A Novel Taper Design Method for Face-Milled Spiral Bevel and Hypoid Gears by Completing Process Method

The design of spiral bevel and hypoid gears that have a shaft extended from both sides of the cone apex (straddle design) is considered. A main difficulty of such a design is determining the length and diameter of the shaft that might be undercut by the head cutter during gear tooth generation. A method that determines the free space available for the gear shaft is proposed. The approach avoids collision between the shaft being designed and the head cutter during tooth generation. The approach is illustrated with a numerical example.

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Cutter Interchangeability for Spiral-Bevel and Hypoid Gear Manufacturing

Volume 4: 9th International Power Transmission and Gearing Conference, Parts A and B ◽

10.1115/detc2003/ptg-48056 ◽

2003 ◽

Cited By ~ 4

Author(s):

Claude Gosselin ◽

Jack Masseth ◽

Wei Liang

Keyword(s):

Test Case ◽

Hypoid Gear ◽

Hypoid Gears ◽

Manufacturing Operations ◽

Before And After ◽

Gear Manufacturing ◽

Spiral Bevel ◽

Tooth Flank ◽

Tooth Flank Surface Topography ◽

Flank Surface

In the manufacturing of spiral-bevel and hypoid gears, circular cutter dimensions are usually based on the desired performance of a gear set. In large manufacturing operations, where several hundred gear geometries may have been cut over the years, the necessary cutter inventory may become quite large since the cutter diameters will differ from one geometry to another, which results in used storage space and associated costs in purchasing and maintaining the cutter parts. Interchangeability of cutters is therefore of significant interest to reduce cost while maintaining approved tooth geometries. An algorithm is presented which allows the use of a different cutter, either in diameter and/or pressure angle, to obtain the same tooth flank surface topography. A test case is presented to illustrate the usefulness of the method: the OB cutter diameter of an hypoid pinion is changed from 8.9500" to 9.1000". CMM results and the comparison of the bearing patterns before and after change show excellent correlation, and indicate that the new pinion can be used in place of the original pinion without performance or quality problems. Significant cost reductions may be obtained with the application of the method.

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Computer-aided manufacturing of spiral bevel and hypoid gears by applying optimization techniques

Journal of Materials Processing Technology ◽

10.1016/s0924-0136(01)00734-8 ◽

2001 ◽

Vol 114 (1) ◽

pp. 22-35 ◽

Cited By ~ 55

Author(s):

Chung-Yunn Lin ◽

Chung-Biau Tsay ◽

Zhang-Hua Fong

Keyword(s):

Optimization Techniques ◽

Computer Aided Manufacturing ◽

Hypoid Gears ◽

Computer Aided ◽

Spiral Bevel

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Flank Correction for Spiral Bevel and Hypoid Gears on a Six-Axis CNC Hypoid Generator

Volume 3: Design and Manufacturing ◽

10.1115/imece2007-43017 ◽

2007 ◽

Cited By ~ 1

Author(s):

Yi-Pei Shih ◽

Zhang-Hua Fong

Keyword(s):

Correction Method ◽

Numerical Control ◽

Cnc Machine ◽

Hypoid Gears ◽

Nc Code ◽

Machine Errors ◽

Highly Sensitive ◽

Spiral Bevel ◽

Tooth Flank ◽

Cutter Head

Because the contact bearings 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.

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Nonrelative sliding of spiral bevel gear mechanism based on active design of meshing line

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

10.1177/0954406218767466 ◽

2018 ◽

Vol 233 (3) ◽

pp. 1055-1067 ◽

Cited By ~ 4

Author(s):

Zhen Chen ◽

Ming Zeng

Keyword(s):

Design Method ◽

Bevel Gear ◽

Transmission Mechanism ◽

Tooth Surface ◽

Design Parameters ◽

Spiral Bevel Gear ◽

Bevel Gears ◽

Gear Mechanism ◽

Active Design ◽

Spiral Bevel

In this paper, an active design method of meshing line for a spiral bevel gear mechanism with nonrelative sliding is presented. First, the general meshing line equations for a nonrelative sliding transmission mechanism between two orthogonal axes are proposed based on the active design parameters. Then, parametric equations for contact curves on the drive and driven spiral bevel gears are deduced by coordinate transformation of the meshing line equations. Further to this, parametric equations for the tooth surface of each bevel gear are derived according to the conical spiral motion of a generatrix circle along the calculated contact curves. Finally, a set of numerical examples is presented based on two types of motion equation of the meshing points. Material prototypes are fabricated and experimentally tested to validate the kinematic performance of the functionally designed spiral bevel gear set.

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