Trends of ultra-precision machining in 2nd Int. Machine Tool Engineers' Conf.

In this paper, current results of a research project combining ultra precision machining and optical measurement are presented. The goal is to improve the quality of specular freeform surfaces manufactured by ultra precision slow slide servo turning by running appropriate correction cycles on the basis of machine integrated measurements. These measurements are conducted using the principle of Phase Measuring Deflectometry (PMD) in order to optically acquire full-field 3D-height data. For this purpose, a special setup the so called Mini PMD that can be operated within the limited installation space of an ultra precision machine tool has been designed and implemented. Results of machine integrated measurements of a specular non-rotational symmetrical surface are presented. Furthermore, using Mini PMD and a rotationally symmetric test surface, a complete correction cycle is demonstrated without the necessity of taking the workpiece off the machine for measurement.

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Finite Element Analysis and Optimization of Thermal Deformation of Resin Concrete Manufacturing Bases

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.543-547.4010 ◽

2014 ◽

Vol 543-547 ◽

pp. 4010-4013

Author(s):

Yao Chen ◽

Xiu Xia Liang ◽

Shuang Qiu

Keyword(s):

Thermal Stability ◽

Machine Tool ◽

Thermal Deformation ◽

Precision Machining ◽

Element Analysis ◽

Excellent Thermal Stability ◽

Good Thermal Stability ◽

Machining Center ◽

Ultra Precision ◽

Thermal Stability Of

Resin concrete generally has good mechanical properties, excellent thermal stability and great vibration resistance, the model of the ultra-precision machining center bed is established to study the thermal stability of the resin concrete using virtual reality and collaborative simulation technology based on Pro/E and ANSYS Workbench. The main factors that affect the machine tool bed thermal deformation were found through analyzing the deformation results and the materials and restrain conditions were optimized. The results proved that the optimized machine tool bed has good thermal stability and theoretical basis was provided to improve the thermal stability of the ultra-precision machining centers.

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A review of machine-tool vibration and its influence upon surface generation in ultra-precision machining

International Journal of Machine Tools and Manufacture ◽

10.1016/j.ijmachtools.2015.01.005 ◽

2015 ◽

Vol 91 ◽

pp. 34-42 ◽

Cited By ~ 76

Author(s):

S.J. Zhang ◽

S. To ◽

G.Q. Zhang ◽

Z.W. Zhu

Keyword(s):

Machine Tool ◽

Surface Generation ◽

Precision Machining ◽

Tool Vibration ◽

Ultra Precision

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Fluctuation prediction of machining accuracy for multi-axis machine tool based on stochastic process theory

Proceedings of the Institution of Mechanical Engineers Part C Journal of Mechanical Engineering Science ◽

10.1177/0954406214562633 ◽

2014 ◽

Vol 229 (14) ◽

pp. 2534-2550 ◽

Cited By ~ 4

Author(s):

Qiang Cheng ◽

Qiunan Feng ◽

Zhifeng Liu ◽

Peihua Gu ◽

Ligang Cai

Keyword(s):

Stochastic Process ◽

Machine Tool ◽

Significant Influence ◽

Geometric Error ◽

Error Modeling ◽

Precision Machining ◽

Machining Accuracy ◽

Geometric Errors ◽

Volumetric Error ◽

Ultra Precision

Geometric error has significant influence on the processing results and reduces machining accuracy. Machine tool geometric errors can be interpreted as a deterministic value with an uncertain fluctuation of probabilistic distribution. Although, the uncertain fluctuation can not be compensated, it has extremely profound significance on the precision and ultra-precision machining to reduce the fluctuation range of machining accuracy as far as possible. In this paper, a typical 3-axis machine tool with high precision is selected and the fluctuations in machining accuracy are studied. The volumetric error modeling of machine tool is established by multi-body system (MBS) theory, which describes the topological structure of MBS in a simple and convenient matrix form. Based on the volumetric error model, the equivalent components of the errors for the three axes are established by reducing error terms. Then, the fluctuations of equivalent errors and the machining accuracy in working planes are depicted and predicted using the theory of stochastic process, whose range should be controlled within a certain confidence interval. Furthermore, the critical geometric errors that have significant influence on the machining accuracy fluctuation are identified. Based on the analysis results, some improvement in the machine tool parts introduced and the results for the modified machine show that the prediction allow for reduction in errors for the precision and ultra-precision machining.

