Showing total 3,273 results

1. Announcement of B. John Davies Prize for the best paper published in IJAMT in 2019.

Author

Schilgerius, Silvia and Nee, Andrew Y. C.

Subjects

PRIZES (Contests & competitions), MACHINING, ENGINEERING laboratories, MECHANICAL engineering, VIBRATION (Mechanics)

Published

2021

2. Finite element simulation of ultrasonic-assisted machining: a review.

Author

Lotfi, Mohammad and Akbari, Javad

Subjects

MACHINING, CUTTING force, MACHINERY, ULTRASONIC waves, CUTTING tools, TITANIUM alloys, ULTRASONIC transducers

Abstract

Ultrasonic-assisted machining is an advanced method which could improve the process of machining. Besides, simulation modeling process is a method to help the researchers analyze different aspects of the process with more details in a shorter time. Simulation of ultrasonic-assisted machining is also a field of research that is of interest to researchers working in the field of machining processes. In recent years, a variety of papers have been published where cutting forces, chip formation, tool wear and temperature, and microstructure changes were simulated. That being the case, a review paper is required to represent the advances implemented by researchers in the simulation of ultrasonic-assisted machining process. Moreover, the difficulties and necessities of this process are mentioned at the end of this review paper. [ABSTRACT FROM AUTHOR]

Published

2021

3. Nanofluids application in machining: a comprehensive review.

Author

Wang, Xiaoming, Song, Yuxiang, Li, Changhe, Zhang, Yanbin, Ali, Hafiz Muhammad, Sharma, Shubham, Li, Runze, Yang, Min, Gao, Teng, Liu, Mingzheng, Cui, Xin, Said, Zafar, and Zhou, Zongming

Abstract

Nanofluids are efficient heat transfer media that have been developed over the past 27 years and have been widely used in the electronic microchannel, engine, spacecraft, nuclear, and solar energy fields. With the high demand for efficient lubricants in manufacturing, the application of nanofluids in machining has become a hot topic in academia and industry. However, in the context of the huge amount of literature in the past decade, existing review cannot be used as a technical manual for industrial applications. There are many technical difficulties in establishing a mature production system, which hinder the large-scale application of nanofluids in industrial production. The physicochemical mechanism underlying the application of nanofluids in machining remains unclear. This paper is a complete review of the process, device, and mechanism, especially the unique mechanism of nanofluid minimum quantity lubrication under different processing modes. In this paper, the preparation, fluid, thermal, and tribological properties of nanofluids are reviewed. The performance of nanofluids in machining is clarified. Typically, in friction and wear tests, the coefficient of friction of jatropha oil-based alumina nanofluids is reduced by 85% compared with dry conditions. The cutting fluid based on alumina nanoparticles improves the tool life by 177–230% in hard milling. The addition of carbon nanotube nanoparticles increases the convective heat transfer coefficient of normal saline by 145.06%. Furthermore, the innovative equipment used in the supply of nanofluids is reviewed, and the atomization mechanisms under different boundary conditions are analyzed. The technical problem of parameterized controllable supply system is solved. In addition, the performance of nanofluids in turning, milling, and grinding is discussed. The mapping relationship between the nanofluid parameters and the machining performance is clarified. The flow field distribution and lubricant wetting behavior under different tool-workpiece boundaries are investigated. Finally, the application prospects of nanofluids in machining are discussed. This review includes a report on recent progress in academia and industry as well as a roadmap for future development. [ABSTRACT FROM AUTHOR]

Published

2024

4. Optimization of the machining of metallic additive manufacturing supports: first methodological approach.

Author

Benoist, Vincent, Baili, Maher, and Arnaud, Lionel

Abstract

Metal additive manufacturing is an active field of innovation. However, for laser power bed fusion (LPBF), supports removal is a major constraint. In this technology, supports are strongly welded to the part to tightly maintain it, avoid distortion, and evacuate thermal load. Although supports are usually optimized for manual removal, machining is often necessary, which can affect post-processing productivity. This paper proposes a comprehensive methodological approach to optimize the selection of cutting parameters, cutting tools, and support structure for LPBF. The aim is to help additive manufacturers find supports that reduce machining costs in terms of time and cutting tool degradation, from among the numerous support designs available. This approach can also optimize the design of lattice structures used inside parts. Our results show that among the 11 designs tested, honeycomb and squared pattern grid supports are the most efficiently machined using the 8-teeth tangential milling of the 3 tools tested, with a good post-machined surface roughness and tools' health. The method considers low magnification optical analysis and an accelerometer sensor, which is easy to use even for small- and medium-sized enterprises. This paper also proposes and analyzes a new kind of porous support using this method. [ABSTRACT FROM AUTHOR]

Published

2024

5. Surface finish and edge preparation of Al2O3 + MgO cutting inserts by grinding and their application in hard turning.

Author

Nardy, Maysa Freitas Mainardes, de Souza, Jose Vitor Candido, dos Santos, Sergio Francisco, de Sampaio Alves, Manoel Cleber, Ribeiro, Marcos Valerio, Antonialli, Armando Ítalo Sette, and Ventura, Carlos Eiji Hirata

Abstract

Due to their high hardness at elevated temperatures and chemical stability, alumina-based ceramic cutting tools have been successfully applied in the machining of ferrous materials, especially quenched and tempered steels. Their low fracture toughness, however, makes it difficult to finish them by grinding, as cracks and defects can occur. In addition, its application in machining processes demands appropriate edge preparation to avoid tool failure. Within this context, the paper aims to demonstrate the applicability of an experimental Al2O3 + MgO ceramic cutting insert in hard turning. For this, grinding tests were performed to determine the most appropriate conditions to improve its surface and edge quality. The effects of cutting and feed speeds, grinding wheel bonding material, and abrasive grain size were investigated. Moreover, different cutting-edge geometries were prepared in this tool material and tested in turning a hardened AISI 4140 steel (50 HRC) to determine their performance regarding tool life and workpiece roughness. The results demonstrated that a finer grinding wheel (D15) combined with high cutting (60 m/s) and feed (10 mm/min) speeds leads to the lowest surface roughness and edge chipping. In addition, both symmetric (Κ = 1) and asymmetric (Κ = 2) edge roundings led to higher tool lives in hard turning in comparison to a single chamfered tool, as they contributed to better load distribution in the cutting region. The paper provides information for the manufacture and application of alumina-based ceramic cutting inserts in the metalworking industry, as it disseminates good manufacturing practices and recommendations for appropriate cutting-edge geometry. [ABSTRACT FROM AUTHOR]

Published

2024

6. Measurement and identification of translational static stiffness in workspace of a machine tool.

Author

Jastrzębska, Joanna, Parus, Arkadiusz, Jastrzębski, Daniel, and Pawełko, Piotr

Subjects

MACHINE tools, WORK measurement, DATA analysis, MEASUREMENT, MILLING-machines, MACHINING

Abstract

This work presents a measurement for the identification of translational quasi-static stiffness of machine tool using Stiffness Workspace System (SWS). The novelty of this work is a significant modification of the SWS. The changes in measurement procedure and data analysis as well as new technical solutions are described in detail. A methodology for generalised translational static stiffness determination is presented. The major purpose of this paper is to provide the information about quasi-static stiffness values that characterise a typical machine tool. The measurement procedure is implemented in a case study on a 5-axis machining centre. Measurement results were used to determine the generalised translational stiffness indicators of points in the workspace. Then, the static stiffness distribution on the XY plane over machining space was estimated. The obtained results confirm the importance of analyses of static stiffness distribution as they point out areas where some possible changes occur. In the conclusion of the paper the utility value of the information of translational static stiffness is emphasised. [ABSTRACT FROM AUTHOR]

Published

2023

7. A novel method for machining accuracy reliability and failure sensitivity analysis for multi-axis machine tool.

Author

Niu, Peng, Cheng, Qiang, Zhang, Caixia, Hao, Xiaolong, Yang, Congbin, and Chen, Chuanhai

Subjects

MACHINE tools, FAILURE analysis, MACHINING, NUMERICAL control of machine tools, MONTE Carlo method, FAILURE mode & effects analysis, SENSITIVITY analysis

Abstract

In the state of machining service, to evaluate the machining accuracy reliability of multi-axis CNC machine tools, analyze the accuracy failure mode and the reliability sensitivity under the failure mode, this paper proposes a research method by the cross-correlation studies of geometric error parameters to improve and promote the accuracy reliability of CNC machine tools. Firstly, by multi-body system theory, the homogeneous coordinate transformation matrix between each body of the machine tool is established, and the spatial machining accuracy model is constructed. At the same time, considering the time series problem in the measurement process of geometric error parameters, this paper studies the correlation between the error parameters for reliability analysis and proposes a novel reliability analysis index for each measurement point in the machine tool workspace. To validation of the method, the analysis results of this paper are compared with those by Monte Carlo simulation. In addition, the accuracy failure conditions of the machine tool are studied, the failure state function of machine tool accuracy is established, and the accuracy failure modes that may occur are analyzed from this, to carry out the accuracy failure sensitivity analysis under the failure mode, and to identify key geometric errors which have a great impact on the machining accuracy reliability of machine tool in the failure mode. Finally, taking a 3-axis machine tool as an example, according to the analysis results, this paper puts forward measures to improve the accuracy reliability and verifies the feasibility of the proposed method. [ABSTRACT FROM AUTHOR]

