2022年, 第19卷, 第4期　
刊出日期：2022-07-28

  

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Research & Development
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  Effect of nitrogen on micro-pores in DD33 single crystal superalloy during solidification and homogenization

  Xiang-wei Li, Chen Wang, You-zhao Zhang, Yu-mei Zhong, Li Wang, Shu-yan Zhang

  《中国铸造》英文版. 2022, 19(4): 281-287. https://doi.org/10.1007/s41230-022-1234-8

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  The DD33 superalloy with ultra-low nitrogen (N) content was prepared by vacuum induced melting, and the effect of N on micro-pores in the DD33 single crystal nickel-base superalloy during solidification and homogenization was investigated by in-situ X-ray computed tomography (XCT). Results indicate that the volume fraction of micro-pores, including shrinkage pores and gas pores, increases from 0.08% to 0.11% with increasing N content from 5 ppm to 45 ppm during solidification. Correspondingly, the level of micro-pores in the sample with high N content is higher than that in the sample with low N content during homogenization at 1,330℃ for different time periods. However, the evolution behaviors of gas pores is different from that of shrinkage pores during solidification and homogenization. The number of gas pores is obviously larger in the high N sample during solidification, while the number of shrinkage pores and gas pores is almost the same in both samples after 1 h homogenization. Quantitative results show that the annihilation of micro-pores is associated with bubble diffusion, while the growth behavior of micro-pores during further exposure is dominated by Kirkendall-Frenkel effect.
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  Simulation and experimental research on extra-squeeze forming method during gradient sand molding

  Er-biao Jiang, Zhong-de Shan, Guang Cheng, Shao-zong Wang, Zhao-xian Gu, Xin-lei Wang

  《中国铸造》英文版. 2022, 19(4): 288-298. https://doi.org/10.1007/s41230-022-1130-2

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  The flexible extrusion forming process (FEFP) is a sand mold patternless manufacturing technology that enables digital near-net shaping of complex sand molds. But, it is difficult to achieve the gradient sand molds with high surface strength and strong interior permeability by FEFP. To solve this problem, an extra-squeeze forming method based on FEFP for gradient sand mold was developed. To further reveal the extra-squeeze forming mechanism, based on the Johnson-Kendall-Roberts (JKR) theory and "gluing" notions, the single and double-sided squeeze models of gradient sand molds were established using the EDEM software. The squeezing processes of sand molds with different cavity depths of 60, 100, 140, 180, and 220 mm were systemically studied under single and double-sided squeeze conditions. The variation in the void fraction of sand mold as also investigated at a variety of extra-squeeze distances of 2, 3, 4, 5, and 6 mm, respectively. Simulation and test results show that a deeper cavity depth weakens the extrusion force transmission, which leads to a decrease in strength. The sand mold permeability and void fraction are identified to be positively correlated, while the tensile strength and void fraction appear to be negatively correlated. The void fraction of sand molds decreases with a longer extra-squeeze distance. A 6 mm extra-squeeze distance for the sand mold with 220 mm cavity depth results in a 26.8% increase in tensile strength with only a 5.7% reduction in the permeability. Hence, the extra-squeeze forming method can improve the quality of the sand mold by producing a gradient sand mold with high surface strength and strong interior permeability.
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  Application of transparent casting moulds prepared by additive manufacturing technology in hydraulic simulation

  Qian Feng, Xing Ran, Ke-hui Hu, Hao-yuan Wang, Zhi-gang Lü

  《中国铸造》英文版. 2022, 19(4): 299-306. https://doi.org/10.1007/s41230-022-1163-6

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  Hydraulic simulation is one of the critical methods to research the filling mechanism of molten metal in the casting process. However, it only performs on test pieces with relatively simple structures due to the limitation of the preparation method. In this study, the method of photocuring additive manufacturing was used to prepare the complex casting mould from transparent photosensitive resin. The pouring test was carried out under different centrifugal conditions, and the filling process of the gating system, support bars and other positions in the vertical direction was recorded and analyzed. The experimental results show that the internal liquid level and the filling process of the test piece prepared by this method can be observed clearly. The angle between the liquid surface and the horizontal plane in the test piece gradually increases as the centrifugal rotational speed increases, which means the filling process is carried out from outside to inside at high rotational speed. The velocity of the fluid entering the runner increases with the increase of rotational speed, but the filling speeds is less affected by the centrifugal speed at other positions. The liquid flow is continuous and stable during the forward filling process, without splashing or interruption of liquid droplets.
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  Sub-pixel high precision dimensional measurement method for aero-engine hollow turbine blade based on industrial computed tomography image

