JP2007192352A - Silent chain - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To regulate bending of link plates to the back face side, without increasing abrasion of a pin hole of the link plates, in a chain of a locker pin structure. <P>SOLUTION: This silent chain 1 is constituted by respectively pivotally connecting these link plates by a pivot member 3 by laminating a large number of link plates 2 having a pair of tooth parts 21 and pin holes 22 in the thickness direction and the longitudinal direction. The pivot member 3 is composed of a pair of locker pins 31. The respective locker pins 31 have respectively a mutually rolling rolling surface 31a and a holding surface 31b formed on the inverse side of this surface. The respective locket pins 31 are attached with a retaining ring member 4 as a regulating member regulating rolling of the respective locked pins 31 from the holding surface 31b side when the link plates 2 bend to the back face side, while allowing the rolling of the respective locker pins 31 when the link plates 2 bend to the meshing side. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a silent chain having a rocker pin structure, and more particularly to an improvement in a structure for restricting bending of a link plate to the back side.

  Silent chains are used as timing chains for automobiles and motorcycles. In general, a silent chain is configured such that a large number of link plates each having a pair of teeth and a pin hole are pivotally connected to each other by a rocker joint composed of a pair of long and short joint pins and a rocker pin inserted into each pin hole. It is comprised by. The end of the longer joint pin of the rocker joint is fixed to the outermost guide plate of the silent chain.

  When such a silent chain is operated, the link plate in the linear span of the silent chain bends to the back side, which may cause the vertical movement of the string to vibrate in a direction perpendicular to the span. is there. Since such a vertical movement of the string generates noise, an improvement for restricting the bending of the link plate to the back side has been conventionally performed.

  In the one disclosed in Japanese Patent Laid-Open No. 63-219942, a rod-shaped elastic member is inserted into the lower gap of the two upper and lower gaps formed by the rolling surfaces of the rocker pin and the joint pin in the pin hole. Has been.

  In this case, when the link plate of the silent chain tries to bend to the back side, the rocker pin and the joint pin roll on each other on the rolling surface, and the lower gap between the rocker pin and the joint pin becomes narrow. At this time, the rolling surfaces of the rocker pins and the joint pins are brought into pressure contact with the elastic member inserted into the lower gap, whereby the rolling of each pin is regulated.

However, in the above-mentioned publication, when each rolling contact surface of the rocker pin and the joint pin comes into pressure contact with the elastic member, a pressing force acts in a direction in which each pin pushes the pin hole. There is a risk of increased wear.
JP 63-219942 A (see FIG. 1)

  The present invention has been made in view of such a conventional situation, and the problem to be solved by the present invention is to silently control the bending of the link plate to the back side without increasing the wear of the pin holes. The point is to provide a chain.

  The silent chain according to the invention of claim 1 is connected to each other so as to be pivotally supported by a pivot member in which a plurality of link plates having tooth portions and pin holes are laminated in the thickness direction and the longitudinal direction and inserted into each pin hole. In the silent chain, the pivot member is composed of a pair of rocker pins, and each rocker pin has a rolling surface that rolls on each other and a holding surface that is formed on the opposite side of the rolling surface. ing. Each rocker pin regulates rolling of each rocker pin from the holding surface side when the link plate is bent to the back side while allowing the rocker pin to roll when the link plate is bent to the meshing side. A regulating member is provided.

  According to the invention of claim 1, since the regulating member that regulates the rolling of each rocker pin when the link plate is bent to the back side is provided so as to regulate from the holding surface side of each rocker pin, When the restricting member acts, the pressing force is not applied in the direction in which the rocker pin pushes the pin hole. Thereby, the bending to the back side of a link plate can be controlled, without increasing abrasion of a pin hole.

  In the invention of claim 2, the restricting member is a retaining ring member attached to an outer peripheral groove formed on the outer periphery of the rocker pin on the holding surface side, and each rocker pin is bent when the link plate is bent to the back side. The rolling of each rocker pin is regulated by pressing against the outer peripheral groove of the rocker.

