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    Identification and Evaluation of Key Error Elements in Complex Composite Aviation Componts Assembly Driven by Mechanism and Data Model Fusion
    GUO Feiyan1, ZHANG Hui2, SONG Changjie1, ZHANG Shuo1
    China Mechanical Engineering    2025, 36 (07): 1530-1543.   DOI: 10.3969/j.issn.1004-132X.2025.07.016
    Abstract1749)      PDF(pc) (6423KB)(311)       Save
     In composite assembly of complex aviation products, the factors such as part deformations under loads, numerous parameters and so on were considered. Deformation error source models for key assembly links caused by positioning and clamping, joining and rebounding were analyzed, and the Jacobian sensor matrix representing error transmission relationship was modified to establish assembly error transmission mechanism model. A support vector regression model was established based on assembly error data, a fusion model of mechanism model and data model was gained. With the predication and compensation model for the calculated values of the error mechanism model and the actual deviation, a Sobol sensitivity analysis method was adopted to calculate the global sensitivity coefficients of different assembly error links, and the key error elements affecting assembly accuracy was identified. Finally, the assembly of wing box component was taken as an example to prove the effectiveness of the proposed method.
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    Research on Differential Steering Mechanism Based on Tire Cornering
    Biaofei SHI, Xiaoming YE, Haoyu LYU, Feng LAI
    China Mechanical Engineering    2025, 36 (10): 2224-2231.   DOI: 10.3969/j.issn.1004-132X.2025.10.008
    Abstract1606)   HTML11)    PDF(pc) (1816KB)(86)       Save

    Differential steering based on tire cornering suited low-speed, large steering radius scenarios of distributed drive electric vehicles(DDEV) without steering mechanisms. In order to study the mechanism of differential steering based on tire cornering, a 7-degree-of-freedom DDEV dynamic model with no steering mechanism and PAC2002 tire model were established. Then, the formation mechanism of differential steering was analyzed and a systematic analysis method from the input of differential longitudinal force to the output of vehicle steering radius of differential steering was proposed by considering the tire force longitudinal-lateral-coupling characteristics. Leveraging the proposed systematic analysis method, the stability of differential steering and the influences of differential longitudinal force, vehicle parameters and tire characteristics on steering radius were studied. Finally, a Carsim/Simulink joint simulation platform was established to simulate differential steering under different influencing factors. The results show that within the range of tire cornering, the larger the differential longitudinal force, the larger the ratio of track width to wheelbase, and the smaller the tire lateral stiffness, the smaller the steering radius.

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    Research on Flexible Job Shop Scheduling Problems Considering Limited AGV Transportation Resources
    Guohui ZHANG, Yihao CAI, Zhixiao LI, Shenghui GUO, Haijun ZHANG
    China Mechanical Engineering    2025, 36 (08): 1811-1823.   DOI: 10.3969/j.issn.1004-132X.2025.08.016
    Abstract1513)   HTML2)    PDF(pc) (3435KB)(117)       Save

    Aiming at the flexible job shop scheduling problems of limited AGV transportation resources in the intelligent manufacturing environments, an integrated scheduling model for limited AGV transportation resources was established with the objective of minimizing the maximum completion time, total energy consumption and the delivery penalty value of workpieces. An improved NSGA -II solution algorithm was proposed to construct a three-stage coding scheme for the integrated scheduling model, and three initialization rules were designed to improve the quality and diversity of the initial population. Combined with the critical path, an improved variable neighborhood search was proposed to enhance the local search capability of the algorithm. In the experimental part, the algorithm was compared with other algorithms using various evaluation indexes, and the experimental results show that the algorithm may effectively solve the integrated scheduling problems of limited AGV transportation resources under different sizes of standard test cases and actual production cases of aviation enterprises. Meanwhile, the effectiveness of the integrated scheduling model was analyzed under different numbers of AGVs, and it is concluded that the number of AGVs in the flexible operation workshop conforms to the law of diminishing marginal effectiveness, so as to provide a reference for the configuration of AGVs in the actual manufacturing workshop.

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    Research on Mechanism Analysis and Online Monitoring System of Camshaft High-speed Grinding Burns
    Zhaohui DENG, Rongjin ZHUO, Jingqiang CHEN, Jimin GE, Lishu LYU, Wei LIU
    China Mechanical Engineering    2025, 36 (08): 1784-1795.   DOI: 10.3969/j.issn.1004-132X.2025.08.014
    Abstract1505)   HTML2)    PDF(pc) (5261KB)(80)       Save

    The high-speed grinding of the non-circular contours of the camshafts was prone to grinding burns, resulting in a decrease in surface quality and service life and even scrapping. Therefore, the mechanism analysis and online monitoring system of camshaft high-speed grinding burns were studied. The influences of processing parameters on grinding burns were discussed. A grinding burn's quantitative evaluation method was proposed by surface morphology and hardness.Frequency and time-frequency domain analysis methods carried out the signal processing and feature extraction. The relationship between the sensing signals and grinding burns was analyzed. The AE (acoustic emission) signal features with a high correlation with grinding burn were extracted based on ReliefF. The monitoring model of grinding burn was established based on GA-SVM(genetic algorithm-support vector machine). And it was verified by experiments. The online monitoring system of camshaft high-speed grinding burns was developed and applied.

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    Thermal Image Input-based ResNet Method for Thermal Error Modeling of Machine Tool Spindles
    Mingfan LI, Long YANG, Sheng LI, Huan GUO, Guoqiang FU
    China Mechanical Engineering    2025, 36 (09): 2057-2067.   DOI: 10.3969/j.issn.1004-132X.2025.09.018
    Abstract1500)   HTML1)    PDF(pc) (5627KB)(125)       Save

    To achieve a high-precision and highly generalizable thermal error model of machine tools, a thermal image input-based ResNet method was proposed for thermal error modeling of CNC machine tool spindles. A thermal image dataset labelled was constructed with thermal error rounding, and a ResNet-based classification model was trained for thermal error prediction using thermal images as inputs. Considering the regression characteristics of the machine tool thermal error time series, a regression output layer was constructed by integrating the probabilities of different classification labels from the classification output layer in a weighted manner, enabling thermal error regression prediction without retraining. The deep features of thermal images and the classification performance of the ResNet model were visualized, confirming the effectiveness of ResNet in feature extraction and strong classification ability. Finally, the ResNet model was compared with GoogLeNet and VGGNet models under different operating conditions, demonstrating the high accuracy and generalization of the ResNet-based thermal error classification and regression models.