  Ya-nan Wang, San-san Shuai, Xing-fu Ren, Tong-tong Hu, Jiang Wang, Zhong-ming Ren

  《中国铸造》英文版. 2022, 19(4): 307-320. https://doi.org/10.1007/s41230-022-2044-8

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  Aero-engine hollow turbine blades are work under prolonged high temperature, requiring high dimensional accuracy. Blade profile and wall thickness are important parameters to ensure the comprehensive performance of blades, which need to be measured accurately during manufacturing process. In this study, a high accuracy industrial computed tomography (ICT) measuring method was developed based on standard cylindrical pin and ring workpieces of different sizes. Combining ICT with cubic spline interpolation, a sub-pixel accuracy was achieved in measuring the dimension of component. Compared with the traditional and whole-pixel level image measurement method, the cubic spline interpolation algorithm has the advantages of high accuracy in image edge detection and thus high accuracy of dimensional measurement. Further, the technique was employed to measure the profile and wall thickness of a typical aerospace engine turbine blade, and an accuracy higher than 0.015 mm was obtained.
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  Effects of Cu content on microstructure and mechanical properties of rheo-diecasting Al-6Zn-2Mg-xCu alloys

  Zhi-guang Ding, Sai-heng Hou, Song Chen, Ze-hua Liu, Da-quan Li, Jian Feng, Fan Zhang, Li-ming Peng

  《中国铸造》英文版. 2022, 19(4): 321-326. https://doi.org/10.1007/s41230-022-1138-7

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  A systematic study on how Cu content affects the microstructure and mechanical properties of rheo-diecasting Al-6Zn-2Mg-xCu alloys during solution treatment and ageing heat treatment was conducted. The swirled enthalpy equilibrium device (SEED) was adopted to prepare the semi-solid slurry of Al-6Zn-2Mg-xCu alloys. The microstructure development and mechanical properties were studied using optical microscopy (OM), scanning electron microscopy (SEM), X-ray diffraction (XRD), differential scanning calorimetry (DSC), as well as hardness and tensile testing. The grain boundary and shape factor were calculated using image processing software (Image-Pro Plus 6.0). Results show that the alloys are composed of typical globular primary α-Al grains, eutectic phases, and smaller secondary α-Al grains. After solution and ageing heat treatment, the eutectic phases are dissolved into Al matrix when the Cu content is lower than 1.5wt.%, while some eutectic phases transform into Al₂CuMg (S) phases and remain at grain boundaries when Cu content reaches 2wt.%. T6 heat treatment significantly enhances the mechanical properties of rheo-diecasting Al-6Zn-2Mg-xCu alloys. When Cu concentration is 0.5wt.%-1.5wt.%, the ultimate tensile strength, yield strength and elongation of T6 treated alloys rise to around 500 MPa, 420 MPa, and 18%, respectively.
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  Design and application of a multichannel “cross” hot tearing tendency device: A study on hot tearing tendency of Al alloys

  Ming Su, Wen-tao Zheng, Deng-ke Fu, Hong-jun Huang, Xiao-jiao Zuo, Chun-yu Yue, Yu-xiang Wang, Xiao-guang Yuan

  《中国铸造》英文版. 2022, 19(4): 327-334. https://doi.org/10.1007/s41230-022-1184-5

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  Hot tearing is one of the most serious defects during the casting solidification process. In this study, a new type of multichannel "cross" hot tearing device was designed. The hot cracks initiation and propagation were predicted by the relationship between temperature, shrinkage force and solidification time during the casting solidification process. The reliability and practicability of the multichannel "cross" hot tearing device were verified by casting experiments and numerical simulations. The theoretical calculation based on Clyne-Davies model and numerical simulation results show that the hot tearing tendency decreases in the order:2024 Al alloy>Al-Cu alloy>Al-Si alloy at a pouring temperature of 670℃ and a mold temperature of 25℃. Feeding of liquid films at the end of solidification plays an important role in the propagation process of hot tearing. The decrease of hot tearing tendency is attributed to the feeding of liquid film and intergranular bridging.
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  Effect of high magnetic field on solidification microstructure evolution of a Cu-Fe immiscible alloy

  Yu-jie Yan, Chen Wei, Yi-xuan He, Chao Li, Ping-xiang Zhang, Jin-shan Li, Jun Wang

