KR101387774B1 - Chain sliding guide shoe - Google Patents

Abstract

The frictional resistance between the chain running guide shoe and the plate of the running roller chain can be reduced, making it easier to return to the center when the roller chain is displaced laterally, and the heat generated by the friction between the roller chain and the running guide surface can be suppressed. The present invention also aims to provide a chain running guide shoe having high dimensional accuracy.

The chain travel guide shoe 3 includes a pair of travel guide surfaces 4 for sliding the plate sections on both sides of the roller chain C, a regulation guide 5 for regulating the lateral movement of the roller chains, and the travel guide surfaces 4. The groove | channel 6 etc. which are provided between and 4 are provided over the full length of a roller chain running direction. The groove 6 is formed in a substantially U-shape with an upward opening, wider than the inner width W2 of the roller chain and narrower than the outer width W1, and the traveling guide surface at the upper end 6b of the groove 6. The chamfer 4a is formed in the corner part of (4).

Description

Chain sliding guide shoe

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a chain running guide shoe of a guide member used for holding tension and sliding action of a roller chain which is rotated between a drive side sprocket and a driven side sprocket to transmit power.

Background Art Conventionally, a timing drive system of an engine includes a tensioner lever (TL) and a guide for guiding a roller chain, which are rotated between a crank shaft and a sprocket installed on each of the cam shafts in the engine room to impart proper tension to a roller chain that is circumferentially rotating. Guide members, such as a lever, are provided.

8 to 10 show examples of the guide member used in the conventional timing drive system. The chain traveling guide shoe 32 provided in the guide member 31 is attached to the shoe attachment member 33 which is the guide member main body. As shown in Fig. 9 (cross section taken along line X9-X9 in Fig. 8), the chain travel guide shoe 32 is provided with a flat pressing contact surface 34 on the entry side and the exit side of the chain. As shown in Fig. 10 (X10-X10 cross section in Fig. 8), a convex push contact surface 35 for slidably guiding the plate cross section of the roller chain C is formed to form a flat push contact surface 34. The convex push contact surface 35 constitutes the running surface 36, and the groove 37 is formed in the center of the running surface 36. In addition, the code | symbol L1, L2 in FIG. 9, FIG. 10 is the inner plate of the roller chain C, the outer plate, and M are rollers (for example, refer patent document 1).

[Patent Document 1] Japanese Patent Publication No. 3269011 (Second page, FIGS. 2, 3, and 5)

The conventional chain travel guide shoe 32 has frictional resistance because the plates L1 and L2 of the roller chain, which slide on the entire surface of the flat pressing contact surface 34 at the entry and exit sides of the chain, are in sliding contact. There is a problem that there is a large problem, and in the middle section, when the running roller chain C is shifted laterally, the plates L1 and L2 are caught by the corners 35a of the convex push-contacting surface 35, and it is difficult to return to the center. Since the raceway correction becomes difficult and the movement to the side is not regulated, there is a problem that it is missed from the chain travel guide shoe 32 or sinks into the groove 37.

In addition, since the groove part 37 in the intermediate section is closed by the flat pressing contact surface 34 provided on the entry side and the exit side, the inflow and outflow properties of the lubricating oil into the groove part 37 in the engine are poor. Since the circulation is not sufficiently performed, the heat generated by the friction between the roller chain and the convex push-contacting surface 35 cannot be cooled by lubricating oil, and the convex push-contact surface is increased by the increase in frictional resistance caused by heat generation. (35) or there was a problem that the wear of the plates L1 and L2 was promoted. In addition, since the cross-sectional shape in the longitudinal direction of the chain running guide shoe 32 is different, there is a problem that deformation is liable to occur during molding or use due to a difference in heat capacity or internal residual stress, and dimensional accuracy deteriorates.

