The most common method currently employed in industry to trim composites is machining either with conventional fluted cutters or with diamond abrasive cutters. Although diamond abrasive machining is a common method for trimming composites, there is no research literature which addresses the use of this type of cutter. As a result, an experimental investigation was undertaken to establish the characteristics of the machined edges produced by diamond abrasive cutters in graphite/epoxy laminates. In addition, preliminary tests were performed to document the cutter forces produced by representative cutters with various grit sizes and feed rates. The machined edges produced were generally found to be free of delamination and characterized by regular grooving produced by the diamond grains. The surface finish was found to be inversely proportional to the grit number and was not affected by feed rate or cutting mode. Cutter forces were generally found to increase with material removal rate and the average side load was generally about 60 percent of the thrust forces.

1.
Konig
W.
,
Wulf
Ch.
,
Grass
P.
, and
Willerscheid
H.
, “
Machining of Fiber Reinforced Plastics
,”
Annals of the CIRP
, Vol.
34
, No.
2
,
1985
, pp.
537
547
.
2.
Vlegelahn, G.L., Kawall, S., Scheuerman, R.J., and Browne, C.W., “Laser Cutting of Fiberglass/Polyester Resin Composites,” Advanced Composite Materials, Proc. of 7th Annual ASM/ESD Advanced Composites Conference, ASM publ., Ohio, 1991, pp. 143–147.
3.
Di Ilio
A.
, and
Tagliaferri
V.
, “
Thermal Damage in Laser Cutting of (0/90)2s Aramid/Epoxy Laminates
,”
Composites
, Vol.
20
, No.
2
, pp.
115
119
.
4.
Lau, W.S., Lee, W.B., and Wang, M., “The Damage of Carbon Fiber Composites Resulting from Electric Discharge Machining,” Mechanics and Mechanisms of Damage in Composites and Multi-Materials, ESIS 11, 1991, pp. 67–80.
5.
Takeyama
H.
, and
Iijima
N.
, “
Machinability of Glass Fiber Reinforced Plastics and Application of Ultrasonic Machining
,”
Annals of CIRP
, Vol.
37
, No.
1
,
1988
, pp.
93
96
.
6.
Koplev, A., “Cutting of CFRP with Single Edge Tools,” Proc. of 3rd Int. Conf. on Composite Materials, Paris, Aug. 1980, pp. 1597–1605.
7.
Koplev
A.
,
Lystrup
A.
, and
Vorm
T.
, “
The Cutting Process, Chips and Cutting Forces in Machining CFRP
,”
Composites
, Vol.
14
, No.
4
,
1983
, pp.
371
376
.
8.
Sadat, A., “Machining of Graphite/Epoxy Composite Material,” SAMPE Quarterly, Jan 1988, pp. 1–4.
9.
Ramulu
M.
,
Faridnia
M.
,
Garbini
J. L.
, and
Jorgenson
J. E.
, “
Machining of Graphite/Epoxy Composite Materials with Polycrystalline Diamond Tools
,”
ASME Journal of Engineering Materials and Technology
, Vol.
113
, No.
4
,
1991
, pp.
430
436
.
10.
Wang
D. H.
,
Ramulu
M.
, and
Wern
C. W.
, “
Orthogonal Cutting Characteristics of Graphite/Epoxy Composite Materials
,”
Transactions of the NAMRI/SME
, Vol.
XX
, 1992, pp.
159
165
.
11.
Packer, S., “The Development and Application of Helical Polycrystalline Diamond End Mills,” presented at the 1991 International Diamond/CBN Conference and Exposition, June, 1991.
12.
Colligan
K.
, and
Ramulu
M.
, “
The Effect of Edge Trimming on Composite Surface Plies
,”
Manufacturing Review
, Vol.
5
, No.
4
,
1992
, pp.
274
283
.
13.
Ramulu
M.
,
Wern
C. W.
, and
Garbini
J. L.
, “
Effect of Fiber Direction on Surface Roughness Measurements on Machined Graphite/Epoxy Composites
,”
Composite Manufacturing
, Vol.
4
, No.
1
,
1993
, pp.
39
51
.
14.
Chattopadhyay
A. K.
,
Chollet
L.
, and
Hintermann
H. E.
, “
On Performance of Chemically Bonded Single-Layer CBN Grinding Wheel
,”
Annals CIRP
, Vol.
39
, No.
1
,
1990
, pp.
309
312
.
15.
Chattopadhyay
A. K.
,
Chollet
L.
, and
Hintermann
H. E.
, “
On Performance of Brazed Bonded Monolayer Diamond Grinding Wheel
,”
Annals CIRP
, Vol.
40
,
1991
, pp.
347
350
.
16.
Lowder, J.T., and Tausch, E.M., “Method of Manufacturing Diamond Abrasive Tools,” United States Patent No. 3,894,673, July 15, 1975.
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