Automated Upgraded Generalized Full-Discretization Method: Application to the Stability Study of a Thin-Walled Milling Process

Based on the full-discretization method, this work presents a generalized monodromy matrix as an exact function of the order of polynomial approximation of the milling state for chatter avoidance algorithm. In other words, the computational process is made smarter since the usual derivation of the monodromy matrices on order-by-order basis – a huge analytical involvement that rapidly gets heavier with a rise in the order of approximation – is bypassed. This is the highest possible level of generalization that seems to be the first of its kind among the time-domain methods as the known generalizations are limited to the interpolating/approximating polynomial of the milling state. It then became convenient in this work to study the stability of milling process up to the tenth order. More reliable methods of the rate of convergence analysis were suggested and utilized in consolidating the known result that the best accuracy of the full-discretization method lies with the third and fourth order. It is seen from numerical convergence analyses that, although accuracy most often decreases with rising order beyond the third-order methods, the trend did not persist with a continued rise in order.

Download Full-text

Stability Prediction of Milling Process With Closed Machining System Dynamics With Flexible Thin-Walled Workpiece

Volume 2B: Advanced Manufacturing ◽

10.1115/imece2015-51454 ◽

2015 ◽

Author(s):

Chao Xu ◽

Pingfa Feng ◽

Dingwen Yu ◽

Zhijun Wu ◽

Jianfu Zhang

Keyword(s):

Support System ◽

Milling Process ◽

Machining Process ◽

Stability Lobe Diagram ◽

Closed Model ◽

Flexible Support ◽

Stability Lobe ◽

Machining System ◽

Thin Walled ◽

The Stability

Despite recent advances and improvements in modeling and prediction of the dynamics of the machining process, an efficient machining process is limited due to chatter and instability of machining system. In fact, the machining system contains various kinds of joints, which cause difficulties in dynamics modeling, simulation and prediction. Moreover, the flexible support system results in large deformation and violent vibration of the workpiece when machining, and the thin-walled workpiece easily gives rise to the chatter of the machining system. Therefore, the dynamics of the flexible support system was considered to calculate stability lobe diagram in the modeling of milling process. The whole machining system was regarded as a closed loop composed by the machine tool structures, support, workpiece and machining process. In this paper, the receptance coupling (RC) method was introduced to predict the dynamics of the closed machining system. A milling process was taken for example to predict the chatter limitations using the dynamics of closed model. The mathematical model of the machining system (machine tool structures, spindle, holder and tool), together with the details of joint contacts, was given based on the RC method. The RC model was used to obtain the dynamics of the system, while receptance of the tool point was coupled. Based on the coupling model of the machining system, the depth limitations under different speeds were estimated for the technology parameter optimization in milling process. The response was considered to be the sum of the cutting point and the support system. The flexibility of the support system was considered to be the feedback of the cutting stiffness. By this means, the traditional model was modified to calculate the stability lobe diagram based on the dynamics of the spindle and support system. Furthermore, the milling experiment was carried out to verify the prediction results, and the dominant natural frequencies of receptance at tool point were obtained by modal testing to define the stability lobe diagram. It was found that the chatter results matched well with the stability lobes. It was concluded that the support system with poor stiffness might cause violent chatter especially when the workpiece was thin-walled. The cutting depth limitations of the flexible support system were lower than that of the rigid one. Moreover, this closed model of the machining system is appropriate for the chatter prediction of the flexible support system or thin-walled workpiece, so it is helpful for a better parameter optimization.

Download Full-text

Influence of Cutter Geometric Parameters on the Stability of Milling Process of Thin-Walled Blades

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.443-444.21 ◽

2012 ◽

Vol 443-444 ◽

pp. 21-26 ◽

Cited By ~ 2

Author(s):

Wei Wei Liu ◽

Xiao Juan Gao ◽

Chen Wei Shan ◽

Wei Jun Tian

Keyword(s):

High Performance ◽

Cutting Parameters ◽

Milling Process ◽

Chatter Vibration ◽

Clamping System ◽

Cutting Deformation ◽

Thin Walled ◽

Simulation Results ◽

The Stability ◽

New System

In this paper, a new experiment procedure is proposed to study the influence of cutter parameters and clamping methods on the stability of the milling process of thin-walled blade. A dedicated fixture is designed to carry out the experiment. Simulation results show that the new clamping system can enhance the rigidity of thin-walled blade to reduce cutting deformation and chatter vibration phenomenon. Then, cutter and cutting parameters can be optimized properly to make the system obtain high rigidity and high performance stable milling process. Industrial application indicates that the new system can improve the cutting performance and ensure the cutting quality.