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    Effects of Glass Fiber Mass Fraction on W-PACIM Pipes of Long Glass Fiber Reinforced Polypropylene
    LIAO Qiansheng1, 3, LIU Hesheng2, KUANG Tangqing2, LIU Jiahao2, ZHANG Wei2
    China Mechanical Engineering    2025, 36 (06): 1329-1337.   DOI: 10.3969/j.issn.1004-132X.2025.06.020
    Abstract1490)      PDF(pc) (6799KB)(59)       Save
    To study the effects of glass fiber mass fraction on W-PACIM pipes with long glass fiber reinforced polypropylene as the outer material and pure polypropylene as the inner material, the influences of glass fiber mass fraction on the residual wall thickness, the orientation distribution of glass fibers and the pressure resistance of the pipes were analyzed by experimental methods. The results show that with the increases of glass fiber mass fraction, the total residual wall thickness of the pipes decreases first and then increases. The outer layer of the pipes may be divided into near the mold wall layer, the middle layer and the near interface layer according to the distribution characteristics of the glass fiber orientations, the orientation of the glass fiber along the melt flow direction increases gradually from the outside to the inside, the uniformity of the distribution of the outer glass fiber decreases with the increase of glass fiber mass fraction. The pressure resistance of pipes increases first and then decreases, when the glass fiber mass fraction is 20%, the pressure resistance of pipes is the best.
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    Thin-walled Workpiece Milling Deformation Error Prediction Based on Multi-source Information Fusion and Ensemble Learning
    YIN Jia1, ZHENG Jian2, LIU Yao3, JIA Baoguo1, DUAN Xiaorui1
    China Mechanical Engineering    2025, 36 (06): 1261-1268.   DOI: 10.3969/j.issn.1004-132X.2025.06.013
    Abstract1488)      PDF(pc) (5304KB)(60)       Save
    In practical machining processes, the dimensional accuracy of thin-walled workpiece was significantly affected by multiple factors including cutting forces, forced vibrations, chatter phenomena, geometric characteristics of workpiece and material properties, rendering deformation prediction and control particularly challenging. A multi-source information fusion method for deformation error prediction in thin-walled workpiece milling processes was developed. Machining parameters, vibration signals, and other relevant data were integrated to establish a deformation error prediction model through Stacking ensemble learning methodology, with comprehensive experimental validation performed. Comparative analyses reveal that the constructed model demonstrates superior robustness, higher accuracy, and enhanced practicality when compared with conventional data-driven prediction methods.
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    Integrated Design Technology for New Energy Vehicle Power Battery Systems
    SHI Peicheng1, SHAN Zixian1, ZHU Hailong1, HAI Bin2, WANG Lei2, LU Fayan2
    China Mechanical Engineering    2025, 36 (07): 1611-1623.   DOI: 10.3969/j.issn.1004-132X.2025.07.024
    Abstract1486)      PDF(pc) (6886KB)(122)       Save
    An integrated design technology of power battery systems for new energy vehicles was elaborated, and the advantages in space utilisation, range, and cost control were shown by analysing the technology such as moduleless, battery chassis integration and battery body integration. Other typical battery technology which promoted the development of automotive industry through structural innovation, thermal management optimisation and fast charging solutions were explored. The development directions of power battery system integration technology were outlooked in terms of intelligent integration, sustainable materials, and standardisation.
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    Ultra-precision Turning Alignment Error Compensation Technology in Multi-axis Simultaneous Operations
    YUAN Jiabin, GUO Xipeng, LI Rong, YIN Shaohui
    China Mechanical Engineering    2025, 36 (07): 1397-1406.   DOI: 10.3969/j.issn.1004-132X.2025.07.001
    Abstract1417)      PDF(pc) (9879KB)(99)       Save
    To address the issues of ineffective compensation for aspheric machining figure errors, an XZB three-axis ultra-precision machining method was proposed. The impact of errors in tool alignment, tool radius and the deviation of tool tip relative to the B-axis rotation center on workpiece surface accuracy was analyzed, and the corresponding compensation methods were presented. Turning experiments of nickel-plated convex aspherical workpieces were conducted. Figure errors of the workpieces were reduceed from 0.6774 μm to 0.0749 μm, with the XZB three-axis linked turning method. Experimental results show that the XZB three-axis linked turning process significantly improves the surface shape accuracy and surface quality of small-diameter aspherical surfaces, compared with the XZ two-axis linked turning method.
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    Intelligent Vehicle Trajectory Planning Based on Spatio-temporal Risk Fields
    Huifang KONG, Chenshun WANG, Qian ZHANG, Tiankuo LIU
    China Mechanical Engineering    2025, 36 (10): 2463-2471.   DOI: 10.3969/j.issn.1004-132X.2025.10.036
    Abstract1291)   HTML0)    PDF(pc) (2976KB)(63)       Save

    Aming to describe and avoid different dimensions of risks faced by intelligent vehicles, a two-layer trajectory planning method was proposed based on spatio-temporal risk fields. Traffic elements were divided into abstract elements and concrete elements, the spatial-temporal risk fields of abstract elements based on Gaussian distribution function and concrete elements based on spatial vector were established respectively to represent the environmental risks faced by intelligent vehicles in three dimensions: vertical, horizontal and temporal. Additionally, the trajectory planning problem of intelligent vehicles was divided into path and speed dual planning problem. The longitudinal-lateral dimension risk and longitudinal-temporal dimension risk were accordingly applied to dynamic planning cost function. Then, the path and speed with the comprehensive lowest cost were calculated, and combined with quadratic programming algorithm, the path and velocity were further optimized to obtain the final trajectory. Simulation results demonstrate that the proposed methodology may effectively characterize spatio-temporal driving risks across diverse scenarios while generating constraint-satisfying trajectories, thereby significantly enhance road driving safety.