  In this case, since the restricting member that restricts the rolling of each rocker pin when the link plate bends to the back side is constituted by a retaining ring member attached to the outer peripheral groove of each rocker pin, Installation becomes easy and the assembly of the silent chain becomes easy. Further, in this case, when the outer peripheral groove of each rocker pin presses against the retaining ring member as the link plate tries to bend to the back side, the retaining ring member elastically receives the pressing force from each rocker pin. Thereby, it can prevent that an excessive twist acts on each rocker pin.

  In the invention of claim 3, the inner peripheral surface of the retaining ring member has a shape along the outer peripheral groove of each rocker pin.

  In this case, when the retaining ring member presses against the outer peripheral groove of each rocker pin as the link plate tries to bend to the back side, the pressing reaction force from the retaining ring member can be received by the entire outer circumferential groove. It is possible to prevent an excessive pressing reaction force from acting locally on each rocker pin.

  In the invention of claim 4, in a state where the silent chain is linearly extended, in a region below the contact point of each rocker pin between the inner peripheral surface of the retaining ring member and the outer peripheral groove of each rocker pin. A void is formed.

  In this case, due to the gap formed between the retaining ring member and the rocker pin, each rocker pin can roll more smoothly when the link plate is bent toward the meshing side.

  As described in the invention of claim 5, the inner peripheral surface of the retaining ring member may have a substantially elliptical shape.

  In the invention of claim 6, when the link plate bends to the back side, the pressing force of each rocker pin acts in the direction of expanding the opening portion of the retaining ring member.

  In this case, when the link plate is bent to the back side and each rocker pin is pressed against the retaining ring member, the retaining ring member is elastically deformed so as to expand the opening portion, so that an excessive twist is applied to each rocker pin. Can be reliably prevented from acting.

  In the invention of claim 7, the restricting member is a retaining ring member that is attached to an outer circumferential groove formed on the outer periphery of the holding surface side of the rocker pin, the outer circumferential groove has a step portion, and the retaining ring member is The retaining ring member has an engaging projection that can engage with the stepped portion, and the retaining ring member engages with the stepped portion of the outer peripheral groove of each rocker pin when the link plate is bent to the back side. This restricts the rolling of each rocker pin.

  In this case, since the restricting member that restricts the rolling of each rocker pin when the link plate bends to the back side is constituted by a retaining ring member attached to the outer peripheral groove of each rocker pin, Installation becomes easy and the assembly of the silent chain becomes easy. In this case, when the link plate bends to the back side, the engaging projection of the retaining ring member engages with the stepped portion of the outer peripheral groove of each rocker pin, so that the pressing force from each rocker pin is increased. Take it elastically. Thereby, it can prevent that an excessive twist acts on each rocker pin.

  In the invention of claim 8, when the link plate bends to the back side, the pressing force of each rocker pin acts in the direction of narrowing the opening portion of the retaining ring member.

  In this case, when the link plate is bent to the back side and the stepped portion of each rocker pin is pressed against the engaging projection of the retaining ring member, the retaining ring member is elastically deformed to push and narrow the opening. Thus, it is possible to reliably prevent an excessive twist from acting on each rocker pin.

  In the invention of claim 9, the outer peripheral groove is formed at the end of the rocker pin outside the outermost link plate of the silent chain, and the retaining ring member is arranged at the end of the rocker pin.

  In this case, the retaining ring member can prevent the rocker pin from coming off. In this case, since each rocker pin extends to the outside of the outermost link plate, the tensile load due to the chain tension can be shared by both rocker pins, thereby improving the load sharing of the pins. . On the other hand, in the case of a conventional rocker joint structure comprising a pair of long and short joint pins and rocker pins, the tip of the longer joint pin at the boundary between the outermost link plate and the outer guide plate The joint pin bears the tensile load due to the chain tension only, and the joint pin may bend and deform.

  In the invention of claim 10, the outer peripheral groove is formed in the rocker pin inside the silent chain, and the retaining ring member is arranged inside the silent chain.