Therefore, this invention solves the problem of the prior art mentioned above, reduces the frictional resistance between the chain travel guide shoe and the plate of the roller chain which runs, and when the roller chain is shifted laterally, the chain travel guide shoe is carried out. It is possible to prevent the plate from being caught by the edge of the plate and to return to the center, and to prevent it from slipping into the groove or deflecting from the chain travel guide shoe, and the roller running by the good inflow and outflow property of the lubricant in the groove. It is an object of the present invention to provide a chain running guide shoe which can suppress heat generation due to friction between the chain and the running guide surface and has high dimensional accuracy.

The present invention according to claim 1 is a pair of driving guide surfaces for slidably guiding plate sections on both sides of the roller chain, and a guide for regulating the lateral movement of the roller chains which are installed on both outermost sides of the pair of running guide surfaces. A chain running guide shoe having a groove or the like provided between a pair of running guide surfaces over the entire length of the roller chain running direction, wherein the groove is formed of an arc-shaped curved surface curved downward, and the groove is the roller. This problem is solved by being formed wider than the inner width of the chain and narrower than the outer width.

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The present invention according to claim 2 is characterized in that the chain travel guide shoe of the present invention according to claim 1 is provided with a standing base end of the regulating guide standing up on the one travel guide surface and the curved surface on the other travel guide surface. The space | interval with the upper end of the groove | channel made is made narrower or substantially the same as the outer width of the said roller chain.

In the present invention according to claim 3, in the chain travel guide shoe of the present invention according to claim 1, a chamfer is formed at a corner portion of the travel guide surface at an upper end of a groove formed of the curved surface.

The present invention according to claim 4 is characterized in that, in the chain travel guide shoe of the present invention according to claim 3, a standing base end of the regulating guide provided on the one travel guide surface and a chamfered part on the other travel guide surface are formed. The distance from the base end is made narrower or substantially the same as the outer width of the roller chain.

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According to the present invention according to claim 1, the chain travel guide shoes, a pair of travel guide surfaces for guiding sliding of the plate cross-sections on both sides of the roller chain, and a side of the roller chain running on both outermost sides of the pair of travel guide surfaces. The chain is provided with a regulating guide for restricting movement, a groove provided between the pair of running guide surfaces, and the entire length of the roller chain traveling direction, and the groove is formed by an arc-shaped curved surface curved downward. The cross-sectional shape of the traveling guide shoe can be made substantially constant in the longitudinal direction to increase the dimensional accuracy.

The groove formed by the curved surface is provided over the entire length of the roller chain running direction, thereby improving the inflow and outflow properties of the lubricating oil in the groove in the engine, improving the flow, and improving circulation. Therefore, when heat is generated by friction between the roller chain and the travel guide surface, cooling can be performed with lubricating oil, and frictional resistance can be reduced, and further, wear of the roller chain or travel guide surface can be suppressed.

Since the groove formed of the curved surface is formed to be wider than the inner width of the roller chain and narrower than the outer width, the sliding area is reduced while allowing the roller chain to run stably without falling into the groove from the travel guide surface. Running frictional resistance can be reduced.

In addition, since the groove is an arc-shaped curved surface, there is no sharp edge between the upper end of the groove and the traveling guide surface, so that the roller chain C when the traveling roller chain C is laterally shifted or meandered, Orbital correction to the center can be performed smoothly.

According to this invention of Claim 2, in addition to the effect which the chain travel guide shoe of this invention of the said Claim 1 achieves, the standing base end of the regulation guide standing up on one travel guide surface, and the groove | channel of the other travel guide surface Since the distance from the upper end is narrower or substantially the same as the outer width of the roller chain, it is possible to reliably prevent falling into the grooves when the roller chain which is pushed in contact with the traveling guide surface is shifted laterally.

According to this invention of Claim 3, since the chamfer part is formed in the edge part of the said driving guide surface in the upper end of the groove | channel which consists of the said curved surface in addition to the effect which the chain traveling guide shoe of this invention of the said Claim 1 achieves, When the roller chain is shifted laterally or meandered, the chamfered portion can prevent the lower end surface of each plate of the roller chain from being caught in the corner portion, so that the track correction to the center of the roller chain C can be smoothly performed. have.

