JP6025261B2 - Chain guide - Google Patents

Description

  The present invention relates to a chain guide that includes a guide shoe that slides and guides a traveling chain, and a plate that reinforces the guide shoe along the chain traveling direction.

Conventionally, in order to stabilize a chain traveling between sprockets and properly maintain a tension, it is commonly used to use a chain guide provided with a guide shoe for slidingly guiding the traveling chain.
For example, as shown in FIG. 10, there is an engine timing system in which a transmission chain CH such as a roller chain suspended endlessly between sprockets S1 and S2 provided on a crankshaft and a camshaft in an engine room E is run. The timing chain CH is endlessly suspended between the drive sprocket S1 attached to the crankshaft in the engine room E and the pair of driven sprockets S2 attached to the camshaft, and the timing chain CH swings. A timing system guided by a guide (swing guide) 500 and a chain guide (fixed guide) 600 is known.

In this known timing system, the fixed guide 600 is fixed in the engine room E by two fixing attachment shafts Q, and the swing guide 500 is suspended around the timing chain CH around the swing mounting shaft P. It is mounted in the engine room E so as to be swingable in a plane.
The chain tensioner T presses the swing guide 500 to appropriately maintain the tension of the timing chain CH and suppress vibrations.
The known chain guide (swing guide) 500 and chain guide (fixed guide) 600 used in such a timing system are integrally formed of synthetic resin, so that the rigidity and durability of the chain guide are ensured. Although it is necessary to increase the rigidity of the guide body and improve the rigidity and durability, there is a problem that it becomes an obstacle to designing the engine room E compactly.

Therefore, the chain guide includes a guide shoe that slides and guides the traveling chain, and a plate that reinforces the guide shoe along the chain traveling direction. It is well-known that a slit groove that can be inserted is provided and a plate with high rigidity and durability is inserted into the slit groove to reduce the occupied space while ensuring the necessary strength, rigidity, and durability for the entire chain guide. (See Patent Documents 1, 2, 3, etc.)
The guide shoes of these known chain guides are made of resin with low thermal conductivity, the plate is made of metal with good thermal conductivity, and the heat generated by sliding between the travel guide part and the chain conducts the guide shoes. Therefore, heat radiation was small, and it was possible to conduct to the plate from the back side of the travel guide part of the guide shoe.

JP 2006-2810 A JP 2003-130156 A JP 2002-266964 A JP 2010-84882 A JP 2009-299728 A JP-A-11-44349

In the chain guides known from Patent Documents 1 to 3, etc., only the end surface of the plate is close to the traveling guide portion, so that heat is conducted from the traveling guide portion to the end surface of the plate, and the side surface of the plate is a slit groove. Since it is housed inside, heat is dissipated mainly only on the opposite end face, and the heat generated in the travel guide cannot be sufficiently dissipated.
For this reason, the temperature of the travel guide portion is always high, and there is a problem that the softening and wear of the resin are promoted, and the sliding resistance is deteriorated or broken.
Further, there is a problem that the resin itself is deteriorated or damaged by heat.
On the other hand, in order to reduce the sliding resistance between the traveling guide part and the chain and reduce the heat generated by sliding, a chain guide provided with a traveling surface groove extending in the chain traveling direction in the traveling guide part is known ( (See Patent Documents 4, 5, 6, etc.).

Therefore, it is conceivable to solve the problem caused by heat by providing a travel guide groove of a chain guide known in Patent Documents 1 to 3 and the like so as to provide a travel surface groove extending in the chain travel direction in Patent Documents 4 to 6 and the like.
However, in the structure in which the pressing force received by the travel guide portion of the guide shoe is reinforced by the plate inserted in the up and down direction, the strength of the guide shoe is significantly reduced due to the provision of the travel surface groove in the travel guide portion. was there.

  For example, as shown in FIG. 11, the travel guide portion 511 is provided with respect to the travel guide portion thickness E from the surface of the travel guide portion 511 of the guide shoe 510 to the uppermost portion of the plate 520 (the bottom portion of the slit groove 512). When the depth D of the travel surface groove 514 is large, a thin portion having a thickness C (= ED) is generated at the bottom of the travel surface groove 514, and the strength of the guide shoe 510 is reduced at the thin portion. It is necessary to design the travel guide thickness E larger than that of the conventional one.

