Endless belt power transmission systems or components – Positive drive pulley or guide roll – With particular belt
Reexamination Certificate
2001-03-30
2003-06-10
Joyce, William C (Department: 3682)
Endless belt power transmission systems or components
Positive drive pulley or guide roll
With particular belt
C474S152000, C474S213000
Reexamination Certificate
active
06575861
ABSTRACT:
CROSS-REFERENCE TO RELATED APPLICATIONS
Not applicable.
STATEMENT REGARDING FEDERALLY SPONSORED RESEARCH OF DEVELOPMENT
Not applicable.
BACKGROUND OF THE INVENTION
A power transmission chain transmits power from a driving sprocket to one or more driven sprockets by forming an endless loop that partially wraps and engages the teeth of sprockets. Rotation of the driving sprocket moves the chain thereby transmitting power through the chain to rotate the driven sprockets engaged by the chain. Power transmission chains are widely used in the automotive industry. In an engine timing application, a chain transmits power from at least one driving sprocket positioned on a crankshaft to at least one driven sprocket positioned on a camshaft. Other automotive applications include, transmitting power from a torque converter to a transmission and transmitting power in the transfer case of a four wheel drive vehicle. Power transmission chains are also widely used in industrial applications.
One type of power transmission chain is known as a “silent chain.” A typical silent chain comprises links that are adjacent to each other along the chain. Each link conventionally forms two teeth that are adjacent to each other along a chain direction of the link, that extend in a front direction that is perpendicular to the chain direction, and that are formed to engage the teeth of a sprocket. Links of a silent chain also conventionally form two apertures, one near each end of the link along the chain direction, that extend through the link in a lateral direction that is perpendicular to the chain direction and perpendicular to the front direction of the link. The links of a silent chain are typically formed by a row of substantially identical flat links, each forming teeth and apertures as described, that are positioned laterally adjacent to each other to collectively form a link of the chain.
A silent chain is formed by positioning rows of flat links adjacent to each other and partially overlapping along the chain directions of adjacent chain links so that apertures at adjacent ends of links are aligned. Pivots, such as pins, extend through the aligned apertures to pivotally join adjacent links. Rows of links are joined in this manner to form an endless loop in which the front direction of the links, the direction that the teeth extend from the chain links, is directed toward the region within the endless loop formed by the chain. Links having teeth extending into the region within the loop are referred to as inverted tooth links. The inner surface of the chain, along which the teeth extend, is referred to as the front side of the chain. The surface of the chain opposite the front side facing outwardly from the region within the endless loop is the back side of the chain.
The inverted tooth links (sometimes referred to as driving links) transfer power between the chain and sprocket along the chain direction. Each tooth of a link defines an inside flank that faces generally along the chain direction toward the adjacent tooth of the link, and an outside flank that faces away from the inside flank of the tooth. The inside flanks of the teeth of an inverted tooth link meet at a crotch between the teeth. The teeth of a link may contact sprocket teeth along their inside flanks or along their outside flanks, or along both flanks. The contact between a link tooth flank and a sprocket tooth may transfer power or may be an incidental contact. An inverted tooth link conventionally may contact a sprocket on a side of a sprocket tooth or at a root between adjacent sprocket teeth.
A row of inverted tooth links is positioned on a sprocket by contact with three sprocket teeth, one at each end of the row along the chain direction, and one between the teeth of the links of that row. A row of links is positioned at each location by contact with the sprocket by the teeth of the links comprising the row contacting the sprocket, by the adjacent teeth of the links of the adjacent rows, or by both. Contact with the sprocket at three locations along the chain direction of the row links limits motion of the row of links on the sprocket.
Silent chains often include guide links. Guide links are conventionally flat plates that are positioned on the lateral outside edges of alternate rows of inverted tooth links. The guide links do not form teeth, but generally extend along the row of links and adjacent to the region between teeth formed by the row of links. The guide links on opposite lateral sides of a row are separated by approximately the lateral width of the sprocket teeth that extend between the teeth of the row of links. The guide links thereby act to position the chain laterally on a sprocket (i.e., maintain the chain on the center of the sprocket) but do not engage a sprocket between teeth of the sprocket.
A conventional silent chain drive is comprised of an endless loop silent chain that wraps at least two sprockets. Each sprocket is mounted to a shaft. Rotation of the shaft on which the driving sprocket is mounted transmits power from the driving sprocket through the chain to rotate a driven sprocket and the shaft to which the driven sprocket is mounted.
FIG. 1
a
illustrates such a basic arrangement. A chain
3
forms an endless loop and partially wraps driving sprocket
1
and driven sprocket
2
that are within the loop. A front side
4
of the chain
3
is adjacent to the region within the endless loop formed by the chain
3
. Teeth extend inwardly along the front side
4
to engage teeth of both the driving sprocket
1
and the driven sprocket
2
. The back side
5
of the chain
3
is the side of the chain opposite the front side
4
and faces outwardly from the chain loop. Both the driving sprocket
1
and the driven sprocket
2
rotate in the same direction, shown counter-clockwise by
FIG. 1
a.
Silent chains may also drive sprockets that engage the back side of the chain. Examples of devices that are driven by the back side of a silent chain (back-driven) include water pumps, injector pumps, and countershafts.
FIG. 1
b
shows a sprocket
6
that is back-driven by the chain
3
. As in
FIG. 1
a,
a driven sprocket
2
engages the teeth on the front side
4
of the chain
3
and rotates in the same direction as the driving sprocket, counter-clockwise in
FIG. 1
b.
Teeth of the back-driven sprocket
6
engage the back side
5
of the chain
3
. The back-driven sprocket
6
rotates in the opposite direction of the driven sprocket
2
.
Often, the back side of the links of a chain that engages and drives a sprocket is configured to engage a sprocket as a single tooth between two adjacent sprocket teeth. The teeth of sprockets engaged by the back side of such links are spaced apart by the length of the chain link. Consequently, these sprockets engage a chain link in fewer and farther separated locations than do front driven sprockets. This results in a lower capacity for power transmission by back-driven sprockets. The lower power transmission capacity is acceptable because back-driven sprockets are frequently located in the slack region of the chain and/or are not required to transmit forces that are as large as can be transmitted by the front side of the silent chain. The fewer and more separated contact locations do not control motion of the chain on the sprocket as does contact with a front driven sprocket.
Noise can be generated by a variety of sources in silent chain drives. One significant source of noise is the impact of sprocket teeth on chain teeth at the onset of engagement of the sprocket by the chain teeth. Among the factors that affect the level of the noise created by impact are the impact velocity between the chain and the sprocket and the mass of chain links contacting the sprocket. Noise created by engaging impact in silent chain drives is generally periodic with a frequency generally corresponding to the frequency of the chain teeth engaging sprocket teeth. This frequency is related to the number of teeth on the sprocket and the speed of the sprocket. The impacts can produce sound having object
Markley George L.
Wigsten Mark MacDonald
Borg-Warner Inc.
Dziegielweski Greg
Joyce William C
McAndrews Held & Malloy Ltd.
McAnulty Timothy
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