Current Issue

• Process Research

  Effect of heat treatment on microstructure and mechanical properties of 42CrMo steel picks

  Yuan Zhizhong, Wang Mengfei, Duan Xubin, Yang Haifeng, Li Biaomin, Luo Rui, Zhao Xiaoqiang, Cheng Xiaonong

  2023, 48(6):  1-8.  doi:10.13251/j.issn.0254-6051.2023.06.001

  Abstract ( 163 )   PDF (7080KB) ( 179 )  

  Taking foreign similar products as references, many kinds of duplex-phase and induction quenching treatments were applied to 42CrMo steel picks. Hardness, impact absorbed energy, microstructure and fracture morphology of the 42CrMo steel picks after different heat treatments were investigated. The effects of heat treatments on microstructure and mechanical properties were analyzed. The results show that after duplex-phase heat treatment process, the microstructure includes lower bainite/martensite (LB/M) and a small amount of retained austenite (RA), grain size is smaller and LB has better comprehensive mechanical properties, and impact absorbed energy is higher than that after quenching and low temperature tempering (Q-T) process. Local induction quenching process not only has the highest impact absorbed energy and the hardness of pick head, but also realizes the axial hardness distribution of hard head and soft handle of the pick, which is beneficial to extending the service life. The fracture morphology of the specimen treated by Q-T process shows cleavage brittle fracture morphology, the specimen treated by multiphase shows quasi cleavage fracture morphology, and the impact specimen treated by local induction quenching shows ductile fracture morphology, which is resulted from the excellent mechanical properties of the quenched and tempered (Q&T) microstructure. The tested data show that the Q&T plus local induction quenching is more suitable for picks used in hard substrate.

  Effect of pulse frequency and duty ratio on microstructure and properties of microarc oxidation coating on Ti6Al4V alloy

  Chen Yuke, Yuan Meini, Zhou Pengfei, Hang Ruiyue, Li Maohua

  2023, 48(6):  9-15.  doi:10.13251/j.issn.0254-6051.2023.06.002

  Abstract ( 48 )   PDF (3907KB) ( 30 )  

  Effects of pulse frequency and duty ratio on microstructure and properties of microarc oxidation coatings prepared on Ti6Al4V alloy in Na₂SiO₃-Na(PO₄)₆ electrolyte system were studied. The morphology, element distribution, phase composition, thickness, roughness and microhardness of the coatings were characterized by means of scanning electron microscope, energy dispersive spectrometer, X-ray diffractometer, coating thickness meter, laser confocal microscope and microhardness tester. The results show that the main elements of Ti6Al4V alloy microarc oxidation coatings are Ti, O and Si. The phase composition is mainly Rutile-TiO₂, Anatase-TiO₂ and amorphous SiO₂. With the increase of pulse frequency, the intensity of Anatase diffraction peak in the coating decreases first and then increases, whereas Rutile shows the opposite trend. With the increase of pulse duty ratio, the intensity of Anatase diffraction peak decreases, while that of Rutile diffraction peak increases. Micro-holes are uniformly distributed on the surface of the coatings. Pulse frequency has little effect on the microstructure and roughness, and the thickness increases first and then decreases. With the increase of duty ratio, the thickness increase rapidly, but the surface gradually appears microcracks and local ablation defects, causing the roughness increase rapidly. The thickness reaches 45.46 μm and the roughness R_a is 4.75 μm at 600 Hz and 20% duty ratio. With the increase of pulse frequency and duty ratio, the microhardness of coatings increases first and then decreases. The maximum microhardness is 863.2 HV0.5 at 600 Hz and 20% duty ratio, compared with Ti6Al4V alloy, the increase is 149.5%.

  Development and controlled cooling process of FH32-HD and FH36-HD higher ductility ship plate steels

  Zhang Xiaoxue, Wang Enmao, Wu Huibin, Zhao Jinbin, Liu Jinxu

  2023, 48(6):  16-22.  doi:10.13251/j.issn.0254-6051.2023.06.003

  Abstract ( 38 )   PDF (5214KB) ( 35 )  

  Using the composition design of low C and Nb+Ti compound addition, two higher ductility ship plate steels FH32 and FH36 were developed by means of optimizing the controlled cooling process of “relaxation-laminar cooling-air cooling”. The tensile properties and microhardness were tested, and the full-thickness A₅ scale specimens were used for tensile testing. The microstructure and inclusions of the tested steels were observed and analyzed by using SEM and EDS. The results show that with the reduction of the initial cooling temperature, that is, the extension of the relaxation time, the ferrite yield earlier, the average grain size and the ratio of soft-hard phases increase. Furthermore, the content of lamellar pearlite increases and the content of granular bainite decreases significantly. The overall elongation increases, but the strength margin greatly decreases. The decrease of the final cooling temperature make the pearlite lamellae reduce firstly and then enlarge, the content of bainite in the structure increases gradually, and the morphology changes from granular bainite to lath bainite. The strength shows an upward trend, but the elongation decreases significantly after reaching a peak at 600 ℃.

  Melting and casting process and quality control of Al-6.3Zn-2.0Mg-0.32Cu aluminum alloy

  Xu Fanfan, Li Heng, Xu Yanchen, Wang Dongming, Li Yukun, Qian Yuerong, Wu Yucheng

  2023, 48(6):  23-28.  doi:10.13251/j.issn.0254-6051.2023.06.004

  Abstract ( 35 )   PDF (2785KB) ( 30 )  

  Melting and casting process of Al-6.3Zn-2.0Mg-0.32Cu aluminum alloy ingots was investigated by optical microscope (OM), field emission scanning electron microscopy (SEM) and X-ray diffraction analyzer (XRD) in aspects of furnace charge, melting, in-furnace refining, online purification treatment of melt and casting process parameters. The results show that the hydrogen content of melt can be controlled within 0.14 mL/100 g, and slag content and ingot segregation can be reduced by controlling the reflow material within 10% and the Zn/Mg ratio being set to 3.2, the melting carries out by a double-rotor refining system, and the casting speed, casting temperature and cooling water flow rate being set to 64-69 mm/min, 700-715 ℃ and 138-144 m³/h/root, respectively, which provides data support for the subsequent production of aluminum alloy ingots of this specification.

  Effect of reverse phase transformation annealing time on microstructure and mechanical properties of 5%Mn cold-rolled medium manganese steel

  Fan Lifeng, Guo Zhiyu, Zhang Zhipeng, Yue Erbin, Xiao Lijun, Gao Jun, He Jianzhong

  2023, 48(6):  29-35.  doi:10.13251/j.issn.0254-6051.2023.06.005

  Abstract ( 44 )   PDF (3671KB) ( 35 )  

  Effect of reverse phase transformation annealing time on microstructure and mechanical properties of 5%Mn cold-rolled medium manganese steel was studied by means of optical microscope, scanning electron microscope, transmission electron microscope, and X-ray diffraction. The results show that the microstructure of the cold-rolled medium manganese steel after quenching at 930 ℃ for 20 min and reverse phase transformation annealing at 675 ℃ for 5-40 min is also martensite, ultra fine grain ferrite and austenite with different volume fractions. When holding time is 5 min, the microstructure continues to be quenched lath martensite, and the volume fraction of austenite is only 8.5%. As the holding time extendes to 10, 20, and 30 min, the volume fraction of austenite increases to 10.56%, 19.7%, and 22.34%, respectively, while the holding time continues to extend to 40 min, the austenite volume fraction decreases to 20.53%. With the increase of holding time, the tensile strength continues to increase, and the elongation, product of strength and elongation increases first and then decreases, the product of strength and elongation reaches the maximum at 30 min, and the comprehensive mechanical properties are the best.

