Dynamic Force Identification in Peripheral Milling Based on CGLS Using Filtered Acceleration Signals and Averaged Transfer Functions

2019 ◽  
Vol 141 (6) ◽  
Author(s):  
Chenxi Wang ◽  
Xingwu Zhang ◽  
Baijie Qiao ◽  
Hongrui Cao ◽  
Xuefeng Chen
Keyword(s):  
Time Domain ◽  
Transfer Functions ◽  
Milling Process ◽  
Dynamic Force ◽  
Band Pass Filter ◽  
Peripheral Milling ◽  
Milling Force ◽  
Force Identification ◽  
Milling Forces ◽  
Acceleration Signals

Dynamic milling forces have been widely used to monitor the condition of the milling process. However, it is very difficult to measure milling forces directly in operation, particularly in the industrial scene. In this paper, a dynamic force identification method in time domain, conjugate gradient least square (CGLS), is employed for reconstructing the time history of milling forces using acceleration signals in the peripheral milling process. CGLS is adopted for force identification because of its high accuracy and efficiency, which handles the ill-conditioned matrix well. In the milling process, the tool with high-speed rotation has different transfer functions between tool nose and accelerometers at different angular positions. Based on this fact, the averaged transfer functions are employed to reduce the error amplification of regularization processing for milling force identification. Moreover, in order to eliminate the effect of idling and high-frequency components on identification accuracy, the Butterworth band-pass filter is adopted for acceleration signals preprocessing. Finally, the proposed method is validated by milling tests under different cutting parameters. Experimental results demonstrate that the identified and measured milling forces are in good agreement on the whole time domain, which verifies the effectiveness and generalization of the indirect method for milling force measuring. In addition, the Tikhonov regularization method is also implemented for comparison, which shows that CGLS has higher accuracy and efficiency.

scholarly journals Industry-Oriented Method for Dynamic Force Identification in Peripheral Milling Based on FSC-LSQR Using Acceleration Signals

2022 ◽  
Author(s):  
Maxiao Hou ◽  
Hongrui Cao ◽  
Qi Li ◽  
Jianghai Shi
Keyword(s):  
High Efficiency ◽  
Machining Process ◽  
Qr Factorization ◽  
Calculation Error ◽  
Dynamic Force ◽  
Milling Force ◽  
Force Identification ◽  
Online Identification ◽  
Ill Posed ◽  
Acceleration Signals

Abstract Online measurement of milling force play a vital role in enabling machining process monitoring and control. In practice, the milling force is difficult to be measured directly with the dynamometer. This paper develops a novel method for milling force identification called least square QR-factorization with fast stopping criterion (FSC-LSQR) method, and the queue buffer structure (QBS) is employed for the online identification of milling force using acceleration signals. The convolution integral of milling force and acceleration signals is discretized, which turns the problem of milling force identification into a linear discrete ill-posed problem. The FSC-LSQR algorithm is adopted for milling force identification because of its high efficiency and accuracy, which handles the linear discrete ill-posed problem effectively. The online identification of milling force can be realized using the acceleration signal enqueue and the milling force dequeue operations of the QBS. Finally, the effectiveness of the method is verified by experiments. The experimental results show that the FSC-LSQR algorithm running time is within \((0.05s)\) and the calculation error is less than \((10\%)\). The proposed method can make the sampling frequency of the milling force reach 10240Hz by employing QBS, which satisfy the industry requirements of milling force measurement.

scholarly journals Milling force identification from acceleration signals using regularization method based on TSVD in peripheral milling

Procedia CIRP ◽  
2018 ◽  
Vol 77 ◽  
pp. 18-21 ◽  
Author(s):  
Chenxi Wang ◽  
Xingwu Zhang ◽  
Baijie Qiao ◽  
Xuefeng Chen ◽  
Hongrui Cao
Keyword(s):  
Regularization Method ◽  
Peripheral Milling ◽  
Milling Force ◽  
Force Identification ◽  
Acceleration Signals

scholarly journals Nickel-Based Alloy Dry Milling Process Induced Material Softening Effect