Published

2023

8. Splice design and electromagnetic analysis of a long-stroke maglev guideway for machine tools.

Author

Xiao, Longxue

Subjects

MACHINE tools, ELECTROMAGNETIC forces, MAGNETIC suspension, ELECTROMAGNETS, FINITE element method, MAGNETIC fields, MACHINING, MAGNETISM

Abstract

This paper explores a new structural design of armature splicing to reduce the machining requirements of maglev guideways. The paper presents the magnetically supported structure and working principle of magnetic levitation worktable machine tools. Rectangular tooth splicing structures for extended long-stroke maglev guideways are designed, and corresponding finite element analysis models are established. After calculating the static three-dimensional magnetic field with the help of ANSYS software, the electromagnetic force produced by the magnetic levitation electromagnet group decreases linearly with increasing splice clearance of the armature and increases linearly with the increasing number of splice teeth. The smaller the number of teeth is or the larger the clearance value is, the more pronounced the change is. When the number of teeth, the width of the teeth and the clearance of the splice are kept constant, the electromagnetic force increases with increasing tooth depth, and a change in the tooth width has little effect on the electromagnetic force. [ABSTRACT FROM AUTHOR]

Published

2021

9. High-precision machining technology based on analytical method for integral impeller with flank milling.

Author

Yu, Dao-Yang, Ding, Zhi, and Tian, Xiao-Qing

Subjects

MACHINING, IMPELLERS, GEOMETRIC modeling, SIMULATION software, MACHINERY, TOOLS, MILLING cutters

Abstract

The paper first introduces R offset tool axis error calculation method. In order to reduce the maximum machining error, the paper presents a new geometric model of tool axis vector for flank milling non-developable ruled surfaces and machining error exact analytical solution is derived. Its main advantage is that the theoretical machining error of each point on the straight generatrix can be calculated. MATLAB software simulation and actual NC machining experiment are conducted to validate the effectiveness of the proposed algorithm. The measurement experimental results show that the actual maximum machining error is basically consistent with the theoretical calculation error, and the machining error can be reduced compared with the previous literature algorithm. [ABSTRACT FROM AUTHOR]

Published

2021

10. Machining assistance techniques: impact on tool wear and surface integrity on aeronautic alloys.

Author

Germain, Guénaël, Ayed, Yessine, Lavisse, Bruno, and Cadoux, Tanguy

Abstract

This article discusses the effect of machining assistance on the machinability and surface integrity of titanium and nickel-based alloys for turning operations. The presented results are based on a literature review of the principal experimental work published by the French research laboratories within the framework of the Manufacturing 21 group. The work presented focuses on the assistances the most studied by the research group: cryogenic assistance and high-pressure assistance. This paper specifically addresses the experimental approaches used to determine the effect of the assistant on the cutting force, tool wear, chip formation, microstructural changes, and residual stresses generated on the workpiece machined surface. This literature review is completed by new results comparing machining tests on the Ti6Al4V titanium alloy using high pressure and cryogenic assistances. The results show that the assistances increase the tool life, as well as improve the surface integrity of the parts. However, these gains are not identical from one material to another. In particular, titanium alloys and nickel alloys show how a very different gains for a fixed assistance. The conclusions presented highlight current trends and research needs. [ABSTRACT FROM AUTHOR]

Published

2024

11. Conventional and laser-assisted machining of laser-borided Monel 400 alloy.

Author

Kukliński, Mateusz, Przestacki, Damian, Bartkowska, Aneta, Kieruj, Piotr, and Radek, Norbert

Subjects

MACHINING, BORON, LASER beams, CUTTING force, ALLOYS, SURFACE roughness

Abstract

This study concentrates on comparing effects of conventional and laser-assisted machining (LAM) of laser-borided Monel 400 alloy. For this purpose, the shaft made from Monel 400 was covered with 200-µm thick boron layer and surface melted using diode laser. For determining the influence of laser beam scanning velocity on final microstructure, microhardness, and depth of melting, four laser beam scanning velocities were set: 5, 6, 8. and 10 m/min. Obtained microstructures are typical for laser-melted metal and are composed of fine crystals. Microhardness increased significantly due to enriching Monel 400 with boron and the level of this increase depends on the laser beam scanning velocity carried out for the process. During both conventional and laser-assisted turning, cutting forces were measured for comparison. Other compared parameters after carrying out these processes were obtained surface roughness and tool life. It was found that it is possible to form laser-borided surface of Monel 400 alloy by machining and using additional laser-assist has a positive impact on the efficiency of the process. Laser-assisted machining allows to lower cutting forces during machining and this leads to extended tool life. On the other hand, this method provides lower values of roughness parameters on the machined surface due to the effect of softening the surface during the process. The paper is the first description of effects obtained by laser-assisted machining of laser-borided surface. [ABSTRACT FROM AUTHOR]

Published

2023

12. A novel multi-pass machining accuracy prediction method for thin-walled parts.

Author

Huang, Qiang, Wang, Sibao, Wang, Shilong, Zhao, Zengya, Wang, Zehua, and Tang, Binrui

Subjects

BACK propagation, SURFACE topography, CUTTING force, MACHINING, MACHINE performance, MACHINERY, PREDICTION models

Abstract

Thin-walled parts (TWPs) are widely used in aerospace, and their service performance is significantly affected by the machining accuracy. Multi-pass machining is used to machine the poor stiffness TWPs. However, it is difficult to accurately predict the final machining accuracy due to surface topography error propagation and accumulation in multi-pass machining. Therefore, this paper proposes a multi-pass machining accuracy prediction method for TWPs based on dynamic factors (cutting force and stiffness). First, a flexible cutting force prediction model, which considers the axial errors determined by the initial surface topography and part deflection, is proposed. Second, a position-pass-dependent stiffness (PPDS) model is established considering the position dependence of stiffness and multi-pass machining material removal. Finally, combining the two models above, a multi-pass machining accuracy prediction method based on a genetic algorithm–back propagation (GA-BP) neural network is proposed. Experiments under various conditions are carried out to validate the proposed method. The machining accuracy (flatness as an example) is as high as 90.8% using the method in this paper, while it is only 73.9% when the accumulative error is neglected. The proposed method can significantly improve the performance of machining accuracy prediction by revealing the error propagation mechanism and the effect of dynamic factors between multi-pass machining. Furthermore, this also provides a theoretical basis for process parameter optimization and machining accuracy improvement in TWP machining. [ABSTRACT FROM AUTHOR]

Published

2023

13. Design of a truss-structured compliant toolholder for machining of structured surfaces.

Author

Paniselvam, Vinodth and Kumar, A. Senthil

Subjects

COMPLIANT mechanisms, COMPLIANT platforms, MACHINING, FINITE element method, DEFORMATIONS (Mechanics), MODAL analysis

Abstract

Cutting toolholders, with designed in-built compliant mechanisms, are frequently used for machining microfeatures. In this paper, compliant structures are designed using trusses as they exhibit a superior strength-to-weight ratio. Systematically stacked two-stage truss structures along with flexure hinges are designed to yield the desired precise cutting motion. The materially reduced efficient design amplifies the output force and greatly assists in overcoming cutting resistance during machining. The characteristics of the designed compliant tool holder are analysed by considering the output force and displacement for a given input. Both mathematical modelling to determine the force and finite element analysis to identify the critical stress regions when subjected to a prescribed input displacement are presented. As part of dynamic analysis, modal analysis and harmonic response studies were performed to determine how the trussed compliant structure deforms when subjected to dynamic loadings. The designed tool holder was additively manufactured using functionally rigid polyamide-12-glass-bead (PA12-GB) material. The performance of the developed cutting tool holder is then verified by machining radially graded surfaces following which, the machining results are presented in this paper. [ABSTRACT FROM AUTHOR]

Published

2023

14. Local corner smoothing algorithm for screw motor high-precision machining.

Author

Yu, Dao-Yang, Ding, Zhi, Tian, Xiao-Qing, and Huang, Xiao-Yong

Subjects

MACHINE dynamics, MACHINE tools, SCREWS, MACHINING, AUTOMATION, ALGORITHMS

Abstract

Linear motion commands of multi-axis computer numerical control (CNC) machine tools need to be smoothed at the transition corners, because the velocity discontinuities at corners can result in fluctuations on machine tool motions and lead to poor surface quality. However, few studies have reported on the transition between non-line contour. The paper proposes a novel two-step local corner smoothing method for non-line contour transition, including path smoothing and feedrate scheduling. In path smoothing, a non-uniform rational B-spline (NURBS) curve is adopted to smooth the adjacent non-line contour of screw rotor section while constraining the cornering error with the set tolerance. The maximum deviation between the original trajectory and smoothed toolpath can be analytically calculated. In feedrate scheduling, a jerk-limited S-curve feedrate scheduling scheme is developed based on machine tool dynamics. Finally, in order to verify the correctness of the proposed method, a series of numerical simulations and actual machining and measurement experiments are conducted, and the simulations and experimental results have showed the good performance of the proposed algorithm. [ABSTRACT FROM AUTHOR]