  Effect of quenching and tempering temperature on microstructure and hardness of hardened H13 steel with Ce

  Chen Shuo, Chen Xuemin, Xu Qihao, Yang Lilin, Tang Zuchuan, Zhao Liping

  2023, 48(6):  36-40.  doi:10.13251/j.issn.0254-6051.2023.06.006

  Abstract ( 64 )   PDF (2316KB) ( 36 )  

  H13 steel with different contents of rare earth Ce was austenitized at different temperatures for 30 min, air-cooling hardened, and then twice tempered at different temperatures for 2 h, air cooling, and then the structure observation and hardness test were carried out. The results shows that when the quenching temperature reaches 1040 ℃, the carbide on the matrix structure and grain boundary is reduced, and the lath martensite is clearer. When the tempering temperature is 580 ℃, the microstructure is tempered martensite + tempered troostite. When the tempering temperature exceeds 600 ℃, and the carbides gather and grow. Therefore, the best heat treatment process is quenched at 1040 ℃ + twice tempered at 580 ℃. When the rare earth Ce content is 0.026%, the grain of the tested steel is the finest, the structure is the most uniform, the hardness is the highest, the quenching hardness is 650.6 HV30, and the tempering hardness is 391.4 HV30.

  Effect of pulsed magnetic field on surface hardness and microstructure of TC4 titanium alloy

  Chen Menghao, Wang Zhefeng, Han Jin, He Ruijun, Zhang Wangfeng, Guo Jiaqi, Kong Lingli, Ni Zhiming

  2023, 48(6):  41-46.  doi:10.13251/j.issn.0254-6051.2023.06.007

  Abstract ( 69 )   PDF (2134KB) ( 26 )  

  In order to improve the surface hardness of TC4 titanium alloy, the pulsed magnetic field and copper sheet driving were adopted to test the TC4 titanium alloy sheet with different voltages and impact times, then the test results were analyzed by using Vickers hardness tester, optical microscope and finite element simulation. The results show that the pulsed magnetic field impact can significantly improve the surface hardness of the TC4 titanium alloy sheet, the maximum hardness value after the treatment is 376.9 HV0.1, and rises 10.9%. In addition, the β phase becomes finer and uniformly distributed. Furthermore, within a certain range, higher energy and multiple impacts are the effective ways to improve the surface hardness of the TC4 titanium alloy sheet.

  Effect of tempering temperature on microstructure and properties of A330M ultra-high strength steel

  Xu Zhongzhi, Han Shun, Geng Ruming, Lei Simin, Li Yong, Wang Chunxu

  2023, 48(6):  46-51.  doi:10.13251/j.issn.0254-6051.2023.06.008

  Abstract ( 38 )   PDF (4069KB) ( 36 )  

  Effect of tempering temperature on microstructure and mechanical properties of A330M ultra-high strength steel in the range of 180-380 ℃ was studied by means of scanning electron microscope (SEM), transmission electron microscope (TEM) and mechanical properties test. The results show that the mechanical properties of the A330M steel are obviously affected by the tempering temperature, and the impact absorbed energy decreases with the increase of tempering temperature. When tempered between 180-380 ℃, the impact fracture morphology of of the tested steel is dimple, quasi-cleavage and intergranular fracture in turn with the increase of tempering temperature, and the ductile fracture changes to brittle fracture. After tempering at different temperatures, the microstructure is mainly composed of lath martensite and retained austenite, martensite lath precipitates a large amount of parallel aciculate ε-carbides, with the increase of tempering temperature, ε-carbide size increases, higher tempering temperature will lead to further precipitation of cementite, resulting in tempering brittleness, reducing the impact property of the tested steel. When tempered at 220 ℃, excellent strength and toughness matching can be obtained, basically eliminating residual stress, with good tempering stability, tensile strength up to 2207 MPa, impact absorbed energy up to 34 J.

  Effect of induced cladding temperature on high temperature oxidation resistance of FeCoCrNiMoBSi high entropy alloy coating

  Zhang Xiaoxian, Xie Fang, Zhai Changsheng, Liu Gang, Peng Yinli, Li Ben, Wu Bingbing, Cai Guangyu

  2023, 48(6):  52-57.  doi:10.13251/j.issn.0254-6051.2023.06.009

  Abstract ( 33 )   PDF (3515KB) ( 26 )  

  In order to solve the oxidation problem of ultra-supercritical boiler tubes and other high temperature components under extreme high temperature conditions, the feasibility of the preparation process of high temperature oxidation resistant FeCoCrNiMoBSi high entropy alloy coating was explored. Three kinds of FeCoCrNiMoBSi high entropy alloy coatings were prepared on 15CrMo substrate by flame thermal spraying combined with induction cladding at different temperatures, as well as the high temperature oxidation tests were carried out on the three kinds of coatings and the substrate respectively. The phase composition, microstructure and elemental composition of the coatings before and after oxidation were compared by means of metallographic observation, XRD, SEM and EDS analysis, their high temperature oxidation performance was analyzed. The results show that the oxidation kinetics curves of the coatings claded at 990, 1020 and 1050 ℃ all follow the parabola rule. After oxidation at 900 ℃ for 120 h, the oxidation mass gain of the above three coatings is 0.58, 0.50 and 0.54 mg/cm² respectively, while the oxidation mass gain of the substrate is 73.28 mg/cm², which is about 146 times of the oxidation mass gain of the coating. It can be seen that the high temperature oxidation resistance of the coating is much better than that of the substrate, and the coating melted at 1020 ℃ has the best oxidation resistance.

  Effect of rolling temperature on microstructure and wear resistance of AZ31 magnesium alloy

  Li Qingfen, Deng Bin, Wu Yuanzhi, Qu Weiming, Liu Xianlan, Xiang Sicheng, Wang Ke, Yin Haoyi

  2023, 48(6):  58-62.  doi:10.13251/j.issn.0254-6051.2023.06.010

  Abstract ( 34 )   PDF (3755KB) ( 26 )  

  AZ31 magnesium alloy after solution treatment was rolled at different rolling temperatures (200, 300 and 400 ℃) to study the effect of rolling temperature on microstructure and wear resistance. The results show that the AZ31 alloy is completely recrystallized after rolling, and the grains are significantly refined, and the second phase is more uniformly and finely distributed. With the increase of rolling temperature, the grain and second phase sizes of the rolled alloy increase, the effect of fine grain strengthening and dispersion strengthening are weakened, the hardness decreases, the thermal stability and wear resistance decrease, and the wear mechanism changes from abrasive wear to adhesive wear.

  Effect of heat treatment on microstructure and mechanical properties of WC-Co cemented carbide anvil

  Hao Shiming, Mao Zhiping, Xie Jingpei

  2023, 48(6):  63-67.  doi:10.13251/j.issn.0254-6051.2023.06.011

  Abstract ( 30 )   PDF (3691KB) ( 31 )  

  In order to eliminate the processing defects introduced in the hammer processing, the WC-Co cemented carbide anvil was annealed at 600 ℃ for 5 h, and its microstructure, WC grain contiguity, WC grain size distribution and hardness were studied by means of scanning electron microscope (SEM), XRD and microhardness tester. The results show that the heat treatment makes the distributions of cobalt element and WC particle size in the WC-Co cemented carbide anvil more uniform, the grain contiguity of tungsten carbide decreases, and the alloy hardness increases.

  Vacuum heat treatment technology for prolonging service life of 20Cr13 steel fertilizer extrusion roller

  Li Bo, Fang Ying, Li Shuangxi

  2023, 48(6):  68-73.  doi:10.13251/j.issn.0254-6051.2023.06.012

  Abstract ( 27 )   PDF (2563KB) ( 27 )  

  In order to prolong the service life of 20Cr13 steel fertilizer extrusion roller, the hardness, microstructure, and acid corrosion resistance of the 20Cr13 stainless steel after vacuum quenching at different temperatures and tempering at 180 ℃ were studied using metallographic microscope, scanning electron microscope, and Rockwell hardness tester. The results show that when the specimen is quenched in a wide temperature range above Ac₁, a certain amount of martensite structure can be obtained to improve the hardness. As the quenching temperature increases, the austenitization becomes more complete and the alloying degree of the matrix becomes higher, and as the austenite grains gradually grow, the residual austenite increases. Therefore, the hardness of the steel first increases and then decreases after quenching and tempering, but the corrosion resistance improves with the increase of quenching temperature. At the same time, by changing the right angle of the inner hole line cutting keyway of the quenched roller to R0.5-R1, the probability of longitudinal cracks cracking along the bottom right angle of the keyway during use is effectively reduced. After quenching at 1050 ℃ and tempering at 180 ℃, the on-site use verification of the roller shows that obtaining a reasonable microstructure after quenching is more conducive to improving the wear and corrosion resistance of the roller than simply pursuing high hardness, greatly improving its service life. After improvement, the average lifespan of extruded fertilizer particles for each pair of rollers reaches 800-1000, which is more than twice the lifespan compared to that of 1000 ℃ quenched and 180 ℃ tempered rollers.

