JP2006258109A - Power transmission device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a power transmission device preventing abnormal wear of a resin pulley and obtaining high strength joining of the pulley and a hub without a bolt and an insert metal fitting or the like. <P>SOLUTION: The power transmission device is provided with a pulley 1 and a hub 2 which consists of an inner hub 21, a damper rubber 22 and an outer hub 23, and forms a torque transmission structure of the hub and the pulley by engaging a hub side engagement part 24 which consists of an elastic body provided on an inner circumference surface side, or an outer circumference surface side or both of the inner and the outer circumference surface side of the outer hub, and a pulley side engagement part 12 provided on a position corresponding to the outer hub of the pulley by projection and recess fitting. Outer shapes of the hub side engagement part and the pulley side engagement side is projection and recess shape and mesh each other. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a power transmission device having a function of a torque limiter, and is particularly suitable for being incorporated in a vehicle compressor.

2. Description of the Related Art Conventionally, in a power transmission device that transmits power to a compressor, a hub and a pulley having a damper damping mechanism such as rubber are coupled with each other as shown in FIGS. 21 (a) and 21 (b). It was done. That is, when the pulley A is made of metal such as iron, the pulley A and the hub B are coupled with a bolt C or the like by screwing the pulley A as shown in FIG. ). Reference sign D is a damper rubber.
Further, in the pulley A made of a resin or the like whose material strength is relatively lower than that of a metal, as shown in FIG. 21B, a fitting E or the like that can be screw-fitted is inserted into the pulley by a method such as insert molding. The hub B and the pulley A are coupled by coupling the bracket E to the bolt C by means of a bolt C or the like (see Patent Document 2).

However, the coupling method shown in FIG. 21 (b) requires a new part such as a metal fitting to be screwed with a bolt or the like, resulting in a problem of high cost. In addition, for example, in the case of a pulley made of a resin material, it is necessary to provide the metal fitting by means such as insert molding, but there is also a problem that the bonding strength between the metal fitting and the resin material is significantly reduced due to a change over time such as creep of the resin material. .
Furthermore, in the case of a resin pulley, a reinforcing material such as glass fiber is mixed in order to improve the material strength, but it is difficult to make the orientation of the glass fiber as intended by the insert of the metal fitting. There is also a problem that the bonding strength around the metal fitting cannot be obtained.

Therefore, in the prior art, as shown in FIG. 21 (c), a convex portion B1 is formed on the outer ring of the hub B and a concave portion A1 is formed on the inner periphery of the resin pulley A (patented). By referring to Document 3, the bolt B or the like is not required when the hub B and the pulley A are fitted.
However, in this prior art, due to excessive torque or torque fluctuation, the convex part of the outer ring and the concave part of the pulley are in direct contact, and the concave part of the resin pulley, which is inferior in strength and wear resistance than the outer ring, is abnormally worn. There is a problem of end up.

JP 2001-153152 A JP 2003-56595 A JP 2002-364667 A

  The present invention has been made in view of the above problems, and its purpose is not to require bolts or insert metal fittings, etc., and can prevent abnormal wear of the resin pulley, and the high strength of the pulley and hub. It is providing the power transmission device from which the coupling structure of this is obtained.

The present invention provides a power transmission device according to each of the claims as means for solving the problems.
The power transmission device according to claim 1 includes a pulley 1 and a hub 2 including an inner hub 21, an outer hub 23, and a torque transmission elastic member 22, and the inner peripheral surface side or outer peripheral surface of the outer hub 23. By engaging the hub side engaging portion 24 made of an elastic material provided on the side or inner and outer peripheral surface side with the pulley side engaging portion 12 provided at a position corresponding to the outer hub 23 of the pulley 1. A torque transmission structure is formed between the hub 2 and the pulley 1, whereby a high-strength coupling between the pulley and the hub can be obtained without the need for bolts or insert fittings.