Download Full-text

Dynamic modeling and stability prediction in milling process of thin-walled workpiece with multiple structural modes

Proceedings of the Institution of Mechanical Engineers Part B Journal of Engineering Manufacture ◽

10.1177/0954405420933710 ◽

2020 ◽

pp. 095440542093371

Author(s):

Zhao Zhang ◽

Ming Luo ◽

Baohai Wu ◽

Dinghua Zhang

Keyword(s):

Dynamic Model ◽

Dynamic Modeling ◽

Milling Process ◽

Test Results ◽

Stability Lobe ◽

Milling Tool ◽

Thin Walled ◽

The Stability ◽

Structural Mode ◽

Stability Lobe Diagrams

Regenerative chatter can easily occur in the milling process of thin-walled workpiece due to the inherently low stiffness. This article aims to predict the stability of thin-walled workpiece in the milling process with a complete dynamic model. First, multiple structural modes of thin-walled workpiece are taken into consideration, and a complete dynamic model of thin-walled workpiece milling system is developed. Then, a numerical integration method is used to achieve the stability lobe diagrams of the milling system and identify the chatter frequency. Besides, the major structural mode, which is responsible for the occurrence of thin-walled workpiece chatter in the milling process, is predicted. A series of milling tests concerning a general cantilever plate are conducted, and the test results agree well with the predicted results, which shows the effectiveness of the proposed method. Finally, the effects of milling tool and structural modes on milling stability are discussed separately, which could provide theoretical basis for the dynamic modeling of thin-walled workpiece in milling process.

Download Full-text

Stability Research Considering Non-Linear Change in the Machining of Titanium Thin-Walled Parts

Materials ◽

10.3390/ma12132083 ◽

2019 ◽

Vol 12 (13) ◽

pp. 2083 ◽

Cited By ~ 2

Author(s):

Haining Gao ◽

Xianli Liu

Keyword(s):

Titanium Alloy ◽

Prediction Model ◽

Dynamic Characteristics ◽

Material Removal ◽

Milling Process ◽

Damping Coefficient ◽

Linear Change ◽

Process Damping ◽

Thin Walled ◽

The Stability

Aiming to solve the problem whereby the damping process effect is significant and difficult to measure during low-speed machining of titanium alloy thin-walled parts, the ploughing coefficient of the flank face is obtained based on the frequency-domain decomposition (FDD) of the measured vibration signal and the energy balance principle, and then the process-damping prediction model is obtained. Aiming to solve the problem of non-linear change of dynamic characteristics of a workpiece caused by the material removal effect in the machining of titanium alloy thin-walled parts, a prediction model of dynamic characteristics of a workpiece is established based on the structural dynamic modification method. Meanwhile, the effect of material removal on the process-damping coefficient is studied, and the internal relationship between the process-damping coefficient and the dynamic characteristics of the workpiece is revealed. The stability lobe diagram is obtained by the full discretization in the titanium alloy milling process. The correctness of the model and stability prediction is verified by experiments under different working conditions. It is found that the coupling characteristics of process-damping and workpiece dynamic characteristics control the stability of the milling process. The research results can provide theoretical support for accurate characterization and process optimization of titanium alloy thin-walled workpiece milling.

Download Full-text

The stability of rectangular thin-walled profile with loading according to the scheme of pure bending

Quality Innovation Education ◽

10.31145/1999-513x-2020-2-41-45 ◽

2020 ◽

pp. 41-45

Author(s):

V.B. Zylev ◽

◽

P.O. Platnov ◽

I.V. Alferov ◽

◽

...