  Effect of annealing on microstructure and mechanical properties of TC25G titanium alloy

  Wang Xiaowei, Dong Yu, Wang Deyong, Yang Lixin, Li Dongkuan, Zhang An, Che Anda, Ma Siqin

  2023, 48(6):  74-79.  doi:10.13251/j.issn.0254-6051.2023.06.013

  Abstract ( 25 )   PDF (3126KB) ( 35 )  

  Effect of different annealing on microstructure and properties of TC25G titanium alloy bars was studied. The results show that the content of primary α phases is very sensitive to the single annealing temperature, and as the single annealing temperature increases, the strength of the alloy increases slowly, and the plasticity increases first and then decreases. With the prolongation of single annealing holding time, the size of primary α phase tends to increase, and the transformation β phase is coarsened gradually, the holding time has a significant impact on plasticity. With the increase of cooling rate, the plasticity decreases obviously and the strength increases obviously. The secondary annealing temperature has an effect on the strength and plasticity of the bar, when the secondary annealing temperature exceeds 600 ℃, the strength increases slightly, while the elongation and reduction of area significantly decrease. The secondary annealing temperature has significant effects on the impact property of the alloy. When the secondary annealing temperature exceeds 600 ℃, the impact property cannot meet the requirements compared to ≥24 J specified in the technical conditions. When the secondary annealing temperature does not exceed 560 ℃, the impact property is significantly improved, meeting the technical requirements.

  Effect of post-weld aging on stress corrosion sensitivity of 7020 aluminum alloy

  Zhou Yongdong, Gong Lanfang, Liu Ziyi

  2023, 48(6):  80-84.  doi:10.13251/j.issn.0254-6051.2023.06.014

  Abstract ( 23 )   PDF (3211KB) ( 24 )  

  Welded joints of 7020 aluminum alloy are often cracked due to stress corrosion. In order to address the above problems, sample of the same welding process were treated by post-weld heat treatment processes of natural aging, one-step aging, two-step over-aging, retrogression and re-aging (RRA). By analyzing the surface micromorphology, microstructure, slow strain rate tensile stress corrosion test results and fracture of the specimens undergone different post-treatments, the effect of different post-weld aging treatment on the stress corrosion cracking resistance of the 7020 welded joints were studied. The results show that after the regression re-aging treatment, the number of pores is decreased, the precipitates free zone is widened, the grain boundary precipitates disappear, and the grain precipitates are refined, by which the welded joints of the 7020 aluminum alloy obtains the lowest stress corrosion tendency.

  Effect of heat treatment process on microstructure and mechanical properties of 17-4PH stainless steel

  Wang Xuming, He Wenwu, Wei Haidong, Chang Xin

  2023, 48(6):  85-88.  doi:10.13251/j.issn.0254-6051.2023.06.015

  Abstract ( 53 )   PDF (2062KB) ( 86 )  

  In order to study structure and properties of 17-4PH stainless steel, a heat treatment process plan was designed and conducted, and then the effects of intermediate adjustment treatment, solution treatment and aging temperature on microstructure and mechanical properties of the 17-4PH steel were studied by means of thermal dilatometric test, metallographic observation, and tests of mechanical properties, hardness and impact property. The results show that the intermediate adjustment treatment can refine the martensite structure, the carbide particles are precipitated in the martensite and austenite, and there is a relatively stable reverse transformation austenite formation. When the solution treatment temperature increases, the increase of strength is not obvious. After the intermediate adjustment treatment, when the aging temperature increases, the content of the reverse transformed austenite structure increases, the impact property increases, but the strength decreases significantly.

  Effect of austenitizing temperature on microstructure and properties of chromium and vanadium alloyed high manganese steel

  Yan Hongtao, Wang Yongjin, Liu Dandan, Qi Hailong, Yang Guang, Mu Rong

  2023, 48(6):  89-94.  doi:10.13251/j.issn.0254-6051.2023.06.016

  Abstract ( 32 )   PDF (3438KB) ( 26 )  

  Effect of austenitizing temperature on microstructure, mechanical properties, and wear resistance of chromium vanadium alloyed high manganese steel was investigated by means of optical microscope, scanning electron microscope, and MLD-10 dynamic load abrasive wear testing machine. The results show that at the austenitizing temperature of 1070 ℃, due to the presence of numerous point like carbides in the microstructure, the tensile strength, yield strength, and hardness of the tested steel reach their maximum values, which are 831 MPa, 460 MPa and 256.6 HBW, respectively. The impact absorbed energy is relatively high, reaching 70.9 J, and its fracture form is quasi cleavage fracture. During impact arrasive wear test process, as the impact energy increases, the wear resistance of the tested steel first increases and then decreases. Moreover, at higher impact energy, the tested steel exhibits better wear resistance when austenitized at 1070 ℃ compared to 1100 ℃.

  Microstructure and intergranular corrosion resistance of 6111 aluminum alloy after different heat treatment processes

  Chi Rui, Xu Zhiyuan, Li Tao, Li Yancheng, Wang Zhidong, Zhang Hua

  2023, 48(6):  95-100.  doi:10.13251/j.issn.0254-6051.2023.06.017

  Abstract ( 29 )   PDF (7505KB) ( 28 )  

  Microstructure and intergranular corrosion of 6111 aluminum alloy solution treated and pre-aged at different temperatures were studied by means of metallographic microscope, transmission electron microscope, X-ray diffractometer. The results show that after solution treatment and pre-aging at different temperatures, the grains are recrystallized, some of which are elongated along the rolling direction. The average grain size is 60-70 μm after solution treatment at 520 ℃ and 540 ℃. The average grain size solution treated at 560 ℃ is slightly larger than that solution treated at 520 ℃ and 540 ℃, about 80 μm. The intergranular corrosion resistance solution treated at 520 ℃ and pre-aged at 80 ℃ is the worst, the corrosion depth is 191.59 μm, the Q phase is continuously distributed at the grain boundary, and the surface grain size is small. The intergranular corrosion resistance solution treated at 540 ℃ and pre-aged at 80 ℃ is the best, and the corrosion depth is 59.63 μm. The Q phase is intermittently distributed at the grain boundary, and no surface grains with smaller size are found.

  Optimization of heat treatment process for high strength steel rail R400HT

  Li Junzheng, Han Zhijie, Zhao Haitao

  2023, 48(6):  101-106.  doi:10.13251/j.issn.0254-6051.2023.06.018

  Abstract ( 21 )   PDF (1809KB) ( 23 )  

  Taking high strength eutectoid rail R400HT as research object, and the microstructure transformation and hardness properties of the R400HT steel rail during cooling were tested, and the CCT curves of the R400HT steel rail was established. On this basis, the range of main heat treatment process parameters of the R400HT steel rail was developed, and the thermal simulation orthogonal experiment was carried out. Through statistical analysis of the test results, the optimal heat treatment process scheme of the R400HT steel rail was obtained. The results show that the optimal treatment process of the R400HT rail steel is that the inlet temperature of 780-800 ℃, the outlet temperature of 480-510 ℃, and the cooling rate of 3.0-3.5 ℃/s. The industrial trial production is carried out according to the above process. The hardness of the trial R400TH rail is 425.5-428.3 HBW, the tensile strength is 1425-1440 MPa, and the microstructure is pearlite, which achieves the expected goal.