Materials ◽  
2020 ◽  
Vol 13 (17) ◽  
pp. 3758 ◽  
Author(s):  
Jun Zha ◽  
Zelong Yuan ◽  
Hangcheng Zhang ◽  
Yipeng Li ◽  
Yaolong Chen
Keyword(s):  
High Speed ◽  
Softening Temperature ◽  
Milling Process ◽  
Dry Milling ◽  
Milling Force ◽  
Softening Effect ◽  
Milling Temperature ◽  
Nickel Based Alloy ◽  
Alloy Softening ◽  
Milling Forces

Improving the cutting efficiency is the major factor for improving the processing of nickel-based alloys. The novelty of this research is the calibrated SiAlON ceramic tool dry milling nickel-based alloy process. Firstly, the nickel-based alloy dry milling process was analyzed through the finite element method, and the required milling force and temperature were deduced. Then, several dry milling experiments were conducted with the milling temperature, and the milling force was monitored. The change in cutting speeds was from 400 m/min to 700 m/min. Experimental results verified the reduction of the dry milling force hypothesized by the simulation. The experiment also indicated that with a cut depth of 0.3 mm, cut width of 6 mm, and feed per tooth of 0.03 mm/z, when milling speed exceeded 527.52 m/min, the milling force began to decrease, and the milling temperature exceeded the nickel-based alloy softening temperature. This indicated that easy cutting could be realized under high-speed dry milling conditions. The interpolation curve about average temperature and average milling forces showed similarity to the tensile strength reduction with the rise of temperature.

Experimental Study on Ball-End Milling of C/C Composite

2013 ◽  
Vol 650 ◽  
pp. 139-144
Author(s):  
Chen Wei Shan ◽  
Ying Zhao ◽  
Dong Peng Cui
Keyword(s):  
Prediction Model ◽  
High Speed ◽  
End Milling ◽  
Orthogonal Experiment ◽  
Carbon Matrix ◽  
Milling Process ◽  
Cutting Depth ◽  
Milling Force ◽  
Ball End Milling ◽  
Milling Forces

Along with the development of high speed machining technology, the ball end milling cutter’s application is more and more widely. An influence of four control parameters, namely feed, cutting depth, spindle speed and cutting width, on cutting forces is investigated. This paper focuses on experimental research of milling process of carbon fiber reinforced carbon matrix composite (C/C composite). The milling force prediction model for milling of composite using the carbide ball-end tools is built by orthogonal experiment. The experiment results show that : the reliability of the this prediction model is quite high, and the effect of milling speed on milling force is not very obvious, but the milling force increases with the increment of feed per tooth, milling depth and milling width. Using this information, a new prediction model for the milling forces is proposed that can be used for C/C composite milling.

The Role of Flank Face Interference in Improving the Accuracy of Dynamic Force Predictions in Peripheral Milling

1999 ◽  
Vol 121 (4) ◽  
pp. 593-599 ◽  
Author(s):  
S. Ranganath ◽  
K. Narayanan ◽  
J. W. Sutherland
Keyword(s):  
Cutting Forces ◽  
Milling Process ◽  
Total Force ◽  
Dynamic Force ◽  
Peripheral Milling ◽  
Flank Face ◽  
Simulation Results ◽  
Chip Removal ◽  
Interference Mechanism

An enhanced model for the dynamic behavior of the peripheral milling process is described. The model predicts the cutting forces and cutter deflections by including the effects of the flank face interference mechanism in addition to the chip removal effects. The interference mechanism is accounted for by considering the flank interference forces to be proportional to the interference volume. The volume of interference is estimated numerically. The total force acting on the tool is a combination of the forces due to the cutting action and forces due to the interference. Experiments performed on 6061-T6 Aluminum validate the simulation results.