Keyword(s):

Pure Bending ◽

Thin Walled ◽

The Stability

Download Full-text

Precise chatter monitoring of thin-walled component milling process based on parametric time-frequency transform method

Journal of Materials Processing Technology ◽

10.1016/j.jmatprotec.2020.116712 ◽

2020 ◽

Vol 283 ◽

pp. 116712 ◽

Cited By ~ 2

Author(s):

Xiaojuan Wang ◽

Qinghua Song ◽

Zhanqiang Liu

Keyword(s):

Milling Process ◽

Transform Method ◽

Time Frequency ◽

Thin Walled

Download Full-text

Basic Concepts in the Stability Theory of Thin-walled Structures

10.1063/1.3526619 ◽

2010 ◽

Author(s):

A. Guran ◽

L. Lebedev ◽

Michail D. Todorov ◽

Christo I. Christov

Keyword(s):

Stability Theory ◽

Thin Walled Structures ◽

Thin Walled ◽

Basic Concepts ◽

The Stability

Download Full-text

A characteristic type of instability in the large deflexions of elastic plates III. Curved rectangular plates in axial compression

Proceedings of the Royal Society of London Series A - Mathematical and Physical Sciences ◽

10.1098/rspa.1954.0051 ◽

1954 ◽

Vol 222 (1148) ◽

pp. 44-59 ◽

Cited By ~ 2

Keyword(s):

Axial Compression ◽

Rectangular Plates ◽

Bending Moments ◽

Elastic Plates ◽

Characteristic Type ◽

Circular Tubes ◽

Axis Parallel ◽

Post Buckling ◽

Thin Walled ◽

The Stability

The analysis of part I is extended to deal with the case of free-edged rectangular plates having an initial curvature about an axis parallel to one pair of opposite edges and loaded by distributed bending moments applied to the straight edges and compressive forces applied to the curved edges. In particular, the stability and post-buckling behaviour of such plates subjected to the compressive forces alone is studied. The axially symmetrical buckling of thin-walled circular tubes in axial compression is also considered. Experimental plates are found to buckle at loads rather lower than those predicted.

Download Full-text

Basic Experimental and Numerical Investigations on Chip Pressing

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.554-557.630 ◽

2013 ◽

Vol 554-557 ◽

pp. 630-637 ◽

Cited By ~ 1

Author(s):

Martin Grüner ◽

Marion Merklein

Keyword(s):

Numerical Simulation ◽

Aluminium Alloys ◽

Testing Machine ◽

Material Model ◽

Extrusion Process ◽

Milling Process ◽

Numerical Investigations ◽

Compression Direction ◽

Universal Testing ◽

The Stability

Aluminium alloys show a great potential for lightweight constructions due to their high strength and low density but the production of this material is very energy consuming. Also the recycling of aluminium alloys, e.g. chips from the milling process, shows different challenges. Beside contamination by cooling lubricant and oxidation of the surface of the chips the melting and rolling process for new semi finish products needs a high amount of energy. TEKKAYA shows a new approach for recycling of aluminium alloy chips by an extrusion process at elevated temperatures producing different kinds of profiles. A new idea is the production of components directly out of chips using severe plastic deformation for joining of the chips similar to the accumulative roll bonding process in sheet metal forming. In a first approach aluminium alloy chips out of a milling process were uniaxial compressed with different loads inside an axisymmetric tool installed in a universal testing machine. The compressed chip disks subsequently were tested with two experiments to gain information on their stability. First experiment is a disk compression test with the disk standing on its cylindrical surface, giving information on the stability perpendicular to the compression direction. Second experiment is a stacked disk compression test with three disks to investigate the stability parallel to compression direction. During all three tests force and displacement values are recorded by the universal testing machine. These data are also processed to calculate or identify input parameters for the numerical investigations. For numerical simulation ABAQUS in conjunction with the Drucker-Prager-Cap material model, which is often used for sintering processes, seems to be a good choice. By numerical simulation of the experiments and comparison with the experiments input parameters for the material model can be identified showing good accordance. This material model will be used in future numerical investigations of an extrusion process to identify tool geometries leading to high strains inside the material and by this to an increased stability of the parts.

Download Full-text