  Effect of surface strengthening on microstructure and properties of C17200 beryllium bronze substrate for logging while drilling equipment

  Xu Zhigang, Yang Yang, Yang Zhongna, Yao Xiaojiang, Qin Caihui, Wang Haipeng, Liu Liang

  2023, 48(6):  107-113.  doi:10.13251/j.issn.0254-6051.2023.06.019

  Abstract ( 32 )   PDF (4400KB) ( 33 )  

  According to fatigue failure case of C17200 beryllium bronze logging while drilling (MWD) equipment, the influence of two different surface strengthening processes on microstructure and properties of the C17200 beryllium bronze substrate were investigated, and the failure mechanism was discussed, then the suitable strengthening process was determined. Laser cladding and high-velocity oxygen-fuel (HVOF) were adopted to clad ceramic coating on the adapter. The microstructure and properties of coated and uncoated specimens were compared and analyzed. Optical microscope (OM) and scanning electron microscope (SEM) were used to characterize microstructure of the substrate, and a high-resolution field emission scan electron microscopy (FESEM) and energy dispersive spectrometer (EDS) was used to characterize the grain boundary phase and intragranular phase composition of the over-aged microstructure of the beryllium bronze. The mechanical properties were tested by means of hardness meter and material testing machines. The results show that the heat input of laser cladding has an adverse effect on microstructure and mechanical properties of the beryllium bronze substrate. The local temperature of the substrate reaches 350 ℃, the microstructure is over-aged, and the increase of grain boundary reaction brings a large number of γCu88be12 nodules which results in the strength decreases and the lowest hardness of the substrate is only 12 HRC. However, the HVOF has little effect on microstructure and properties of the substrate, and the microstructure and properties are normal without aged structure. It is concluded that the HVOF sprayed ceramic coating can improve the reliability and safety of the adapters, which is suitable for the surface reinforcement of C17200 beryllium bronze for MWD equipment.

  Effect of heat treatment temperature on mechanical properties of commercial pure titanium for metal diaphragms

  Ouyang Ruijie, Miao Chunhao, Zhang Hai, Yang Wenbo, Dong Xiangyu

  2023, 48(6):  114-117.  doi:10.13251/j.issn.0254-6051.2023.06.020

  Abstract ( 26 )   PDF (1344KB) ( 27 )  

  Effect of heat treatment temperature on mechanical properties of TA1ELI pure titanium plate for metal diaphragm was studied in order to improve the properties of raw materials, plasticity and inversion performance of metal diaphragms. The results show that compared with the original state, after vacuum heat treatment at 610, 660 and 710 ℃, the tensile strength, proof strength at 0.2% non-proportional extension and percentage reduction of area decrease, but the elongation increases with the increase of heat treatment temperature. When vacuum heat treatment is performed at 710 ℃, the elongation can reach more than 60%. Through the study of heat treatment process, the influence of different heat treatment temperature on mechanical properties of the material is obtained. Reasonable heat treatment process parameters can be formulated according to the actual design characteristics of the metal diaphragms.

  Three stage nitriding process of 25Cr3MoA steel gear

  Zhang Haiwei, Ma Xiaofeng, Ma Ning, Shen Lin, Jiang Dong

  2023, 48(6):  118-120.  doi:10.13251/j.issn.0254-6051.2023.06.021

  Abstract ( 37 )   PDF (1749KB) ( 52 )  

  Nitriding test of 25Cr3MoA steel gear was carried out. The results show that when the depth of nitrided layer is 0.35-0.41 mm, the problem of the pulse-like and network-like nitride appearing in the microstructure of gears and internal splines during long-term nitriding can be solved by means of the three-stage nitriding process.

  Effect of solution treatment on microstructure and properties of Al-Zn-Cu-Mg-Zr-Ce alloy

  Guo Fengjia, Ma Fang, Xiao Fulai, Chi Rui, Wang Jingtao, Sun Ning

  2023, 48(6):  121-125.  doi:10.13251/j.issn.0254-6051.2023.06.022

  Abstract ( 31 )   PDF (2040KB) ( 34 )  

  Effect of solution treatment on microstructure and properties of Al-7.5Zn-1.5Cu-1.5Mg-0.12Zr-0.1Ce aluminum alloy was studied by means of metallographic microscope, scanning electron microscope and tensile testing machine. The results show that under the solution treatment process with temperature range of 460-480 ℃ and holding time of 30-120 min, after single stage solution treatment at 470 ℃ for 2 h, recrystallization occurs and most of the second phase dissolves into the matrix. Compared with other single stage solution treatment, the solution effect is the best, and the comprehensive mechanical properties is good after aging treatment. After 450 ℃×1 h+475 ℃×1 h two-stage solution treatment, due to the release of deformation energy at low temperature and low recrystallization degree, the solution effect is better than that of the single stage solution treatment, and the comprehensive mechanical properties of the alloy is better after aging treatment.

  Influence of solution treatment and aging temperature on microstructure and shear strength for TC4 titanium alloy bolt

  Sun Hongye, Qi Yue, Yu Chuankui, Liu Tong, Ren Shizhang, Ma Ke, Ma Xu

  2023, 48(6):  126-129.  doi:10.13251/j.issn.0254-6051.2023.06.023

  Abstract ( 60 )   PDF (2780KB) ( 26 )  

  Effects of solution treatment temperature and aging temperature on microstructure and shear strength of TC4 titanium alloy were studied by SEM and material testing machine. The results show that comparing the microstructure of the aviation bolts made of the TC4 titanium alloy at different regions including the head center, head edge, R, and bolt core, it is found that due to the faster cooling rate of the head edge compared to the center, where the content of secondary α phase transformed from β phase is higher, and the grain aggregation and growth are more obvious. At the solution temperature of the β single-phase zone, the bolt core and other internal areas are distributed with crisscross martensite, and the dispersion strengthening effect is better. In the solution treatment temperature range of 800-1020 ℃, the shear strength basically increases with the increase of solution treatment temperature. When the solution treatment temperature is 1020 ℃, the shear strength first increases and then decreases with the increase of aging temperature, and the shear strength of the TC4 titanium alloy is the highest after solution treatment at 1020 ℃ and aging at 538 ℃.

  Effect of cooling process on microstructure and mechanical property of Q500qE bridge steel

  Wu Fengjuan, Yang Hao, Qu Jinbo

  2023, 48(6):  130-135.  doi:10.13251/j.issn.0254-6051.2023.06.024

  Abstract ( 35 )   PDF (3945KB) ( 28 )  

  Taken high-strength bridge steel Q500qE as the object, the influence of different cooling processes on its microstructure and properties were studied. The results show that under the low speed cooling process (5 ℃/s), the microstructure mainly consists of granular bainite with coarse M/A islands, which exhibits a low strength and poor toughness, in spite of a low yield ratio. The high speed cooling process (25 ℃/s) leads to a lath bainite dominant microstructure with spherical and rod-like M/A islands, with a much improved strength and toughness, but a high yield ratio. Upon the interrupted cooling process (20 ℃/s+air cooling+20 ℃/s), a multiphase microstructure, containing polygonal ferrite, lath bainite and granular bainite, with fine and dispersed M/A islands, is obtained, which results in the lowest yield ratio, highest toughness, and best overall properties.

  Microstructure and Properties

  Annealing microstructure and properties of 0.27 mm thick high-strength non-oriented electrical steel

  Chen Tianyu, Song Xinli, Peng Yufan, Jia Juan, Cheng Zhaoyang

  2023, 48(6):  136-141.  doi:10.13251/j.issn.0254-6051.2023.06.025

  Abstract ( 26 )   PDF (3922KB) ( 31 )  

  In order to study the effect of annealing temperature on microstructure evolution and properties of 0.27 mm thick high-strength non-oriented electrical steel, the cold-rolled tested steel sheet was annealed at 800-960 ℃ for 3 min, and then the microstructure was analyzed by OM, the grain orientation and microtexture were analyzed by EBSD, the iron loss and magnetic induction strength were tested by magnetic equipment, and the mechanical properties were tested by universal tensile testing machine. The results show that complete recrystallization occurs and equiaxed ferrite is obtained in the cold rolled steels annealed at different temperatures for 3 min. With the increase of annealing temperature, the average grain size increases from 9.56 μm to 72.89 μm, and the volume fraction of {111} plane texture, which is unfavorable to magnetic properties, first increases and then decreases. The high frequency iron loss P_1.0/400 reduces from 28.09 W/kg to 16.02 W/kg, and the average value of magnetic induction intensity B₅₀₀₀ is in the range of 1.63-1.64 T. With the increase of annealing temperature from 800 ℃ to 960 ℃, the grain size is increased and the strengthening effect of grain refinement is weakened, the yield strength reduces from 510 MPa to 437 MPa, and the tensile strength decreases from 609 MPa to 531 MPa.