Coupled thermal and mechanical analyses of micro-milling Inconel 718

2018 ◽  
Vol 233 (4) ◽  
pp. 1112-1126 ◽  
Author(s):  
Xiaohong Lu ◽  
Hua Wang ◽  
Zhenyuan Jia ◽  
Yixuan Feng ◽  
Steven Y Liang
Keyword(s):  
Inconel 718 ◽  
Cutting Temperature ◽  
Milling Process ◽  
Micro Milling ◽  
Force Model ◽  
Temperature Model ◽  
Milling Force ◽  
Mechanical Coupling ◽  
Milling Forces ◽  
Milling Force Model

Micro-milling forces, cutting temperature, and thermal–mechanical coupling are the key research topics about the mechanism of micro-milling nickel-based superalloy Inconel 718. Most current analyses of thermal–mechanical coupling in micro-milling are based on finite element or experimental methods. The simulation is not conducive to revealing the micro-milling mechanism, while the results of experiments are only valid for certain machine tool and workpiece material. Few analytical coupling models of cutting force and cutting temperature during micro-milling process have been proposed. Therefore, the authors studied coupled thermal–mechanical analyses of micro-milling Inconel 718 and presented a revised three-dimensional analytical model of micro-milling forces, which considers the effects of the cutting temperature and the ploughing force caused by the arc of cutting edge during shear-dominant cutting process. Then, an analytical cutting temperature model based on Fourier’s law is presented by regarding the contact area as a moving finite-length heat source. Coupling calculation between micro-milling force model and temperature model through an iterative process is conducted. The novelty is including cutting temperature into micro-milling force model, which simulates the interaction between cutting force and cutting temperature during micro-milling process. The established model predicts both micro-milling force and temperature. Finally, experiments are conducted to verify the accuracy of the proposed analytical method. Based on the coupled thermal–mechanical analyses and experimental results, the authors reveal the effects of cutting parameters on micro-milling forces and temperature.

Modeling of dynamic milling forces considering the interlaminar effect during milling multidirectional CFRP laminate

2020 ◽  
pp. 073168442097176
Author(s):  
Fuji Wang ◽  
Guangjian Bi ◽  
Fuda Ning
Keyword(s):  
Superposition Principle ◽  
Milling Process ◽  
Force Model ◽  
Milling Force ◽  
Cfrp Laminate ◽  
Near Net Shape ◽  
Milling Forces ◽  
Milling Force Model ◽  
First Time

The milling process is always required to achieve dimensional tolerance for the near-net-shape carbon fiber reinforced polymer (CFRP) parts. However, delamination and cracking are inevitably induced in milling CFRP due to the excessive milling forces. The milling forces should be thereby well controlled to reduce damages of CFRP parts. Developing a theoretical milling force model is an effective approach to understand the mechanism of milling force generation. Recent studies have established the predictive models; however, the interlaminar effect impacting the material removal process is not considered during milling multidirectional CFRP laminate, limiting the predictive model accuracy. In this work, a model of dynamic milling force for multidirectional CFRP laminate was developed by considering the interlaminar effect for the first time. The specific cutting energy predicted by the artificial neural network methodology was employed to calculate the milling forces during milling a single CFRP layer. Meantime, the support of the layer was enhanced due to the interlaminar effect, and the correction coefficients for each type of support were proposed to reflect the role of this effect. Then, the overall milling forces for multidirectional CFRP laminate can be obtained via the superposition principle, which agreed well with the experimentally measured results.

scholarly journals Mechanics and Dynamics of Ball End Milling

1998 ◽  
Vol 120 (4) ◽  
pp. 684-692 ◽  
Author(s):  
Y. Altıntas¸ ◽  
P. Lee
Keyword(s):  
Time Domain ◽  
Transfer Functions ◽  
End Milling ◽  
Orthogonal Cutting ◽  
Chip Thickness ◽  
Milling Process ◽  
Body Motion ◽  
Ball End Milling ◽  
Cutting Model ◽  
End Milling Process

Mechanics and dynamics of cutting with helical ball end mills are presented. The helical ball end mill attached to the spindle is modelled by orthogonal structural modes in the feed and normal directions at the tool tip. For a given cutter geometry, the cutting coefficients are transformed from an orthogonal cutting data base using an oblique cutting model. The three dimensional swept surface by the cutter is digitized using the true trochoidal kinematics of ball end milling process in time domain. The dynamically regenerated chip thickness, which consists of rigid body motion of the tooth and structural displacements, is evaluated at discrete time intervals by comparing the present and previous tooth marks left on the finish surface. The process is simulated in time domain by considering the instantaneous regenerative chip load, local cutting force coefficients, structural transfer functions and the geometry of ball end milling process. The proposed model predicts cutting forces, surface finish and chatter stability lobes, and is verified experimentally under both static and dynamic cutting conditions.

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