According to this invention of Claim 4, in addition to the effect which the chain travel guide shoe of this invention of the said 3rd achieves, in the standing base end of the regulation guide standing up on said one travel guide surface, and the other travel guide surface, Since the distance from the base end part of the chamfer part is narrower or substantially the same as the outer width of the said roller chain, when the roller chain which runs is shifted laterally and moved, it can reliably prevent falling in a groove | channel.

The chain running guide shoe of the present invention is, for example, a tensioner lever TL for properly maintaining the tension of the roller chain C of the timing chain drive system of the engine, and a guide lever for guiding the running of the roller chain C. It is used for the guide member G, such as GL).

As shown in Fig. 1, the timing chain drive system is a roller chain C rotated between a drive sprocket S1 provided on a crankshaft in an engine room and a pair of driven sprockets S2, S3 attached to a camshaft. And a guide member (G) such as a tensioner lever (TL) for applying tension to the roller chain (C), a guide lever (GL) for guiding the roller chain (C), and a roller chain (C). Is in sliding contact with the chain running guide shoe of the guide member (G). This guide member G attaches a chain travel guide shoe to the lever main body used as a shoe attachment member, or integrally forms the lever main body and the chain travel guide shoe, and presses and slides the roller chain C which travels. It works. In addition, the code | symbol T in FIG. 1 is a tensioner, B1 is a pivot support shaft of tensioner lever TL, B2, B3 is an attachment shaft of guide lever GL.

Here, in order to explain the embodiment of the present invention more easily, the chain running guide shoe which is a reference example of the present invention is shown in FIGS. 1 to 5.

1 is an explanatory view of a timing chain drive system, FIG. 2 is a side view of a guide member having a chain travel guide shoe as a reference example for easier understanding of an embodiment of the present invention, FIG. 3 is a plan view of the chain travel guide shoe, and FIG. 4 (A) is sectional drawing of a guide member, (B) is an enlarged view of a principal part, FIG. 5 is explanatory drawing when the roller chain is shifted laterally.

The guide member 1 attaches the chain running guide shoe 3 to the shoe attachment member 2. For example, when the guide member 1 is the guide lever GL, the guide member 1 is attached to the shoe attachment member 2. , Is attached to the engine room. As shown in FIGS. 3 and 4, the chain travel guide shoe 3 includes a pair of travel guide surfaces 4 and 4 for slidably guiding the end faces of the inner and outer plates L1 and L2 of the roller chain C; A roller chain (C) runs through a regulation guide (5, 5), which is provided on both outermost sides of the pair of travel guide surfaces, and a groove (6) provided between the pair of travel guide surfaces (4, 4). Over the entire length of the direction. In addition, the code | symbol M is a roller.

The regulating guides 5 and 5 provided on the traveling guide surface 4 have a raised portion 5a at the lower end of the side end surface 5c, and the raised portion 5a at the traveling guide surface 4. The proximal end of is the standing upright end 5b of the regulation guide 5. On the other hand, the raised portion 5a may not necessarily be provided, and in this case (when the raised portion 5a is not provided), the running guide surface 4 and the side end surface 5c of the regulation guide 5 are orthogonal. The corner portion 5d (see FIG. 5) becomes a standing base end of the regulation guide 5.

The groove 6 is a substantially U-shaped groove in which the top is opened, and the chain entry side and the exit side are open. In addition, the width W3 of the groove 6 is formed wider than the inner width W2 of the roller chain C and narrower than the outer width W1 as shown in FIG. 4. And the chamfer 4a of circular arc shape (curvature radius R1) is formed in the corner part of the travel guide surface 4 in the upper end 6b of the groove | channel 6, and the chamfer 4a in the travel guide surface 4 is carried out. ) Is the base end 4b.