  According to the silent chain according to the present invention, the restriction member that restricts the rolling of each rocker pin when the link plate is bent to the back side is provided so as to restrict from the holding surface side of each rocker pin. When this occurs, the rocker pin does not exert a pressing force in the direction of expanding the pin hole, and this can restrict the bending of the link plate to the back side without increasing the wear of the pin hole. There is.

<Example 1>
FIGS. 1 to 7 are views for explaining a silent chain according to a first embodiment of the present invention. FIG. 1 is a front partial view showing a state in which the silent chain is linearly extended. FIG. 3 is a partially enlarged perspective view, FIG. 3 is a front partial view of the rocker pin, FIG. 4 is a sectional view taken along line IV-IV in FIG. 3, FIG. 5 is a transverse sectional enlarged view of the rocker pin portion in FIG. FIG. 7 is a cross-sectional enlarged view of the rocker pin portion in FIG. 6.

  As shown in FIG. 1, the silent chain 1 is formed by laminating a number of link plates 2 having a pair of teeth 21 and pin holes 22 in the thickness direction (perpendicular to the paper surface in the figure) and the longitudinal direction (the left-right direction in the figure). Each of the pin holes 22 is connected by a pivot member 3 so as to be pivotally supported.

  Each tooth portion 21 includes an inner flank surface 21a and an outer flank surface 21b. The pin hole 22 is formed in a substantially circular shape or a substantially long hole shape extending in the lateral direction, and has a sheet surface 22a on the end side of the link plate. The pivot member 3 is composed of a pair of rocker pins 31. Each rocker pin 31 has a rolling surface 31a that rolls on each other and a holding surface 31b that is formed on the opposite side of the rolling surface 31a. The holding surface 31 b is engaged with the sheet surface 22 a of the pin hole 22. Each rocker pin 31 extends to the outside of the outermost link plate 2 and has an equivalent length (see FIG. 2).

  As shown in FIGS. 3 and 4, an outer peripheral groove 31 c that extends in a generally arc shape or an elliptic shape is formed on the outer peripheral surface on the holding surface 31 b side at the end of each rocker pin 31. As shown in FIGS. 1 and 2, a retaining ring member 4 as a regulating member is attached to each outer peripheral groove 31 c of each rocker pin 31.

  The retaining ring member 4 is disposed outside the outermost link plate 2. As shown in FIG. 5, the retaining ring member 4 includes a ring-shaped portion 40 and a pair of operation portions 41 for expanding the diameter thereof. The ring-shaped part 40 is formed in a substantially elliptical shape extending in the vertical direction (vertical direction in FIG. 1). The substantially elliptical inner peripheral surface 40a of the ring-shaped portion 40 is disposed along the outer peripheral groove 31c of the rocker pin 31, and allows the rocker pins 31 to roll when the link plate 2 bends to the meshing side. However, it is provided so as to restrict rolling of each rocker pin 31 when the link plate 2 bends to the back side from the holding surface 31b side.

  As shown in FIG. 5, in a state where the silent chain 1 is linearly extended, it is preferable that the ring-shaped portion 40 of the retaining ring member 4 does not apply a pressing force to the rocker pin 31. That is, it is preferable that the deformation amount of the ring-shaped portion 40 of the retaining ring member 4 is zero when the retaining ring member 4 is attached to the outer peripheral groove 31c of the rocker pin 31 in a state where the silent chain 1 is linearly extended. . Each operation portion 41 of the retaining ring member 4 has a locking hole 41a for inserting and locking the tool.

  More preferably, as shown in FIG. 5, each rocker between the inner circumferential surface 40 a of the retaining ring member 4 and the outer circumferential groove 31 c of each rocker pin 31 in a state where the silent chain 1 is linearly extended. A gap e is formed in a region below the contact point C of each rolling surface 31a of the pin 31.