11, when the width B of the running surface groove 514 is larger than the thickness A of the plate 520 (width of the slit groove 512), or as shown in FIG. 12, the center line of the running surface groove 514 And the center line of the plate 520 (slit groove 512) is deviated and the width direction end of the running surface groove 514 extends outward in the width direction from above the plate 520 (slit groove 512). The pressing force from the surface of the portion 511 cannot be effectively received by the plate 520 from directly below.
This increases the bending of the travel guide portion 511 in the width direction, so that it is necessary to further increase the strength of the thin portion. To further increase the thickness C of the thin portion, the travel guide portion thickness E is further increased. It was necessary to design large.

  The present invention solves the above-mentioned problems, reduces the occupied space while ensuring the necessary strength, rigidity, and durability with a simple configuration, and reduces the sliding resistance between the travel guide portion and the chain, An object of the present invention is to provide a highly durable chain guide that reduces heat generated by sliding and generates less wear and damage.

The invention according to claim 1 is a chain guide including a guide shoe that slides and guides a traveling chain, and a plate that reinforces the guide shoe along the chain traveling direction.
The guide shoe has a travel guide portion extending in the chain travel direction, and a slit groove into which the plate can be inserted from below on the back side of the travel guide portion, and the travel guide portion travels in the chain travel direction. The guide shoe has a surface groove, and the guide shoe has a high pressing force region in a predetermined range in the chain traveling direction from a mounting portion attached to a mounting target or a tensioner contact portion that contacts the tensioner, and a low pressing force in other ranges. and a region, the groove width of the running surface grooves in the high pressure region, rather smaller than the groove width of the slit groove at 0 or more, the groove width of the running surface grooves in said low pressure region is greater than 0 Therefore, the problem is solved.

In the invention according to claim 2, in addition to the structure of the chain guide according to claim 1, the depth of the running surface groove is smaller than ½ of the distance from the surface of the running guide portion to the bottom of the slit groove. Thus, the problem is solved.
In the invention according to claim 3, in addition to the structure of the chain guide according to claim 1 or 2, the running surface groove and the slit groove are formed on the same center line in the width direction of the chain. This solves the problem.
In the invention according to claim 4, in addition to the structure of the chain guide according to any one of claims 1 to 3, the depth from the bottom of the slit groove to the opening is on the back side of the low pressing force region. The problem is solved by being formed shallower than the depth on the back surface side of the high pressing force region.

According to the fifth aspect of the present invention, in addition to the structure of the chain guide according to any one of the first to fourth aspects, the groove width of the running surface groove is a groove width of the slit groove in the low pressing force region. The problem is solved by being larger.
The invention according to claim 6 is a guide shoe having a slit groove into which a plate can be inserted from below on the back side of a travel guide portion extending in the chain travel direction, and the travel guide portion travels in the chain travel direction. The guide shoe has a surface groove, and the guide shoe has a high pressing force region in a predetermined range in the chain traveling direction from a mounting portion attached to a mounting target or a tensioner contact portion that contacts the tensioner, and a low pressing force in other ranges. and a region, the groove width of the running surface grooves in the high pressure region, rather smaller than the groove width of the slit groove at 0 or more, the groove width of the running surface grooves in said low pressure region is greater than 0 Therefore, the problem is solved.

According to the chain guide according to the first aspect and the guide shoe according to the sixth aspect, the guide shoe has a slit groove into which the plate can be inserted from below on the back side of the travel guide part, and the chain of the travel guide part. groove width in the high pressure region of the running surface grooves extending in the running direction is more than 0 at rather smaller than the groove width of the slit groove, the groove width of the running surface grooves in the low pressure region, the greater than 0 Ikoto, press It is possible to reduce the thin portion with a high pressure portion, and there is always a portion without a running surface groove above the plate in the slit groove, so that the pressing force can be effectively received by the plate.
Accordingly, the strength of the guide shoe with respect to the pressing force is only slightly reduced, it is not necessary to design a large travel guide portion, the space occupied is reduced while securing strength, rigidity and durability, and a travel surface groove is provided. As a result, the sliding resistance between the travel guide portion and the chain can be reduced, and the heat generated by the sliding can be reduced.

According to the configuration of the second aspect of the present invention, since the depth of the running surface groove is smaller than 1/2 of the distance from the surface of the running guide portion to the bottom portion of the slit groove, it is possible to further reduce the thin portion. Become.
According to the configuration of the third aspect of the present invention, since the running surface groove and the slit groove are formed on the same center line in the width direction of the chain, the running surface groove is formed above the plate in the slit groove. There are always no parts on both sides in the width direction of the plate, and the pressing force can be more effectively received by the plate.
In addition, this can prevent the travel guide portion from being bent to one side in the width direction, and the travel guide portion can be prevented from being tilted and guided while being tilted, and in the width direction. Accumulation of local heat due to uneven generation of heat is suppressed, and deterioration or breakage of the guide shoe due to heat can be reduced.

