Your search keyword '"Zhebin Shen"' showing total 4 results

1. Five-Axis Path Smoothing Based on Sliding Convolution Windows for Cnc Machining

Author

Haorong Zhang, Yijie Wu, Peng Zhang, Zhebin Shen, Hengbo Li, and Fei Lou

Published

2023

2. A smoothing method of continuous line-segment path in CNC machining based on real-time transformation of interpolation points

Author

Peng Zhang, Fei Lou, Peng Guo, Zhebin Shen, Haorong Zhang, and Yijie Wu

Subjects

business.product_category, Computer science, Mechanical Engineering, ComputingMethodologies_IMAGEPROCESSINGANDCOMPUTERVISION, Industrial and Manufacturing Engineering, Computer Science Applications, Machine tool, Transformation (function), Line segment, Machining, Control and Systems Engineering, Numerical control, Point (geometry), business, Algorithm, Software, Smoothing, ComputingMethodologies_COMPUTERGRAPHICS, Interpolation

Abstract

The G-code for CNC machining of free-form surfaces is usually composed of continuous line segments. The sudden change of velocity direction at the corner of adjacent line segments will cause the vibration of the machine tool, eventually affecting the machining quality. Therefore, this paper proposes a novel smoothing method for line segments based on the real-time transformation of interpolation points (SSTI). Firstly, this method generates a smoothing interval on the line-segment path, which centered on the current original interpolation point. Secondly, a smoothed interpolation point corresponding with the current interpolation point is obtained, by a transformation according to the line-segment path in the smoothing interval. Finally, to ensure the machining accuracy, the smoothing error of the smoothed interpolation point is checked and controlled. Compared with conventional smoothing methods, the SSTI method has no special requirements on the original line-segment path, such as the length of line segments, the angle of corners, and the quantity of endpoints. Simulation and experimental results show that the SSTI method proposed in this paper has good adaptability to different types of line-segment paths, and the smooth optimization can be achieved under the premise of ensuring machining accuracy. The proposed method offers an effective trajectory-optimization strategy for the CNC machining of continuous line-segment path.

Published

2021

3. A Feedrate-Constraint Method for Continuous Small Line Segments in CNC Machining Based on Nominal Acceleration

Author

Ronghua Wang, Peng Guo, Zhebin Shen, Hengbo Li, Peng Zhang, Fei Lou, Yijie Wu, and Haorong Zhang

Subjects

Technology, business.product_category, QH301-705.5, Computer science, QC1-999, corner, Mechanical engineering, feedrate, Servomechanism, law.invention, CNC machining, Acceleration, Line segment, Machining, Control theory, law, continuous small line segments, General Materials Science, Biology (General), QD1-999, Instrumentation, Fluid Flow and Transfer Processes, Physics, Process Chemistry and Technology, General Engineering, acceleration, Engineering (General). Civil engineering (General), Computer Science Applications, Machine tool, Chemistry, Trajectory, Numerical control, TA1-2040, business

Abstract

When the CNC machining of continuous small line segments is performed, the direction of the machine tool movement will change abruptly at the corner of adjacent line segments. Therefore, a reasonable constraint on the feedrate at the corner is the prerequisite for achieving high-speed and high-precision machining. To achieve this goal, a feedrate-constraint method based on the nominal acceleration was proposed. The proposed method obtains the predicted value of acceleration during the machining process by the machining trajectory prediction and acceleration filtering. Then, the feedrate at the corner is constrained, according to the predicted acceleration. Specifically, for any corner of adjacent line segments, the proposed method assumes that the CNC machining of a short path centered on the corner is carried out at a constant feedrate. First, the actual machining trajectory is predicted according to the transfer function of the servo system. Then, the nominal acceleration, when the CNC machining is carried out to the corner, is calculated and processed by a low-pass FIR filter. Last, the feedrate-constraint value at the corner is obtained according to the nominal acceleration and the preset normal acceleration. The advantage of the proposed method is that it can be used for different machining paths consisting of long segments or continuous small segments and it has no special requirement for the accuracy of the machining path. As a result, the feedrate-constraint value obtained is reasonable and the smooth machining process can be ensured. The simulation results in both 2D and 3D machining paths show that the proposed method is insensitive to the length of the line segment and the angle of the corner, and the calculated feedrate-constraint value is close to the theoretical value, which has good stability and versatility. In contrast, the feedrate-constraint values obtained by conventional methods change abruptly along the machining path, especially in the 3D simulation, which will damage the machining quality. The experiment was performed on a three-axis CNC machine tool controlled by a self-developed controller, and a free-form surface workpiece was machined by a conventional feedrate-constraint method and the proposed method, respectively. The experimental results showed that the proposed method can make the feedrate of the machining process higher and more stable. Then, machining defects such as overcutting and undercutting can be avoided and the machining quality can be improved. Therefore, the article proposes a new method to constrain the feedrate at the corner of continuous small line segments, which can improve the machining efficiency and quality of the CNC machining.

Published

2021

4. A Feedrate Planning Method for the NURBS Curve in CNC Machining Based on the Critical Constraint Curve

Author

Guang Yang, Fei Lou, Peng Guo, Yijie Wu, Haorong Zhang, Hengbo Li, Peng Zhang, and Zhebin Shen

Subjects

0209 industrial biotechnology, Technology, Computer science, QH301-705.5, QC1-999, 02 engineering and technology, Kinematics, Curvature, feedrate planning, Acceleration, 020901 industrial engineering & automation, 0203 mechanical engineering, Machining, Control theory, General Materials Science, Biology (General), Instrumentation, QD1-999, Fluid Flow and Transfer Processes, Process Chemistry and Technology, Physics, General Engineering, Engineering (General). Civil engineering (General), Computer Science Applications, Constraint (information theory), Chemistry, 020303 mechanical engineering & transports, NURBS, feedrate-constraint value, curvature, Trajectory, Numerical control, acceleration/deceleration, TA1-2040, Arc length

Abstract

The curvature of the NURBS curve varies along its trajectory, therefore, the commonly used feedrate-planning method, which based on the acceleration/deceleration (Acc/Dec) model, is difficult to be directly applied in CNC machining of a NURBS curve. To address this problem, a feedrate-planning method based on the critical constraint curve of the feedrate (CCC) is proposed. Firstly, the problems of existing feedrate-planning methods and their causes are analyzed. Secondly, by considering both the curvature constraint and the kinematic constraint during the Acc/Dec process, the concept of CCC which represents the relationship between the critical feedrate-constraint value and the arc length is proposed. Then the CCC of a NURBS curve is constructed, and it has a concise expression conforming to the Acc/Dec model. Finally, a feedrate-planning method of a NURBS curve based on CCC and the Acc/Dec model is established. In the simulation, a comparison between the proposed method and the conventional feedrate-planning method is performed, and the results show that, the proposed method can reduce the Acc/Dec time by over 40%, while little computational burden being added. The machining experimental results validate the real-time performance and stability of the proposed method, and also the machining quality is verified. The proposed method offers an effective feedrate-planning strategy for a NURBS curve in CNC machining.

Published

2021