  Microstructure and thermal impact property of B-Y doped silicon compound coating on TiAlNb9 alloy surface

  Wang Cunxi, Liang Guodong, Tian Xingda, Li Yongquan

  2023, 48(6):  142-146.  doi:10.13251/j.issn.0254-6051.2023.06.026

  Abstract ( 26 )   PDF (1672KB) ( 22 )  

  B-Y doped silicon compound coating was prepared on surface of TiAlNb9 alloy by pack cementation process with 15Si-4B-8NaF-2Y₂O₃-71Al₂O₃(mass fraction, %), the structure and phase composition of the co-deposition coating were analyzed by means of scanning electron microscopy, X-ray diffractometry and electron probe, and the thermal impact properties of Si-B-Y co-deposition coating and TiAlNb9 substrate were compared. The results show that the Si-B-Y co-deposition coating prepared by holding at 1050 ℃ for 6 h has an uniform and dense composite structure with a thickness of about 14 μm. The outer layer consists of TiB₂ and (Ti, Nb)Si₂ phases, the middle layer consists of (Ti, Nb)₅Si₃ phase, and the inner layer consists of TiAl₂ and small amounts of TiB phases. Under the thermal impact at 1000 ℃, the substrate cracks in the TiAlNb9 alloy continue to grow, and there are bifurcated cracks in the middle, the penetrating cracks appear after 47 times of thermal impact. However, the Si-B-Y co-deposition coating has a long crack initiation time, the initiation of cracks is frequent and dispersive, and with the increase of the number of thermal impact, several small cracks finally merge into one place and penetrate through the substrate after 59 times of thermal impact, but the cracks do not extend horizontally at the interface of the film base, and the whole deposition layer does not fall off, indicating that Si-B-Y co-deposition coating can improve the thermal impact property of the TiAlNb9 alloy to a certain extent.

  Hot deformation behavior and microstructure evolution of 7075 aluminum alloy

  Li Chen, Wang Hebin, Ou Ping, Wang Hang, Wang Junfeng, Zhang Jishan

  2023, 48(6):  147-156.  doi:10.13251/j.issn.0254-6051.2023.06.027

  Abstract ( 58 )   PDF (4768KB) ( 30 )  

  Hot compression test was carried out for the as-solid solution treated 7075 aluminum alloy by MMS-100 thermo-mechanical simulator and the flow stress constitutive model of the alloy was constructed at 350-450 ℃ and strain rate among 0.01-10 s^-1. Based on the dynamic material model and microstructure, the optimum process window for the hot deformation was determined. The results show that after solution treatment at 475 ℃, the MgZn₂ phase is all dissolved back into the matrix, and with the increase of solution treatment time, the fraction of Al₂CuMg and Al₇Cu₂Fe dissolved in matrix increases. The flow stress of the alloy increases with the decrease of temperature and increase of strain rate, and the hot deformation activation energy calculated is approximately Q=153.724 kJ/mol. The power dissipation coefficient gradually increases with the temperature increasing and strain rate decreasing, the flow instability zones move to higher strain rate with the increase of strain, the optimum processing window of the alloy is deformation temperature of 420-450 ℃ and strain rate of 0.01-0.02 s^-1.

  Precipitation and temperature field simulation of high molybdenum non-magnetic steel during isothermal deformation

  Jiang Yiming, Qu Huapeng, Lang Yuping, Feng Hanqiu, Chen Haitao, Li Xiangming

  2023, 48(6):  156-161.  doi:10.13251/j.issn.0254-6051.2023.06.028

  Abstract ( 32 )   PDF (3597KB) ( 31 )  

  Temperature field of water cooling process in the isothermal deformation process of a high molybdenum non-magnetic steel was simulated by the DEFORM finite element simulation software, and the sensitive precipitation temperature range of the precipitated phases was obtained with the thermal insulation test of the tested steel, and the types of precipitated phases in the isothermal deformation process were studied. The results show that the sensitive precipitation temperature range is 700-900 ℃. According to the simulation results, the maximum temperature difference of the surface and the center of the specimen is 300 ℃, and it is considered that the center exists a high temperature zone close to the sensitive precipitation temperature range in the water cooling process, resulting that the risk of precipitation is greatly increased. The isothermal deformation process has a promoting effect on the nucleation and growth of the precipitated phases, and the precipitated phase in the isothermal deformed specimen and as-aged specimen is determined to be Cr₂₃C₆ according to the XRD diffraction pattern calibration.

  Solution treatment process and hot deformation behavior of 12Cr-F/M steel

  Tang Qi, Pan Qianfu, Wu Yu, Jiang Wenlong, Liu Sanzheng, Huang Lanlan

  2023, 48(6):  162-166.  doi:10.13251/j.issn.0254-6051.2023.06.029

  Abstract ( 39 )   PDF (3727KB) ( 20 )  

  Microstructure evolution of 12Cr-F/M steel under different heat treatment processes (heating at 1100-1200 ℃ and holding for 1-2 h) was studied, and hot deformation behavior of the steel under deformation temperature of 800-1000 ℃ and strain rate of 0.01-10 s^-1 was also studied by using thermal simulation compression tests. The results show that as the solution treatment temperature increases, the ferrite grain size in the 12Cr-F/M steel first decreases and then increases. With the prolongation of holding time, the ferrite grains all grow and coarsen. After the solution treatment, some low melting point Laves precipitates in the matrix decompose and dissolve in the matrix, and the total amount gradually reducing. After solution treated at 1150 ℃ for 1 h, the ferrite grain size in the steel matrix is smaller, while the amount of Laves precipitates is less. The flow stress of the 12Cr-F/M steel during high-temperature deformation decreases with increase of the temperature, and increases with increase of the strain rate.

  Hot deformation behavior and dynamic recrystallization law of GH2150 alloy

  Lou Haonan, Liu Jiaao, Mei Feiqiang, Cao Yichao, Song Xiyu, Zhang Weihong

  2023, 48(6):  167-172.  doi:10.13251/j.issn.0254-6051.2023.06.030

  Abstract ( 44 )   PDF (4108KB) ( 25 )  

  Hot deformation behavior and dynamic recrystallization evolution of GH2150 alloy under different test parameters were studied by hot compression test with Gleeble-3800 thermal simulation machine. The results show that in the range of 1000-1200 ℃, when the strain rate is 0.1-5 s^-1 and the deformation amount is 30%, 50% and 70%, respectively, the peak stress of the alloy decreases with the increase of deformation temperature and decrease of strain rate. Combined with the true stress-true strain curves and Arrhenius formula, the hot deformation constitutive equation of the GH2150 alloy is obtained. The average relative error between the calculated and the actual results is 4.36%, and the correlation coefficient is R=0.992, showing in good agreement. It is found by drawing dynamic recrystallization diagram that large deformation is beneficial to increase the recrystallization fraction of the GH2150 alloy. The dynamic recrystallization behavior is mainly affected by deformation temperature at 50% deformation, and low strain rate at 70% deformation is more beneficial to the recrystallization.

  Morphology of 6Al3Mg coating inhibition layer and its effect on coating adhesion

  Li Yan, Li Tiejun, Liu Guanghui, Xu Chengliang, Qin Hancheng

  2023, 48(6):  173-177.  doi:10.13251/j.issn.0254-6051.2023.06.031

  Abstract ( 33 )   PDF (3777KB) ( 22 )  

  6Al3Mg coating on the steel substrate was removed by electrochemical stripping but with the inhibition layer between the coating and the substrate retained. The morphologies of the inhibition layers between the specimens with good and with poor coating adhesion was compared by means of scanning electron microscope and electron probe. The results show that the morphology of the inhibition layers of the 6Al3Mg coating is granular, and that Si and Al elements completely coincide at the interface between the coating and the substrate. Due to the large amount of Al inside the coating, the distribution state of Si can be used to characterize the formation of the inhibition layer. For the specimens with good coating adhesion, the distribution of Si presents a continuous state, and the formation of inhibition layer is good, and dense granular inhibition layer can be observed by scanning electron microscope. While for the specimens with poor coating adhesion, the distribution of Si is discontinuous and the formation of inhibition layer is poor.