In the power transmission device according to the second aspect, the pulley 1 is made of a resin material. Thus, in the present invention, even if the pulley 1 is made of a resin material, the hub side engaging portion 24 is made of an elastic member, so that abnormal pulley wear can be prevented.
In the power transmission device according to the third aspect, the outer shapes of the hub-side engagement portion 24 and the pulley-side engagement portion 12 are irregular shapes such as involute splines and trochoids. Engage and a high strength connection between the pulley and the hub is obtained.

The power transmission device according to claim 4 is configured such that the hub-side engagement portion 24 and the pulley-side engagement portion 12 have a fitting structure, so that the two fit firmly without using bolts or the like. Can be combined.
In the power transmission device according to the fifth aspect, the hub side engaging portion 24 is provided on the outer hub 23 by integral molding or adhesion. That is, the outer hub 23 and the hub-side engagement portion 24 may be integrally formed by insert molding, or the hub-side engagement portion 24 may be attached to the outer hub 23 by adhesion.
In the power transmission device according to the sixth aspect, the hub side engagement portion 24 is integrally formed as a part of the elastic member 22 for torque transmission, thereby reducing the number of parts.

In the power transmission device according to the seventh aspect, a plurality of slits 25 are formed in the rear side portion of the hub side engaging portion 24 and the outer hub 23 at intervals in the circumferential direction. In the case of being made of a material such as a resin having a relatively lower strength than that of the pulley, a reinforcing portion (rib) for securing the strength may be necessary. In such a case, if the hub-side engaging portion 24 is formed in a complete annular shape, the rib of the resin pulley and the hub-side engaging portion 24 may interfere with each other and may not be assembled. By forming the slit 25 in the rear side portion of the hub side engaging portion 24 and the outer hub 23, the problem of assembly can be avoided.
In the power transmission device according to the eighth aspect, at least one of the first or second hub side engagement portions 24a and 24b of the hub side engagement portion 24 or the inner or outer surfaces 11a and 11b of the recess 11 of the pulley 1 is provided. Is formed in a substantially tapered shape, and thereby, the assembling property between the hub 2 and the pulley 1 can be improved.

In the power transmission device according to the ninth aspect, the outer hub 23 is an outer ring 23 that is a separate body from the hub-side engagement portion 24.
In the power transmission device according to the tenth aspect, the entire surface of the outer ring which is the outer hub 23 is covered with an elastic material such as rubber or resin forming the torque transmission elastic member 22 or the hub side engagement portion 24. As a result, the outer ring has no exposed portion on the outside, and it is not necessary to apply coating, etc., and the corrosion resistance and antiglare property of the outer hub can be improved, and the aesthetics can be further improved. Moreover, since the painting process can be eliminated, the factory environment is improved and the necessary equipment is not required, so that the cost can be reduced.

In the power transmission device according to the eleventh aspect, the outer ring 23, which is an outer hub, is provided with a reinforcing portion 23a that protrudes into the hub-side engagement portion 24. The strength of the part can be improved.
In the power transmission device according to the twelfth aspect, the outer ring 23 is made of metal, whereby the strength of the outer hub 23 can be improved.

The power transmission device according to claim 13 is formed by offsetting the hub side engaging portion 24 to the base side of the rotary shaft 3 as compared with the torque transmitting elastic member 22 and pressing the metal outer ring 23 from the radial direction. Thus, a space S for squeezing the metal outer ring 23 installed on the outer periphery of the torque transmission elastic member 22 can be secured, and a squeezing step can be added to the torque transmission elastic member 22. Durability can be secured.
In the power transmission device according to the fourteenth aspect, the hub side engaging portion 24 is offset to the base side of the rotating shaft 3 as compared with the torque transmitting elastic member 22, and the inner hub 21 or The balancer weight 9 attached to the rotary shaft 3 is arranged, and the balancer weight 9 can be arranged in the space S formed by offsetting in this way, and a low-noise, low-vibration power transmission device is provided. can get.