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    C-warping Mechanism and Treatment Strategies in Leveling Processes of Strip Steels
    YANG Yonghui1, ZHANG Ji1, TAN Hailong1, NIU Baicao1, BAI Zhenhua1, 2, 3
    China Mechanical Engineering    2025, 36 (06): 1345-1351.   DOI: 10.3969/j.issn.1004-132X.2025.06.022
    Abstract1281)      PDF(pc) (1401KB)(65)       Save
     In order to solve the problems of C-warping defects in strip steels in the leveling processes, the processing parameters in the strip leveling processes were optimized, and a set of C-warping prediction and treatment strategies for strip steels were developed. The formation mechanism of C-warping was analyzed from three aspects: rolling, processing lubrication systems and the influences of anti-wrinkle rollers and anti-trembling rollers on the forces of strip steels. The stress distribution of the horizontal direction of the outlet strips in the thickness was obtained, based on the stress analysis of the strips under the assumption of half-plane infinite body, the maximum and minimum transverse elongation in the thickness direction of the strips were obtained, and the height of the C warp of the strips was obtained through the geometric relationship. A set of optimal height settings of anti-wrinkle rollers and anti-trembling rollers were sought to minimize the objective function of the comprehensive control, and the elongation in the direction of strip thickness was controlled, so as to reduce C-warp. The model and treatment strategies were applied to a leveling unit in China, and the prediction errors of C warping height are controlled within 10%, and the maximum warpage ranges of the unit are reduced from 1.4~6.5 mm to 0.9~4.5 mm. The results show that the C warpage prediction and treatment strategy meet the production demands, and the warpage values are significantly reduced, which reduces the repair rate caused by warpages.
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    Study on Thickness Distribution of Single Point Incremental Hydroforming of Complex Shaped Parts
    SHANG Miao, LI Yan, SHAN Shunkun, YANG Mingshun
    China Mechanical Engineering    2025, 36 (06): 1338-1344.   DOI: 10.3969/j.issn.1004-132X.2025.06.021
    Abstract1276)      PDF(pc) (10225KB)(77)       Save
    To analyze and enhance the performances of single point incremental forming for complex shaped parts, a new process combining SPIF and hydroforming was presented for manufacturing multi-featured parts with spire structures. The forming processes of the target parts were designed, the theoretical prediction model of thickness was established, and the effects of different hydraulic parameters on the thickness distribution of the target parts in different forming stages were analyzed. The experimental results show that complex shaped parts may be formed using the new processes and appropriate hydraulic pressures; the geometric errors between the experimental and theoretical profiles may be reduced from 11.44% to 5.18% with assistance compared to SPIF without hydraulic assistance; the thickness distribution patterns are related to the assisted pressure, forming heights, forming shape, etc., and the established theoretical model may be used to predict the thickness distribution of complex shaped parts.
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    Modelling and Optimisation of Dynamic Scheduling in Chinese Materia Medica Pharmaceuticals Workshops Based on Multiple Motivation Drivers
    ZHAO Peirui1, DENG Chao1, ZHU Bo1, YAN Wenbin1, LIANG Min2, CHEN Min2
    China Mechanical Engineering    2025, 36 (06): 1247-1260,1299.   DOI: 10.3969/j.issn.1004-132X.2025.06.012
    Abstract1253)      PDF(pc) (19210KB)(82)       Save
    A dynamic scheduling problem of Chinese materia medica pharmaceutical workshop driven by multiple dynamic factors(DSP-CMMPW-MDF) model was established, the multiple dynamic factors such as raw material shortages, emergency order insertions, and machine breakdowns. An improved artificial bee colony with Q-learning(IABC-QL) algorithm was proposed to solve the DSP-CMMPW-MDF with the optimization objective of minimizing makespan. In the IABC-QL algorithm, an opposition-based learning strategy was proposed to generate the initial population, ensuring high quality and diversity of the population individuals. Five local search operations were designed to enhance the deep exploration capability of the algorithm. Thus the proposed model and algorithm were applied to a Chinese materia medica pharmaceutical granule production workshop. The results show that the proposed model may effectively improve the flexibility and adaptability of the production systems in the face of uncertainties. Additionally, a comparison with existing algorithms validates the effectiveness of the proposed algorithm.
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    Vehicle Lateral Control Strategy Integrating Road Curvature Feedforward
    Xinyou LIN, Zhongwei JIN, Yunliang TANG
    China Mechanical Engineering    2025, 36 (11): 2774-2782.   DOI: 10.3969/j.issn.1004-132X.2025.11.036
    Abstract1233)   HTML0)    PDF(pc) (2868KB)(59)       Save

    Aiming at the problems of low tracking accuracy of autonomous vehicles in the road with large curvature curves, the influences of road curvature on the lateral control strategy were focused, the lateral control strategy was improved and optimized based on the traditional model predictive control(MPC) algorithm from three aspects of vehicle model modeling, yaw stability and time domain optimization, respectively. The road curvature was integrated into the vehicle model, and an error dynamics model with curvature feedforward was established. And then, a lateral control strategy was designed based on curvature feedforward MPC algorithm. Then, a lateral stability constraint consisting of lateral vehicle speed and steady-state lateral angular velocity was added to the strategy to enhance the lateral stability of the vehicles under high curvature conditions. A MAP map was established based on genetic algorithm to optimize the prediction and control time domains of the strategy, taking into account the relationships among vehicle speed, road curvature and time domain. Simulation analysis was conducted, and the results show that the improved lateral control strategy may effectively improve the path tracking precision and lateral stability of the vehicles. Finally, the effectivenesses of the curvature feedforward MPC strategy were verified through real vehicle road tests.

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    Research Status and Development Trends of Failure Modes, Effects, and Criticality Analysis for CNC Machine Tool Reliability
    TIAN Hailong1, 2, SUN Yuzhi1, 2, YANG Zhaojun1, 2, LIU Zhifeng1, 2, CHEN Chuanhai1, 2, HE Jialong1, 2
    China Mechanical Engineering    2025, 36 (07): 1430-1441.   DOI: 10.3969/j.issn.1004-132X.2025.07.005
    Abstract1218)      PDF(pc) (1000KB)(143)       Save
    FMECA played an important role in reliability maintenance of CNC machine tools. Current researches focused on 4 aspects: comprehensive evaluation of multiple factors, integration of multi-source hierarchical information, integration of multiple analysis methods, and dynamic characteristic modeling. By systematically combination of existing research results, the advantages and existing problems of the 4 aspects were analyzed. Evolution path of machine tool failure modes, effects and criticality analysis were explained by the integration of the characteristics of industrial needs, which provides a theoretical basis for building a high-precision machine tool reliability evaluation system.
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    Multicollinearity Parameter Feature Selection for Manufacturing Processes Based on LLEs
    HU Sheng1, 2, GAO Bingbing1, ZHANG Xi1, LIU Dengji1
    China Mechanical Engineering    2025, 36 (06): 1238-1246.   DOI: 10.3969/j.issn.1004-132X.2025.06.011
    Abstract1178)      PDF(pc) (7980KB)(65)       Save
    In manufacturing processes, a large number of parameters were easily caused to have multicollinearity, which led to problems such as inaccurate prediction of quality indicators. To address these problems, a feature selection method for multicollinear parameters in the manufacturing processes was proposed based on LLE. Firstly, the multicollinearity of the manufacturing process parameters was diagnosed, and then the multicollinearity was eliminated by using the least absolute shrinkage and selection operator(LASSO) regression. Secondly, the LLE algorithm was used to perform feature selection on the parameters after LASSO regression to obtain independent feature spaces, and they were input into the whale optimization algorithm-support vector machine(WOA-SVM) model to verify the parameter feature selection effectiveness of the proposed algorithm. Finally, the effectiveness of the proposed method was verified through case analysis. The results show that compared with the original data, the proposed method may obtain more accurate prediction results under a lower-dimensional feature space, the correlation coefficient value is up to 0.9702, and the accuracy of feature selection increases by 24.989%.
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    Research on Passive Compliance Control Method of High Altitude Wind Turbine Blade Grinding Robots Based on Improved ADRC
    Hao LI, Xinrong LIU, Yiqin LIU, Diqing FAN
    China Mechanical Engineering    2025, 36 (08): 1832-1841.   DOI: 10.3969/j.issn.1004-132X.2025.08.018
    Abstract1159)   HTML6)    PDF(pc) (3159KB)(108)       Save