  Microstructure and Properties

  Thermoplastic and constitutive equations of microalloyed gear steel 18CrNiMo7-6 for carburizing

  Yang Shaopeng, Zhou Dayuan, Wang Yaqian, Jing Hongliang, Wu Shengfu, Hu Fangzhong, Wang Kaizhong, Wang Maoqiu

  2023, 48(6):  178-185.  doi:10.13251/j.issn.0254-6051.2023.06.032

  Abstract ( 26 )   PDF (3524KB) ( 28 )  

  Hot compression test was subjected on Nb microalloyed gear steel 18CrNiMo7-6 by Gleeble-2000D thermal simulation testing machine to investigate the thermoplastic properties of the tested steel at deformation temperatures between 900-1100 ℃ and strain rates at 0.01, 0.1, 1 and 10 s^-1, respectively. The activation energy of thermal deformation was calculated, and the constitutive equation of peak stress was constructed. The results show that the stress-strain curves of the tested steel exhibits typical dynamic recrystallization characteristics, which is the main softening mechanism. At the same strain rate, the higher the deformation temperature, the better the thermoplastic properties, and dynamic recrystallization is a thermal activation process. The main carbides present in the tested steel are calculated by using Thermo-calc thermodynamic software to be M₂₃C₆, and NbC. The full solution temperature of NbC reaches 1180 ℃, and Nb is mainly composed of NbC precipitates. The precipitation content of NbC at different deformation temperatures is 0.0343%, 0.0322%, 0.0289%, 0.0236% and 0.0156%, respectively. The peak stress constitutive equation of the tested steel is established by using Arrhenius hyperbolic sine function. The activation energy of hot deformation is determined to be Q=344.55 kJ/mol, and the average error between the peak stress predicted by the model and the measured peak stress is 1.5%.

  Microstructure and properties of non-quenched and tempered steel with high nitrogen content

  Mu Xianglin, Chao Yuelin, Ma Yue, Sun Qisong, Cheng Sihua, Liu Kun

  2023, 48(6):  186-190.  doi:10.13251/j.issn.0254-6051.2023.06.033

  Abstract ( 28 )   PDF (3234KB) ( 32 )  

  Microstructure and properties of three 45MnVS-based non-quenched and tempered steels with different vanadium and nitrogen contents were studied by using EBSD, TEM and performance test, etc. The results show that by increasing the N content, the precipitation of V(C, N) and VN can be promoted, and the significant grain refinement effect can be obtained with a large number of fine and dispersed precipitates as the nucleation sites to promote the pearlite transformation and pin the grain boundary. The high nitrogen non-quenched and tempered steel has good combination of strength and toughness, the yield strength reaches 580 MPa, and the impact absorbed energy reaches 57 J, when it is produced with the process of holding at 1150 ℃ for 60 min, and then initial rolling at 1000 ℃, final rolling at 900 ℃.

  Continuous cooling transformation curves and microstructure of new-type slot edge steel

  Xu Haifeng, Li Hai, Li Fengmin, Fu Shengmin, Ming Keyu, Yu Yan

  2023, 48(6):  191-196.  doi:10.13251/j.issn.0254-6051.2023.06.034

  Abstract ( 26 )   PDF (4338KB) ( 27 )  

  Continuous cooling transformation behavior of a new-type slot edge steel was studied by thermal dilatometer, optical microscope and Vickers hardness tester, and the continuous cooling transformation (CCT) curves were obtained. The results show that the CCT curve diagram includes high temperature ferrite-pearlite transition zone, middle temperature bainite transition zone and low temperature martensite transition zone. When the cooling rate is less than 0.14 ℃/s, it is mainly the high temperature ferrite-pearlite transition zone. When the cooling rate is 0.14-0.81 ℃/s, the room temperature microstructure is mainly composed of ferrite, pearlite and bainite. When the cooling rate is 0.81-1.62 ℃/s, the room temperature microstructure is composed of ferrite, pearlite, bainite and martensite. When the cooling rate is 4.05 ℃/s, the high temperature transformation zone disappears, and the room temperature microstructure is bainite and martensite. When the cooling rate is higher than 8.10 ℃/s, it is a single-phase transformation zone of martensite. With the cooling rate increasing from 0.06 ℃/s to 40.5 ℃/s, the microstructure changes from ferrite+pearlite to bainite +martensite, and finally to single-phase martensite, and the room temperature microhardness increases from 195 HV5 (0.06 ℃/s) to 515 HV5 (40.5 ℃/s).

  Microstructure and magnetic properties of non-oriented silicon steel for compressor motor after secondary annealing

  Lu Jiadong, Huang Jie, Zhang Jianlei, Yue Chongxiang

  2023, 48(6):  197-201.  doi:10.13251/j.issn.0254-6051.2023.06.035

  Abstract ( 34 )   PDF (3550KB) ( 25 )  

  Evolution of microstructure and magnetic properties of non-oriented silicon steel with different composition systems after secondary annealing by same process was studied. The results show that the ferrite grain size of non-oriented silicon steel is further increased and the magnetic properties are improved after secondary annealing treatment. The potential for improving the magnetic properties of non-oriented silicon steel is related to the composition, and is independent of the annealing temperature of the product. Among these composition systems, the ferrite grains of non-oriented silicon steel with high Al composition system are easier to grow up after secondary annealing treatment, and the magnetic properties is the best. The average grain size can reach 159 μm, and the core loss reduction is 1.14 W/kg. Besides, the magnetic induction of non-oriented silicon steel under low magnetizing force is significantly improved after secondary annealing treatment, and then the magnetic conductivity under low magnetizing force is improved. In the range of 0.5-1.5 T of motor working magnetic induction, the magnetic conductivity of non-oriented silicon steel after secondary annealing treatment is significantly higher. The core of the compressor motor is suitable for using non-oriented silicon steel with high Al composition system.

  Microstructure and properties of laser clad stainless steel on surface of oil damper piston rod

  Shi Yaojun, Zhou Huashan, Sun Hua, Xia Shaohua

  2023, 48(6):  202-205.  doi:10.13251/j.issn.0254-6051.2023.06.036

  Abstract ( 23 )   PDF (2872KB) ( 30 )  

  Two stainless steel powders were used to repair the surface of oil damper piston rod by laser cladding with HP-115 five-axis laser additive manufacturing system. The cladding quality, microstructure and microhardness of the stainless steel clad layer were analyzed by means of dye penetrant inspection, OM and microhardness tester. The corrosion resistance of the clad layer was studied by means of salt spray test chamber. The results show that two kinds of the clad layers are of good quality. The thickness of the clad layer and the heat-affected zone is about 0.65 mm and 0.5 mm, respectively. The microstructure of the clad layer mainly includes fine equiaxed and dendritic crystals, coarse cellular crystals and planar crystals. The average microhardness of 12.43%Cr and 16.26%Cr laser clad layers is 729 HV0.3 and 617 HV0.3, respectively, which is significantly improved compared to 250 HV0.3 of the substrate, and the microhardness of stainless steel powder 12.43%Cr laser clad layer meets the hardness requirements of the surface coating of oil damper piston rod. Compared with the substrate, both types of the stainless steel alloy powders laser clad layers have better corrosion resistance.

  Materials Research

  Effect of vanadium on microstructure and properties of hot-rolled invar alloy

  Feng Liang, Fan Xuanyu, Chen Jiwu, Yu Yanchong, Zhang Jinling

  2023, 48(6):  206-210.  doi:10.13251/j.issn.0254-6051.2023.06.037

  Abstract ( 25 )   PDF (2566KB) ( 28 )  

  Effect of trace V on microstructure, mechanical properties and thermal expansion properties of hot-rolled invar alloy was studied by means of optical microscopy, scanning electron microscopy (SEM), transmission electron microscopy (TEM), Vickers hardness tester, electronic universal tensile testing machine, and thermal expansion tester. The results show that grain size of the hot-rolled invar alloy significantly reduces and the microstructure is dramatically refined after adding 0.14%C and 0.63%V. The yield strength and tensile strength reach 348 MPa and 569 MPa, respectively, which is enormously improved compared with the conventional invar alloy. And the elongation is 40.0%, thermal expansion coefficient α_{20-200 ℃}=3.16×10^-6℃^-1, which is still at a low level. Solution strengthening, grain refinement and precipitation strengthening are the main reasons for improvement of mechanical properties of the invar alloy.