In the power transmission device according to the fifteenth aspect, the maximum width HW of each convex portion 241 of the hub side engaging portion 24 is equal to or greater than the maximum width PW of each convex portion 121 of the pulley side engaging portion 12. As a result, the strength of each convex portion 241 of the hub side engaging portion 24 can be improved, and the hub side engaging portion 24 is not worn abnormally, and further, the convex portion 241 is not destroyed.
In the power transmission device according to the sixteenth aspect, a gap g of 0.001 mm or more is provided between the tip portion 241a of the convex portion 241 of the hub side engaging portion 24 and the bottom portion 122a of the concave portion 122 of the pulley side engaging portion 12. As a result, the tip portion 241a of the convex portion 241 of the hub-side engaging portion 24 made of an elastic member can be prevented from being worn by sliding in contact with the pulley-side engaging portion 12. it can.

In the power transmission device according to the seventeenth aspect, the R1 portion 242d and the R2 portion 242e are formed on both sides of the bottom portion 242a of the concave portion 242 of the hub side engaging portion 24, and the R1 portion 242d on the rotational direction side is in the counter-rotating direction. R-shaped portion having a larger diameter than the R2 portion 242e on the side, thereby reducing the tensile stress S generated at the root portion of the convex portion 241 of the hub-side engaging portion 24 due to excessive torque. It is possible to prevent damage to the convex portion 241 and improve the durability of the power transmission device.
In the power transmission device according to claim 18, the side surfaces 241b and 241c of the respective convex portions 241 of the hub side engaging portion 24 and the side surfaces 122b and 122c of the respective concave portions 122 of the pulley side engaging portion 12 are brought into contact with each other. And the torque transmission surface TF is disposed on the normal line NL of the pulley 1, whereby an uneven fitting portion between the hub side engagement portion 24 and the pulley side engagement portion 12 is formed. It is possible to prevent a slight slip during torque transmission.

In the power transmission device according to the nineteenth aspect, the torque transmission surface TF is shifted from the normal line NL by a predetermined angle in the rotational direction of the pulley 1, and even in this case, the occurrence of slight slippage during torque transmission is prevented. It can be avoided sufficiently.
In the power transmission device according to claim 20, the side surface of each convex portion 121 of the pulley side engaging portion 12 and the side surface of each concave portion 242 of the hub side engaging portion 24 are in contact with each other to form a torque transmission surface TF. The rotation-side torque transmission surface TF and the counter-rotation-side torque transmission surface TF of each convex portion of the pulley-side engagement portion are substantially parallel to each other. Even in such a case, the pulley 1 and the hub It is possible to prevent the occurrence of a slight slip at the two concave-convex fitting portions.

  In the power transmission device according to the twenty-first aspect, a low coefficient of friction material is provided on the surface of the hub side engaging portion 24 by adhesion, coating, surface treatment, or the like. Abrasion can be improved and a long-life power transmission device can be obtained.

  Hereinafter, a power transmission device according to an embodiment of the present invention will be described with reference to the drawings. The power transmission device of the present invention is suitable for being assembled in a compressor of a vehicle air conditioner. FIG. 1 is a front view of the power transmission device according to the first embodiment of the present invention, and FIG. 2 is a cross-sectional view taken along line AA of FIG. The power transmission device according to the present invention has a power transmission between a pulley 1 that is a driving side rotating member that receives driving from an engine or a motor, and a hub 2 that is a driven side rotating member fixed to a rotating shaft 3 of the compressor. Torque). The pulley 1 and the hub 2 are provided coaxially.

  The pulley 1 is rotatably mounted via a bearing device 5 on a cylindrical portion 41 provided on one end side of the housing 4 of the compressor. The pulley 1 is preferably molded from a thermoplastic synthetic resin, but may be formed from a metal material such as iron. When the pulley 1 is made of resin, the pulley 1 and the bearing device 5 are usually integrated by insert molding. A belt (not shown) is wound around the outer peripheral surface of the pulley 1 and is rotated by external power such as an engine or a motor. The bearing device 5 is fitted to the cylindrical portion 41 and is prevented from moving in the axial direction by a retaining ring (snap ring) 7 fitted in a groove formed on the outer peripheral surface of the cylindrical portion 41. The housing 4 and the rotating shaft 3 are sealed by a shaft seal device 6 to prevent leakage of refrigerant, oil, and the like.