According to the configuration described in claim 4, the depth from the bottom of the slit groove to the opening is formed shallower on the back side of the low pressing force region than on the back side of the high pressing force region. The exposed area not sandwiched by the slit grooves on the side surface of the plate on the back side of the low pressing force region can be widened, and the heat conducted to the plate can be effectively dissipated. And damage can be reduced.
According to the configuration of the fifth aspect of the present invention, the sliding resistance between the traveling guide portion and the chain is further reduced by the groove width of the traveling surface groove being larger than the groove width of the slit groove in the low pressing force region, The heat generated by sliding can be reduced, and in the low pressing force region, there is little influence of the decrease in the strength of the guide shoe against the pressing force. It is possible to ensure durability.

The perspective view of the plate of the chain guide which concerns on 1st Embodiment of this invention. The perspective view from the other direction of the chain guide which concerns on 1st Embodiment of this invention. The (a) top view and (b) side view of the chain guide which concern on 1st Embodiment of this invention. Cross-sectional explanatory drawing of the high pressing force area | region of the chain guide which concerns on 1st Embodiment of this invention. Cross-sectional explanatory drawing at the time of chain driving | running | working of FIG. II sectional view explanatory drawing of FIG.3 (b). The perspective view of the plate of the chain guide which concerns on 2nd Embodiment of this invention. The perspective view from the other direction of the chain guide which concerns on 2nd Embodiment of this invention. The (a) top view and (b) side view of the chain guide which concern on 2nd Embodiment of this invention. Explanatory drawing of the timing system of the conventional engine. Cross-sectional explanatory drawing of the conventional chain guide. Cross-sectional explanatory drawing of the other conventional chain guide.

A chain guide according to the present invention is a chain guide provided with a guide shoe that slides and guides a traveling chain, and a plate that reinforces the guide shoe along the chain traveling direction. The travel guide part has a slit groove into which the plate can be inserted from below on the back side of the travel guide part. The travel guide part has a travel surface groove extending in the chain travel direction. It has a high pressing force area within a predetermined range in the chain running direction from the attachment part attached to the object or a tensioner abutting part that contacts the tensioner, and a low pressing force area in the other range, and travels in the high pressing force area. the groove width of side Slots is rather smaller than the groove width of the slit groove at 0 or more, the groove width of the running surface grooves in the low pressure region is sized castings than 0, with a simple configuration, the necessary The occupation space is reduced while ensuring the degree, rigidity and durability, the sliding resistance between the travel guide and the chain is reduced, the heat generated by the sliding is reduced, and there is little occurrence of wear and breakage and durability. As long as it is high, its specific configuration may be any.

The guide shoe of the present invention is a guide shoe having a slit groove into which a plate can be inserted from below on the back side of a travel guide portion extending in the chain travel direction, and the travel guide portion is a travel surface extending in the chain travel direction. The guide shoe has a groove with a high pressing force region in a predetermined range in the chain traveling direction from a mounting portion attached to the mounting target or a tensioner contact portion that contacts the tensioner, and a low pressing force region in the other range. has a groove width of the running surface grooves in the high pressure region, rather smaller than the groove width of the slit groove at 0 or more, the groove width of the running surface grooves in the low pressure region, if the size castings from 0 The specific configuration may be any.

The plate is a metal material, and is preferably manufactured by punching from a rolled steel plate, but it is possible to use a known appropriate material and manufacturing method according to various conditions such as rigidity, durability, formability, and cost. Just choose one.
The material of the guide shoe is preferably a synthetic resin, but a known appropriate material may be selected according to various conditions such as friction resistance, rigidity, durability, moldability, and cost.

A chain guide 100 (swing guide) according to an embodiment of the present invention will be described with reference to the drawings.
As shown in FIGS. 1 to 6, the chain guide 100 includes a guide shoe 110 that slides and guides a traveling chain, and a plate 120 that reinforces the guide shoe 110 along the chain traveling direction.
The guide shoe 110 is made of a resin material, and includes a travel guide portion 111 extending in the chain travel direction, and a slit groove 112 into which the plate 120 can be inserted from below on the back side of the travel guide portion 111.
A running surface groove 114 extending in the chain running direction is provided in the center of the surface of the running guide 111 in the width direction.
The plate 120 is made of a plate-like member extending in the chain running direction, has a predetermined curved shape along the chain running direction, and has a uniform cross section. It is inserted and fixed in the groove 112.