As shown to FIG. 4, FIG. 5, the standing base end part 5b of the regulation guide 5 standing up on one running guide surface 4 among the pair of running guide surfaces 4 and 4, and the other running | running | working The space | interval W5 of the formation base part 4b of the chamfer part 4a in the guide surface 4 is narrower than or substantially the same as the outer width W1 of the roller chain C (W5 <= W1). In Fig. 4, reference numeral W4 denotes an interval from the side end surface 5c, which is a wall surface of the other regulation guide 5 facing one wall surface 6a of the groove, and W6, a side end surface of the regulation guide 5; It is the interval between (5c).

The effect of the chain running guide shoe 3 which consists of the said structure is as follows.

The chain travel guide shoe 3 includes a pair of travel guide surfaces 4 and 4, a regulation guide 5 and 5 installed on both outermost sides of the pair of travel guide surfaces 4 and 4, and a pair of travel guide surfaces. Since the grooves 6 and the like provided between (4, 4) are provided over the entire length of the roller chain C running direction, the cross-sectional shape of the chain running guide shoe 3 is almost the same over the entire length. Therefore, when produced by injection molding with resin, for example, it is cooled and cured evenly over the entire length, and the reduction in dimensional accuracy due to cooling unevenness and the decrease in dimensional accuracy due to internal residual stress deformation can be suppressed. have.

Since the grooves 6 are provided over the entire length of the roller chain C running direction, the inflow and outflow properties of the lubricating oil into the grooves 6 in the engine are improved, the flow is improved, and the circulation is also improved. Therefore, when heat is generated by the friction between the roller chain C and the travel guide surface 4, the lubricant can be cooled with lubricating oil and the frictional resistance can be reduced, and further, the roller chain C or the travel guide surface 4 can be reduced. ) Wear can be suppressed.

As shown in FIG. 4, when the roller chain C travels substantially in the width direction of the chain travel guide shoe 3, the width W3 of the groove 6 is the inner width W2 of the roller chain C. As shown in FIG. Since it is wider than) and narrower than the outer width W1 of the roller chain C, only a part of end surfaces of the plates L1 and L2 of the roller chain C are in sliding contact with the travel guide surface 4 and thus the sliding area Because of this reduction, running frictional resistance can be reduced, and stable running can be achieved without the roller chain C falling from the running guide surface 4 into the groove 6.

Moreover, since the chamfer 4a is formed in the corner part of the travel guide surface 4 in the upper end 6b of the groove | channel 6, when the roller chain C which runs to shift sideways or meanders, the chamfer part Since the lower end surfaces of the plates L1 and L2 of the roller chain C can not be caught by the corner portions by the 4a, the orbital correction to the center of the roller chain C can be smoothly performed. By the regulation guide 5, it is possible to prevent the deviation from the running guide surface 4.

In addition, the chain travel guide shoe 3 runs on the other side of the standing base end 5b of the regulating guide 5 which is set up on one travel guide surface 4 of the pair of travel guide surfaces 4 and 4. Formation of the chamfer 4a in the guide surface 4 The distance W5 with the base end 4b is narrower or substantially the same as the outer width W1 of the roller chain C (W5? As shown in the figure, when the roller chain C which runs is shifted laterally and moved, it can be reliably prevented from falling in the groove 6.

Example 1

6 is a cross-sectional view of the guide member 11 having the chain running guide shoe 13 of the first embodiment of the present invention. The guide member 11 attaches the chain travel guide shoe 13 to the shoe attachment member 12. As shown in FIG. 6, the chain travel guide shoe 13 includes a pair of travel guide surfaces 14 and 14 for guiding sliding end faces of the inner and outer plates L1 and L2 of the roller chain C. The control guides 15 and 15 which are installed on both outermost sides of the traveling guide surfaces 14 and 14, and the grooves 16 and the like provided between the pair of traveling guide surfaces 14 and 14 are connected to the roller chain C. I have it over the full length of the driving direction.

