JP3503527B2 - Silent chain - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a silent chain used to form a part of a power transmission device.

[0002]

2. Description of the Related Art The basic structure of this type of silent chain is that a number of link plates forming a pair of teeth are arranged in the longitudinal direction and the plate thickness direction, respectively, and they are pins (connecting members). Is connected in a state of being relatively rotatable by, and is configured as an endless shape (annular shape) as a whole. Such a silent chain has a function of traveling while being wound around the driving side sprocket and the driven side sprocket and transmitting the torque of the driving side sprocket to the driven side sprocket.

In the meantime, in the region where the teeth of the link plate, which move sequentially, are separated from the driven side sprocket and mesh with the driving side sprocket during running of the silent chain, that is, in the span region, the natural frequency determined by the specifications of the silent chain. In many cases, string vibration occurs, which causes unpleasant noise.

An example of a silent chain capable of suppressing such string vibration is described in Japanese Patent Application Laid-Open No. 8-74939. The silent chain described in this publication has a link plate in which a pair of pin holes are formed, a connecting pin that is inserted into the pin hole to connect the link plates, and a guide plate that is arranged on the outermost side of the link plate. have. Further, a spring ring having a pair of pin holes is arranged between the guide plate and the link plate or between the adjacent link plates. A connecting pin is inserted into the pair of pin holes.

In the silent chain having the above-mentioned structure, the elastic force of the spring ring presses the link plates in the thickness direction, and the surface pressure of the contact portion between the link plates is increased. Then, when the silent chain travels, even if a force for rotating the link plates relative to each other is exerted in the span region, the relative rotation is increased because the frictional force of the contact surface between the link plates is increased. It is suppressed and the string vibration can be reduced.

[0006]

By the way, when the link plates located in the span region are sequentially meshed with the drive side sprockets during running of the silent chain, the moving direction of the link plates is changed from the straight direction to the sprocket. It switches to the direction (pseudo arc direction) along the outer shape of. In this way, when the moving direction of the link plates is switched, the adjacent link plates relatively rotate about the connecting pin.

However, in the silent chain described in the above publication, due to the elastic force of the spring ring,
The link plates are constantly pressed in the thickness direction, and the contact surface pressure between the link plates is increased. For this reason, a large frictional force is generated even when the link plates rotate relative to each other in the portion where the moving directions of the link plates are switched, and the relative rotation between the link plates is hindered. Therefore, the power loss may increase and the torque transmission efficiency of the silent chain may decrease.

The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a silent chain capable of suppressing string vibration without increasing power loss.

[0009]

In order to achieve the above object, the invention of claim 1 has a plurality of links each having a tooth portion meshed with a sprocket and having a pair of connecting holes. A plate and a connecting member that is inserted into a connecting hole of link plates that are overlapped in the thickness direction, and that connects the link plates in a relatively rotatable state to connect a number of link plates endlessly; A silent chain that is provided with a plurality of plate-shaped springs that apply a pressing force in the thickness direction to the link plate, and that travels in a state of being wound around a plurality of sprockets. However, it is said that a plurality of springs are arranged in the running direction of the silent chain so that they overlap each other in the projection plane in the thickness direction of each link plate. In the in the overlapping portion in the projection plane of each spring, the teeth of the link plates,
The pressing force applied to the link plate when the tooth portion of the link plate is engaged with the other sprocket is larger than the pressing force applied to the link plate during the time of separating from one sprocket and engaging with the other sprocket. It is characterized in that a pressing force control mechanism for controlling so as to be smaller is provided.

According to the first aspect of the present invention, when the silent chain travels, the link plates rotate relative to each other until the teeth of the link plates separate from one sprocket and mesh with the other sprocket. The frictional force when the force for rotating the link plates relative to each other when the tooth portion of the link plate meshes with the other sprocket is smaller than the frictional force when the force is applied.

According to a second aspect of the present invention, in addition to the structure of the first aspect, a pair of holes penetrating the spring in the thickness direction is formed, and the connecting member is inserted into the pair of holes, and The pressing force control mechanism includes a pressing portion formed in a straight line along the running direction of the silent chain.