  The front end 31 of the rotary shaft 3 of the compressor protrudes from the housing 4, and a threaded portion is formed on the outer peripheral surface of the front end 31. The cylindrical hub 2 is fixed to the front end 31 by screwing. ing. For fixing the hub 2 to the rotary shaft 3, other fixing methods such as spline engagement and bolt mounting can be appropriately employed. Reference numeral 8 denotes a washer.

The hub 2 includes an inner hub 21, a damper rubber 22 that is an elastic member for torque transmission, and an outer hub 23, and a hub side engagement portion 24.
The inner hub 21 has a cylindrical portion 21 a that is screwed to the tip portion 31 of the rotary shaft 3 and a cylindrical flange portion 21 c that protrudes to the front side (left side in FIG. 2) and whose outer peripheral surface is joined to the damper rubber 22. And a disc-shaped intermediate portion 21b connecting the cylindrical portion 21a and the flange portion 21c. A screw portion is formed on the inner peripheral surface of the cylindrical portion 21a. The inner hub 21 is formed of a metal material such as iron.

The outer hub 23 has a cylindrical shape and is formed of a metal material such as iron, like the inner hub 21.
An annular damper rubber 22 that is an elastic member for torque transmission is formed of an elastic material such as rubber, and is disposed and held between the inner hub 21 and the outer hub 23, and the outer peripheral surface of the flange portion 21 c of the inner hub 21 and It is joined to the inner peripheral surface of the outer hub 23 by means such as adhesion. The damper rubber 22 not only functions as an elastic body for torque transmission but also functions as a torque damper.

  A first hub side engaging portion 24a is provided on the inner peripheral surface on the rear side (right side in FIG. 2) of the outer hub 23, and a second hub side engaging portion 24b is provided on the outer peripheral surface thereof. 23 is provided over substantially the entire circumference. The first and second hub side engaging portions 24a, 24b are formed of an elastic material such as rubber or resin, and the outer shape thereof is an uneven shape such as an involute spline or trochoid. The first and second hub-side engaging portions 24a and 24b are joined to the respective peripheral surfaces of the outer hub 23 by adhesion or the like, or are formed integrally with the outer hub 23 by insert molding. The hub-side engagement portion 24 may be provided on the inner peripheral surface or one of the outer peripheral surfaces of the outer hub 23 or, as shown in FIG. 2, the first and second hub sides. The engaging portions 24 a and 24 b and the damper rubber 22 may be integrated so that the first and second hub side engaging portions 24 a and 24 b wrap around the rear side portion of the outer hub 23.

  On the other hand, in the pulley 1, an annular recess 11 for receiving the hub side engaging portion 24 is formed on the front side surface. The first and second pulley-side engaging portions 12a and 12b whose outer shape is an uneven shape such as an involute spline or trochoid are attached to the inner surface 11a and the outer surface 11b of the annular recess 11 by means such as adhesion. It is joined. In addition, you may make it stick the pulley side engaging part 12 to one of the inner surface 11a of the cyclic | annular recessed part 11, or the outer surface 11b. The first and second pulley side engaging portions 12a and 12b are also formed of an elastic material such as rubber or resin.

  Thus, by fitting the hub side engaging portion 24 into the annular recess 11 (pulley side engaging portion 12) of the pulley 1, the first hub side engaging portion 24a, the first pulley side engaging portion 12a, Are engaged, and the second hub side engaging portion 24b and the second pulley side engaging portion 12b are engaged with each other, whereby the hub 2 and the pulley 1 are connected.

  As described above, in the first embodiment, the hub 2 and the pulley 1 are coupled to each other by fitting the hub side engaging portion 24 provided on the hub 2 and the pulley side engaging portion 12 provided on the pulley 1. At the same time, it is carried out by meshing in an uneven shape with its outer shape, so that a power transmission structure having a high transmission force can be obtained without requiring a bolt or the like.