    To cope with unknown disturbances at high altitudes and maintain a constant contact forces at the end of a high-altitude wind turbine blade repair robots during polishing, a passive compliant control algorithm was proposed based on an improved ADRC approach. The algorithm combined dead-zone compensation and gravity compensation algorithms, fully considering issues such as gas compressibility in the pneumatic systems, characteristics of electrical proportional valve dead zones, changes in tilt angle during polishing processes, and unknown disturbances during high-altitude operations.A tracking differentiator was utilized for excessive input signals, a state observer was employed to monitor system disturbances, and compensated through a state error feedback control law. By establishing the mathematical model of the control systems and conducting simulation analysis, it is found that this control algorithm improves both force control performance and response speed compared to the traditional proportional-integral-derivative(PID) algorithm. An experimental platform was constructed to conduct experiments under various operating conditions. The experimental results show that the control algorithm systems achieve 44.6% to 51.4% reductions in settling time, a decrease in the absolute maximum error by 45.4% to 69.4%, and reductions in mean square error by 56.5% to 91.2%. Therefore, this algorithm demonstrates improved dynamic response performance and force control accuracy, along with strong disturbance rejection capabilities and robustness, providing a theoretical foundation for practical engineering applications.

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    High-precision Industrial Robot Teaching Method Based on 6D Light Pens
    Jihuang LIANG, Weifeng WANG, Haibin WU
    China Mechanical Engineering    2025, 36 (11): 2710-2719.   DOI: 10.3969/j.issn.1004-132X.2025.11.029
    Abstract1103)   HTML0)    PDF(pc) (2880KB)(41)       Save

    Aiming at the problems of poor precision, sensitivity to light and restricted teaching range in current industrial robot vision teaching methods, a high-precision industrial robot teaching method was proposed based on a 6D light pen. The light pen was equipped with three infrared-emitting marker balls, and infrared binocular camera mounted on the robot's end-effector captured the marker balls to obtain their 3D position coordinates and 3D pose information. Two measures were implemented to enhance the vision teaching precision of the 6D light pens. Firstly, a hand-eye calibration method was proposed based on infrared light-emitting marker balls, which significantly improved the transformation precision from the camera coordinate system to the robot tool coordinate system. Secondly, an adaptive camera tracking method was proposed, allowing the robot to automatically track the position of the light pen through the camera mounted on the end-effector, ensuring that the marker balls remain centered in the camera's field of view, thus effectively improving the teaching precision. Finally, the captured teaching trajectory was transformed into the robot base coordinate system to achieve trajectory programming and tracking. Experimental results show that the maximum single-point error of the light pens is as 0.63 mm, the maximum pose error is as 2.1432°, and the maximum trajectory error is as 0.73 mm. The proposed teaching method may achieve high-precision and high-efficiency teaching for robots.

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    Multi-objective Trajectory Planning of Manipulators Based on Improved SSA
    Jianlin LIU, Haisong HUANG, Qingsong FAN, Chi MA, Langlang ZHANG
    China Mechanical Engineering    2025, 36 (09): 2047-2056.   DOI: 10.3969/j.issn.1004-132X.2025.09.017
    Abstract1090)   HTML2)    PDF(pc) (5244KB)(139)       Save

    To optimize the three objectives of efficiency, energy consumption and impacts at the same time, a multi-objective trajectory planning model was proposed based on an improved SSA. Firstly, the artificial potential field method (APF) was used for path planning to obtain the shortest and collision-free path of the manipulator grasping the materials, and the key motion sequence was extracted to establish a multi-objective function. Then, aiming at the problems of multi-objective salp swarm algorithm (MSSA), such as poor diversity of initial population, easy to fall into local optimum and slow convergence in solution set space, an improved algorithm namely logistic-sine multi-objective salp swarm algorithm(LMSSA)was proposed. The algorithm combined logistic-sine chaotic mapping, pinhole imaging learning strategy and golden sine development strategy to optimize the control nodes of the seventh-order B-spline curve and complete the multi-objective motion trajectory planning of the robotic arms. Finally, the trajectory planning model was applied to the actual grasping tasks of the manipulator UR16e by building MATLAB-CoppeliaSim-UR16e experimental platform. Experimental results show that based on LMSSA, the manipulator motion planning method realizes the accurate, efficient and energy-saving motion trajectory planning of the manipulator, and is successfully applied to the actual operation scenes.

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    Tool Wear Monitoring Based on IWOA-IECA-BiLSTM Model
    BAO Zhenke, CAO Huajun, QIN Fengze, CHEN Zhixiang, TAO Guibao
    China Mechanical Engineering    2025, 36 (12): 2936-2943.   DOI: 10.3969/j.issn.1004-132X.2025.12.016
    Abstract1082)   HTML1)    PDF(pc) (2374KB)(44)       Save

    To improve the monitoring accuracy of tool wear during machining, a BiLSTM model based on IWOA and IECA mechanism was proposed. Tool wear data segments from the PHM2010 dataset were intercepted, and multi-domain features were extracted. Tool wear strongly correlated features were then obtained by screening with the Pearson correlation coefficient. The input features were used to train the model. The BiLSTM module in the model effectively captured temporal features within the data. The IECA attention mechanism module enhances the feature representational capability. The IWOA module optimized the model's hyperparameters, further improving the model accuracy. The model performance was finally tested based on three-fold cross-validation and compared with several other models. The results demonstrate that the IWOA-IECA-BiLSTM tool wear monitoring model achieves the best performance on most test sets. On test sets C1C4 and C6, the root mean square error (RMSE) values are as low as 6.5, 12.46, and 9.28, respectively.