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Study on Axial Oil Chamber Design for High Performance Hydrostatic Spindle

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.701-702.869 ◽

2014 ◽

Vol 701-702 ◽

pp. 869-873

Author(s):

Shao Hsien Chen ◽

Shang Te Chen ◽

Chien Cheng Hsu

Keyword(s):

Machine Tool ◽

High Performance ◽

Development Trend ◽

Ball Screw ◽

Precision Machining ◽

Large Size ◽

Chamber Design ◽

Ultra Precision ◽

Bearing Stiffness ◽

Application Scope

Ultra-precision machining and large-size equipments are themostprimary development trend ofcurrentmachine tooland hydrostatic products arekeytechnologiesof ultra-precision machining equipments. However, these equipmentsmostlyprocess miniature components, thus the adopted tools are relatively small and the spindlesare mainlybuilt-in types of HSK32-HSK25 withover30,000r. Some processing equipments are even equipped with hydrostatic or gas-static spindles. The studyextends theaxialoilchamberto radialonesto expand theaction areaofaxialoil pressureand form a closed oil seal edge by combining theradialclearance. Consequently, theaxialbearing stiffnesscan be enhancedtoenlarge the application scope of hydrostatic spindle. The designmodecan enhanceaxialstiffness ofspindle modulesor strengthenthe stiffness of hydrostatic spindlein a ball screw.

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Research on Influence of the Material Anisotropy to the Surface Quality during SPDT Machining of Crystal KDP

Materials Science Forum ◽

10.4028/www.scientific.net/msf.532-533.209 ◽

2006 ◽

Vol 532-533 ◽

pp. 209-212 ◽

Cited By ~ 1

Author(s):

Ming Jun Chen ◽

Ying Chun Liang ◽

Jing He Wang ◽

Xin Zhou Zhang

Keyword(s):

Theoretical Analysis ◽

Machine Tool ◽

Cutting Force ◽

Surface Quality ◽

Smooth Surface ◽

Precision Machining ◽

Optimal Parameters ◽

Material Anisotropy ◽

Crystal Anisotropy ◽

Ultra Precision

A theoretical analysis on the variation regularity of cutting force caused by the material anisotropy with different orientation of KDP is analyzed firstly; influence and regularity of the variation are obtained. Analysis result shows that the crystal anisotropy of KDP is an important factor in obtaining the super-smooth surface. Then experiments are realized on the machine tool, results afford the variation regularity of cutting force caused by the anisotropy with different orientation of KDP, which certifies the correctness of this theoretical analysis. For ultra-precision machining of the KDP at large negative rake diamond cutter (-45°) and the optimal parameters, the super-smooth surface (rms is 8.702 nm, Ra is 6.895 nm) can be obtained on the plane (001).

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3D Simulation of the Ultra-Precision V-Groove Machine Tool

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.679.111 ◽

2016 ◽

Vol 679 ◽

pp. 111-115

Author(s):

Hui Jing Huang ◽

Wei Qiang Gao ◽

Jian Qun Liu

Keyword(s):

Machine Tool ◽

Collision Detection ◽

Three Dimensional ◽

Numerical Control ◽

Machining Process ◽

3D Simulation ◽

Precision Machining ◽

Hardware Platform ◽

Nc Code ◽

Ultra Precision

This paper develops a three dimensional (3D) simulation system with QT platform and OpenGL 3D library by adopting the driver and Aerotech’s linear motor as hardware platform and INtime and A3200 controller as the software platform. The system uses numerical control (NC) code syntax checking module to test the NC code syntax and applies 3D simulation module to display the actual machining process. The interference and collision detection module is built in this system to detect the problem during the actual processing. The system therefore contributes to avoiding the trial and tests for the ultra-precision machining process and improving the machining efficiency as well as reducing the loss of ultra-precision components of machine tool due to the collision.

