Circular & Total Runout

Geometric Tolerancing Geometric Tolerancing is used to specify the shape of features. Things like: •Straightness •Flatness •Circularity •Cylindricity •Angularity •Profiles •Perpendicularity •Parallelism •Concentricity •And More... Geometric Tolerances are shown on a drawing with a feature control frame. Runout is specified on cylindrical parts. It is measured by placing a gage on the part, and rotating the part through 360 degrees. The total variation is recorded as the runout. • Circular runout is measured at one location. • Total Runout is measured along the entire specified surface. Principles of Engineering Drawing Thayer Machine Shop

Gear Types

The most common types of gears are illustrated in Figs. 5.16 to 5.25. Other available types are generally modifications of the basic gears shown. Gear nomenclature and definitions can be found in ANSI/AGMA 1012-F90, Gear Nomenclature, Definitions of Terms with Symbols.1 Spur gears A spur gear has a cylindrical pitch surface and teeth that are parallel to the axis. Spur gears operate on parallel axes (Fig. 5.16). Spur rack A spur rack has a plane pitch surface and straight teeth that are at right angles to the direction of motion (Fig. 5.16). Helical gears A helical gear has a cylindrical pitch surface and teeth that are helical. Parallel helical gears operate on parallel axes. Mating external helical gears on parallel axes have helices of opposite hands. If one of the mating members is an internal gear, the helices are of the same hand (Fig. 5.17). Single-helical gears Gears have teeth of only one hand on each gear (Fig. 5.18). Double-helical gears Gears have both right-hand and left-hand teeth on each gear. The teeth are separated by a gap between the helices (Fig. 5.19).Where there is no gap, they are known as herringbone gears. Wormgearing Includes worms and their mating gears. The axes are usually at right angles (Fig. 5.20). Wormgear (wormwheel) The gear that is the mate to a worm. A wormgear that is completely conjugate to its worm has a line contact and is said to be enveloping. An involute spur gear or helical gear used with a cylindrical worm has point contact only and is said to be nonenveloping (Fig. 5.20). Cylindrical worm A worm that has one or more teeth in the form of screw threads on a cylinder. Enveloping worm (hourglass) A worm that has one or more teeth and increases in diameter from its middle portion toward both ends, conforming to the curvature of the gear (Fig. 5.20). Double-enveloping wormgearing This is comprised of enveloping (hourglass) worms mated with fully enveloping wormgears (Fig. 5.21). Bevel gears These are gears that have conical pitch surfaces and operate on intersecting axes that are usually at right angles (Fig. 5.22). Miter gears These are mating bevel gears with equal numbers of teeth and with axes at right angles (Fig. 5.23). Straight bevel gears These have straight tooth elements which, if extended, would pass through the point of intersection of their axes (Fig. 5.24). Spiral bevel gears These have teeth that are curved and oblique (Fig. 5.24). Hypoid gears Similar in general form to bevel gears, hypoid gears operate on nonintersecting axes (Fig. 5.25). 

Standard Handbook of Plant Engineering (3rd Edition)

By: Rosaler, Robert © 2002 McGraw-Hill
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