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    Vehicle Yaw and Roll Stability Control Based on Dynamic Output Feedback
    YIN Xizhi1, 2, 3, HU Sanbao1, 2, 3, FENG Zhiyong1, 2, 3
    China Mechanical Engineering    2025, 36 (07): 1453-1462.   DOI: 10.3969/j.issn.1004-132X.2025.07.007
    Abstract1040)      PDF(pc) (3520KB)(66)       Save
    In order to improve the yaw and roll stability of in-wheel motor drive electric vehicles under extreme conditions such as high speed and low adhesion, a 3-DOF multi-cell model of vehicle lateral dynamics was established, and a robust layered controller was proposed. The local optimal solution of the upper-level reduced-order dynamic output feedback controller was obtained by iterative search, with the demands for the pole configuration and H∞ performance constraints at the same time. With the optimization objective of minimizing the comprehensive tire load rate, the optimal torque of the lower four wheels was obtained. Simulink and CarSim co-simulation results show that this control strategy may significantly improve vehicle stability under different working conditions, and maintain robustness to system parameter variations and external disturbances. 
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    Residual Life Prediction for Bearings Based on Bearing Degradation State Assessment and IGAT-BiGRU Network
    SONG Lijun, LIU Songlin, XIN Yu, MA Jinghua, XIE Zhengqiu
    China Mechanical Engineering    2025, 36 (07): 1562-1572.   DOI: 10.3969/j.issn.1004-132X.2025.07.019
    Abstract883)      PDF(pc) (8759KB)(44)       Save
    Due to the influences of working conditions and operating conditions, the collected status monitoring data was interfered with strong noise in full life cycle of rolling bearings, and the bearing operating life degradation was nonlinear, which seriously affected the accuracy of residual life prediction. So, a bearing residual life prediction method was proposed based on a joint high-precision FPT degradation state evaluation and an IGAT-BiGRU network, and the XJTU-SY full life cycle bearing dataset was used to verify the effectiveness of the proposed method. The results show that the proposed prediction method may effectively capture the deep spatiotemporal features that characterize the bearing degradation states, and significantly improve the residual life prediction accuracy, compared with methods such as CNN-LSTM.
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    Rigid-flexible Coupling Identification of MDOF Excitation for Door Limiter and Shaking Optimization of Window Frame during Closing
    Chengzhan LI, Pengcheng GUO, Congchang XU, Luoxing LI, Yongfu XIAO, Shuxia JIANG
    China Mechanical Engineering    2025, 36 (11): 2792-2800.   DOI: 10.3969/j.issn.1004-132X.2025.11.038
    Abstract855)   HTML2)    PDF(pc) (3581KB)(72)       Save

    Aiming at the problems that traditional NVH analysis struggled to accurately extract and predict the dynamic excitation and response of vehicle doors during rotation, a new method was proposed and applied to vibration transfer function analysis based on rigid-flexible coupling for identifying MDOF excitation. Taking the abnormal shaking of the window frame during door closing in a specific vehicle model as the research objective, a whole vehicle rigid-flexible coupling model was established by using multibody dynamics method. The MDOF acceleration dynamic excitation at the limiter installation points was extracted for transfer function analysis. The comparison between simulation and testing results shows that consistent peak values of vibration acceleration are detected at 12 Hz, which verifies the accuracy of the rigid-flexible coupling model. Then, the key factors affecting window frame shaking during door closing were analyzed via simulation, identifying the limiter structure as the core optimization target. An optimization scheme was proposed, and vibration transfer function analysis under the extracted dynamic excitation shows that the optimized limiter structure may significantly reduce the window frame shaking level during door closing.