Published

2023

15. Sensor fusion and the application of artificial intelligence to identify tool wear in turning operations.

Author

Al-Azmi, A., Al-Habaibeh, Amin, and Abbas, Jabbar

Subjects

ARTIFICIAL intelligence, MACHINE learning, PROCESS capability, SIGNAL processing, DETECTORS

Abstract

This paper aims to develop an effective sensor fusion model for turning processes for the detection of tool wear. Fusion of sensors' data combined with novelty detection algorithm and learning vector quantisation (LVQ) neural networks is used to detect tool wear and present diagnostic and prognostic information. To reduce the number of sensors required in the monitoring system and support sensor fusion, the ASPS approach (Automated Sensor and Signal Processing Selection System) is used to select the most appropriate sensors and signal processing methods for the design of the condition monitoring system. The experimental results show that the proposed approach has demonstrated its efficacy in the implementation of an effective solution for the monitoring tool wear in turning. The results prove that the fusion of sensitive sensory characteristic features and the use of AI methods have been successful for the detection and prediction of the tool wear in turning processes and show the capability of the proposed approach to reduce the complexity of the design of condition monitoring systems and the development of a sensor fusion system using a self-learning method. [ABSTRACT FROM AUTHOR]

Published

2023

16. Five-axis Tri-NURBS spline interpolation method considering compensation and correction of the nonlinear error of cutter contacting paths.

Author

Chen, Liangji, Wei, Zisen, and Ma, Longfei

Subjects

INTERPOLATION, SIMPLE machines, SPLINE theory, MACHINING, MACHINE tools, SPLINES, VECTOR control

Abstract

In order to improve the accuracy of position and direction of the tool axis vector and the controlling accuracy of cutter contacting (CC) paths between the cutter and workpiece in the traditional five-axis NURBS interpolation method, a five-axis Tri-NURBS spline interpolation method is proposed in this paper. Firstly, the spline interpolation instruction format is proposed, which includes three spline curves, the CC point spline, the tool center point spline, and the tool axis point spline. The next interpolation parameter is calculated based on the tool center point spline combined with the conventional parametric interpolation method. Different from the traditional spline interpolation using the same interpolation parameter for all spline curves, the idea of equal ratio configuration of parameters is proposed in this paper to obtain the next interpolation parameter of each spline curve. The next interpolation tool center point, tool axis point, and CC point on the above three spline curves can be obtained by using different interpolation parameters, so as to improve the accuracy of position and direction of the tool axis vector. Secondly, the producing mechanism of the nonlinear error of CC paths of the traditional spline interpolation is analyzed and the mathematical calculation model of the nonlinear error is established. And then, the compensation and correction method of nonlinear error is also proposed to improve the controlling accuracy of CC paths. In this method, the next CC point on the cutter can be first obtained according to the next interpolation tool center point, tool axis point, and CC point on the three spline curves. And then, the error compensation vector is determined with the two next CC points. To correct the nonlinear error between the next CC point on the cutter and the CC point spline curve, the cutter is translated so that the two next CC points can coincide. In the end, the new tool center point and tool axis point after translation can be calculated to obtain the motion control coordinates of each axis of the machine tool. The MATLAB and VERICUT software are used as a simulation of the real machining data. The results show that the proposed method can effectively reduce the nonlinear error of CC paths. It has high practical value for five-axis machining in effectively controlling the accuracy of CC paths and improving the machining accuracy of complex surfaces. [ABSTRACT FROM AUTHOR]

Published

2022

17. Smoothing and compressing algorithm of toolpath with complex contour in NC machining.

Author

Zhang, Liang, Lu, Juan, Ou, Chengyi, Ma, Junyan, and Liao, Xiaoping

Subjects

NUMERICAL control of machine tools, LEAST squares, MACHINING, CUTTING force, ALGORITHMS, IMAGE compression, STATISTICAL smoothing

Abstract

The continuous short line segment processing method in CNC machining has the defect of frequent fluctuation of feedrate, which affects the quality and efficiency. For this problem, the local and global methods are common solutions. The local method is to insert transition curves at the corners to obtain a smooth toolpath, but this method does not essentially reduce the number of accelerations and decelerations, and it is difficult to insert transition curves between tiny straight sections. Although the global method can obtain smooth tool trajectories, the parametric interpolation method is not suitable for middle- and low-end CNC machine tools. The article proposes an adaptive tool path generation method with the original part contour as the research object and discretizes the NURBS curves into smooth trajectories consisting of large segments of straight lines and circular arcs. The article mimics the crawling characteristics of snakes and designs a double-headed snake algorithm based on the least squares method to implement this process. First, given the start and end points of the curve, two snakeheads search for the maximum linear and circular segments that satisfy the error constraint in the curve direction. The winner will then be selected as the candidate track segment through a competition mechanism. Finally, all trajectory segments are connected to obtain a smooth tool path. Experiments show that the toolpath data of the method in this paper are reduced by 75.56% compared with commercial CAM software when the contour error threshold is the same, and the contour error is reduced by more than one order of magnitude when the number of toolpath segments is equal. In addition, the method in this paper can obtain a smoother machining surface and more stable cutting force, thus achieving a win‒win situation of quality and efficiency. [ABSTRACT FROM AUTHOR]

Published

2023

18. Optimization techniques for energy efficiency in machining processes—a review.

Author

abdelaoui, Fatima Zohra El, Jabri, Abdelouahhab, and Barkany, Abdellah El

Subjects

METALWORK, MATHEMATICAL optimization, POWER resources, MANUFACTURING processes, NATURAL resources, CUTTING fluids, MACHINING, ENERGY consumption

Abstract

Metal working process is one of the main activities in mechanical manufacturing industry; it is considered as a major consumer of energy and natural resources. In material removal process, the selection of cutting parameters and cooling or cutting liquid is necessary to save energy and achieve energy efficiency as well as sustainability. During the last two decades, the number of publications in this field has rapidly increased and has shown the importance of this research area. This review paper identifies and reviews in detail a total of 166 scientific studies which exhibit original contributions to the field and address multiple energy efficiency challenges. The recently developed models of energy consumption and different materials used in the machining process are presented. Therefore, this study describes various techniques for modeling and optimizing machining operations such as turning, milling, and drilling. Modeling techniques, experimental methods, multi-objective and single-objective optimization methods, and hybrid techniques optimization are presented in a detailed manner compared to previous review papers where only energy models are discussed. It can help practitioners and researchers to select the most appropriate approach for the desired experience and to highlight the progress of these methods in terms of machining energy efficiency. Additionally, this paper provides a review of different cutting fluids adopted in machining processes. This paper assists researchers and manufacturers in making advantageous technical decisions that have substantial economics in terms of energy saving. [ABSTRACT FROM AUTHOR]

Published

2023

19. Towards advanced manufacturing systems for large parts: a review.

Author

Yong, Lu, Zhifu, Ma, and Yuan, Xue

Subjects

MANUFACTURING processes, MACHINE tools, MACHINING, STRUCTURAL optimization

Abstract

Large-mechanical-part machining is a very important trend for modern industry to develop, and it has attracted a lot of attention from advanced industries. As an important element of the research, the manufacturing system for large parts has been widely studied. In order to get a comprehensive understanding of this kind of system, the state of the art in several aspects including the classification of the system, major challenges facing each kind of system, structure and optimizes design of the system are summarized in this paper. The manufacturing system is divided into two categories: large workshop machine tools and light and agile machine systems. The design and optimization methods for large workshop machine tool structural parts are summarized. Common techniques for error compensation are also analyzed. Development of the light and agile machine system is stated, and its further classification is carried out. Significantly, features as well as advantages and disadvantages of different systems are analyzed. Finally, this paper gives out further research on the manufacturing systems for large parts. [ABSTRACT FROM AUTHOR]

Published

2023

20. A novel control strategy for suppression of regenerative chatter in conventional lathe.

Author

Sureshbabu, Durai Martin and Thyla, Pudukarai Ramaswamy

Subjects

SURFACE finishing, LATHES, MACHINE tools, MACHINE dynamics, INDUSTRIAL costs, MACHINING