As shown in FIG. 4, the cross-sectional shape of the running surface groove 114 is such that the width B is smaller than the thickness A of the plate 120 (the width of the slit groove 112), and the top of the plate 120 (slit) from the surface of the running guide 111. The depth D of the travel surface groove 114 is smaller than 1/2 (C (= ED)> D) with respect to the travel guide portion thickness E up to the bottom of the groove 112).
Further, the center line of the running surface groove 114 in the width direction and the center line of the plate 120 (slit groove 112) are configured to coincide with each other.

As a result, the provision of the running surface groove 114 does not cause an extremely thin portion, and a decrease in the strength of the guide shoe 110 is suppressed.
Further, as shown in FIG. 5, the widthwise end portion of the travel surface groove 114 does not extend outward in the width direction from the plate 120 (slit groove 112), and the travel guide portion 111 of the outer portion of the travel surface groove 114 does not extend. Since the pressing force from the surface can be effectively received by the plate 120 from directly below, the bending in the width direction is also suppressed.

In the chain guide 100 (swing guide) as in the present embodiment, generally, the vicinity of one end portion (the left side in FIG. 3) of the guide shoe 110 is a mounting hole 113 into which a swinging mounting shaft is inserted. Is provided, and the vicinity of the other end (the right side in FIG. 3) constitutes a tensioner contact portion 118.
When the chain is guided by the travel guide portion 111 of the guide shoe 110, the pressing force due to the chain tension is finally received by the mounting shaft and the tensioner, so the vicinity of the mounting portion 117 and the tensioner contact portion. The pressing force is concentrated in the vicinity of 118.

For this reason, as shown in FIG. 3, a high pressing force region 115 is formed in a predetermined range in the chain traveling direction from the attachment portion 117 and the tensioner contact portion 118, and the other range becomes a low pressing force region 116.
In the present embodiment, the running surface groove 114 has the same cross-sectional shape in all sections without distinction between the high pressing force region 115 and the low pressing force region 116. As long as the cross-sectional shape condition is satisfied, the low-pressure region 116 may not satisfy the above-described cross-sectional shape condition.
That is, in the low pressing force region 116, the width B of the running surface groove 114 may be equal to or greater than the thickness A of the plate 120 (width of the slit groove 112), and the depth D is 1 of the running guide portion thickness E. / 2 or more (C (= ED) ≦ D), and the center line of the running surface groove 114 in the width direction may not coincide with the center line of the plate 120 (slit groove 112).

In the present embodiment, the depth from the bottom portion to the open portion of the slit groove 112 is formed on the back surface side of the low pressing force region 116 to be shallower than the depth on the back surface side of the high pressing force region 115.
As a result, as shown in FIG. 6, the exposed area not sandwiched between the slit grooves 112 on the side surface of the plate 120 can be widened, and the heat conducted to the plate 120 can be effectively dissipated.
Further, since the portion where the slit groove 112 is shallow is the low pressing force region 116, the heat dissipation can be improved with almost no influence on the strength, rigidity and durability of the guide shoe 110.

A chain guide 200 (swing guide) according to an embodiment of the present invention will be described with reference to the drawings.
As shown in FIGS. 7 to 9, the chain guide 200 includes a guide shoe 210 that slides and guides a traveling chain, and a plate 220 that reinforces the guide shoe 210 along the chain traveling direction.
The guide shoe 210 is made of a resin material, and includes a travel guide portion 211 that extends in the chain travel direction, and a slit groove 212 into which the plate 220 can be inserted from below on the back side of the travel guide portion 211.
A running surface groove 214 extending in the chain running direction is provided in the center of the surface of the running guide 211 in the width direction.
The plate 220 is made of a plate-like member extending in the chain traveling direction, has a predetermined curved shape along the chain traveling direction, and has a uniform cross section. Inserted and fixed in the groove 212.

As shown in FIGS. 7 and 9A, the running surface groove 214 is not provided in the high pressing force region 215 formed in a predetermined range in the chain running direction from the mounting portion 217 and the tensioner contact portion 218. (That is, the groove width of the running surface groove 214 in the high pressing force region 215 is 0), and it is provided only in the low pressing force region 216 in the middle part thereof.
In the cross-sectional shape of the running surface groove 214 provided in the low pressing force region 216, the width B is equal to or greater than the thickness A of the plate 220 (width of the slit groove 212), as in the conventional example shown in FIG. The depth D of the traveling surface groove 214 is ½ or more with respect to the traveling guide portion thickness E from the surface of the portion 211 to the uppermost portion of the plate 220 (the bottom of the slit groove 212) (C (= E− D) ≦ D).
Further, the center line of the running surface groove 214 in the width direction and the center line of the plate 220 (slit groove 212) are configured to coincide with each other.

