Abstract

Because the contact patterns of spiral bevel and hypoid gears are highly sensitive to tooth flank geometry, it is desirable to reduce the flank deviations caused by machine errors and heat treatment deformation. Several methods already proposed for flank correction are based on the cutter parameters, machine settings, and kinematical flank motion parameters of a cradle-type universal generator, which are modulated according to the measured flank topographic deviations. However, because of the recently developed six-axis Cartesian-type computer numerical control (CNC) hypoid generator, both face-milling and face-hobbing cutting methods can be implemented on the same machine using a corresponding cutter head and NC code. Nevertheless, the machine settings and flank corrections of most commercial Cartesian-type machines are still translated from the virtual cradle-type universal hypoid generator. In contrast, this paper proposes a flank-correction methodology derived directly from the six-axis Cartesian-type CNC hypoid generator in which high-order correction is easily achieved through direct control of the CNC axis motion. The validity of this flank-correction method is demonstrated using a numerical example of Oerlikon Spirac face-hobbing hypoid gears made by the proposed Cartesian-type CNC machine.

1.
Krenzer
,
T. J.
, 1984, “
Computer Aided Corrective Machine Settings for Manufacturing Bevel and Hypoid Gear Sets
,”
Fall Technical Meeting
,
Washington, D.C.
, AGMA Paper No. 84-FTM-4.
2.
Litvin
,
F. L.
,
Kuan
,
C.
,
Wang
,
J.-C.
,
Handschuh
,
R. F.
,
Masseth
,
J.
, and
Maruyama
,
N.
, 1993, “
Minimization of Deviations of Gear Real Tooth Surfaces Determined by Coordinate Measurements
,”
ASME J. Mech. Des.
1050-0472,
115
, pp.
995
1001
.
3.
Litvin
,
F. L.
, and
Fuentes
,
A.
, 2004,
Gear Geometry and Applied Theory
, 2nd ed.,
Cambridge University Press
,
New York
.
4.
Lin
,
C.-Y.
,
Tsay
,
C.-B.
, and
Fong
,
Z.-H.
, 1998, “
Computer-Aided Manufacturing of Spiral Bevel and Hypoid Gears With Minimum Surface-Deviation
,”
Mech. Mach. Theory
0094-114X,
33
(
6
), pp.
785
803
.
5.
Krenzer
,
T. J.
,
Hunkeler
,
E. J.
, and
Goldrich
,
R. N.
, 1991, “
Multi-Axis Bevel and Hypoid Gear Generating Machine
,” U.S. Patent No. 4,981,402.
6.
Goldrich
,
R. N.
, 1989, “
Theory of 6-Axis CNC Generation of Spiral Bevel Gear and Hypoid Gears
,” AGMA Paper No. 89-FTM-9.
7.
Gosselin
,
C.
,
Nonaka
,
T.
,
Shiono
,
Y.
,
Kubo
,
A.
, and
Tatsuno
,
T.
, 1998, “
Identification of the Machine Settings of Real Hypoid Gear Tooth Surfaces
,”
ASME J. Mech. Des.
1050-0472,
120
, pp.
429
440
.
8.
Fong
,
Z.-H.
, 2000, “
Mathematical Model of Universal Hypoid Generator With Supplemental Kinematic Flank Correction Motions
,”
ASME J. Mech. Des.
1050-0472,
122
, pp.
136
142
.
9.
Shih
,
Y.-P.
, and
Fong
,
Z.-H.
, 2007, “
Mathematical Model for the Universal Face-Hobbing Hypoid Gear Generator
,”
ASME J. Mech. Des.
1050-0472,
128
, pp.
457
467
.
10.
Thomas
,
J.
, and
Vogel
,
O.
, 2005, “
6M Machine Kinematics for Bevel and Hypoid Gears
,”
Proceedings of the International Conference on Gears in Munich
, VDI Brief No. 1904.1, pp.
435
451
.
11.
Dong
,
X.-Z.
, 2002,
Design and Manufacture for Epicycloidal Spiral Bevel and Hypoid Gears
,
China Machine Press
,
Beijing
, in Chinese.
You do not currently have access to this content.