Abstract

Realizing good quality of machined parts at reduced production time and cost is an important task. Cutting parameters have a major influence on the cost and material removal rate (MRR). Chatter, a dominant phenomenon that occurs during machining, affects the selection of cutting parameters. It is present in almost all machining operations and is a major obstacle in achieving accuracy and productivity. Regenerative chatter, in particular, is the most detrimental to any process and it creates excessive vibration between the tool and the workpiece, preventing possible higher MRR. In addition, it leads to poor surface finish and accelerated tool wear. Either best machining parameters for an existing condition or good machine tool dynamics through minor modification improves MRR. This paper opts for the latter method by modifying the existing tool-post in a conventional lathe with a semi-active biodegradable MR fluid-filled tool-post. Stability lobe diagrams (SLD) prepared through frequency response functions (FRF) for the existing and modified tool-posts revealed that there is an increase of 23% in damping ratio, and furthermore, the chatter-free depth of cut in turning increased from 0.831 to 1.355 mm, i.e., an increase of 63%, irrespective of the spindle speed, along with improved surface finish. [ABSTRACT FROM AUTHOR]

Published

2023

21. Study on grinding force of high volume fraction SiCp/Al2024 composites.

Author

Guo, Guangyan, Gao, Qi, Wang, Quanzhao, and Pan, Shichao

Subjects

TANGENTIAL force, FRACTIONS, MACHINING

Abstract

In view of the difficult machining characteristics of high volume fraction SiCp/Al composites, this paper researches the grinding force variation of grinding SiCp/Al composites with grinding rod. A diamond grinding rod with a diameter of 3mm is used to grind the SiCp/Al2024 composite with 60% volume fraction by the method of end face grinding. By measuring the tangential grinding forces and normal grinding forces after grinding, the theoretical model of unit grinding force is deduced. According to the experimental parameters of spindle speed, feed rate, and grinding depth, this paper derives the theoretical model of grinding force based on SiCp/Al2024 composites. And it clarifies the influence mechanism of grinding depth and feed rate on grinding force and explores the variation of grinding parameters on grinding force under dry grinding condition. Then the variation rule of grinding component force ratio is obtained. The related research and theoretical model have theoretical guiding significance for exploring the grinding properties of hard-to-machine materials. [ABSTRACT FROM AUTHOR]

Published

2023

22. Non-uniform machining allowance planning method of thin-walled parts based on the workpiece deformation constraint.

Author

Zhang, Zhengzhong, Cai, Yonglin, Xi, Xiaolin, and Wang, Haitong

Subjects

WORKPIECES, DEFORMATIONS (Mechanics), FINITE element method, CUTTING force, MACHINING

Abstract

In order to reduce the machining deformation of thin-walled parts during milling, a non-uniform allowance planning method for thin-walled parts based on the workpiece deformation constraint with the idea of adding materials in reverse material removal sequence is proposed in this paper. This method does not require accurate deformation prediction and extensive experiments compared to traditional error compensation methods. It strives to maximize the allowance to enhance the stiffness of the in-process workpiece. First, a cutting force threshold calculation method is proposed according to the finite element method. The cutting force threshold at different positions is calculated by obtaining the local stiffness characteristics at the cutter-contact point under the constraint of allowable deformation. And then, the maximum machining allowance at the cutter-contact point is calculated depending on the cutting force model. Considering that the stiffness of the workpiece is position-dependent and affected by material removal, the stiffness of the workpiece is updated by adding elements in the reverse cutting direction, and the finishing stock is obtained by surface fitting. Experimental results show that compared with the traditional uniform allowance method, the error of the proposed method is reduced by about 83%, which can effectively reduce the deformation and improve the machining accuracy. [ABSTRACT FROM AUTHOR]

Published

2023

23. Optimization of machining strip width using effective cutting shape of flat-end cutter for five-axis free-form surface machining.

Author

Wu, Baohai, Liang, Mancang, Zhang, Ying, Luo, Ming, and Tang, Kai

Subjects

MACHINING, CUTTING tools, MILLING cutters, COMPRESSOR blades, SIMULATION software

Abstract

Tool postures of the flat-end cutter can make a huge difference to both machining strip width and machining efficiency in five-axis end milling. Most of current methods evaluate the machining strip width and implement a tool orientation optimization by finding two intersection points between the effective cutting profile of a flat-end cutter and the offset surface profile which represents machined surface. However, real machining strip width and real residual height should be formed between two adjacent cutter contours. As the results, two problems of current methods cannot be avoided: (1) Machining strip width computed on a single cutter location cannot accurately represent the distance between two adjacent tool paths and (2) excessive overlap or larger span length between two adjacent cutter contours leads to unsteady residual height, which causes surface quality differences. In order to solve the above problems, a more suitable method for computing machining strip width is presented and proved in this paper. A flat-end cutter is adopted and the analytical model of effective cutting shape for this kind of tool is constructed firstly. Later, a geometric foundation to achieve optimization is established by investigating the impact of different flat-end cutter postures on the machining strip width. Furthermore, the reasonable strip width is obtained and optimized by implementing an iterative and optimization approach under the given scallop height. A three-dimensional centrifugal compressor blade is used as a numerical example to verify the approach presented in this paper. To prove the superiority of the involved method, the research gives a comparison with UG method with the same cutting parameters. Numerical experiment suggests that machining efficiency of the paper's method improves by 37.85%. Finally, a machining simulation is performed in the VERICUT software to testify that a uniform error distribution is created. [ABSTRACT FROM AUTHOR]

Published

2018

24. The influence of CAD model continuity on accuracy and productivity of CNC machining.

Author

Kučera, David, Linkeová, Ivana, and Stejskal, Michal

Subjects

NUMERICAL control of machine tools, RAPID prototyping, CONTINUITY, GEOMETRIC modeling, THREE-dimensional modeling, MACHINING, METAL cutting

Abstract

Efficient and productive manufacturing of freeform shapes requires a suitable three-dimensional CAD model at the entrance to the CAM system. The paper deals with the impact of NURBS or B-spline CAD model geometric continuity on the accuracy and productivity of 5-axis ball-end milling of freeform surfaces. The relationship between a different order of CAD model geometric continuity and the quality of the toolpath generated in CAM system is analysed and demonstrated on an example of a Blisk blade profile. In order to reveal the effect of CAD geometry on the quality of the machined surface, linear interpolation of cutter location points, i.e. piecewise linear discrete toolpath, is considered. Also, no further smoothing of the toolpath is applied. The distance of the cutter location points is commonly used as the indicator of toolpath quality. In addition, the discrete curvature of a linear discrete toolpath is introduced here, and its dependence on the curvature and continuity of the underlying CAD model is demonstrated. In this paper, it is shown that increasing the order of CAD model geometric continuity significantly eliminates sharp changes in the distance of cutter location points, and smoothes the discrete curvature of the toolpath. Finally, it is experimentally verified that increasing the continuity of the CAD model from G0 to G3, while maintaining the same cutting conditions, leads to an increase in workpiece accuracy and a reduction in machining time, without the need to smooth the toolpath generated in the CAM system. [ABSTRACT FROM AUTHOR]

Published

2023

25. A deep learning-based approach for machining process route generation.

Author

Zhang, Yajun, Zhang, Shusheng, Huang, Rui, Huang, Bo, Yang, Lei, and Liang, Jiachen

Subjects

DEEP learning, MACHINING, MANUFACTURING processes, PRODUCTION planning, HUMAN-computer interaction

Abstract

As the core machining process element in the overall manufacturing process of a part, the machining process route plays an important role in improving final manufacturing quality. In the current CAPP system, the decision-making of the process route still depends on human-computer interaction and essentially depends on human intelligence. In the past decade, deep learning technology architecture has been gradually improved, which provides a new enabling technology for intelligent process planning. Recently, some researchers have applied deep learning to process route decision-making. However, due to the challenges of data representation and deep learning network construction, this promising solution is still at infancy. To address the two challenges, this paper presents a novel process route generation approach based on deep learning. First, we propose a fourth-order tensor model to represent the geometry and technological requirements of a part. And the relation matrix is constructed to represent the relationships among machining features. The process route is represented as a sequential set of one-hot vectors. Then, we construct an encoder-decoder neural architecture to automatically generate the machining process route for the part. The 3D convolution neuron network-based encoder converts the geometry, technological requirements, and the information of the relationships among machining features into a higher layer of vector representation, and the long short-term memory network-based decoder maps this representation to the process route. The whole neural architecture including the encoder and decoder is jointly trained to maximize the conditional probability of the target process route given the training part. Finally, the paper takes slot cavity parts as examples to verify the feasibility and effectiveness of the proposed approach. [ABSTRACT FROM AUTHOR]

Published

2021

26. 3D numerical modeling and experimental validation of machining Nomex® honeycomb materials.