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    Optimization and Experimental Study of Bolt Retreat Groove Rolling Wheels Based on Finite Element Simulation
    NIU Yanzhao1, LIU Hongwei1, SONG Yali2, ZHU Xianglong1, HUANG Jiamei2, KANG Renke1
    China Mechanical Engineering    2025, 36 (06): 1214-1221.   DOI: 10.3969/j.issn.1004-132X.2025.06.009
    Abstract823)      PDF(pc) (15061KB)(88)       Save
    The bolt retreat groove surfaces were susceptible to stress concentration and prone to fatigue failure. To bolster the fatigue resistance of bolts retreat groove surfaces, a specialized rolling tool for the retreat grooves was engineered. The structure of the rolling wheels was optimized based on finite element simulation outcomes of the interaction between the rolling wheel and the bolts retreat grooves. The optimized parameters were utilized to create the rolling tools, and a rolling experiments were carried out. The effectiveness of the rolling wheel parameter optimization was validated by assessing the rolled surface quality, fracture morphology, and fatigue life. The findings indicate that the most favorable residual stress results on the retreat groove surfaces are obtained with a YG8 material rolling wheel with diameter of 60 mm and face angle of 45°. A rolling wheel fillet radius of 0.9 mm produces the deepest residual compressive stress layers, a radius of 1.1 mm yields the highest subsurface residual compressive stress value, and a radius of 1.2 mm generates the maximum surface compressive stress. Trials were conducted with rolling tools featuring three distinct fillet radii, and the extended fatigue life of the bolts is ascertained with a 0.9 mm fillet radius rolling wheels, thereby confirming the optimal configuration of the rolling tools.
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    Research on Construction Techniques for Wind Power Equipment Contextual Knowledge Graphs
    SHI Zhiyuan1, 2, KONG Zhiwei2, CHEN Junzhen3, WANG Shuying3
    China Mechanical Engineering    2025, 36 (06): 1206-1213.   DOI: 10.3969/j.issn.1004-132X.2025.06.008
    Abstract744)      PDF(pc) (10201KB)(89)       Save
    Traditional methods for constructing knowledge graphs didnt consider the contextual constraints on knowledge, making it challenging to effectively represent the complex associative relationships among vast knowledge in complex electromechanical equipment like wind turbines. This limitation hindered the practical applications of knowledge graphs in the production processes. This paper proposed a method for constructing a context-aware knowledge graph tailored for wind turbine equipment. Initially, the method extracted contextual knowledge, module meta-knowledge, and module instance knowledge generated from project customization. Utilizing the SHACL, an ontology model was constructed, incorporating context paths and attribute value constraints, thereby precisely characterizing and extracting various knowledge types. Furthermore, an ontology parsing-based algorithm is introduced for visualizing contextual knowledge subgraphs. Through the parsing of contextual knowledge classes within the ontology, data observation windows were generated for each contextual class, facilitating the construction of multi-dimensional visualization interactions tailored to specific scenarios. Through practical applications, the proposed method effectively integrates module meta-knowledge with project-specific module instance knowledge, meeting the demands for precise representation and diverse application scenarios in wind turbine equipment knowledge.
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    Modeling and Identification of Robot End-payloads Based on Joint Torque Balance
    GAO Guanbin1, 2, ZHAO Siguo1, 2, LI Yingjie1, 2
    China Mechanical Engineering    2025, 36 (06): 1188-1197.   DOI: 10.3969/j.issn.1004-132X.2025.06.006
    Abstract740)      PDF(pc) (8978KB)(113)       Save
     To address the challenges of decoupling center of mass parameters in existing end-payload identification methods and the difficulty of implementation on robots with non-open controllers, a torque-balance-based modeling and identification method was proposed for robot end-payloads. The identifiability conditions of the end-payloads were analyzed under joint torque balance, and identification models for the end-payload mass and center of mass position were established. To further decouple the mass and center of mass parameters, a three-step identification strategy was designed, where the load mass was identified first, followed by the center of mass position in x and y, and finally in z. This strategy effectively eliminated the error terms introduced by the projection of joint torques in the identification models. The efficiency of the proposed method was validated through simulation and experiments. Compared with the built-in identification method of a non-open-source six-degree-of-freedom robot, the average error in mass identification is reduced from 0.103 kg to 0.032 kg, while the average error in center of mass position identification is decreased from 50.25 mm to 4.14 mm. Furthermore, compared with dynamics parameter identification, the mass identification error is reduced from 0.179 kg to 0.083 kg, and the center of mass position error is reduced from 10.13 mm to 4.33 mm.
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    Fusion of Degradation Feature Information and Remaining Life Prediction for Rolling Bearings
    ZHANG Jianyu, WANG Liuzhen, XIAO Yong, MA Yanan
    China Mechanical Engineering    2025, 36 (07): 1553-1561.   DOI: 10.3969/j.issn.1004-132X.2025.07.018
    Abstract723)      PDF(pc) (7450KB)(66)       Save
    To address the demands for remaining life prediction of rolling bearings, a prediction model was proposed based on SAE and BiLSTM network. Taking the full-life vibration data of rolling bearings as research object, a degradation index set was constructed by developing a hyperbolic inverse transformation-based health indicator and a frequency-domain harmonic degradation factor. The SAE was employed for feature fusion to extract key features and eliminate redundant information. Meanwhile, the BiLSTM model was utilized to capture temporal dependencies and achieve full-cycle life prediction. Experimental results demonstrate that the proposed model outperforms support vector regression, extreme learning machines, and convolutional neural networks in terms of smaller prediction errors and stronger generalization capabilities.
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    Analysis of Adhesion Characteristics of Novel Negative-pressure Adhesion Wall-climbing Robots
    DONG Weiguang1, LIU Aihua2, SONG Yifeng2
    China Mechanical Engineering    2025, 36 (06): 1198-1205.   DOI: 10.3969/j.issn.1004-132X.2025.06.007
    Abstract685)      PDF(pc) (6528KB)(133)       Save
    Addressing the challenge in optimizing the adhesion performance of wall-climbing robots based on negative pressure adhesion method due to the complexity of internal flow fields and difficulties in precise modeling, a flow field modeling method was proposed based on flow rate conservation. According to the structural characteristics of negative pressure adhesion systems of a wall-climbing robot, mathematical models of airflow field in negative pressure adhesion systems were built by combining the laws of thermodynamics and N-S equations using air flow rate as the related factor. Then, key influencing factors of adhesion performance were identified based on the model: sealing ring width, leakage gap height, and centrifugal pump power. The effective adhesion forces were changing with airflow of adhesion systems. Results of the simulation and prototype experiments show that the models constructed herein may accurately reflect the changing rules of adhesion performance, and may provide evidences for the optimization of adhesion performance of wall climbing robots with negative pressure adhesion method. Finally, according to the movement characteristics of the wall-climbing robots, adsorption performance optimization strategy was increasing the rated adsorption force to self gravity ratio while decreasing the effective adsorption force to self gravity ratio.
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    Fault Diagnosability Evaluation of Meta Actuation Units Based on SABO-VMD
    Hongyu GE, Zhan ZHAO, Anxiang GUO, Jiarui SUN
    China Mechanical Engineering    2025, 36 (08): 1774-1783.   DOI: 10.3969/j.issn.1004-132X.2025.08.013
    Abstract679)   HTML1)    PDF(pc) (2765KB)(110)       Save

    This paper introduced an evaluative approach to gauge the complexity of fault diagnosis within meta actuation units. The methodology commences with the decomposition of fault signals from these units, utilizing a VMD technique refined by SABO. The processes included the applications of a Kurtosis-based criterion to select pertinent intrinsic mode functions (IMFs), culminating in the creation of a feature vector grounded in envelope entropy. The evaluative task then pivoted on employing Cosine distance as a measure of similarity, recasting the fault diagnosability problems into one of assessing the likeness of vibration signal feature vectors across varying fault conditions. A diagnosability evaluation matrix for the meta actuation units was formulated, which layed the foundation for a diagnostic index. It is concluded with an empirical validation using a worm gear-based meta actuation unit; the findings confirm the method’s efficacy in quantitatively gauging the diagnosability of diverse fault patterns.

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    A Reliability Allocation Method Considering Distribution and Transmission Models for Mechanical Systems
    WANG Zhichao1, LIU Chao1, RAN Yan2, CHEN Yifan3, JIANG Dongxiang1, ZHANG Genbao2, 3
    China Mechanical Engineering    2025, 36 (06): 1143-1150.   DOI: 10.3969/j.issn.1004-132X.2025.06.001
    Abstract639)      PDF(pc) (1184KB)(163)       Save
    To address the problems of the allocation reliability of lower-level units being greater than that of the upper-level unit in the multi-layer structure reliability allocation of mechanical systems, a novel reliability allocation method was proposed. Firstly, the mechanical systems were divided into a system-function-motion-action(SFMA) hierarchy structure. Then, according to the hierarchy structure consisting of distribution and transmission models, the reliability allocation techniques were proposed by combining the minimum cost method and reliability function, and the reliability allocation models of the mechanical systems, function units, motion units, and sub-motion units were established from top to bottom. Finally, taking the gear grinding machine as an example, the feasibility and effectiveness of the proposed method were verified.
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    Molecular Dynamics Simulation of Microscopic Crack Initiation and Extension Mechanism in 8Cr4Mo4V Bearing Steels
    Tianyu MA, Gu GONG, Hongrui CAO, Jianghai SHI, Xunkai WEI, Lijun ZHANG
    China Mechanical Engineering    2025, 36 (10): 2179-2189.   DOI: 10.3969/j.issn.1004-132X.2025.10.003
    Abstract611)   HTML63)    PDF(pc) (7456KB)(525)       Save

    To investigate the influences of cementite on the mechanics properties of the matrix and the initiation and propagation of microcracks in 8Cr4Mo4V bearing steels, molecular dynamics models were used to systematically analyze the effects of cementite's geometric parameters (such as shape, size, and position) on crack initiation and extension mechanism. And combined with cohesive force theory, the characteristics of interface crack propagation were studied. The results indicate that cementite significantly enhances the mechanics properties of the bcc-Fe matrix, with smaller cementite particles providing a more pronounced strengthening effectiveness. While the shape and position of cementite exert a relatively minor impact on overall mechanics performance, sharper inclusions accelerate crack propagation, and the position of inclusions determines the crack propagation path. Furthermore, interfaces between the bcc-Fe matrix and cementite, as well as twin boundaries with larger misorientation angles, exhibit increased resistance to crack initiation and propagation.