According to the invention of claim 2, in addition to the same effect as in claim 1, when the tooth portions of the link plate mesh with the other sprocket, the link plates rotate relative to each other. The area in which the pressing portions that apply the pressing force in the thickness direction overlap each other in the projection plane in the thickness direction of each link plate decreases.

According to a third aspect of the present invention, in addition to the structure of the second aspect, the pressing portion is provided in a region passing along the running direction of the silent chain and passing through the pair of holes. To do.

According to the invention of claim 3, in addition to the same effect as in claim 2, the spring for applying a pressing force to the link plate whose tooth portion is separated from any sprocket is a plurality of springs. In the projection plane in the thickness direction of each link plate, the pressing portions have a maximum overlapping length in the running direction of the silent chain.

According to a fourth aspect of the present invention, in addition to the structure of the first aspect, there is a tooth portion meshed with the sprocket, and
A plurality of link plates that are inserted into the link holes of a plurality of link plates provided with a pair of link holes and the link plates that are stacked in the thickness direction, and that link plates are linked so that they can rotate relative to each other. And a plurality of plate-shaped springs that apply a pressing force in the thickness direction to the link plate, and a silent member that runs while being wound around a plurality of sprockets. In the chain, the plurality of springs are arranged in the running direction of the silent chain such that some of the plurality of springs overlap each other in the projection plane in the thickness direction of each link plate, and A pair of holes penetrating the spring in the thickness direction are formed at overlapping portions in the projection plane, and the connecting portion is formed in the pair of holes. Is inserted into the surface of the spring, the friction coefficient of the belt-shaped region passing through the pair of holes and along the running direction of the silent chain is the friction coefficient of the region other than the belt-shaped region. It is characterized by being set larger than.

According to the fourth aspect of the present invention, in the link plates positioned so that the tooth portion is separated from one sprocket and meshes with the other sprocket, within the projection plane in the thickness direction of each link plate. In the link plates where the teeth engage with the other sprocket and rotate relative to each other than the area where the belt-shaped regions having a large friction coefficient overlap each other, the belt-shaped regions having a large friction coefficient in the projection plane in the thickness direction of each link plate The overlapping area is smaller.

[0017]

BEST MODE FOR CARRYING OUT THE INVENTION Next, an embodiment of the present invention will be described with reference to the drawings. Figure 2 shows the chain drive mechanism unit K
FIG. 1 is a front view showing a chain drive mechanism unit K1 used for forming a part of various power transmission devices, for example, a transfer of a four-wheel drive vehicle or a camshaft of a vehicle engine. Used for drive mechanism. The chain drive mechanism unit K1 has a silent chain 1, a drive side sprocket 2 and a driven side sprocket 3 around which the silent chain 1 is wound.

FIG. 1 is a partial plan view of the silent chain 1, and FIG. 3 is a partial front view of the silent chain 1. The silent chain 1 has a plurality of link plates 4, and the front shape of each link plate 4 is set to a shape including two wedge-shaped tooth portions 5. On the base end side of the tooth portion 5 of each link plate 4,
Two connecting holes 6 are formed to penetrate the link plate 4 in the thickness direction. The front shape of the connecting hole 6 is substantially circular.

A large number of link plates 4 are arranged in the longitudinal direction and a large number in the thickness direction. Here, when the link plates 4 are arranged in the thickness direction thereof, the adjacent link plates 4 are arranged so as to be displaced by half in the longitudinal direction. And the connecting hole 6 of the link plates 4 adjacent to each other in the thickness direction
The link plates 4 are rotatably connected to each other by inserting the rocker pins 7 into the.

Guide plates 8 are arranged on the side surfaces of the link plates 4 arranged at both ends of each link plate 4 in the thickness direction. Further, two holes 9 penetrating the guide plate 8 in the thickness direction are formed, and the rocker pins 7 are inserted into the respective holes 9. Then, both ends of each rocker pin 7 in the longitudinal direction are subjected to crimping so that the rocker pin 7 does not drop from the connecting hole 6 and the hole 9. In this manner, by connecting the link plates 4 in the longitudinal direction and the thickness direction thereof, the endless (in other words, annular) silent chain 1 as shown in FIG. 2 is configured. Further, the tooth portions 5 of each link plate 4 are directed to the inner side of the silent chain 1, and the tooth portions 5 of the plurality of link plates 4 forming a part of the silent chain 1 are connected to the drive side sprocket 2 and the driven side. It is meshed with the sprocket 3.

