Face hobbing, a continuous indexing and double-flank cutting process, has become the leading method for manufacturing spiral bevel gears and hypoid gears because of its ability to support high productivity and precision. The method is unsuitable for cutting straight bevel gears, however, because it generates extended epicycloidal flanks. Instead, this paper proposes a method for fabricating straight bevel gears using a virtual hypocycloidal straight-line mechanism in which setting the radius of the rolling circle to equal half the radius of the base circle yields straight lines. This property can then be exploited to cut straight flanks on bevel gears. The mathematical model of a straight bevel gear is developed based on a universal face-hobbing bevel gear generator comprising three parts: a cutter head, an imaginary generating gear, and the motion of the imaginary generating gear relative to the work gear. The proposed model is validated numerically using the generation of face-hobbed straight bevel gears without cutter tilt. The contact conditions of the designed gear pairs are confirmed using the ease-off topographic method and tooth contact analysis (TCA), whose results can then be used as a foundation for further flank modification.

References

1.
Al-Daccak
,
M. J.
,
Angeles
,
J.
, and
González-Palacios
,
M. A.
, 1994, “
Modeling of Bevel Gears Using the Exact Spherical Involute
,”
ASME J. Mech. Design
,
116
(
2
), pp.
364
368
.
2.
Hünecke
,
C.
, 2010, “
The Road Leads Straight to Hypoflex®
,”
Gear Technol.
, pp,
54
57
.
3.
Ichino
,
K.
,
Tamura
,
H.
, and
Kawasaki
,
K.
, 1996, “
Method for Cutting Straight Bevel Gears Using Quasi-Complementary Crown Gears
,”
ASME Design Eng. Div.
,
88
, pp.
283
288
.
4.
Chang
,
C. K.
, and
Tsay
,
C. B.
, 2000, “
Mathematical Model of Straight Bevel Gears With Octoid Form
,”
J. Chin. Soc. Mech. Eng.
,
21
(
3
), pp.
239
245
.
5.
Fuentes
,
A.
,
Iserte
,
J. L.
,
Gonzalez-Perez
,
I.
, and
Sanchez-Marin
,
F. T.
, 2011, “
Computerized Design of Advanced Straight and Skew Bevel Gears Produced by Precision Forging
,”
Comput. Meth. Appl. Mech. Eng.
,
200
(
29–32
), pp.
2363
2377
.
6.
Jiao
,
J.
, and
Cao
,
X.
, 2011, “
Generation and TCA of Straight Bevel Gear Drive With Modified Geometry
,”
Appl. Mech. Mater.
,
86
, pp.
403
406
.
7.
Litvin
,
F. L.
,
Chaing
,
W. S.
,
Kuan
,
C.
,
Lundy
,
M.
, and
Tsung
,
W. J.
, 1991, “
Generation and Geometry of Hypoid Gear-Member With Face-Hobbed Teeth of Uniform Depth
,”
Int. J. Mach. Tools Manufact.
,
31
(
2
), pp.
167
181
.
8.
Shih
,
Y. P.
,
Fong
,
Z. H.
, and
Lin
,
G. C. Y.
, 2007, “
Mathematical Model for a Universal Face Hobbing Hypoid Gear Generator
,”
ASME J. Mech. Design
,
129
(
1
), pp.
38
47
.
9.
Shih
,
Y. P.
, and
Fong
,
Z. H.
, 2007, “
Flank Modification Methodology for Face-Hobbing Hypoid Gears Based on Ease-Off Topography
,”
ASME J. Mech. Design
,
129
(
12
), pp.
1294
1302
.
10.
ASNI/AGMA ISO 23509-A08
, 2008,
Bevel and Hypoid Gear Geometry
,
Alexandria
,
VA
.
11.
Litvin
,
F. L.
, and
Fuentes
A.
, 2004,
Gear Geometry and Applied Theory
, 2nd ed.,
Cambridge University Press
,
Cambridge
, Chap. 9.
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