Author

Jaafar, Mohamed, Nouari, Mohammed, Makich, Hamid, and Moufki, Abdelhadi

Subjects

CUTTING tools, HONEYCOMB structures, MODEL validation, MACHINING, CUTTING force, MACHINABILITY of metals

Abstract

Machining of Nomex® honeycomb materials is the biggest challenge in industry because of the complex forms and geometry of the honeycomb structure. The latter is characterized by a low density with orthotropic mechanical behavior. The thin walls of the composite structure make the shaping of this material very difficult. Studying interactions between the cutting tool and material, cutting forces, and chip formation allow to understand the machining process of Nomex® honeycomb. This paper presents 3D numerical modeling of machining Nomex® honeycomb using different orthotropic approaches and failure criteria: (i) monolayer isotropic approach, (ii) monolayer orthotropic approach with Tsai-Wu failure criteria, and (iii) monolayer orthotropic approach with Hashin failure criteria. A comparison between experiments and numerical cutting forces was performed to validate the proposed model. The interaction between the tool and the honeycomb walls, which make it possible to observe the different stages of the chip formation process, was carefully modeled. [ABSTRACT FROM AUTHOR]

Published

2021

27. Wire breakage prevention for reciprocated traveling WEDM based on discharge location detection.

Author

Xu, Ling-Yi, Xi, Xue-Cheng, Li, Zi-Lun, Ma, Jie-Yu, Gao, Qiang, and Zhao, Wan-Sheng

Subjects

ELECTRIC metal-cutting, DISCHARGE coefficient, FUZZY logic, WORKPIECES, MACHINING

Abstract

This paper presents a wire breakage prevention method and a corresponding system for reciprocated traveling wire-EDM based on discharge location detection. The wire breakage risk is evaluated using the consecutive discharge concentration coefficient (CDCC) value and the number of arcs. CDCC characterizes the proximity of a sequence of consecutive discharge locations occurring in a short time, which takes both time and spatial domain into consideration. The system employs two fuzzy logic controllers to adjust machining parameters according to the degree of discharge concentration and the servo tracking performance detected. Verifications are conducted by cutting two workpieces with variable heights, including a stair-shaped and a hollow one. The machining tests show that the proposed system can significantly gain machining efficiency without wire breakage hazards. [ABSTRACT FROM AUTHOR]

Published

2022

28. Analysis of machining quality of 304 stainless steel deep hole by changing angle of gun drill.

Author

Xie, Chen, Li, Liang, Zhang, Ying, Lou, Jiacheng, and Pan, Yu

Subjects

STAINLESS steel, MACHINING, CUTTING machines, ANGLES, FIREARMS, ELECTROCHEMICAL cutting, BITS (Drilling & boring), CUTTING (Materials)

Abstract

With the continuous development of the manufacturing industry, the proportion of deep hole machining in mechanical processing is increasing. In 304 stainless steel, as a kind of difficult machining material, its deep hole machining demand is also increasing year by year. Due to the physical characteristics of 304 stainless steel and the uncontrollability of gun drilling, the quality of deep hole processing is relatively poor. In this paper, some experimental studies are carried out to solve this engineering problem. Firstly, by analyzing the structure of the gun head, this paper establishes the stress model of the gun head in the processing process. Then, the accuracy of the theory is verified by experiments. Secondly, this research carried out multiple single-factor drilling experiments to change the front angle of the internal and external edges of the gun drill to control the cutting force in the machining process. Based on the analysis of the test results, the influence of the change of the gun drill's internal and external edge angle on the surface quality of hole wall, chip forming, and hole straightness offset is explored. The results show that the increase in the internal angle of a gun drill can promote the surface roughness of the hole wall and chip forming. And properly increasing the external angle can slow down the straightness offset of the hole. Finally, for the deep hole processing of 304 stainless steel, this paper gives the best edge angle selection of gun drill. [ABSTRACT FROM AUTHOR]

Published

2022

29. Experimental investigation of tool deflection in micro-milling of fine-grained graphite.

Author

Cica, Djordje, Sredanovic, Branislav, and Mijušković, Goran

Subjects

MACHINING, ELECTRODES, ANGLES, GEOMETRY, MILLING (Metalwork), GRAPHITE

Abstract

The micro-milling process is one of the most suitable methods for the accurate machining of devices in the micro-domain and is implemented for a wide range of materials. Fine-grained graphite is extensively used as electrode material for micro-electrical discharge machining because of its excellent thermal, chemical, and electrical properties. Dimensional accuracy and form accuracy are among main goals in the micro-milling process of the 3D micro-form electrodes. Among the numerous factors that affect the quality of the machined micro-components, tool deflection is the most significant. This paper investigates the influence of fine-grained graphite type, depth of cut, tool wear, cutting edge radius size, workpiece inclination angle, and machining strategy as control factors on tool deflection. The experimental results presented in this paper provide important insight into tool deflection issues for improving machining accuracy in micro-milling process of graphite electrodes with complex 3D geometry and high aspect ratio. [ABSTRACT FROM AUTHOR]

Published

2022

30. An experimental study of multi-sensor tool wear monitoring and its application to predictive maintenance.

Author

Herrera-Granados, German, Misaka, Takashi, Herwan, Jonny, Komoto, Hitoshi, and Furukawa, Yoshiyuki

Abstract

Wear in cutting tools is a critical issue that can lead to reduced product quality, increased production costs, and unexpected downtime. To mitigate these challenges, the implementation of tool wear monitoring systems and predictive maintenance strategies has gained significant attention in recent years. Early detection or prediction of tool wear is vital to optimize tool life and maintain the manufacturing processes efficiently. This paper presents a method to determine the tool wear progression based on the collaboration of direct and indirect monitoring techniques. By analyzing the monitoring of data from force, vibration, and current sensors to estimate the tool wear state, and correlating this information with a photographic database of the tool wear progression used to create an image recognition system, it is possible to classify the tool wear at any moment into three states: Good, Moderate, and Worn. A case study was conducted to test the advantages and limitations of the proposed method. The case study also shows that the improvement of the prediction of the tool wear state might be useful in the decision-making of whether the tool life can be extended, or the tool must be replaced, as well as in the detection of anomalies during the machining process, aiming its improvement and the reduction of operational costs. [ABSTRACT FROM AUTHOR]

Published

2024

31. A study on multi-hole machining of high-power density electron beam using a vaporized amplification sheet.

Author

Kim, HyunJeong, Jung, SungTaek, Lee, JooHyung, and Baek, SeungYub

Subjects

ELECTRON beams, ELECTRON density, MACHINING, STAINLESS steel, METALLIC surfaces, MECHANICAL properties of condensed matter

Abstract

Recently, electron beam machining technology has been used in various ways depending on the industrial field. It is used in technologies in the fields of shipbuilding, aerospace, and transportation. In the case of the existing electron beam machining technology, a technology for welding or joining two materials was proposed. In this paper, in order to perform electron beam drilling, a multi-hole is created by increasing the instantaneous vaporization pressure during electron beam machining through a vaporized amplification sheet. A vaporized amplification sheet was prepared for electron beam drilling. The vaporized amplification sheet was made of a 1:3.25 combination of silicone and brass powder. Also, in order to bond the produced vaporized amplification sheet to the SUS 304 stainless steel, a primer was applied on the surface of the metal material to firmly bond the two materials with different properties. If the bonding is weak, the effectiveness decreases due to pressure leakage during electron beam machining. Multi-holes were processed using the fabricated material to fix an acceleration voltage of 120 kV and a current of 12 mA. Also, to compare the multi-hole shape and the processing result, the comparison was performed according to the exposure time of the electron beam. The lower the exposure time, the more fine holes were secured, and as the exposure time increased, the molten pool phenomenon occurred, and processing was not performed in the experimental results. [ABSTRACT FROM AUTHOR]

Published

2021

32. An integrated methodology of volumetric error modeling, validation, and compensation for horizontal machining centers.