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Straightness Error Compensation for Ultra-Precision Machining Based on a Straightness Gauge

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.381-382.105 ◽

2008 ◽

Vol 381-382 ◽

pp. 105-108 ◽

Cited By ~ 8

Author(s):

Guo Hui Cao ◽

Yoshiharu Namba

Keyword(s):

Machine Tool ◽

Error Compensation ◽

Surface Profile ◽

Displacement Sensor ◽

Precision Machining ◽

The Real ◽

Nano Scale ◽

Nc Program ◽

Ultra Precision ◽

Straightness Error

A method of straightness error compensation is presented, which is used in ultra-precision machining with nano-scale accuracy for a large mandrel manufacture. A set of measurement system in situ is developed, in which an ultra-smooth glass-ceramic flatness gauge and a non-contact micro displacement sensor with nano-scale resolution were used as a reference and sensor to get the straightness error of machine tool movement. The real straightness error can be obtained after subtracting the surface profile of the gauge from the original straightness error curve. Based on the real straightness error data, a new NC program was made for compensating the error from the axis movement of machine tool. As a result, after straightness error compensation, the straightness errors of two axes of ultra-precision machine tool are 68nm/400mm and 54nm/300mm respectively.

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Design of a Three-Axis Desktop Micro Milling Machine Tool

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.589-590.735 ◽

2013 ◽

Vol 589-590 ◽

pp. 735-739 ◽

Cited By ~ 1

Author(s):

Xiang Cheng ◽

Xian Hai Yang ◽

Li Li ◽

Jun Ying Liu

Keyword(s):

Machine Tool ◽

Three Dimensional ◽

Milling Process ◽

Micro Milling ◽

Precision Machining ◽

Milling Machine ◽

Design And Optimization ◽

Linear Motors ◽

Ultra Precision ◽

Open Control

Micro milling process is more favorite than other processes for its unique advantages in ultra-precision machining of miniature components with intricate three-dimensional geometrical feature made of various materials. Aiming at micro milling applications, a three-axis desktop milling machine tool with linear motors and nano-meter linear scales has been introduced. Natural granite is used as the frame material and air-bearing cylinders are used for z-axis gravity balancing. Finite element method is applied to the design and optimization of the machine structures. The designed machine adopts linear motors and 5nm resolution linear scale using an open control architecture. The workspace is 100mm×100mm×100mm and the overall size is 610mm×650mm×630mm. Experimental evaluations show the sub-micron machining feasibility of the introduced machine.

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Research of an Open CNC System for MRF Machine Tool Based on UMAC

Key Engineering Materials ◽

10.4028/www.scientific.net/kem.589-590.648 ◽

2013 ◽

Vol 589-590 ◽

pp. 648-653

Author(s):

Ming Jun Chen ◽

Zhan Yue Guo ◽

He Nan Liu ◽

Bo Yu ◽

Hui Peng ◽

...

Keyword(s):

Machine Tool ◽

Notch Filter ◽

Numerical Control ◽

Precision Machining ◽

Contour Error ◽

Cnc System ◽

Open Cnc ◽

Ultra Precision ◽

Open Cnc System ◽

Universal Motion

In order to use magnetorheological finishing (MRF) to accomplish ultra-precision machining of complex curve surfaces, an open computer numerical control (CNC) system based on universal motion and automation controller (UMAC) has been developed. The paper introduces the hardware structure of the system, elucidates the control algorithm and parameters tuning of PID + velocity/acceleration feed-forward + notch filter, and explains the design of a friendly human-machine interface (HMI) to satisfy the need of actual manufacturing and complicated numerical control. With the open CNC system, a 4mm-diameter circle is polished on the MRF experimental prototype with the contour error of 1.67% and the surface roughness Ra of 1.4nm. Experimental results prove that the open CNC system for the MRF machine tool meets the requirements of ultra-precision machining.

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