility decreases. Due to the weakened orientation and the refined microstructure, the scattering of phonons is enhanced, leading to a reduced lattice thermal conductivity. However, due to the deterioration of the electrical properties for the blocks, the dimensionless thermoelectric value (ZT) of the bulks with SiC has no improvement. When the volume fraction of SiC is 0.40%, the block samples show the best thermoelectric performance with ZT = ~0.81 at 322 K.

Research progress of inhomogeneous structure cemented carbide based on surface modification

CHEN Jian, LIU Bing-yao, DENG Xin, WU Shang-hua, Liu jin-yang

2022, 40(1): 60-66. doi: 10.19591/j.cnki.cn11-1974/tf.2020020003

[Abstract](665) [FullText HTML] (223) [PDF 2165KB](147)

Abstract:
Surface modification is the treatment technology that makes the tailored surface microstructure different from that of the matrix, which can efficiently control the mechanical properties of the material surface. Therefore, the surface modification can improve the microstructure of the cemented carbides, effectively avoid the limitation of the homogeneous structure cemented carbides on the microstructure and macroscopic properties, and provide the technical scheme for the preparation of the high performance inhomogeneous structure cemented carbides. Due to the late start of the surface modification research and a mass of surface modification methods, the selection of surface modification methods and the modification mechanism are still not clear. The material system, preparation mechanism, microstructure, and mechanical properties of the graded cemented carbides obtained by chemical surface modification were summarized in this paper, the methods and functions of the graded cemented carbide coatings obtained by physical surface modification were concluded. The application and research progress of the surface modification used for the cemented carbides were analyzed to provide the reference for the preparation of the cemented carbides with high wear resistance and good fracture toughness.

Effect of SiC content on friction properties of SiC_p/Al composites

XU Bao-hai, LIU Lian-jun, CHE Ming-chao, LI Li

2022, 40(1): 67-71. doi: 10.19591/j.cnki.cn11-1974/tf.2020030014

[Abstract](404) [FullText HTML] (216) [PDF 3468KB](118)

Abstract:
The SiC_p/Al composites were prepared by the powder metallurgy technology, and the influences of SiC particle mass fraction on the density, Brinell hardness, microstructure, friction, and wear of the SiC_p/Al composites were investigated. The results show that, a small amount of Al₄C₃ compounds can be formed on the surface of SiC particles, improving the bonding properties. With the increase of SiC mass fraction, the density of the SiC_p/Al composites has no obvious change, when the SiC mass fraction increases to 25%, the density decreases obviously. The Brinell hardness of the SiC_p/Al composites increases first and then decreases with the increase of SiC mass fraction. When SiC mass fraction is 20%, the optimal Brinell hardness is HBW 114 and the average friction coefficient can reach to the maximum as 0.3425, the surface morphology after friction is flat and shallow furrows, and the SiC particles has not obvious spalling.

Metal powder injection molding technology and numerical simulation

HOU Cheng-long, GUO Jun-qing, CHEN Fu-xiao, HUANG Tao

2022, 40(1): 72-79. doi: 10.19591/j.cnki.cn11-1974/tf.2020120007

[Abstract](917) [FullText HTML] (580) [PDF 2312KB](99)

Abstract:
Metal powder injection molding (MIM) can be used to manufacture the high performance precision parts with the special shape in large quantities and low cost, which is regarded as one of the research hotspots in the field of the advanced manufacturing technology. The MIM technology was summarized in this paper, including the powder preparation, the binder selection, the mixing, the injection, and the subsequent debinding and sintering. The development, status, and new technology of MIM were introduced, the numerical simulation of MIM was deeply analyzed, and the development trend of MIM was prospected.

Fracture morphology and microstructure analysis of Mo–La nozzles for solid rocket motor

LIN Bing-tao, HE Jun, LIU Zhong-wei, WANG Cheng-yang, LI Ming, SUN Xiao-xia, ZHOU Shu-qiu

2022, 40(1): 80-85. doi: 10.19591/j.cnki.cn11-1974/tf.2021070003

[Abstract](469) [FullText HTML] (154) [PDF 2207KB](45)

Abstract:
The ablated Mo–La nozzle samples were obtained through the ground thermal test of solid rocket motor. The metallographic structures of the samples before and after ablation was compared and analyzed. The mechanical properties of Mo–La materials were tested at room temperature and 1000 ℃. The results show that the Mo–La nozzles used in solid rocket motor with working time of 2.1 s have the complete inner profile shape, no significant change in size, and good ablation resistance. The metallographic structure before and after ablation reminds the grain recrystallization, especially at the high working temperature position in the middle of nozzle and nozzle, and the morphology changes obviously from the slender fiber to the equiaxed grain. The molybdenum is toughened by the lanthanum oxide particles, the necking and dimple appear on the fracture surface of alloy samples at 1000 ℃ and room temperature, the dimple depth is greater at high temperature, and the tensile strength and elongation decrease.

Application and development of metal additive manufacturing technology in the field of nuclear industry

MA Qing-yuan, DU Pei-nan, PENG Ying-bo, ZHANG Rui-qian, ZHANG Wei

2022, 40(1): 86-94. doi: 10.19591/j.cnki.cn11-1974/tf.2020110005

[Abstract](671) [FullText HTML] (608) [PDF 2270KB](153)

Abstract:
Additive manufacturing can produce the arbitrary complex shape parts, which has the advantages of fast, efficient, economical, fully intelligent, and fully flexible manufacturing. Based on the introduction of the typical metal additive manufacturing technology at home and abroad, the application of the metal additive manufacturing technology in the field of nuclear industry was overviewed in this paper, the performance of nuclear material products prepared by the additive manufacturing was summarized, and the advantages of the metal additive manufacturing in the field of nuclear industry were proved by the practical cases. At the same time, the development trend of the additive manufacturing technology in the field of nuclear materials was forecasted based on the application background of the innovative reactor technology for the nuclear materials.

2022 Vol. 40, No. 1