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    Influences of MCMBs on Electrolytic Dressing and Grinding Performances of Multi-layer Brazed Diamond Grinding Wheels
    LIU Wei1, 2, CHANG Jiaqi1, 2, LI Boxin1, 2, YAN Can1, 2, DENG Zhaohui3, WAN Linlin1, 2
    China Mechanical Engineering    2025, 36 (06): 1151-1158.   DOI: 10.3969/j.issn.1004-132X.2025.06.002
    Abstract604)      PDF(pc) (12170KB)(90)       Save
    The oxide film of large particle size multi-layer brazed diamond grinding wheel had poor quality and insufficient thickness during electrolytic dressing, which led to poor grinding performances. MCMB were added to the abrasive layers to improve this situation. The effects of different MCMB contents on the performances of the grinding wheel and the electrolytic dressing grinding characteristics were investigated. The results show that MCMB may significantly improve the electrolytic film-forming ability of the grinding wheel, the maximum thickness of the oxide film is as 104 μm, and the compactness and adhesion are improved. The ground surface morphology of the test groups containing MCMB has higher integrity and fewer fracture pits. Compared with the test groups without MCMB, the values of surface roughness Ra of the MCMB test groups with a volume fraction of 5% decrease by 29.8% when the workpiece speed is as 40 mm/s and the grinding depth is as 15 μm, and the subsurface damage depth is reduced by 47.9% when the workpiece speed is as 30 mm/s and the grinding depth is as 20 μm.
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    Experimental and Molecular Dynamics Simulation for Mechanics Properties of 45 Steel Treated by Plasma
    Zhaobo PENG, Jinxing KONG, Dongxing DU, Hankun LUO, Hen YUE
    China Mechanical Engineering    2025, 36 (10): 2190-2197.   DOI: 10.3969/j.issn.1004-132X.2025.10.004
    Abstract600)   HTML34)    PDF(pc) (2599KB)(315)       Save

    To investigate the influences of plasma treatment on the mechanics properties of 45 steel, the changes of mechanics properties of 45 steel before and after treatment were studied by combining experiments and molecular dynamics simulation. The test results show that the hardness and tensile mechanics properties of 45 steel are obviously decreased after plasma treatment. Under the treatment durations of 1, 5 and 10 min, the nano-hardnessis decreased by 12%, 21% and 28% respectively, and the longer the treatment time, the better the modification effect, and the duration of the modification effect is more than 20 h. When the thickness of tensile specimens is as 0.1, 0.15 and 0.2 mm, the tensile strength decreases by 3.3%, 4.5% and 5.3%, and the elongation after fracture decreases by 39.69%, 42.17% and 42.49%, respectively. The molecular dynamics simulation results show that the number and strength of Fe-Fe bonds in 45 steel are reduced after plasma modification, resulting in the reduction of yield strength and surface hardness of the materials, which is basically consistent with the experimental results.

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    A Novel Deformable Serial Pipeline Inspection Robots:Design, Modeling and Experimentation
    Yixin ZHANG, Yinan MIAO, Zhiheng YI, Wenjing WAN, Xingjian WANG, Song ZENG, Shaoping WANG
    China Mechanical Engineering    2025, 36 (09): 2140-2149.   DOI: 10.3969/j.issn.1004-132X.2025.09.026
    Abstract596)   HTML14)    PDF(pc) (4346KB)(169)       Save

    In response to the urgent demands for daily maintenance and inspection of oil and gas pipelines, a novel modular pipeline inspection robot named RoboChain-Ⅰ, featuring adaptive deformation capabilities, was proposed herein. Unlike most wheel-based pipeline robots, the robot adopted a cell-inspired modular biomimetic design with more flexible joint redundant rotational degrees of freedom(DOF), allowing the robot to actively deform in response to pipelines with varying shapes and diameters. Each module was equipped with dual-wheel independent drive, and a pair of pitch and yaw actuation mechanisms were installed at the front and rear. The modules were connected by passive elastic damping support structures or controllable electromagnetic adhesion-separation rigid structures, which improved the robot's ability to navigate complex pipelines and adapt to various environments. The forces acting on the robots during their motions inside the pipeline were modeled, and kinematics simulations were conducted using Adams. The selection of design parameters for the model was validated accordingly. A comprehensive series of experiments were conducted to evaluate RoboChain-Ⅰ's performance, including terrestrial locomotion, straight pipe traversal, elbow pipe navigation, diameter-varying pipeline adaptation, and active mother-child separation. Experimental results validate the robot's effectiveness and reliability in performing inspection tasks within complex three-dimensional pipeline networks with diameters ranging from 175~440 mm, demonstrating maximum velocities of 0.87 m/s on flat surfaces and 0.4 m/s within pipelines.

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    Accelerated Load Spectrum Preparation for RV Reducer Service Conditions
    YANG Yu1, 2, LI Xiaolei2, TAO Yourui1, 2, GUO Qiyu1, 2, YE Nan1, 2
    China Mechanical Engineering    2025, 36 (06): 1170-1177.   DOI: 10.3969/j.issn.1004-132X.2025.06.004
    Abstract595)      PDF(pc) (4157KB)(113)       Save
    Aiming at the needs of reliability analysis and life prediction of RV reducers for industrial robot joints, a method of compiling accelerated load spectrum for RV reducers was proposed based on service conditions. On-site collection of industrial robot joint torque-time data and data preprocessing, the Markov chain Monte Carlo methods(MCMC) were applied for time-domain reconstruction and service conditions were synthesized as a typical RV reducer reconstruction of the load history. The rainfall counting methods were used for statistical counting, distribution fitting and parameter estimation, to obtain the statistical distribution laws of the mean-amplitude of the load. The mean-amplitude two-dimensional load spectrum obtained by frequency extrapolation were transformed into 8-level one-dimensional program loading spectrum, and accelerated based on the actual applications of RV reducers, which was compiled into a one-dimensional accelerated program loading spectrum of RV reducers, which greatly shortened the fatigue life test cycle.
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    Design and Kinematics Modeling of Extensible Snake-like Manipulators
    WANG Xuhao, SHENG Wolong, WU Mengli, XU Yilong, ZHAO Xiaowei, CAO Yiran
    China Mechanical Engineering    2025, 36 (12): 2885-2893.   DOI: 10.3969/j.issn.1004-132X.2025.12.010
    Abstract589)   HTML7)    PDF(pc) (4235KB)(82)       Save