  Moreover, even if the pulley 1 is formed of a relatively low-strength material such as resin, insert molding such as metal fittings is not required, and a low-cost power transmission structure can be obtained. Furthermore, since insert molding is not required, deterioration of the flow of the strength improving material (glass fiber or the like) in insert molding can be avoided, and the pulley can be increased in strength as intended.

  Furthermore, since the engaging portion made of an elastic material is provided on the outer hub, even if it is a resin pulley, abnormal wear occurs at the fitting portion due to the difference in strength and wear resistance of the hub and pulley members. Can be prevented.

  In the first embodiment, the hub side engaging portion 24 and the outer hub 23 are described as being formed in an annular shape with the entire circumference being continuous, but in this embodiment, FIG. As shown in the perspective view of the hub, a plurality of slits 25 may be formed at appropriate intervals in the circumferential direction between the hub side engaging portion 24 and the rear side portion of the outer hub 23. . By making the hub side engaging portion 24 and the rear side portion of the outer hub 23 into a plurality of divided shapes in this way, for example, a pulley 1 made of a material such as a resin whose strength is relatively inferior to that of a metal pulley 1. In the pulley structure in which the strength reinforcing portion (rib) 11c and the like are provided in the radial direction on the bottom surface of the concave portion 11 of the pulley 1, the pulley 1 can be provided by making the strength reinforcing portion (rib) 11c correspond to the slit 25. An inexpensive, small and light power transmission device can be obtained without worrying about the interference with the hub 2.

FIG. 4 is a cross-sectional view of the pulley showing the second embodiment. In the second embodiment, the outer surface 11b of the recess 11 of the pulley 1 is formed in a substantially tapered shape (inclined) so as to be slightly narrowed from the front side to the rear side. Thereby, the assembly | attachment property of the hub 2 and the pulley 1 can be improved, and the productivity can be improved. Naturally, the inner surface 11a of the recess 11 of the pulley 1 may be formed in a substantially tapered shape, and further, both the outer surface 11b and the inner surface 11a may be formed in a substantially tapered shape.
Further, the outer shape of one or both of the first or second hub side engaging portions 24a and 24b of the hub side engaging portion 24 which is not the pulley 1 side but the hub 2 side may be formed in a substantially tapered shape.

  FIG. 5 is a cross-sectional view of a main part showing the third embodiment. In the first embodiment, the upper surface of the outer hub 23 is exposed outside the portion where the second hub side engaging portion 24b is formed, that is, the upper surface of the front side portion is exposed to the outside. Thus, if there is a portion where the upper surface of the outer hub 23 is not covered with the torque transmitting elastic member 22, for example, when the outer hub 23 is formed of a metal outer ring 23, the corrosion resistance is increased. There are problems and aesthetics are not desirable. Therefore, in the first embodiment, it is necessary to paint the upper surface of the outer hub 23 exposed to the outside. Therefore, in the third embodiment, the entire surface including the exposed upper surface 23 b of the outer hub 23 is covered with the torque transmission elastic member 22. The exposed upper surface 23b may be covered with a thin elastic member 22. Other configurations are basically the same as those in the first embodiment, and thus description thereof is omitted.

  Thereby, the corrosion resistance of the outer hub (outer ring) 23 can be improved. Further, since the outer hub 23 has the same color as that of the torque transmitting elastic member 22, for example, if a black elastic material is selected, the antiglare property is good and the luxury feeling can be improved. Furthermore, since there is no need for painting and the painting process can be eliminated, the factory environment is improved and the necessary equipment is not required, so that the cost can be reduced.

  FIG. 6 is a cross-sectional view of a main part showing the fourth embodiment, and FIG. 7 is a front view of the upper half of the power transmission device of the fourth embodiment. In the first to third embodiments, the uneven portion of the hub side engaging portion 24 is formed of the same elastic material as the torque transmitting elastic member 22. Therefore, during high load operation where the compressor driving torque is large, or when the compressor seizes and excessive torque is generated in the concavo-convex portion of the hub side engaging portion 24, the strength of the concavo-convex portion or The strength of the adhesive that bonds the hub side engaging portion 24 to the inner and outer circumferences of the outer hub (outer ring) 23 is insufficient, and the uneven portion and the hub side engaging portion 24 are cracked or the uneven portion is destroyed. There is a risk of malfunction.