Further, a disc spring 10 is arranged between the link plates 4 arranged adjacent to each other in the thickness direction. The disc spring 10 is formed of a material such as spring steel into a plate shape, and the disc spring 10 has a front shape similar to the link plate 4. As shown in FIG. 3, the area of the disc spring 10 on the projection plane of the link plate 4 in the thickness direction is set to be smaller than the area of the link plate 4.

FIG. 4 is a front view of the disc spring 10 before the silent chain 1 is assembled, and FIG.
6 is a sectional view taken along line VV of FIG.
It is a side surface sectional view in a line. The disc spring 10 has two teeth 11 protruding toward the inner side of the silent chain 1, and a pair of holes 12 is formed at the base end side of the two teeth 11 to penetrate the disc spring 10 in the thickness direction. Is formed. The front shape of the pair of holes 12 is substantially circular, and the inner diameter of the hole 12 and the inner diameter of the connecting hole 6 are set to be the same.

The disc spring 10 is connected to both sides of the strip-shaped piece 13 in the width direction of the strip-shaped piece 13 which passes through the centers of the pair of holes 12, and is inclined by a predetermined angle with respect to the strip-shaped piece 13. , 15 and. That is, the disc spring 10
As shown in Fig. 6, the cross-sectional shape of the side is almost "dogleg".
It is bent into. In other words, the disc spring 10
The silent chain 1 is bent in a plane (not shown) orthogonal to the traveling direction. In this way, the apparent bending rigidity of the disc spring 10 is enhanced. Each disc spring 10 is provided between the link plates 4 with the inclined pieces 14 and 15 oriented in the same direction. The pair of holes 12 are formed by the strip-shaped piece 13 and the inclined piece 1.
The tooth portion 11 is formed on one of the inclined pieces 15 and is arranged over four and fifteen. The tooth portion 11 is arranged toward the inside of the silent chain 1.

The disc springs 10 constructed as described above are assembled between the link plates 4 as shown in FIG. 1 in such a manner that a part of each disc spring 10 in the longitudinal direction is overlapped. The rocker pin 7 is inserted into each hole 12. Then, in a state where both ends of the rocker pin 7 are subjected to crimping, that is, in the assembled state of the silent chain 1, the planar shape of the disc spring 10 is substantially straight due to the assembling load. Therefore, the elastic force of the disc spring 10 acts on each link plate 4 in the thickness direction thereof.

Correspondence between the embodiment of the present invention and the configuration of the present invention will be described. That is, the drive side sprocket 2 corresponds to one sprocket of the present invention, the driven side sprocket 3 corresponds to the other sprocket of the present invention, the rocker pin 7 corresponds to the connecting member of the present invention, and the disc spring 10 corresponds to this. The strip 13 corresponds to the spring of the invention.
Corresponds to the pressing force control mechanism and the pressing portion of the present invention.

The chain drive mechanism unit K1 having the above structure
The operation of will be described. When the drive side sprocket 2 rotates counterclockwise in FIG. 2, the silent chain 1 travels (rotates) in the counterclockwise direction in FIG. 2, the torque of the drive side sprocket 2 is transmitted to the driven side sprocket 3, and the driven side sprocket 3 is driven. The side sprocket 3 rotates counterclockwise in FIG. Next, a specific operation of the silent chain 1 during traveling will be described.

First, in the area from the disengagement position A1 where the tooth portion 5 of the link plate 4 separates from the driven sprocket 3 to the meshing position B1 where the toothing 5 of the link plate 4 meshes with the driving sprocket 2, that is, the span area S1, a large number of A part of the link plate 4 moves in a substantially linear direction. Then, in the silent chain 1 of this embodiment, the link plates 4 are pressed in the thickness direction by the elastic force of the disc springs 10, and the contact surface pressure between the link plates 4 is increased. Further, as shown in FIG. 3, the strip-shaped pieces 13 of the adjacent disc springs 10 are positioned substantially linearly. That is, the angle formed by the center lines (not shown) in the lengthwise direction between the strip-shaped pieces 13 is set to approximately zero degrees.