Next, the function and effect of this embodiment will be described.
As shown in FIG. 1, when each link plate 2 is bent to the meshing side from a state where the silent chain 1 is linearly extended, each rocker pin 31 rolls on each rolling surface 31 a and each rocker pin 31. The point of contact moves upward from point C in FIG. 5, and each rocker pin 31 attempts to move to the “C” -shaped arrangement. In this case, since the gap e is formed in the region below the contact point C between each outer peripheral groove 31c of each rocker pin 31 and the inner peripheral surface 40a of the ring-shaped portion 40 of the retaining ring member 4, Each rocker pin 31 moves so as to fill the gap e. Thereby, when the link plate 2 bends to the meshing side, the rolling of each rocker pin 31 is not restricted by the inner peripheral surface 40a of the retaining ring member 4, and the rolling of each rocker pin 31 is smooth. Done.

  Next, when each link plate 2 bends to the back side as shown in FIG. 6, each rocker pin 31 rolls in a direction opposite to that at the time of meshing, and as shown in FIG. 7, each rocker pin 31. Tries to move to an inverted “C” shaped arrangement. As a result, the contact point of each rocker pin 31 moves from the point C in FIG. 5 to the lower point C ′.

  At this time, each outer peripheral groove 31 c of each rocker pin 31 is in pressure contact with the inner peripheral surface 40 a of the ring-shaped portion 40 of the retaining ring member 4, so that the opening between the operation portions 41 of the retaining ring member 4 is expanded. Power is applied. FIG. 7 shows a state where the diameter of the ring-shaped portion 40 of the retaining ring member 4 is expanded and the opening between the operation portions 41 is expanded. At this time, the elastic repulsion force due to the elastic deformation of the ring-shaped portion 40 acts on each rocker pin 31, and the rolling of each rocker pin 31 is restricted.

  In this way, the retaining ring member 4 restricts the bending of the link plate 2 to the back side from the holding surface 31b side of each rocker pin 31, so that when the link plate 2 is bent to the back side, the rocker The pressing force is not applied in the direction in which the pin 31 pushes the pin hole 22 apart. Thereby, the bending to the back side of the link plate 2 can be regulated without increasing the wear of the pin hole 22, and the vertical movement of the string of the chain can be prevented.

  In this case, the retaining ring member 4 is disposed at the end of the rocker pin 31, so that the retaining ring member 4 can prevent the rocker pin 31 from coming off. Furthermore, in this case, since each rocker pin 31 extends to the outside of the outermost link plate 2, the tensile load due to the chain tension can be shared by both rocker pins 31. Sharing can be improved. On the other hand, in the case of a conventional rocker joint structure comprising a pair of long and short joint pins and rocker pins, the tip of the longer joint pin at the boundary between the outermost link plate and the outer guide plate The joint pin only bears the tensile load due to the chain tension, and the joint pin may bend and deform.

<Example 2>
FIGS. 8 to 13 are views for explaining a silent chain according to a second embodiment of the present invention. FIG. 8 is a partially enlarged perspective view of the silent chain extended linearly, and FIG. 9 is a rocker. FIG. 10 is a cross-sectional view taken along line XX of FIG. 9, FIG. 11 is an enlarged cross-sectional view of the rocker pin portion in FIG. 8, and FIG. 12 is a cross-sectional view of the rocker pin portion with the silent chain bent to the meshing side. FIG. 13 is an enlarged cross-sectional view of the rocker pin portion in a state where the silent chain is bent to the back side. In these drawings, the same reference numerals as those in the first embodiment denote the same or corresponding parts.

  In this second embodiment, as shown in FIG. 9 and FIG. 10, the outer peripheral groove 31 c formed in the outer peripheral surface on the holding surface 31 b side at the end of each rocker pin 31 is stepped. The point which has the part 31d differs from the said 1st Example. Further, as shown in FIGS. 8 and 11, an engagement protrusion 41 ′ that engages with the step portion 31 d of the rocker pin 31 is provided in the substantially C-shaped retaining ring member 4 ′ attached to the outer circumferential groove 31 c. It has been. The inner peripheral surface 40 ′ a of the retaining ring member 4 ′ is disposed along the outer peripheral groove 31 c of the rocker pin 31.