  Mechanical properties and corrosion resistance of hot-dipped Zn-Al-Mg coating based on first-principles

  Shi Jianqiang, Zhang Siyuan, Jiang Haitao, Li Shouhua, Cao Xiaoen, Tian Shiwei

  2023, 48(6):  211-218.  doi:10.13251/j.issn.0254-6051.2023.06.038

  Abstract ( 23 )   PDF (5069KB) ( 29 )  

  Effect of Zn, MgZn₂ and Mg₂Zn₁₁ in the hot-dipped Zn-Al-Mg coating products on the coating surface was systematically evaluated by using the first-principles calculation method. It is found that Mg₂Zn₁₁ has mechanical anisotropy and structural instability, which explains the phenomenon that the addition of Mg decreases the plasticity of the material. From the microscopic level, the reason why MgZn₂ improves the corrosion resistance of the hot-dipped Zn-Al-Mg coating is revealed. Mg atoms in MgZn₂ are found to effectively protect Zn atoms and hinder the corrosion of Zn atoms in MgZn₂ by Cl^-. The results deeply analyze the mechanical properties and corrosion resistance of the dipped Zn-Al-Mg coating from the theoretical aspect, which is helpful to guide the composition design and microstructure control of the coating, thus improving production efficiency.

  Effects of Mn content and annealing process on microstructure and properties of Cu-xMn-0.2Ce-0.2Zr alloys

  Xu Liangliang, Tan Dunqiang

  2023, 48(6):  219-228.  doi:10.13251/j.issn.0254-6051.2023.06.039

  Abstract ( 24 )   PDF (6919KB) ( 34 )  

  Effects of Mn content and annealing process on microstructure and properties of cold-rolled Cu-xMn-0.2Ce-0.2Zr (x=5, 6, 7, 8) alloys were studied by microstructure observation, X-ray diffraction analysis, and measurements of resistivity and temperature coefficient of resistance, micro Vickers hardness and Tafel polarization curves. The results show that with the increase of Mn content, the resistivity gradually increases, the temperature coefficient of resistance gradually decreases, and the preferential orientation of the alloy is (220)_Cu crystal plane. After annealing at 250, 350, 450 and 550 ℃, the alloy recovers and recrystallizes, so that the internal stress is reduced, and the micro Vickers hardness decreases with the increase of annealing temperature and the extension of holding time. When the Mn content is 7%, the alloy gets good comprehensive properties. After annealing at 350 ℃ for 1 h and water cooling, the resistivity is 22.3 μΩ·cm, and the temperature coefficient of resistance (TCR_{25-125 ℃}) is 116×10^-6/℃. The self corrosion potential and self corrosion current density are -0.172 V and 1.86 μA/cm², respectively, indicating that the Cu-7Mn-0.2Ce-0.2Zr alloy has excellent electrical properties in the working temperature range, and also has good corrosion resistance.

  Effect of Mg content on microstructure and properties of as-cast and as-rolled Al-Zn-Mg alloy

  Qin Xiangzhi, Zhao Jialei, Wang Kaige, Li Bing, Zhao Wei

  2023, 48(6):  229-236.  doi:10.13251/j.issn.0254-6051.2023.06.040

  Abstract ( 22 )   PDF (6599KB) ( 24 )  

  Effect of Mg content on the microstructure and mechanical properties of Al-Zn-Mg alloy and the effect of aging treatment after cold rolling on the strain hardening were studied by analysis of the as-cast and as-rolled microstructure and mechanical properties of Al-6.0Zn-xMg (x=2, 3, 4) alloys undergone different deformation+heat treatments with XRF, SEM, OM and universal tensile testing machine. The results show that the Mg content has only little effect on the morphology, grain size and second phase type in as-cast state, where the amount of non-equilibrium eutectic phase T-AlZnMg increases with increasing Mg content. When the Mg content is 4%, the amount of eutectic phase decreases, which is related to the increase of MgZn₂ disperse phase near the grain boundaries. After homogenization treatment, hot rolling and cold rolling processing, the high melting point Al₃Fe phase is broken and distributed along the rolling direction. The microstructure transforms as following: as-cast microstructure→fiber microstructure→recrystallized microstructure→fiber microstructure. With the increase of Mg content, the strengths of the as-rolled Al-6.0Zn-xMg alloys increase, but the increments decrease. Aging treatment after cold rolling results in an 80-100 MPa decrease of the strength, and 6%-8% increase of the elongation. Among the three alloys, the Al-6.0Zn-4Mg alloy shows the best comprehensive properties.

  Overview

  Research progress on toughening modification of laser clad coating

  Wei Xinlong, Fu Erguang, Dai Fanchang, Ban Aolin, Wu Duoli, Zhang Chao

  2023, 48(6):  237-248.  doi:10.13251/j.issn.0254-6051.2023.06.041

  Abstract ( 31 )   PDF (4666KB) ( 90 )  

  Laser cladding improves the performance of metal surfaces and achieves surface strengthening. However, it is often found that due to the reduced toughness of the coating, cracks and defects appear on the surface of the coating. The reasons for cracks in laser clad coatings due to reduced toughness are summarized, including internal stress caused by temperature gradient difference, stress concentration in laser clad layers, and small pores in clad layers. At the same time, factors affecting the toughness of laser clad layers are summarized, including the selection of clad materials, the setting of laser cladding process parameters, and the heat treatment methods of cladding materials. On this basis, the progress in improving the crack defects of laser clad coatings in recent years is emphasized, and methods to enhance the toughness of laser clad coatings are studied and searched for, including adding composite ceramic reinforcement phase and rare earth element powder to the cladding powder to change its composition, adding a transition layer between the substrate and the cladding layer, changing laser cladding process parameters such as the laser power, scanning rate, and spot diameter, preheating the substrate before cladding and heat treating the coating after cladding, external ultrasonic vibration and electromagnetic field, as well as coupling of ultrasonic vibration and electromagnetic field and other energy field assistance. Aiming at the shortcomings of various methods for enhancing the toughness of laser clad coatings, the research prospects of future methods for toughening and modifying laser clad coatings are explored.

  Numerical Simulation

  Temperature uniformity of steel strip during continuous annealing process based on internal and external coupled heat transfer simulation of radiant tube

  Hu Ye, Jiang Zeyi, Zhang Xinru, Zhao Yantao

  2023, 48(6):  249-257.  doi:10.13251/j.issn.0254-6051.2023.06.042

  Abstract ( 25 )   PDF (3260KB) ( 21 )  

  Aiming at the problem of steel strip temperature uniformity during the heating process of radiant tube in vertical steel strip continuous annealing furnace, a coupled model of flow, combustion and heat transfer inside and outside the tube of W-type radiant tube and an unsteady heat conduction model inside the steel strip were established. The effect of temperature distribution on the surface of the radiant tube on temperature uniformity of the steel strip was studied by simulation. The results show that during the heating-up process of the steel strip, the temperature distribution in the width direction is concave, which is related to the high temperature at both ends of the radiant tube and the radiant adiabatic effect of the furnace wall, the temperature difference increases first and then decreases gradually, and the maximum temperature difference of a 1200 mm wide steel strip in the middle stage of heating can reach 13.6 ℃. The temperature difference in the width direction of the strip increases slowly at first and then decreases rapidly with the increase of the strip width. When the strip width is small, the temperature difference in the width direction increases with the increase of power, and the opposite is true when the strip width is large. When the width of the strip is close to the length of radiant tube, the temperature difference in the width direction of the strip is the smallest, which can be reduced to within 5 ℃. In the early stage of heating, the surface temperature of the radiant tube is the most uneven, and in the middle stage of heating, the temperature difference in the width direction of the strip is the largest.

