Book contents
- Frontmatter
- Contents
- Foreword by Graziano Curti
- Preface
- Acknowledgments
- 1 Coordinate Transformation
- 2 Relative Velocity
- 3 Centrodes, Axodes, and Operating Pitch Surfaces
- 4 Planar Curves
- 5 Surfaces
- 6 Conjugated Surfaces and Curves
- 7 Curvatures of Surfaces and Curves
- 8 Mating Surfaces: Curvature Relations, Contact Ellipse
- 9 Computerized Simulation of Meshing and Contact
- 10 Spur Involute Gears
- 11 Internal Involute Gears
- 12 Noncircular Gears
- 13 Cycloidal Gearing
- 14 Involute Helical Gears with Parallel Axes
- 15 Modified Involute Gears
- 16 Involute Helical Gears with Crossed Axes
- 17 New Version of Novikov–Wildhaber Helical Gears
- 18 Face-Gear Drives
- 19 Worm-Gear Drives with Cylindrical Worms
- 20 Double-Enveloping Worm-Gear Drives
- 21 Spiral Bevel Gears
- 22 Hypoid Gear Drives
- 23 Planetary Gear Trains
- 24 Generation of Helicoids
- 25 Design of Flyblades
- 26 Generation of Surfaces by CNC Machines
- 27 Overwire (Ball) Measurement
- 28 Minimization of Deviations of Gear Real Tooth Surfaces
- References
- Index
16 - Involute Helical Gears with Crossed Axes
Published online by Cambridge University Press: 04 September 2009
- Frontmatter
- Contents
- Foreword by Graziano Curti
- Preface
- Acknowledgments
- 1 Coordinate Transformation
- 2 Relative Velocity
- 3 Centrodes, Axodes, and Operating Pitch Surfaces
- 4 Planar Curves
- 5 Surfaces
- 6 Conjugated Surfaces and Curves
- 7 Curvatures of Surfaces and Curves
- 8 Mating Surfaces: Curvature Relations, Contact Ellipse
- 9 Computerized Simulation of Meshing and Contact
- 10 Spur Involute Gears
- 11 Internal Involute Gears
- 12 Noncircular Gears
- 13 Cycloidal Gearing
- 14 Involute Helical Gears with Parallel Axes
- 15 Modified Involute Gears
- 16 Involute Helical Gears with Crossed Axes
- 17 New Version of Novikov–Wildhaber Helical Gears
- 18 Face-Gear Drives
- 19 Worm-Gear Drives with Cylindrical Worms
- 20 Double-Enveloping Worm-Gear Drives
- 21 Spiral Bevel Gears
- 22 Hypoid Gear Drives
- 23 Planetary Gear Trains
- 24 Generation of Helicoids
- 25 Design of Flyblades
- 26 Generation of Surfaces by CNC Machines
- 27 Overwire (Ball) Measurement
- 28 Minimization of Deviations of Gear Real Tooth Surfaces
- References
- Index
Summary
INTRODUCTION
Involute helical gears are widely applied in the industry for transformation of rotation between parallel and crossed axes. Figure 16.1.1 shows an involute helical gear drive with crossed axes in 3D-space. A gear drive formed by a helical gear and a worm gear is a particular case of a gear drive with crossed axes (Figure 16.1.2). Gear tooth surfaces are in line contact for involute helical gear drives with parallel axes and in point contact for involute helical gear drives with crossed axes.
The theory of involute gears and research in this area have been presented by Litvin [1968], Colbourne [1987], Townsend [1991], and Litvin et al. [1999, 2001a, 2001c, 2001d] and the theory of shaving and honing technological processes are discussed in the works of Townsend [1991] and Litvin et al. [2001a]. Despite the broad investigation that has been accomplished in this area, the quality of misaligned involute helical gear drives is still a concern of manufacturers and designers. The main defects of such misaligned gear drives are (i) appearance of edge contact, (ii) high levels of vibration, and (iii) the shift of the bearing contact far from the central location.
To overcome the defects mentioned above, some corrections of gear geometry have been applied in the past: (i) correction of the lead angle of the pinion (requires regrinding), and (ii) crowning in the areas of the tip of the profile and the edge of the teeth (based on the experience of manufacturers).
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- Chapter
- Information
- Gear Geometry and Applied Theory , pp. 441 - 474Publisher: Cambridge University PressPrint publication year: 2004