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Abstract

The helical flutes in drills are usually made by grinding cylindrical rods to form helically swept grooves. In order to maintain the quality of the fluting process for microdrills, grinding wheels must be trued and dressed regularly. It is therefore quite important to examine the profile accuracy of trued and dressed wheels. With the aid of machine vision, this paper presents an image-based method for examining the profile accuracy of grinding wheels used for microdrill fluting. Using thin plate specimens ground to yield two-dimensional contours for duplicating the topographical profiles of inspected grinding wheels, digital images of the ground contours can be captured in order to detect their coordinate data by edge detection. A contour matching method is then developed to calculate the relative deviations between the theoretical and detected inspected contours, and the profile accuracy of the inspected grinding wheel can thus be indirectly evaluated. To test the proposed method, a machine vision system was built, and experiments examining diamond grinding wheels used for machining helical flutes in microdrills were conducted. The results showed that the proposed contour matching method could achieve sufficient repeatability in the examination of wheel contours.

Keywords

grinding wheel wheel contour examination microdrill fluting machine vision image processing contour matching method

References

Topoint Technology Corp. http://www.topoint.tw/en/index.htm.

Tera Autotech Corp. http://www.teraauto.com.tw/english/main.php.

Inasaki

Okamura

, ‘Monitoring of dressing and grinding processes with acoustic emission signals’ Ann CIRP 34 (1) (1985): 277–280.

Gomes de Oliveira

J. F.

Dornfeld

D. A.

Winter

, ‘Dimensional characterization of grinding wheel surface through acoustic emission’ Ann CIRP 43 (1) (1994): 291–294.

Hundt

Leuenberger

Rehsteiner

Gygax

, ‘An approach to monitoring of the grinding process using acoustic emission (AE) technique’ Ann CIRP 43 (1) (1994): 295–298.

Webster

Marinescu

Bennett

Lindsay

, ‘Acoustic emission for process control and monitoring of surface integrity during grinding’ Ann CIRP 43 (1) (1994): 299–304.

Mokbel

A. A.

Maksoud

T. M. A.

, ‘Monitoring of the condition of grinding wheels using acoustic emission technique’ J. Mater. Processing Technol. 101 (1–3) (2000): 292–297.

Gomes de Oliveira

J. F.

Dornfeld

D. A.

, ‘Application of AE contact sensing in reliable grinding monitoring’ Ann CIRP 50 (1) (2001): 217–220.

Brinksmeier

Werner

, ‘Monitoring of grinding wheel wear’ Ann CIRP 41 (1) (1992): 373–376.

10.

Sodhi

M. S.

Tiliouine

, ‘Surface roughness monitoring using computer vision’ Int. J. Mach. Tools Mf. 36 (7) (1996): 817–828.

11.

Blunt

Ebdon

, ‘The application of three-dimensional surface measurement techniques to characterizing grinding wheel topography’ Int. J. Mach. Tools Mf. 36 (11) (1996): 1207–1226.

12.

Butler

D. L.

Blunt

L. A.

See

B. K.

Webster

J. A.

Stout

K. J.

, ‘The characterisation of grinding wheels using 3D surface measurement techniques’ J. Mater. Processing Technol. 127 (2) (2002): 234–237.

13.

Furutani

Ohguro

Hieu

N. T.

Nakamura

, ‘In-process measurement of topography change of grinding wheel by using hydrodynamic pressure’ Int. J. Mach. Tools Mf. 42 (13) (2002): 1447–1453.

14.

Furutani

Hieu

N. T.

Ohguro

Nakamura

, ‘Automatic compensation for grinding wheel wear by pressure based in-process measurement in wet grinding’ Precision Engng 27 (1) (2003): 9–13.

15.

Lachance

Bauer

Warkentin

, ‘Application of region growing method to evaluate the surface condition of grinding wheels’ Int. J. Mach. Tools Mf. 44 (7–8) (2004): 823–829.

16.

J. C.

Tarng

Y. S.

, ‘Measuring wear of the grinding wheel using machine vision’ Int. J. Adv. Mf. Technol. 31 (1) (2006): 50–60.

17.

Weng

Cohen

Herniou

, ‘Camera calibration with distortion models and accuracy evaluation’ IEEE Trans. Pattern Anal. Mach. Intell. 14 (10) (1992): 965–980.

18.

NI vision concepts manual (2007) pp. 3.1–3.18 and 11.1–11.22 (National Instrument Corp., Austin, Texas).

19.

Jain

Kasturi

Schunck

, Machine vision (1995): Pp. 140–185 210–223, and 309–364 (McGraw-Hill, New York).

20.

Gonzalez

R. C.

Woods

R. E.

, Digital image processing (Upper Saddle River, New Jersey: Prentice-Hall 2002): Pp. 568–585.

21.

Faires

J. D.

Burden

, Numerical methods 3rd edition, (Pacific Grove, California: Thomson Learning 2003): Pp. 340–348.

22.

Arora

J. S.

, Introduction to optimum design (New York: McGraw-Hill 1989): Pp. 347–425.

23.

MATLAB optimization toolbox user's guide—version 3.1.1 (Natick, Massachusetts: The MathWorks Inc. 2007).

Examining the profile accuracy of grinding wheels used for microdrill fluting by an image-based contour matching method

Abstract

Abstract

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References