Author

Hu, Teng, Wang, Wenkuan, Jiang, Yang, Mi, Liang, and Yao, Xiaopeng

Subjects

WORKPIECES, MACHINE tools, MACHINING, MACHINERY, THEORY of screws

Abstract

It is crucial to perform volumetric error forward analyses of horizontal machining centers, including modeling, validation, and compensation, so that workpiece machining accuracies can be improved. Aiming at solving three major problems so far emerged in the machine tool volumetric error forward analyses, an integrated methodology is proposed in this paper. Firstly, in order to formulate a kinematic model without uncertainties and inconsistencies, a principle to determine the correct product relations of nominal motions to motion errors is systematically developed. Secondly, a novel validation approach based on the concept of volumetric vector Euclidean norm is demonstrated in this paper, assuring that the constructed volumetric error model can be quantitatively assessed without engaging any compensation processes. Thirdly, an optimal compensation technology is also presented to achieve the objective that the compensation residual errors, which are likely generated from the existing inverse superposition compensation strategies, can be diminished or even eliminated. A commercial horizontal machining center is selected to apply and verify the proposed integrated methodology. [ABSTRACT FROM AUTHOR]

Published

2021

33. Towards advanced prediction and control of machining distortion: a comprehensive review.

Author

Aurrekoetxea, Maria, Llanos, Iñigo, Zelaieta, Oier, and López de Lacalle, Luis Norberto

Subjects

MACHINING, PRODUCTION control, MANUFACTURING processes, NONLINEAR equations, WASTE products

Abstract

Machining precision components involves challenging distortion issues that entail high costs and material and energy waste to the industry. In parallel, advanced control of production processes is a rapidly growing field because of its unique capabilities to solve multi-agent nonlinear problems and develop control actions based on knowledge and experience. Despite the several studies carried out on the subject, research keeps fragmenting distortion issues in different niches of components, and comprehensive reviews considering distortion as a cross-cutting technical hitch have never been reported. In this paper, a study compiling recent advances in machining distortion control from a holistic perspective is presented. For the first time, distortion understanding is unified, offering a new perspective, more practical and comprehensive, which includes intelligent systems. This novel way of attaining the research on distortion distinguishes three interconnected pillars: distortion source identification and quantification, distortion simulation model development, and control strategies drafting and application. The paper guides the reader through several distortion investigations of different kinds and provides classifications never addressed in the field with which a profound understanding of the issue can be achieved. Finally, future trends and key enabling technologies to drive the advanced control and minimization of machining distortions are outlined. [ABSTRACT FROM AUTHOR]

Published

2022

34. A systematic method for automated manufacturability analysis of machining parts.

Author

Xu, Tongming, Xue, Junli, Chen, Zhuoning, Li, Jianxun, and Jiao, Xuerui

Subjects

MACHINE parts, CONCURRENT engineering, INDUSTRIAL costs, PRODUCTION increases, MACHINING

Abstract

Model-based definition (MBD) technology has gained popularity in recent years. It provides an opportunity for a deeper integrated digital design and manufacturing of mechanical products. Automated manufacturability analysis (AMA) could solve increasing production costs and the manufacturing cycle caused by design defects and is the crucial support of concurrent engineering. This paper studies a systematic method for automated manufacturability analysis, which converts the design model to a structuralized feature model (SFM) with machining feature recognition. Furthermore, the machining feature-associated graph (MFAG) is proposed to describe SFM, and the meta-model expression of the knowledge rule is detailed. Finally, AMA knowledge modeling and reasoning methods are introduced. The method proposed in this paper addresses the automated manufacturability analysis of machining parts and provides a reference for MBD application in concurrent engineering. [ABSTRACT FROM AUTHOR]

Published

2022

35. Study on the micro through holes machining using the electrochemical machining (ECM) method with a graphite electrode.

Author

Zhu, Likuan, Hao, Jinhui, Xu, Bin, and Wang, Bei

Subjects

ELECTROCHEMICAL cutting, ELECTRODES, GRAPHITE, MICROMACHINING, MACHINING

Abstract

Electrochemical machining is widely used in biomedical, aerospace, automotive, and other fields. The development of electrochemical machining (ECM) is restricted by many factors such as the difficulty of preparing micro-electrode, large machined gap and serious stray corrosion. In this paper, we present a method to fabricate micro-holes by combining micro-graphite electrode with hollow structure. Firstly, a sealed graphite electrode was proposed to guarantee that the sediment can be fully removed by the flowing electrolyte. Then, the effect of machined parameters such as the pulse frequency, machined voltage, electrode feeding speed, and electrolyte concentration on machining quality was studied. By optimizing the machined parameters, the minimum value of micro-hole taper with 0.07 could be obtained. To improve the shape precision of workpiece, this paper designed the hollow structure inside the electrode. With the increasing of the pulse frequency, the machining accuracy of micro-holes increased. The results suggested that the pulse frequency of 100 kHz, the machined voltage of 18 V, the feeding speed of 1 µm/s, and electrolyte concentration of 5% were more suitable for micro-holes machining with ECM. [ABSTRACT FROM AUTHOR]

Published

2022

36. Formation mechanism of tearing defects in machining Nomex honeycomb core.

Author

Jiang, Jiaming and Liu, Zhanqiang

Subjects

HONEYCOMB structures, CUTTING force, MACHINING, AEROSPACE industries, BOND strengths, MILLING cutters

Abstract

Nomex honeycomb core has been widely applied in aerospace industries due to its superior strength and rigidity. However, the machining defects of honeycomb core can deteriorate the bonding strength between honeycomb core and connective face sheet. This paper investigates the tearing defects formatted in milling process of Nomex honeycomb core. Firstly, a cutting force model is proposed to predict the milling forces under various tool entrance angles. Then, finite element simulation for machining honeycomb wall is conducted to reveal the formation mechanism of tearing defects. The accuracy of the model is verified by a group of experiments under different entrance angles and the relative error is below 25% in 1-direction and 20% in 2-direction. It is found that the formation of tearing defects is closely related to the deformation of honeycomb wall and the component of cutting force in direction parallel to wall. The tool entrance angle can be thus optimized based on the reduction of tearing defects. The optimized entrance angle of double wall is among 40° and 70°. [ABSTRACT FROM AUTHOR]

Published

2021

37. Control of machining distortion stability in machining of monolithic aircraft parts.

Author

Fan, Longxin, Li, Liang, Yang, Yinfei, Zhao, Guolong, Han, Ning, Tian, Hui, and He, Ning

Subjects

MACHINING, RESIDUAL stresses, POTENTIAL energy, COMPUTER simulation

Abstract

Machining distortion has been a long-term obstacle in the machining of aircraft monolithic parts. Furthermore, its stability has to be considered. The machining distortion stability represents the fluctuation degree of the machining distortion. This paper investigates the evolution of elastic energy induced by initial residual stress inside materials, revealing that this evolution directly affects machining distortion. In this paper, the concept of machining distortion stability and bending potential energy is defined. By analyzing bending potential energy releasing, this study proposes a novel method for improving machining distortion stability through optimization of material removal sequence. Numerical simulation and milling experiments are performed to verify and validate the model, respectively. The results indicate that the machining distortion stability is significantly improved when optimized material removal sequence is applied. By controlling the machining distortion stability, the final distortion can be further reduced via re-machining the machining datum at the beginning of the finishing stage. [ABSTRACT FROM AUTHOR]

Published

2021

38. New STEP-NC-compliant system to automate process planning for the turning process.

Author

Elmesbahi, Abdelilah, Buj-Corral, Irene, El Mesbahi, Jihad, and Bensaid, Oussama

Subjects

CAD/CAM systems, PRODUCTION planning, COMPUTER-aided process planning, AUTOMATION, MACHINE parts, MACHINING

Abstract

STEP-NC is a smart standard, developed by the International Organization for Standardization (ISO) as a substitute for the ISO 6983 G-code, because the language of the G-Code, normally used for computer numerical control (CNC), is qualified as being unable to link the CAD/CAM/CNC digital chain and meet the needs of modern intelligent manufacturing in terms of tractability, interoperability, flexibility, adaptability, and extensibility. The purpose of this work is to implement the new STEP-NC standard in a computer-aided process planning (CAPP) turning process to overcome the shortcomings of ISO 6893 G-code and enable the process to meet the demands of modern manufacturing. Therefore, the first objective of this paper is to design and implement a CAPP for the turning process, designated as CAPP-Turn, to ensure machining of rotational parts within this modern vision. However, to achieve the CAPP-Turn system, it is necessary to build a robust automatic manufacturing feature recognition (AMFR) module to establish full communication between the first two links of the digital chain, the design CAD and manufacturing CAM, by using a hybrid graph-rules method. The second objective of this work is to elaborate a new consistent-fast algorithm that allows one to extract the machining turning entities for parts with the most efficiency and complex geometry. It then becomes necessary to introduce the main machining entities defined within the framework of this standard and to explain the different parameters that are necessary for the unambiguous definition of these entities whether of a geometric, topological, or other nature. In fact, most of the AMFR systems presented in the literature are restricted to the external turning process and cannot handle parts with complex geometry and interacting features. Moreover, the frontal turning features are largely neglected in most of these systems, despite their importance for fulfilling certain functions in mechanical systems. This article first details the global architecture of the CAPP-Turn and clearly describes the interaction between the CAD part and STEP-NC output file. It then explains the model of the AMFR system, which encompasses (i) a parser module that translates geometric and topological data from a STEP AP203 CAD file into Python entity class objects; (ii) an AMFR that analyzes the objects created and applies predefined rules to construct all possible turning machining; and (iii) a module capable of distinguishing external features from internal, frontal features from axial, and handling interacting features from the simple features. After these steps, the AMFR provides all suitable sequencings for part machining. Finally, to demonstrate the potential advantages and power of the proposed AMFR, a selected part is chosen for testing. The result shows that the AMFR performs well in recognizing all types of features regardless of their type: internal or external, axial or frontal, simple or interacting. [ABSTRACT FROM AUTHOR]