Specifically, the main part of the region where the disc spring 10 exerts a pressing force on the link plate 4 in the thickness direction, that is, the strip-shaped pieces 13 in the projection plane of the link plate 4 in the thickness direction. Overlapping area (hatched area)
P1 is set to the maximum length in the longitudinal direction of the disc spring 10. In this way, all of the strip-shaped pieces 13 overlap (interlace) in the projection plane of the link plate 4 in the thickness direction, and the contact surface pressure per unit area between the link plates 4 is further increased. Has been.

Therefore, even if a force for rotating the link plates 4 relative to each other is exerted in the span region S1, since the frictional force of the contact surface between the link plates 4 is increased, the rocker pin 7 is removed. The relative rotation between the link plates around the center is suppressed. Therefore, in the span region S1, string vibration (vibration in the vertical direction in FIG. 2) at the natural frequency determined by the specifications of the silent chain 1 is suppressed, and unpleasant noise (noise) can be avoided.

Next, the operation of the link plate 4 sequentially moving from the span region S1 toward the meshing position B1 by the running of the silent chain 1 will be described.
In this case, since the moving direction of the link plate 4 becomes a pseudo arc shape along the outer diameter of the drive side sprocket 2,
The link plates 4 relatively rotate about the rocker pin 7 within a predetermined angle range. That is, the angle formed by the longitudinal centerlines (not shown) of the strips 13 exceeds zero degrees. Then, in the projection plane of the link plate 4 in the thickness direction, the overlapping region P of the strip-shaped pieces 13 with each other.
The area of 2 sharply decreases from the area of the overlapping region P1 at the time of the span region S1. Therefore, the span area S1
When the link plate 4 approaches the meshing position B1, the contact surface pressure between the link plates 4 is reduced,
The frictional force between the contact surfaces between them is reduced and relative rotation is facilitated. Therefore, the power loss due to the frictional force between the link plates 4 is suppressed, and the decrease in the torque transmission efficiency of the chain drive mechanism unit K1 can be suppressed. That is, the function of suppressing the string vibration of the silent chain 1 and the function of suppressing the power transmission loss can both be achieved.

In this embodiment, the surface roughness of the band-shaped area including the pair of holes in the disc spring can be set to be rougher than the surface roughness of the other areas. According to this structure, when the link plates are in the span region, the strip-shaped regions of the disc springs are located substantially linearly and all overlap each other in the projection plane in the thickness direction of the link plates. The frictional force between the contact surfaces of the link plates is increased. On the other hand, when the link plates approach the meshing position from the span region, the relative rotation of the link plates reduces the overlapping area of the strip regions, so that the frictional force between the contact surfaces of the link plates decreases. Therefore, the same effect as that of the above embodiment can be obtained. In this way, the surface roughness of a part of the disc spring is
As a specific example of setting the surface roughness of the disc spring to be rougher than that of the disc spring, that is, setting the friction coefficient of a part of the disc spring to be larger than the friction coefficient of the other region, use a friction material on the surface of the disc spring. A method of attaching is exemplified. Further, in this embodiment, the disc spring can be arranged between the link plate and the guide plate.

[0032]

According to the invention of claim 1, while the silent chain is running, the link plates are allowed to rotate relative to each other until the link plates are separated from one sprocket and reach the other sprocket. Even if the force that acts is applied, the frictional force at the contact surface between the link plates is increased, and the string vibration of the silent chain can be suppressed. On the other hand, when the force of trying to rotate the link plates relative to each other by the teeth of the link plates meshing with the other sprocket, the frictional force on the contact surface between the link plates decreases, It is possible to suppress loss and suppress a decrease in torque transmission efficiency.

According to the second aspect of the present invention, when the link plates rotate relative to each other, the pressing portions that apply a pressing force from the plurality of springs in the thickness direction of the link plates move in the thickness direction of each link plate. By reducing the overlapping area in the projection plane and reducing the pressing force per unit area between the pressing portions, the same effect as in claim 1 can be obtained.

According to the third aspect of the present invention, the same effect as that of the second aspect can be obtained, and in the state where the link plates do not rotate relative to each other, a pressing force is applied from the plurality of springs in the thickness direction of the link plates. The pressing portions to be applied have the maximum overlapping length in the running direction of the silent chain within the projection plane in the thickness direction of each link plate. Therefore, the relative rotation suppressing function when a part of the silent chain linearly moves is improved, and the string vibration can be further suppressed.