  Therefore, in the fourth embodiment, the outer hub (outer ring) 23 is provided with a plurality of reinforcing portions 23a in the normal direction, and the reinforcing portions 23a are embedded in the uneven portions of the second hub side engaging portion 24b. The reinforcing portion 23a may be formed integrally with the outer hub 23 by cutting and raising a part of the outer hub 23, or may be formed separately and fixed to the outer hub 23 by welding or the like. In the fourth embodiment, the reinforcing portion 23a is formed so as to face outward in the radial direction, the plurality of slits 25 are provided in the circumferential direction in the second hub side engaging portion 24b, and the uneven portion is formed. When divided into a plurality of groups, as shown in FIG. 7, reinforcing portions 23a are embedded in the convex portions on both sides of the group. Since other configurations are basically the same as those of the first embodiment, description thereof is omitted.

  As described above, by providing the outer hub 23 with the reinforcing portion 23 a and embedding the reinforcing portion 23 a in the concave and convex portion of the hub side engaging portion 24, the strength of the concave and convex portion can be improved. That is, when excessive torque is generated, torque is received by the reinforcing portion 23a, so that a large displacement of the elastic member can be suppressed, and damage to the elastic member can be prevented.

FIG. 8 shows first to third modifications (a), (b), and (c) of the fourth embodiment. That is, in the first modification of FIG. 8A, the outer hub 23 is provided with the reinforcing portion 23a so as to face inward in the radial direction. The reinforcing portion 23a is the first hub side engaging portion. It is embedded in the uneven part of 24a.
In the second modification of FIG. 8B, the reinforcing portion 23a provided on the outer hub 23 so as to face outward in the radial direction is formed in the concavo-convex portion of the second hub side engaging portion 24b in the rotational direction. On the other hand, it is embedded only in the convex portion corresponding to the rear side in the group.
In the third modification of FIG. 8C, the reinforcing portion 23a provided on the outer hub 23 so as to face outward in the radial direction is formed in the concavo-convex portion of the second hub side engaging portion 24b in the rotational direction. On the other hand, it is embedded only in the convex portion corresponding to the front side in the group.
In any case of the first to third modifications described above, the strength of the hub side engaging portion 24 can be improved.
In the first modification of FIG. 8A, the outer hub 23 includes both the first hub side engaging portion 24a on the inner peripheral side and the second hub side engaging portion 24b on the outer peripheral side. The reinforcing portion 23a is embedded in the convex portion of the first hub side engagement, but as shown in FIGS. 9A and 9B, the outer hub 23 has the hub side engaging portion 24 only on the inner peripheral side. In this case, a part of the outer ring 23 may be embedded in the hub side engaging portion 24 as the reinforcing portion 23a. Similarly, in the case where the hub side engaging portion 24 is provided only on the outer peripheral side of the outer hub 23, a part of the outer ring 23 may be embedded in the hub side engaging portion as the reinforcing portion 23a.
9A is a cross-sectional view taken along the broken line XX ′ in FIG. 9B, and the reference numerals shown in FIGS. 9A and 9B are the same as those in the other embodiments. The same configuration is indicated.

  FIG. 10 is a cross-sectional view of an essential part showing the fifth embodiment, and FIG. 11 shows another embodiment of the present invention for comparison with the fifth embodiment. As shown in the first embodiment of FIG. 2 and the comparative example of FIG. 11, the hub side comprising the axial center A of the cylindrical elastic portion 22 a that is the main body portion of the torque transmitting elastic member 22 and the torque transmitting elastic member 22. In the case where the engagement portion 24 and the axial center B are installed with almost no offset, the cylindrical elastic portion 22a cannot be drawn and the durability of the cylindrical elastic portion 22a is significantly reduced, resulting in excessive torque or excessive amount. When a torque fluctuation is applied, the cylindrical elastic portion 22a of the torque transmitting elastic member 22 may be destroyed. Therefore, in the fifth embodiment, the hub side engaging portion 24 formed of the torque transmitting elastic member 22 and the cylindrical elastic portion 22a that is the main body portion of the torque transmitting elastic member 22 are provided in an offset shape. This also enables drawing of the outer peripheral portion of the cylindrical elastic portion 22a (the outer peripheral portion of the outer hub).