  As with the retaining ring member 4, the retaining ring member 4 ′ allows each rocker pin 31 to roll when the link plate 2 bends to the meshing side, and allows each of the link plate 2 to bend to the back side. The rocker pin 31 is provided so as to restrict the rolling of the rocker pin 31 from the holding surface 31b side, but here, the engaging projection 41 ′ of the retaining ring member 4 ′ is engaged with the step portion 31d of the rocker pin 31. However, the point that restricts the rolling of the rocker pin 31 is different from the first embodiment.

  As shown in FIG. 11, in the state where the silent chain 1 is linearly extended, the inner peripheral surface 40 ′ a and the engaging protrusion 41 ′ of the retaining ring member 4 ′ are respectively the outer peripheral groove 31 c and the step difference of the rocker pin 31. It is preferable that no pressing force is applied to the portion 31d. That is, it is preferable that the amount of deformation of the retaining ring member 4 ′ is zero when the retaining ring member 4 ′ is attached to the outer peripheral groove 31 c of the rocker pin 31 with the silent chain 1 extending linearly.

  More preferably, as shown in FIG. 11, in a state where the silent chain 1 is linearly extended, between the engaging projection 41 ′ of the retaining ring member 4 ′ and the stepped portion 31 d of each rocker pin 31. No gap is formed, and the engaging protrusion 41 ′ is in contact with the step portion 31d.

Next, the function and effect of this embodiment will be described.
As shown in FIGS. 8 and 11, when each link plate 2 is bent to the meshing side from the state where the silent chain 1 is extended linearly, each rocker pin 31 rolls on each rolling surface 31a, The contact point of the rocker pin 31 moves from the point C in FIG. 11 to the upper point C ₁ (FIG. 12), and each rocker pin 31 moves to the “C” -shaped arrangement. As a result, a gap e ′ is formed between the stepped portion 31d of the rocker pin 31 and the engaging projection 41 ′ of the retaining ring member 4 ′. In this case, when the link plate 2 bends to the meshing side, the rolling of each rocker pin 31 is not restricted by the retaining ring member 4 ′, and the rolling of each rocker pin 31 is performed smoothly. .

Next, when each link plate 2 bends to the back side, each rocker pin 31 rolls in a direction opposite to that at the time of meshing, and as shown in FIG. Try to move to a letter-shaped arrangement. As a result, the contact points of the rocker pin 31 moves from point C in FIG. 11 at a point C ₂ lower.

  At this time, each step portion 31d of each rocker pin 31 is in pressure contact with each engaging projection 41 ′ of the retaining ring member 4 ′, and a force is applied in a direction to push and narrow the opening of the retaining ring member 4 ′. . At this time, an elastic repulsion force due to elastic deformation of the retaining ring member 4 ′ acts on each step portion 31 d of each rocker pin 31, thereby restricting rolling of each rocker pin 31.

  In this way, the retaining ring member 4 'regulates the bending of the link plate 2 to the back side from the holding surface 31b side of each rocker pin 31, so when the link plate 2 is bent to the back side, The rocker pin 31 does not apply a pressing force in the direction in which the pin hole 22 is expanded. Thereby, the bending to the back side of the link plate 2 can be regulated without increasing the wear of the pin hole 22, and the vertical movement of the string of the chain can be prevented.

  In this case, the retaining ring member 4 ′ is disposed at the end of the rocker pin 31, so that the retaining ring member 4 ′ can prevent the rocker pin 31 from coming off. Furthermore, in this case, since each rocker pin 31 extends to the outside of the outermost link plate 2, the tensile load due to the chain tension can be shared by both rocker pins 31. Sharing can be improved.

  In the first and second embodiments, the example in which the outer peripheral groove 31c of the rocker pin 31 is formed at the end of the rocker pin 31 is shown, but the application of the present invention is not limited to this. The outer peripheral groove 31 c may be formed at a position near the center in the longitudinal direction of the rocker pin 31. In this case, the retaining ring member is disposed inside the silent chain.