According to the fourth aspect of the present invention, in the link plates positioned between the time when the tooth portion is separated from the one sprocket and meshes with the other sprocket, within the projection plane in the thickness direction of each link plate. Thus, the area where the belt-shaped regions having a large friction coefficient overlap with each other becomes large. Therefore,
Until the link plates move away from one sprocket and reach the other sprocket, the frictional force on the contact surface between the link plates is increased even if the force to rotate the link plates relative to each other acts. The string vibration of the silent chain can be suppressed. On the other hand, when the force of trying to rotate the link plates relative to each other by the teeth of the link plate meshing with the other sprocket, the area where the belt-shaped regions with large friction coefficients overlap decreases Since the frictional force between the contact surfaces of the two is reduced, the loss of power is suppressed and the reduction of torque transmission efficiency can be suppressed.

[Brief description of drawings]

FIG. 1 is a plan view showing a part of a silent chain of the present invention.

FIG. 2 is a front view of a chain drive mechanism unit having a silent chain according to the present invention.

FIG. 3 is a partial front view of the silent chain shown in FIG.

FIG. 4 is a front view of a disc spring of the silent chain shown in FIGS.

5 is a plan sectional view taken along the line VV of FIG.

6 is a side sectional view taken along line VI-VI in FIG.

[Explanation of symbols]

1 ... Silent chain, 2 ... Drive side sprocket,
3 ... Driven side sprocket, 4 ... Link plate,
5 ... Tooth part, 6 ... Connection hole, 7 ... Rocker pin, 10
... disc springs, 12 ... holes, 13 ... strips.

─────────────────────────────────────────────────── ─── Continuation of front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) F16G 13/00-17/00

Claims (4)

(57) [Claims] 1. A plurality of link plates each having a tooth portion meshing with a sprocket and provided with a pair of connecting holes, and inserted into connecting holes of link plates that are stacked in the thickness direction, and , A linking member that links the link plates to each other so that they can rotate relative to each other and connects a number of link plates endlessly, and a plurality of plate-shaped springs that apply a pressing force in the thickness direction to the link plates. In a silent chain that is equipped with and travels in a state of being wrapped around a plurality of sprockets, a part of the plurality of springs is overlapped with each other in a projection plane in the thickness direction of each link plate. The springs are arranged in the running direction of the silent chain, and the link plates are formed in the overlapping portions of the springs in the projection plane. When the tooth portion of the link plate meshes with the other sprocket, the link plate has a tooth portion of the link plate that is meshed with the other sprocket more than the pressing force applied to the link plate until the tooth portion separates from the one sprocket and meshes with the other sprocket. The silent chain is characterized by being provided with a pressing force control mechanism for controlling so that the pressing force applied to the roller becomes smaller. 2. A pair of holes penetrating the spring in a thickness direction is formed, the connecting member is inserted into the pair of holes, and the pressing force control mechanism has a running direction of a silent chain. The silent chain according to claim 1, further comprising a pressing portion that is linearly formed along the line. 3. The silent chain according to claim 2, wherein the pressing portion is provided in a region passing along the traveling direction of the silent chain and passing through the pair of holes. 4. A plurality of link plates each having a tooth portion meshed with a sprocket and provided with a pair of connecting holes, and inserted into the connecting holes of the link plates that are stacked in the thickness direction, and , A linking member that links the link plates to each other so that they can rotate relative to each other and connects a number of link plates endlessly, and a plurality of plate-shaped springs that apply a pressing force in the thickness direction to the link plates. In a silent chain that is equipped with and travels in a state of being wrapped around a plurality of sprockets, a part of the plurality of springs is overlapped with each other in a projection plane in the thickness direction of each link plate. The springs are arranged in the running direction of the silent chain, and the thickness of each of the springs is set to an overlapping portion in the projection plane of each spring. A pair of holes penetrating in the direction is formed, and the connecting member is inserted into the pair of holes, and the pair of holes pass through the pair of holes on the surface of the spring and the running direction of the silent chain. The silent chain is characterized in that the coefficient of friction of the belt-shaped region along the is set to be larger than the coefficient of friction of the region other than the belt-shaped region.