The regulating guides 15 and 15 provided on the traveling guide surface 14 have a raised portion 15a at the lower end of the side end surface 15c, and the proximal end of the raised portion 15a is standing up of the regulated guide 15. The base end 15b is provided. On the other hand, the raised portion 15a may not necessarily be provided, and in this case, an orthogonal corner portion (not shown) between the running guide surface 14 and the side end surface 15c of the regulation guide 15 becomes an upright foundation end portion. .

The groove | channel 16 consists of the curved surface of the circular arc shape (curvature radius R2) curved downward, and the chain entrance side and the exit side are open | released. In addition, the width W7 of the groove 16 is formed wider than the inner width W2 of the roller chain C and narrower than the outer width W1.

In addition, as shown in FIG. 6, the upper end of the standing base end 15b of the regulating guide 15 provided on one travel guide surface 14 and the groove 16 on the other travel guide surface 14. The space | interval W8 with 16a is narrower than or substantially the same as the outer width W1 of the roller chain C. As shown in FIG.

The effect of the chain running guide shoe 13 which consists of the said structure is as follows.

The chain travel guide shoe 13 includes a pair of travel guide surfaces 14 and 14, a restriction guide 15 and 15 installed on both outermost sides of the pair of travel guide surfaces 14 and 14, and a pair of travel guide surfaces. Since the groove | channel 16 etc. which consist of the downward curved arc-shaped curved surface provided between 14 and 14 are provided over the full length of the roller chain C running direction, the chain running guide shoe 13 ) Becomes almost the same cross-sectional shape over the entire length. For example, in the case of manufacturing by injection molding with a resin, it is cooled and cured evenly over the entire length, resulting in lowered dimensional accuracy due to cooling unevenness and internal residual stress. The fall of the dimensional precision by deformation can be suppressed.

Since the groove 16 which consists of an arc-shaped curved surface is provided over the full length of the roller chain C running direction, the inflow and outflow property of the lubricating oil in the groove 16 in an engine improves, and a flow improves. At the same time, the circulation property is also improved. Therefore, when heat is generated by the friction between the roller chain C and the traveling guide surface 14, the lubricant can be cooled and the frictional resistance can be reduced. C) or wear of the running guide surface 14 can be suppressed.

As shown in FIG. 6, when the roller chain C travels almost the center of the chain travel guide shoe 13, the width W7 of the groove 16 is the inner width W2 of the roller chain C. As shown in FIG. Since it is wider and narrower than the outer width W1 of the roller chain C, since only a part of end surfaces of the plates L1 and L2 of the roller chain C are in sliding contact with the travel guide surface 14, the sliding area is reduced. In addition, the running frictional resistance can be reduced, and stable running can be performed without the roller chain C falling from the running guide surface 14 into the groove 16 formed of an arc-shaped curved surface.

In addition, since the groove 16 is an arc-shaped curved surface, there is no sharp edge portion between the upper end 16a of the groove 16 and the travel guide surface 14, so that the roller chain C that travels is on the side. When it shifts or meanders, the track correction to the center of the roller chain C can be performed smoothly.

Moreover, the space | interval W8 of the upright base end part 15b of the regulation guide 15 standing up on one travel guide surface 14, and the upper end 16a of the groove | channel 16 in the other travel guide surface 14 ) Is narrower than or substantially the same as the outer width W1 of the roller chain C, and as shown in FIG. 6, when the running roller chain C shifts laterally, it falls in the groove 16. You can certainly prevent that.

[Example 2]

7 is a cross-sectional view of the guide member 21 having the chain travel guide shoe 23 of the second embodiment of the present invention. The chain traveling guide shoe 23 of Example 2 is corresponded to the thing which provided the chamfer 24a in the corner part of the upper end of the groove | channel which consists of the curved surface in the traveling guide surface of the said Example 1.

The guide member 21 attaches the chain travel guide shoe 23 to the shoe attachment member 22. As shown in Fig. 7, the chain travel guide shoe 23 is a pair of travel guide surfaces 24 and 24 for guiding sliding end surfaces of the inner and outer plates L1 and L2 of the roller chain C. The control guides 25 and 25 installed on both outermost sides of the traveling guide surfaces 24 and 24 of the roller guides, and the grooves 26 provided between the pair of traveling guide surfaces 24 and 24, respectively. I have it over the full length of the driving direction.