It is a front fragmentary view of the state where the silent chain by the 1st example of the present invention was extended straight. FIG. 2 is a partially enlarged perspective view of FIG. 1. It is a front fragmentary view of a rocker pin. FIG. 4 is a sectional view taken along line IV-IV in FIG. 3. It is a cross-sectional enlarged view of the rocker pin part in FIG. It is a front fragmentary view of the state where the silent chain is bent to the back side. It is a cross-sectional enlarged view of the rocker pin part in FIG. It is a partially expanded perspective view of the state where the silent chain according to the second embodiment of the present invention is extended linearly. FIG. 9 is a partial front view of the rocker pin. FIG. 10 is a sectional view taken along line XX in FIG. 9. It is a cross-sectional enlarged view of the rocker pin part in FIG. It is a cross-sectional enlarged view of a rocker pin part in a state where the silent chain is bent toward the meshing side. It is a cross-sectional enlarged view of a rocker pin part in a state where the silent chain is bent to the back side.

Explanation of symbols

1: Silent chain

2: Link plate 21: Tooth part 22: Pin hole

3: Pivoting member 31: Rocker pin 31a: Rolling surface 31b: Holding surface 31c: Peripheral groove 31d: Stepped portion

4, 4 ': Retaining ring (regulating member)
40a, 40′a: inner peripheral surface 41 ′: engagement protrusion

e: Air gap

Claims (10)

In the silent chain formed by laminating a large number of link plates having tooth portions and pin holes in the thickness direction and the longitudinal direction, and pivotally connected by pivot members inserted into the respective pin holes,
The pivot member is composed of a pair of rocker pins, and each rocker pin has a rolling surface that rolls on each other and a holding surface that is formed on the opposite side of the rolling surface. And
The rocker pins allow the rocker pins to roll when the link plate is bent to the back side while allowing the rocker pins to roll when the link plate is bent to the meshing side. A regulating member that regulates from the holding surface side is provided,
Silent chain characterized by that. In claim 1,
The regulating member is a retaining ring member that is attached to an outer circumferential groove formed on an outer circumference of the rocker pin on the holding surface side, and the outer circumference of each rocker pin when the link plate is bent to the back side. The rolling of each rocker pin is regulated by being pressed against the groove,
Silent chain characterized by that. In claim 2,
The inner peripheral surface of the retaining ring member has a shape along the outer peripheral groove of each rocker pin.
Silent chain characterized by that. In claim 3,
In a state where the silent chain is linearly extended, a gap is formed in a region below the contact point of each rocker pin between the inner circumferential surface of the retaining ring member and the outer circumferential groove of each rocker pin. Formed,
Silent chain characterized by that. In claim 2,
The inner peripheral surface of the retaining ring member has a substantially elliptical shape,
Silent chain characterized by that. In claim 2,
When the link plate bends to the back side, the pressing force of each rocker pin acts in the direction of expanding the opening portion of the retaining ring member,
Silent chain characterized by that. In claim 1,
The regulating member is a retaining ring member that is attached to an outer circumferential groove formed on an outer circumference of the rocker pin on the holding surface side, and the outer circumferential groove has a step portion, and the retaining ring member is the step portion. The retaining ring member has a stepped portion in the outer peripheral groove of each rocker pin when the link plate is bent to the back side. The rolling of each rocker pin is regulated by engaging with
Silent chain characterized by that. In claim 7,
When the link plate bends to the back side, the pressing force of each rocker pin acts in the direction of narrowing the opening portion of the retaining ring member,
Silent chain characterized by that. In claim 2 or 7,
The outer circumferential groove is formed at the end of the rocker pin outside the outermost link plate of the silent chain, and the retaining ring member is disposed at the end of the rocker pin.
Silent chain characterized by that. In claim 2 or 7,
The outer peripheral groove is formed in the rocker pin inside the silent chain, and the retaining ring member is arranged inside the silent chain.
Silent chain characterized by that.

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