Published

2023

39. An iso-scallop tool path generation method for three-axis machining freeform surface.

Author

Wang, Tian-Li, Liu, Wei, Fan, Lv-Yang, Zhang, Zi-Yu, and Li, Peng-Fei

Subjects

GOLDEN ratio, DISCRETIZATION methods, MACHINING, POINT set theory, SCALLOPS

Abstract

Iso-scallop tool path has uniform scallop height (maximum allowed value) between cutter location (CL) points on the adjacent line, which can maximize interval values of tool path and minimize total lengths of tool path. However, iso-scallop tool path generation process is more complicated than common iso-parameter and iso-planar tool path. In order to avoid exceptions happened in offsetting surface or transforming surface to mesh, this paper generates iso-scallop tool path directly on surface. To improve computational efficiency, based on geometric principle of scallop height and iso-scallop CL points, scallop points are iteratively calculated based on a discrete feature point set including the golden section points. An initial CL location is calculated to be closer to the wanted theoretical iso-scallop point. And an adaptive discretization method is proposed to obtain discrete feature points on surface. The minimum distance from feature points to the CL point is calculated iteratively for the wanted iso-scallop CL point. Both scallop points and iso-scallop CL points are calculated iteratively by a small amount of feature points for efficiency improvement. Two examples of typical freeform surface are used to test the presented method. The results indicate that the scallop height of iso-scallop tool path is uniform, and total lengths are shorter than lengths of iso-planar tool path. [ABSTRACT FROM AUTHOR]

Published

2023

40. Study on an approach for decoupling and separating the thermal positioning errors of machining center linear axes.

Author

Xiaopeng, Yao, Teng, Hu, Xiaohu, Wang, Liang, Mi, and Guofu, Yin

Subjects

MACHINING, LASER interferometers, NUMERICAL control of machine tools, CRITICAL point (Thermodynamics), MACHINERY, TEMPERATURE sensors, MACHINE tools

Abstract

CNC machining center linear axis thermal positioning errors, seen as the synthetic consequences of geometric and thermal errors, respectively generated due to the manufacturing and assembling inaccuracies and the asymmetric thermal deformation of the machining center structure, are significantly affected by varying position of the cutting point and shifting state of temperature field. Hence, developing a practical approach to reduce or even to eliminate thermal positioning errors is crucial. This paper proposes an approach to decouple and separate machining center linear axis thermal positioning errors, based on which a highly accurate prediction model of the thermal positioning error is formulated. A sensitivity analysis-based thermal critical point optimization method is presented where grey theory is borrowed to characterize the mapping between thermal positioning error and varying temperature fields, according to which the highly related temperature sensors are derived. The thermal positioning errors are then decoupled and separated into geometric and thermal errors by adopting multiple regression algorithm and linear fitting approach, respectively. Accordingly, the comprehensive thermal positioning error prediction model is constrcuted, based on which the compensation approach is also proposed. Next, the corresponding compensation module is developed within the SIEMENS 840D CNC system to realize the online compensation strategy, providing the engineering applications. Experimental validations are performed on a commercial machining center, where the thermal positioning errors of the Z-axis are measured with the help of a laser interferometer testing kit and a thermal inspection instrument. The data comparisons indicate that the maximum thermal positioning errors of the Z-axis in the cold and warm state are respectively decreased for 87.09 % and 49.87 % after activating the compensation module, which also suggests that the proposed approach is adequate and accurate to decouple and separate the thermal positioning errors. [ABSTRACT FROM AUTHOR]

Published

2023

41. Integrated and efficient cutter-workpiece engagement determination in three-axis milling via voxel modeling.

Author

Nie, Zhengwen and Feng, Hsi-Yung

Subjects

BOUNDARY layer (Aerodynamics), WORKPIECES, MILLING cutters, MODEL airplanes, MACHINING

Abstract

This paper presents a new and highly efficient voxel modeling method to determine cutter-workpiece engagement (CWE) in three-axis milling. The method voxelizes both the workpiece and milling cutter in a voxel-based machining simulation space. This allows workpiece model update during machining to be done without the intensive intersection calculations between the cutter and workpiece. In addition, unlike the existing methods that update workpiece and compute CWE individually, the updated workpiece model and CWE are computed in an integrated fashion in the present work. This further reduces the involved computational load. At each cutter location, a voxel model of the cutter surface is created first by slicing the cutter surface by the voxel layer boundary planes to obtain a sequence of circles along the cutter axis. A main contribution of this work is the development of a unique fast increment and decrement scheme to voxelize each circle. Workpiece update and CWE determination can then be done simultaneously from the created voxel model of the cutter surface. A series of case studies have been performed to demonstrate the effectiveness of the proposed method. It can be seen that the proposed method is able to compute CWE very efficiently while maintaining accuracy comparable to the specified voxel size. [ABSTRACT FROM AUTHOR]

Published

2023

42. Analysis and optimization of the process parameters on surface roughness in ball burnishing of AISI O2 hardened steel.

Author

Cica, Djordje and Kramar, Davorin

Subjects

SURFACE roughness, BURNISHING, BIOLOGICALLY inspired computing, MACHINING, RESPONSE surfaces (Statistics), ORTHOGONAL arrays, STEEL

Abstract

In this study, analysis and optimization of the machining parameters on the surface roughness in the ball burnishing process of AISI O2 hardened steel have been performed. The initial surface roughness value, ball diameter, burnishing force, burnishing speed, and burnishing feed were considered control factors, and Taguchi's L36 orthogonal array was employed to reduce the number of experiments. The response surface methodology (RSM) was used to develop a mathematical prediction model of the surface roughness in terms of the above parameters and to analyze interactions among the control factors as well. Additionally, analysis of variance (ANOVA) was applied to determine the significance of each burnishing parameter. The gray wolf optimization (GWO) algorithm, a relatively new bio-inspired algorithm, was introduced in the second part of the paper to obtain the optimum control factors of the ball burnishing process. Confirmation experiments were performed to verify identified optimal level of the burnishing parameters and to demonstrate the effectiveness of the GWO algorithm for the optimization of machining problems. [ABSTRACT FROM AUTHOR]

Published

2023

43. Optimizing 5-axis tool positioning and orientation for machining CFRP curved surfaces: considering fibers' orientation.

Author

Li, Jiongqi, Jin, Huihui, Hu, Qirui, Lin, Zhiwei, and Fu, Jianzhong

Subjects

FIBER orientation, CARBON fiber-reinforced plastics, MACHINING, SURFACE finishing, SURFACE roughness, MILLING (Metalwork), SPORTING goods

Abstract

Carbon fiber-reinforced plastic/polymer (CFRP) is a composite material widely used in industries such as aerospace, medical equipment, and sport products. The angle between the cutting and fiber orientations significantly impacts surface quality during the machining process due to CFRP's pronounced anisotropy. An acute angle results in a superior surface finish, whereas an obtuse angle can lead to defects. Milling of CFRP curved surfaces necessitates accurate tool position control, given the fiber orientation changes. This paper introduces a novel tool positioning method for machining CFRP curved surfaces, which considers fiber orientation. This strategy ensures an acute angle between the cutting and fiber orientations at any position, thereby enhancing machining quality. Furthermore, a tool position smoothing method is implemented to eliminate machine traces. Simulations and CFRP machining experiments are conducted to demonstrate the strategy's effectiveness. Microscopic observation and surface roughness tests reveal a 52% reduction in surface roughness of CFRP specimens, with most machining-induced cracks eliminated. [ABSTRACT FROM AUTHOR]

Published

2023

44. Analytical modeling of workpiece temperature in laser-assisted milling considering the combined effect of multi-heat sources.

Author

Zeng, Haohao, Zheng, Yan, Li, Xin, and Yang, Dong

Subjects

WORKPIECES, LASER beam cutting, MACHINING, TEMPERATURE

Abstract

Laser-assisted milling (LAM) is generally regarded as a promising process for machining difficult-to-cut materials. Accurate prediction of workpiece temperature is an essential prerequisite for the configuration of process parameters in LAM. An analytical thermal model concerning the combined effect of multi-heat sources is presented in this paper to predict the workpiece temperature in LAM. To deal with the complex geometry and kinematics problems in the LAM process, the method of heat source discretization and temperature superposition is used in the thermal model. In addition, the influence of material softening caused by laser heating on cutting heat source is considered. A series of LAM experiments are conducted to validate the thermal model. Good agreement between the predicted and measured results indicates the proposed model is effective. Further, the effect of spindle speed and feed per tooth on workpiece temperature is discussed. This work can be applied to optimize process parameters in LAM for reasonable machined surface integrity. [ABSTRACT FROM AUTHOR]

Published

2023

45. Registration algorithm for near-net-shape blade based on multi-tolerance constraints.

Author

Feng, Yazhou, Zheng, Huan, and Ren, Junxue

Subjects

RECORDING & registration, ALGORITHMS, TORSION, MACHINING

Abstract

A multi-tolerance constraint-based registration algorithm for near-net-shape blades is proposed for problems of small machining allowance and positioning difficulties of near-net-shape blades. A global registration model based on the tolerance constraint of contour degree and a local registration model based on the constraints of position degree and torsion degree are established under multi-tolerance constraints. The registration algorithm proposed in this paper is verified using actual measurement data of a near-net-shape blade and its nominal model, and the solution process of the registration model is given. The analysis shows that the registration algorithm based on multi-tolerance constraints can effectively improve the registration accuracy of the near-net-shape blade. Registration parameters are optimized to make the out-of-tolerance value to be zero. Finally, based on the registration results, machining experiments are conducted on a near-net-shape blade. The results show that deviations of leading and trailing edge profiles are machined within the required limits. The proposed registration method is effective to improve the machining accuracy. [ABSTRACT FROM AUTHOR]

Published

2023

46. A novel geometric error compensation method for improving machining accuracy of spiral bevel gear based on inverse kinematic model.