  《中国铸造》英文版. 2022, 19(4): 335-341. https://doi.org/10.1007/s41230-022-1243-7

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  The liquid phase separation behavior and the evolution of the solidification microstructure of a binary Cu₅₀Fe₅₀ alloy were investigated under the conditions of without and with a 10 T magnetic field, with different undercooling during the solidification process. Results show that the combined effect of Stokes motion and Marangoni convection leads to the formation of the core-shell structure under the condition without the magnetic field. In addition, specific gravity segregation is reinforced by increasing the undercooling, resulting in Fe-rich phase drifts towards the sample edge. In the 10 T magnetic field, the Fe-rich phase is elongated in the parallel direction of the magnetic field under the action of demagnetization energy due to the difference of static magnetic energy and surface energy. In the vertical direction, through the action of Lorentz force, the convection in the melt is inhibited and Fe-rich phase becomes more dispersed. Meanwhile, the diffusion of the two phases and the coagulation of the Fe-rich phases are also restrained under the magnetic field, therefore, the phase volume fraction of the Fe-rich phase decreases at the same undercooling in the 10 T magnetic field. The magnetic field inhibits the segregation behavior in the vertical direction of the magnetic field, and at the same time, improves the gravitational segregation to a certain extent, which has a very important impact on microstructure regulation.
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  Iterative reverse deformation optimization design of castings based on numerical simulation of solidification thermal stress

  Yu-hao Chen, Dun-ming Liao, Wei-dong Li, Tao Chen, Ming Yang, Jun-ke Shi

  《中国铸造》英文版. 2022, 19(4): 342-350. https://doi.org/10.1007/s41230-022-2034-x

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  In the casting process, in order to compensate for the solidification shrinkage to obtain higher dimensional accuracy of the casting, it is often necessary to modify the original design of castings, and a suitable compensation method has a decisive impact on the dimensional accuracy of the actual casting. In this study, based on solidification simulation, a design method of reverse deformation is proposed, and two compensation methods, empirical compensation and direct reverse deformation, are implemented. The simulation results show that the empirical compensation method has problems such as difficulty in determining the parameters and satisfaction of both the overall and local accuracy at the same time; while based on the simulation results for each node of the casting, the direct reverse deformation design achieves the design with shape. In addition, the casting model can be optimized through iterative revisions, so that higher dimensional accuracy can be continuously obtained in the subsequent design process. Therefore, the direct reverse deformation design is more accurate and reasonable compared to empirical compensation method.
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  Optimization of investment casting process for K477 superalloy aero-engine turbine nozzle by simulation and experiment

  Xin Hao, Guo-huai Liu, Ye Wang, Shi-ping Wu, Zhao-dong Wang

  《中国铸造》英文版. 2022, 19(4): 351-358. https://doi.org/10.1007/s41230-022-1092-4

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  In order to reduce the shrinkage porosity of nickel-based superalloy castings in the investment casting process, the effects of different gating systems on mold filling, solidification process, and prediction of shrinkage porosity of aero-engine turbine nozzle castings were investigated by simulation and experimental methods. Results show that the design of the vertical runner would cause greater turbulence of the melt in the riser during the mold filling process, and the outer runner is not necessary. With the decrease in number of runners, the hot spot moves down towards the casting, and the shrinkage and porosity defects are formed in the casting below the riser. In the original designs, a certain tendency of shrinkage and porosity defect is found in the vanes, inner rings, and outer rings of the castings by both simulation prediction and experiment. Finally, based on the processing optimization, the aero-engine turbine nozzle casting with no shrinkage and porosity defects is obtained.
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  Revealing effect of aluminum alloying on work hardening and impact behaviors of low-density Fe-18Mn-1.3C-2Cr-(4, 11)Al casting steel

  Zhi-bin Zheng, Hao-kun Yang, A. P. Shatrava, Wai-wah Lai, Jun Long, Kai-hong Zheng

  《中国铸造》英文版. 2022, 19(4): 359-368. https://doi.org/10.1007/s41230-022-2004-3

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  The present study designed two kinds of Fe-18Mn-1.3C-2Cr-(4, 11)Al (wt.%) low-density steels. Tensile and impact tests were carried out to evaluate the work hardening and impact toughness properties via aluminum (Al) alloying control. Meanwhile, microstructure evolution and fracture morphology were investigated by X-ray diffraction (XRD), a scanning electron microscope (SEM) equipped with electron backscatter diffraction (EBSD), a transmission electron microscope (TEM), and a stereo-optical microscope (OM). It is found that the Al addition obviously promotes the dislocation planar slipping, resulting in cleavage and brittle impact fracture in 11wt.% Al steel. Besides, the microband-induced plasticity (MBIP) mechanism is found in 4wt.% Al containing steel, introducing considerable work hardening capacity and impact toughness of 156.8±17.4 J. The present study provides a direct illustration of the relationship between work hardening and impact toughness behaviors of these two low-density steels for potential application as impact-resistant components.