The regulating guides 25 and 25 provided on the traveling guide surface 24 have a raised portion 25a at the lower end of the side end surface 25c, and the proximal end of the raised portion 25a is standing up of the regulated guide 25. The base end 25b is provided. On the other hand, the raised portion 25a may not necessarily be provided, and in this case, an orthogonal corner portion (not shown) of the running guide surface 24 and the side end surface 25c, which is the wall surface of the regulation guide 25, is a standing base end. Becomes

The groove 26 is a curved surface having a circular arc shape (curvature radius R2) curved downward, and the chain entry side and the exit side are open. In addition, the width W9 of the groove 26 is formed wider than the inner width W2 of the roller chain C and narrower than the outer width W1. And the chamfer 24a of circular arc shape (curvature radius R3) is formed in the corner part of the travel guide surface 24 in the upper end of the groove 26, and the formation of the chamfer 24a in the travel guide surface 24 is carried out. The proximal end is the proximal end 24b.

In addition, as shown in FIG. 7, the standing base end 25b of the regulating guide 25 standing on one travel guide surface 24 and the chamfer 24a on the other travel guide surface 24 are shown. The space | interval W10 with the formation base end part 24b is narrower than or substantially the same as the outer width W1 of the roller chain C (W10 <= W1).

The effect of the chain running guide shoe 23 which consists of the said structure is as follows.

The chain travel guide shoe 23 is provided with a pair of travel guide surfaces 24 and 24, a regulation guide 25 and 25 installed on both outermost sides of the pair of travel guide surfaces 24 and 24, and a pair of travel guide surfaces. Since the groove 26 etc. which consist of the downward curved arc-shaped curved surface provided between (24, 24) are provided over the full length of the roller chain C running direction, the chain running guide shoe 23 ) Becomes almost the same cross-sectional shape over the entire length. For example, in the case of manufacturing by injection molding with a resin, it is cooled and cured evenly over the entire length, resulting in lowered dimensional accuracy due to cooling unevenness and internal residual stress. The fall of the dimensional precision by deformation can be suppressed.

Since the groove 26 which consists of an arc-shaped curved surface is provided over the full length of the roller chain C running direction, the inflow and outflow property of the lubricating oil in the groove 26 in an engine improves, and flow improves. At the same time, the circulation is also improved, and when heat is generated by the friction between the roller chain C and the travel guide surface 24, the lubricant can be cooled and the frictional resistance can be reduced. C) or wear of the running guide surface 24 can be suppressed.

When the roller chain C runs near the center of the chain travel guide shoe 23, the width W9 of the groove 26 is wider than the inner width W2 of the roller chain C, and the roller chain C Since it is formed narrower than the outer width (W1) of the roller chain (C), only a part of the end surface of the plate (L1, L2) of the roller chain (C) is in sliding contact with the travel guide surface 24, the sliding area is reduced to reduce the running friction resistance At the same time, it is possible to perform stable running without the roller chain C falling from the running guide surface 24 into the groove 26 formed of an arc-shaped curved surface.

Since the chamfer 24a is formed in the corner part of the travel guide surface 24 in the upper end of the groove 26, when the roller chain C which runs is shifted laterally or meanders, the chamfer 24a Since the lower end surfaces of the plates L1 and L2 of the roller chain C can be prevented from being caught by the corner portions, the raceway correction to the center of the roller chain C can be smoothly performed.

Moreover, the space | interval W8 of the upright foundation end part 25b of the regulation guide 25 standing up on one travel guide surface 24, and the upper end of the groove | channel 26 in the other travel guide surface 24, Since it is narrower or substantially the same as the outer width W1 of the roller chain C, as shown in FIG. 6, when the running roller chain C shifts laterally, it is reliably falling in the groove 26. As shown in FIG. It can prevent.