    A novel snake-like manipulator was proposed, the modular joints of the manipulator were designed with an active extensible degree of freedom, which increased the overall motion flexibility and adaptability in complex spaces. Kinematics modeling of the snake-like manipulators was carried out. The mappings among actuator space, joint space and end task space were analyzed. Considering the characteristics of the extensible joints, two novel joint-end inverse kinematics algorithms were proposed, i.e. the integrated method by combing the conventional FABRIK algorithm with Jacobian-based iterative algorithm, and the modified FABRIK algorithm with iteratively updated link lengths. Numerical simulations were conducted to verify computational accuracy and efficiency. The results show that both methods have better accuracy, while the modified FABRIK algorithm has higher computational efficiency. Finally, a prototype was constructed, and experiments were carried out to validate motion capabilities of the proposed snake-like manipulators.

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    Development Trends and Prospects of Additive Manufacturing Technology for Cemented Carbide Cutting Tools
    JIANG Feng1, 2, HU Ronghui1, DENG Jiedong1, ZHANG Tian1, HUANG Guoqin1, 2, XU Yangli1, 2, LI Yousheng3, LIU Chao4
    China Mechanical Engineering    2025, 36 (06): 1300-1313.   DOI: 10.3969/j.issn.1004-132X.2025.06.017
    Abstract566)      PDF(pc) (9282KB)(113)       Save
    Two technical routes for the additive manufacturing of cemented carbide cutting tools were reviewed: the powder bed fusion  route based on thermal forming, and the forming-debinding-sintering based on cold printing of  green bodies, followed by debinding and sintering. The powder bed fusion technique might produce cemented carbide cutting tools with near-theoretical density, but issues such as porosity, cracking, decarburization and cobalt evaporation remained. By adjusting parameters such as laser energy density, scanning speed, and powder characteristics, the quality of the printed components might be significantly improved. The forming-debinding-sintering technique might produce cutting tools with excellent surface quality and superior mechanics properties, but challenges such as binder residue and component shrinkage persisted. By optimizing key parameters such as binder type, debinding process, and sintering temperature, the density and mechanics properties of the components might be enhanced. Additionally, heat treatment processes such as vacuum sintering, hot pressing, and hot isostatic pressing might further eliminate internal defects in the materials, thereby improving the overall performance of the cutting tools. 
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    Molecular Dynamics Simulation and Parameter Optimization Research for Abrasive Flow Finishing of Additive Manufactured Nozzle Convergent and Divergent Sections
    LYU Qian, LIU Weiwei
    China Mechanical Engineering    2025, 36 (12): 3017-3022.   DOI: 10.3969/j.issn.1004-132X.2025.12.026
    Abstract559)   HTML3)    PDF(pc) (2228KB)(41)       Save

    Aiming at the current difficultes in surface finishing of additively manufactured complex internal flow channels, a multiscale simulation and experimental study of the abrasive flow finishing process was conducted.The abrasive flow velocity under typical pressures was determined through fluid simulation, and the micro-cutting processes were modeled using LAMMPS to establish the relationship between velocity and micro-cutting force. Results indicate that at 60~70 m/s, the cutting force stabilized with moderate magnitude, material removal remaines uniform, and the surface is free of burrs and scratches, defining an ideal finishing condition that provides a theoretical basis for process optimization. Orthogonal experiments with three factors and three levels were carried out on additively manufactured specimens featuring spiral flow channels. Post-finishing results demonstrate effective elimination of typical defects such as powder adhesion, stair-stepping, balling, and support residues, reducing surface roughness Ra from 7 μm to below 0.7 μm and Rp from 21 μm to below 1.25 μm.

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    Nanosecond Laser Machining of Spiral Grooves of Dry Gas Seal Rotational Ring Surfaces
    Wenqian LI, Zhanqiang LIU, Jinfu ZHAO, Bing WANG, Yukui CAI
    China Mechanical Engineering    2025, 36 (10): 2207-2214.   DOI: 10.3969/j.issn.1004-132X.2025.10.006
    Abstract555)   HTML85)    PDF(pc) (3972KB)(600)       Save

    An experimental study on the nanosecond laser processing of the spiral groove on the dry gas seal rotational ring surfaces made of GH4169 was carried out. Orthogonal tests and one-factor methods were utilized to reveal the effects of laser power, scanning speed, filling spacing and repetition frequency on the spiral groove depth and bottom roughness Ra, and to determine the appropriate combination of laser processing parameters. The results show that the greatest influence on the depth of the spiral grooves on the surfaces of GH4169 alloy is the laser power, followed by the repetition frequency and the scanning speed, and the greatest influence on the roughness of the groove bottoms is the scanning speed, followed by the repetition frequency and the scanning spacing. With the laser power of 18 W, scanning speed of 40 mm/s, fill spacing of 0.005 mm, and repetition frequency of 50 kHz, the spiral grooves on the machined rotational ring surfaces is able to meet the machining requirements of groove depth of 7 μm, and groove bottom roughness of Ra≤0.8 μm.

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    Rotor Unbalance Recognition Based on Multidimensional Complex Feature Fusion and CNN-GRU
    Jianjian WANG, Yuhe LIAO, Lei YANG, Jiutao XUE
    China Mechanical Engineering    2025, 36 (09): 1905-1915.   DOI: 10.3969/j.issn.1004-132X.2025.09.001
    Abstract548)   HTML10)    PDF(pc) (3434KB)(131)       Save

    The existing unbalance identification algorithm without trial weight adopted an optimization algorithm framework and approximated the optimal solution through numerous iterative operations. However, such strategies typically faced the limitations of slow convergence speed and the tendency to fall into local extrema. Therefore, neural networks were used to directly learn and analyze the complex mapping relationship between unbalance vibration response and unbalance, thus realizing high-precision unbalance identification. A sufficient unbalance vibration dataset with labels was constructed by simulating the rotor dynamics model. A feature fusion mechanism was designed to address the multi-dimensional complex-valued characteristics of unbalanced data. At the core algorithm level, a CNN-GRU hybrid model was constructed. In this model, CNN was responsible for extracting local spatial features from vibration data, while GRU captured temporal dependencies within the vibration data. By integrating information from both spatial and temporal domains, the model’s generalization ability and recognition accuracy were significantly enhanced. The unbalance recognition results of test set data and experimental bench demonstrate that this method may accurately predict the unbalance of the rotors, providing a rapid and accurate guide for dynamic balancing in the field without trial weights.

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