  Analysis on temperature field in plasma nitriding of titanium alloy cylindrical workpiece based on Ansys simulation

  Han Xiao, He Ruijun, Zhu Shuo, Wang Yun, Feng Runhua, Kong Lingli

  2023, 48(6):  258-264.  doi:10.13251/j.issn.0254-6051.2023.06.043

  Abstract ( 25 )   PDF (2798KB) ( 22 )  

  To solve the problem that the temperature distribution of cylindrical workpiece cannot be obtained in real-time in the process of titanium alloy ion nitriding, the temperature field of the titanium alloy cylindrical workpiece of different sizes under various conditions was simulated through the steady temperature field numerical simulation based on Ansys software, and a series of temperature field distribution characteristics of cylindrical workpiece were obtained. The results show that in the nitriding mode completely relying on plasma bombardment without auxiliary heating, the maximum temperature range of the titanium alloy single cylinder workpiece can reach 7.8 ℃, the temperature field is symmetrical, and the temperature is high in the center and low at both ends at axial direction. After the auxiliary heating at both ends is added, the maximum temperature range of the same cylindrical workpiece is reduced to 5.6 ℃, the temperature at both ends is significantly increased, and the uniformity of temperature field is improved, but such uniformity becomes worse with the increase of cylinder wall thickness. The axial temperature uniformity of the cylinder can be improved by adjusting the auxiliary power. In the radial direction, the temperature of the inner wall of the cylinder is higher than that of the outer wall, and the temperature difference between the inner and outer walls increases with the increase of wall thickness. The numerical simulation results can provide a reference for the optimization of ion nitriding process of titanium alloy cylindrical workpiece.

  High-pressure gas quenching test of automobile gears and optimization of quenching chamber structure

  Lü Huyue, Chen Xuyang, Cong Peiwu, Lu Wenlin, Du Chunhui

  2023, 48(6):  264-269.  doi:10.13251/j.issn.0254-6051.2023.06.044

  Abstract ( 26 )   PDF (6227KB) ( 25 )  

  Because the gear and other workpieces in the high-pressure gas quenching were greatly affected by the multilayer workpiece heat storage and the wind speed decrease layer by layer, resulting in the slow cooling of the workpieces placed in the center and the bottom area of gas quenching chamber, it is difficult to meet the hardness requirements of the gear center. The fluid simulation software was used to simulate the high-pressure gas quenching process. The three-dimensional modeling of the gas quenching chamber and the workpiece stack with structured mesh division was established of automobile gears, and then simulation was carried out, based on which the structure of gas quenching chamber was optimized. The results show that after optimization, the high-pressure air flows at the inlet converge to the central area, increasing the inflow velocity of the central area by about 24% and increasing the cooling rate of this area. Subsequently, the high-pressure gas quenching chamber was renovated and verified through experiments. The results show that this method is effective and feasible.

  Test and Analysis

  Causes and countermeasures of martensitic structure formation in flash welded joint of U71Mn steel rail

  Yu Zhe, Jiang Ming, Zhang Qian, Du Hanqiu

  2023, 48(6):  270-276.  doi:10.13251/j.issn.0254-6051.2023.06.045

  Abstract ( 28 )   PDF (4933KB) ( 27 )  

  Martensite, as an abnormal microstructure in U71Mn steel rail flash welded joint, will decrease the safety of the joint, so it is necessary to study its formation causes and countermeasures. Taking U71Mn steel rail flash welded joint as the research object, the single normalizing treatment and dual-normalizing treatment were carried out by Gleeble-1500D thermal simulation testing machine. The microstructure and element composition before and after normalizing treatment were analyzed by means of optical microscope and scanning electron microscope. The distribution law and formation causes of martensite microstructure in the U71Mn steel rail flash welded joint were discussed, and the corresponding countermeasures were put forward and verified on the spot. The results show that the distribution of martensite in the flash welded joint of the U71Mn steel rail is consistent with the segregation of C, Mn element. The martensite in flash welded joint mainly occurs in the manganese rich and carbon rich area, in which the content of Mn element is more than twice that of the base metal. Flash welding will aggravate Mn element segregation in the U71Mn steel rail. Normalizing treatment has no obvious effect on Mn element segregation in U71Mn steel rail flash welding joint, but it can accelerate the diffusion of C element and reduce the occurrence of martensite to a certain extent. By reducing the content of Mn in U71Mn steel rail and providing proper normalizing treatment can greatly eliminate or even avoid the occurrence of martensite.

  Process improvement for coercivity nonconformity of DT4C electrical iron sleeve parts

  Zhao Jinlong, Ren Weibin, Li Jianyu

  2023, 48(6):  277-280.  doi:10.13251/j.issn.0254-6051.2023.06.046

  Abstract ( 75 )   PDF (2079KB) ( 30 )  

  Annealing process was studied in order to solve the coercivity nonconformity problem of DT4C electrical iron sleeve parts after annealing by vacuum hydrogen annealing furnace at 900 ℃. The results show that after 1120 ℃×4 h + 900 ℃×4 h two-stage annealing, the coercivity and grain size of the tested rod are significantly reduced compared with 900 ℃×4 h annealing, and the coercivity at different cooling rates during the process from 1120 ℃ to 900 ℃ is qualified and the difference is not significant. And the cooling rate reaches 240 ℃/h, the processing efficiency of the parts can be improved. The coercivity of unqualified batch sleeve parts after two-stage annealing meets the requirements of HB/Z 5015—1994.

  Surface decarburization behavior of tool steel S2

  Sun Xiaoming, Xiang Nan, Li Ning

  2023, 48(6):  281-286.  doi:10.13251/j.issn.0254-6051.2023.06.047

  Abstract ( 25 )   PDF (3393KB) ( 20 )  

  Effect of different holding time and heating temperatures on the depth of decarburization layer of S2 tool steel under air atmosphere was studied. Fick's first law was used to predict the depth of surface decarburization layer, and the theoretical value calculation model was fitted with the actual depth of decarburization layer of the S2 tool steel. The results show that a full decarburization layer is formed easily on the surface when heated at 770 ℃, and the maximum depth is 0.40 mm. The depth of decarburization layer deepens with the extension of heating time. When the heating time reaches 7 h, the depth of decarburization layer decreases due to the surface oxidation of the S2 steel surface. Ferrite + bainite semi-decarburization layer on the S2 steel surface is formed when heated at 1000 ℃. When heated at 950-1000 ℃, the minimum depth of decarburization layer is 0.06 mm.

  Application of laser nitrogen potential measurement and control system in nitrocarburizing

  Wang Jianxin, Li Jingyu, Wu Kai

  2023, 48(6):  286-290.  doi:10.13251/j.issn.0254-6051.2023.06.048

  Abstract ( 28 )   PDF (1481KB) ( 24 )  

  Taking nitrocarburizing atmosphere as the research object, hydrogen sensor with oxygen probe and laser nitrogen potential sensor measure methods of K_N and K_C were introduced, and the influence of K_N and K_C on composition and structure of white layer in nitrocarburizing process was explained. The results show that the laser nitrogen potential measurement and control system can simultaneously measure and calculate the K_N and K_C of the nitrocarburizing atmosphere, and even if the gas ratio changing during the process do not effect the measurement of K_N.

  Effect of thin rubber layer on shot peening quality of metal surface

  Fan Junkai, Liu Shuai, Jia Zenghui, Zhao Wu, Liu Wei

  2023, 48(6):  291-296.  doi:10.13251/j.issn.0254-6051.2023.06.049

  Abstract ( 25 )   PDF (2950KB) ( 20 )  

  Finite element analysis model of multiple shot peening was established to analyze the improvement effect of thin rubber layer on the surface shot peening quality of Q235 steel and compared with the traditional shot peening method, and then it was verified by experiments. The results show that compared with the traditional shot peening, paving thin rubber layer can improve the surface residual compressive stress while reducing the surface roughness of the specimen, but the depth range of the residual compressive stress layer is reduced. The thickness of thin rubber layer is the key factor affecting the depth of residual compressive stress layer. The thin rubber layer increases the impact area of the shot peening on the surface of the specimen, prolongs the impact time, and effectively disperses the single shot impact energy, so that the shot peening quality of the specimen surface can be improved on the premise that the strength of the residual compressive stress field on the surface of the specimen is basically the same as that of the traditional shot peening.