The traveling surface groove 214 is not provided in the high pressing force region 215 (that is, the groove width of the traveling surface groove 214 in the high pressing force region 215 is 0). No part is produced, there is no decrease in strength, and no bending occurs in the width direction.
Further, in the low pressing force region 216, the width B of the running surface groove 214 is equal to or greater than the thickness A of the plate 220 (width of the slit groove 212), and the depth D is equal to or greater than ½ of the thickness E of the travel guide portion. Even if (C (= ED) ≦ D), the sliding resistance between the travel guide portion 211 and the chain is greatly increased without substantially affecting the strength, rigidity, and durability of the guide shoe 210 as a whole. The heat generated by sliding can be reduced.
In the present embodiment, the traveling surface groove 214 is not provided in the high pressing force region 215 (that is, the groove width of the traveling surface groove 214 in the high pressing force region 215 is 0). Similar to the embodiment, a running surface groove having a width B smaller than the thickness A of the plate 220 (width of the slit groove 212) may be provided continuously or intermittently.

The chain guides 100 and 200 of the first embodiment and the second embodiment are configured as swing guides that are swingably mounted on one swing mounting shaft P. However, a plurality of mounting shafts Q for fixing are used. You may comprise as a fixed guide fixed to.
Further, although the running surface grooves 114 and 214 are formed in an arc shape in a sectional view, any shape may be used in a sectional view as long as the width and depth match the scope of the present invention.
In addition, various modifications such as the shape, position, size, and arrangement relationship of each component of the chain guide are possible.
Moreover, it is not limited to what is provided in the engine which has a timing system, It can apply to various apparatuses.
Furthermore, the present invention is not limited to a transmission mechanism using a chain, and may be applied to a similar transmission mechanism such as a belt or a rope, and can be used in various industrial fields.

100, 200, 500 ... Chain guide (swing guide)
600 ... Chain guide (fixed guide)
110, 210, 510 ... guide shoes 111, 211, 511 ... travel guide parts 112, 212, 512 ... slit grooves 113, 213 ... mounting holes (of the guide shoes)
114, 214, 514... Running surface grooves 115, 215... High pressing force region 116, 216... Low pressing force region 117, 217. , 220, 520... Plates 121, 221, 521... Mounting holes (for guide shoes)
S1 ・ ・ ・ Drive sprocket S2 ・ ・ ・ Driven sprocket CH ・ ・ ・ Timing chain P ・ ・ ・ Mounting shaft (for swinging)
Q ... Mounting shaft (for fixing)
T ・ ・ ・ Chain tensioner

Claims (6)

A chain guide comprising a guide shoe for slidingly guiding a traveling chain, and a plate for reinforcing the guide shoe along the chain traveling direction,
The guide shoe has a travel guide portion extending in the chain travel direction, and a slit groove into which the plate can be inserted from below on the back side of the travel guide portion,
The travel guide has a travel surface groove extending in the chain travel direction,
The guide shoe has an attachment portion attached to an attachment object, or a high pressing force region in a predetermined range of the chain traveling direction from a tensioner contact portion that contacts the tensioner, and a low pressing force region in other ranges,
The groove width of the running surface grooves in the high pressure region, rather smaller than the groove width of the slit groove at 0 or more,
The groove width of the running surface grooves in the low pressure region, a chain guide, wherein the size Ikoto than 0.   2. The chain guide according to claim 1, wherein a depth of the travel surface groove is smaller than a half of a distance from a surface of the travel guide portion to a bottom portion of the slit groove.   The chain guide according to claim 1 or 2, wherein the running surface groove and the slit groove are formed on the same center line in the width direction of the chain.   The depth from the bottom part of the slit groove to the open part is formed shallower than the depth on the back side of the high pressing force region on the back side of the low pressing force region. Item 4. The chain guide according to any one of Items 3 to 3.   The chain guide according to any one of claims 1 to 4, wherein a groove width of the running surface groove is larger than a groove width of the slit groove in the low pressing force region. A guide shoe having a slit groove in which a plate can be inserted from below on the back side of the travel guide portion extending in the chain travel direction,
The travel guide has a travel surface groove extending in the chain travel direction,
The guide shoe has an attachment portion attached to an attachment object, or a high pressing force region in a predetermined range of the chain traveling direction from a tensioner contact portion that contacts the tensioner, and a low pressing force region in other ranges,
The groove width of the running surface grooves in the high pressure region, rather smaller than the groove width of the slit groove at 0 or more,
The guide shoe groove width of the running surface grooves in the low pressure region, characterized characterized the magnitude Ikoto than 0.

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