Author

Chen, Peng, Wang, Sanmin, Li, Bo, and Li, Fei

Subjects

MACHINE tools, BEVEL gearing, NUMERICAL control of machine tools, MACHINING, MILLING-machines, MACHINERY

Abstract

The geometric errors (GEs) of the spiral bevel gear milling machine will seriously affect the machining accuracy of the tooth surface and need to be compensated. In this paper, an innovative method for compensating the geometric error of CNC gear milling machine is proposed. This method describes the explicit relationship between the motion axis of the machine tool and the geometric errors, realizes the dynamic compensation by tooth, and improves the machining accuracy and machining efficiency of the tooth surface. Firstly, the actual forward kinematics model (FKM) is constructed based on the geometric errors module, and the error tooth surface with GEs is established. Secondly, the corresponding relationship between the machine setting parameters of the spiral bevel gear universal generation machine (UGM) and the CNC machine tool motion axis is given, and then the functional expression between the motion axis with geometric errors and the machine setting parameters is established, which is the inverse kinematics model (IKM). Then, the tooth surface error correction model is established according to the relationship between the machine setting parameters and the tooth surface errors. The compensation amount of the machine setting parameters obtained by the model is introduced into the IKM to obtain the GEs compensation model. Finally, the effectiveness of the geometric error compensation technique is verified by numerical analysis and experiments. The results show that the tooth surface errors, contact stress, and loaded transmission error after geometric errors compensation are significantly reduced, and the contact pattern meets the design requirements, which verifies the feasibility and effectiveness of the geometric errors compensation technology. [ABSTRACT FROM AUTHOR]

Published

2023

47. Significant step towards efficient electrical discharge machining titanium alloys.

Author

Zhou, Ming, Hu, Tianshang, Mu, Xin, Zhao, Meng, JianweiYang, Ye, Qing, Xu, Pei, Yang, Lei, and Xin, Fangqing

Subjects

TITANIUM alloys, MULTIVARIABLE control systems, ADAPTIVE control systems, MACHINING, THERMAL conductivity, COST control

Abstract

There have been high demands of high-quality, highly efficient processing methodologies on "difficult-to-cut" titanium alloys. The current methods for dealing with this kind of materials are mainly mechanical cutting ones. However, because of high processing costs, poor surface qualities, and restrictive machining operations, the costs of mechanical cutting methods are high. Electrical discharge machining (EDM), because of its flexibility, was considered as a supplement. However, serious difficulties arose while machining titanium alloys by EDM. Because of low thermo-conductivity of titanium alloys, the liquid temperature in gap between electrode and workpiece rose quickly after a series of pulse discharges. The high temperature of gap liquid usually led to gap liquid breakdown strength to decline. The consequence was discharging pulses tended out to be stable arc pulses or short pulses, burning workpiece surface and wearing electrode. The machining process became unstable. The low thermal conductivity of titanium alloys was the inherent property which could be hardly changed, and at present, the only way to settle the hard-to-cut problem of machining titanium alloys by EDM was to seek a way to keep gap liquid breakdown strength not go down so fast but still be suitable for effective pulse discharges. To solve this problem, this paper first listed three conditions to be met and analyzed the reasons to affect gap liquid breakdown strength in detail and concluded with three factors, gap distance, amount of chips left in gap, and gap liquid deionization after pulse discharges and then came up with a proposition to the problem. Technically, the proposition was accomplished by constructing a multiple-variable adaptive control system in which gap servo-voltage proportional to gap distance was in charge of discharging extent of pulses, electrode-discharging time decided the amount of chips produced in an electrode discharging cycle, and pulse-off time decided gap liquid deionization after discharges. These variables were timely regulated to keep the liquid breakdown strength suitable for discharging and meanwhile avoiding arcing in machining. The verification test demonstrated that the multivariable control system really helped electrical discharge machining titanium alloys in severe machining situations and proved its usefulness in applications. [ABSTRACT FROM AUTHOR]

Published

2023

48. Offline fast modification of position loop gains for five-axis machining.

Author

Lyu, Dun, Ye, Xinxin, Zhang, Huijie, and Liu, Hui

Subjects

JACOBIAN matrices, MACHINE tools, MACHINING, MACHINERY, KINEMATICS, PREDICTION models

Abstract

Servo matching (SM) controls the contour error (CE) by coordinating the tracking error (TE) of each axis, which is a basic strategy of CE control. However, the five-axis SM approach has not been widely used in engineering because of the long time to compute the modification of the position loop gain (PLG). This paper establishes the function relationship between the five-axis PLG and parts CE based on the Jacobian matrix. An offline PLG fast modification approach for parts CE in five-axis machining was proposed based on the above criteria. Using this approach, five-axis machine tools could modify the PLG of each axis for specific parts to improve contour accuracy. Compared to the traditional approach, the servo control model prediction, forward kinematics transformation (FKT), and tool contour pose search are omitted in the proposed approach. Therefore, the computational load is reduced significantly, computing time is reduced by more than 98%, and average contour accuracy is improved by more than 57%. [ABSTRACT FROM AUTHOR]

Published

2023

49. Influence of uncertain parameters on machining distortion of thin-walled parts.

Author

Li, Xiaoyue, Qi, Hao, Tao, Qiang, and Li, Liang

Subjects

MACHINING, CUTTING force, FUZZY logic, RESIDUAL stresses, MILLING cutters, MACHINERY

Abstract

Thin-walled parts refer to lightweight structural parts comprised of thin plates and stiffeners. During the machining process of thin-walled parts, machining distortion often occurs due to uncertain factors such as varying stiffness, cutting force, cutting temperature, residual stress, and other factors. This paper studied the minimization of the failure probability of machining distortion by controlling the uncertainties of inputs. For this, a fuzzy inference model for the machining system was proposed to determine the effects of uncertain factors on the machining distortion errors, which was composed of rule frame and result frame. In the rule frame, machining parameters, outline size, and wall thickness were used as inputs. In the result frame, linear stiffness, cutter path, as well as cutting force were taken as the input parameters. The values of machining distortion were the output, taken into a threshold function. Comprehensive matching was defined to measure the importance of uncertain inputs to outputs. Machining distortion will exceed the specification (failure) with the increase in comprehensive matching. Therefore, the comprehensive matching index evaluates the effects of the uncertainties on the machining distortion and quantifies the effects of given uncertain parameters. Two engineering examples were employed to illustrate the accuracy and efficiency of the proposed approach. It revealed that the comprehensive matching of cutting force to the failure probability of machining distortion was the maximum, 0.040, which was 12 to 13 times greater than that of linear stiffness or cutter path. [ABSTRACT FROM AUTHOR]

Published

2023

50. Measurement-based two-layer optimization scheme for machining system with repetitive and batch characteristics.

Author

Wang, Jing, Zhang, Jie, Zhang, Fuwang, Sun, Zhongbo, Sui, Zhen, and Tian, Yantao

Subjects

BATCH processing, MACHINING, MANUFACTURING processes, ITERATIVE learning control, TIME-varying systems, ADAPTIVE control systems, GRINDING machines

Abstract

Most machining systems repeat predetermined tasks during machining. In most cases, the measurement of parts is carried out after the production of parts. However, in the actual production process, even if the system measurement is allowed or controllable in the whole production cycle, it often needs to pay more costs and the implementation is more complex. With the intention of improving the above characteristics of the industrial process with repeated batch processing and the optimization problem of the machining system that cannot be measured frequently, based on this, this paper proposes a measurement-based integrated two-level optimization strategy. In this two-layer strategy, the repeated update strategy is used to perform within-run correction to ensure the tracking accuracy and the cycle-to-cycle corrections are based on cycle-to-cycle control adaptive scheme to improve the optimization performance. The scheme combines real-time tracking and offline optimization, and the reactivity of the processing system is effectively improved. In order to make the two-layer optimization scheme more versatile, this paper introduces the periodic time-varying system and increases the flexibility of constraints and applies it to CNC cam grinding. Simulation and experiments verify the effectiveness and superiority of the scheme. [ABSTRACT FROM AUTHOR]

Published

2022