Although each Example was demonstrated above, the chain traveling guide shoe of this invention may be attached separately to a shoe attachment member, or may be formed integrally with a shoe attachment member. The chain running guide shoe may be any one as long as the friction resistance with the roller chain, such as plastic or metal, is small. As the material, it is possible to achieve durability in a high temperature environment and to achieve smooth sliding contact running of the chain. The material is suitable. When using plastics, it is preferable to use materials, such as synthetic resin materials, such as polyamide 6 resin, polyamide 46 resin, polyamide 66 resin, and polyacetal resin, for example.

1 is an explanatory diagram of a timing chain drive system.

2 is a side view of a guide member having a chain running guide shoe as a reference example for easier understanding of the present invention.

3 is a plan view of the guide member.

4: (A) is sectional drawing of a guide member, (B) is an enlarged view of a principal part.

5 is an explanatory diagram when the roller chain is shifted laterally.

6 is a side view of a guide member having a chain running guide shoe of Embodiment 1. FIG.

7 is a sectional view of a guide member having a chain running guide shoe of Embodiment 2. FIG.

8 is a perspective view of a conventional guide member.

FIG. 9 is a cross-sectional view taken along line X9-X9 of FIG. 8.

10 is a cross-sectional view taken along line X10-X10 of FIG. 8.

Description of the Related Art

1: guide member

2: shoe attachment member

3: chain driving guide shoe

4: driving guide surface

4a: chamfer

4b: Proximal end of forming chamfer

5: regulatory guide

5a: rising part

5b: Standing-up end of the regulatory guide

5c: Wall surface (side section) of the regulation guide

5d: orthogonal edges

6: home

6a: wall of the groove

6b: top of the groove

11: guide member

12: shoe attachment member

13: chain driving guide shoe

14: driving guide surface

15: regulatory guide

15a: rising part

15b: standing foundation end

15c: Wall surface (side section) of the regulation guide

16: groove made of curved surface

16a: top of the groove

21: guide member

22: shoe attachment member

23: chain driving guide shoe

24: driving guide surface

24a: chamfer

24b: Proximal end of forming chamfer

25: regulatory guide

25a: rising part

25b: Standing foundation end

25c: wall surface (side section)

26: home

L1: External Plate

L2: Inner Plate

C: roller chain

W1: Outer width of roller chain

W2: inner width of roller chain

W3: width of groove

W4: Opposing one wall surface of the groove with the wall surface of the other regulatory guide

W5: distance between the standing base end of the regulatory guide and the forming end of the chamfer

W6: width of the groove 6

W7: width of the groove 16

W8: distance between the standing base end and the upper end 16a of the groove

W9: width of the groove 26

W10: distance between the standing base end and the forming end of the chamfer

Claims (6)

Between a pair of traveling guide surfaces for guiding sliding of the end surfaces of the plates on both sides of the roller chain, a regulation guide for regulating the lateral movement of the roller chains which are installed on both outermost sides of the pair of traveling guide surfaces, and between the pair of traveling guide surfaces. As a chain running guide shoe having a groove or the like provided over the entire length of the roller chain running direction, A chain running guide shoe, characterized in that the groove is formed of an arcuate curved surface curved downward, and the groove is formed to be wider than the inner width of the roller chain and narrower than the outer width. The distance between the upright base end of the regulation guide standing up on said one travel guide surface, and the upper end of the groove | channel consisting of the said curved surface in the other travel guide surface is narrower than the outer width of the said roller chain, Or a chain running guide shoe characterized by the same. The chain running guide shoe according to claim 1, wherein a chamfer is formed at a corner of said running guide surface at an upper end of said groove formed of said curved surface. The distance between the standing base end of the regulation guide standing up on the said one driving guide surface, and the base end part of the chamfer part in the other traveling guide surface is narrower than or equal to the outer width of the said roller chain. A characteristic chain running guide shoe. delete delete

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