  That is, in the fifth embodiment, the rear half of the outer side of the outer hub 23 is surrounded by the torque transmission elastic member 22 and the outer peripheral surface thereof is made uneven to form the hub side engaging portion 24. The inner peripheral surface of the front half of the outer side of the outer hub 23 and the outer peripheral surface of the inner hub 21 sandwich the torque transmitting elastic member 22 to form a cylindrical elastic portion 22a. The axial center B of the hub side engaging portion 24 and the axial center A of the cylindrical elastic portion 22a are offset by ε. The offset amount ε is preferably ¼ or more with respect to the minimum wall thickness t of the cylindrical elastic portion 22a. As a result, a space S is secured in the upper part on the front side of the outer hub 23 so that the outer peripheral portion of the cylindrical elastic portion 22a (the outer peripheral portion of the outer hub 23) is drawn by the jig shown in FIG. . This drawing process is performed for the purpose of improving the durability of the elastic member 22, and the drawing rate is known to be about several tens of percent of the outer shape of the cylindrical elastic portion 22a. In FIG. 5, the step 23c is formed on the outer hub 23 to indicate that this drawing has been performed. Other configurations are basically the same as those in the first embodiment.

  10 shows a structure in which the inner hub 21 and the rotary shaft 3 are connected via a torque limiter 26, but as shown in FIG. The present embodiment can also be applied to a structure in which are directly connected.

  FIG. 12 is a longitudinal sectional view of the power transmission device showing the sixth embodiment. In the sixth embodiment, the weight portion 91 of the balancer weight 9 is accommodated in the space S using the space S formed in the fifth embodiment. The balancer weight 9 has a substantially disk shape as a whole, and a weight portion 91 is provided in the vicinity of the outer peripheral portion thereof. The balancer weight 9 is fixed to the front side of the inner hub 21 by a fixture 10 such as a rivet or a bolt, and the weight portion 91 is formed in a space S formed on the front side of the second hub side engagement portion 24b. It is attached so as to be in the corresponding position. Note that the balancer weight 9 may be attached by a screw or the like without using the fixture 10 or by means such as press-fitting or caulking. Other configurations are basically the same as those in the first embodiment.

  Thus, by installing the balancer weight 9 using the space S, it is possible to provide a power transmission device that can be installed without requiring a significant increase in physique and that is low in noise and vibration.

13A and 13B are a front view and a cross-sectional view illustrating an example of a drawing process of the cylindrical elastic portion 22a. The hub 2 including the outer hub 23, the torque transmission elastic member 22 including the hub side engagement portion 24, the inner hub 21 and the torque limiter 26 is set in the jig 200, and the cylindrical elasticity of the torque transmission elastic member 22 is set. A plurality of cams 16 (16 in FIG. 13) abut on the outer periphery of the portion 22a and are arranged in the circumferential direction. The cam 201 has a trapezoidal shape and has a tapered surface on the outside. Corresponding to these cams 201, the same number of jigs 202 as the cams 201 are arranged in the circumferential direction outside the cams 201. The jig 202 is also trapezoidal and has a tapered surface on the inside. The cam 201, the taper surface, and the taper surface of the jig 202 are disposed in contact with each other. By sliding the jig 202 from right to left in FIG. 15, the cam 201 moves in the direction of reducing the diameter. . Accordingly, the cylindrical elastic portion 22a of the torque transmitting elastic member 22 is pressed in the radial direction and drawn. Accordingly, the outer peripheral portion of the cylindrical elastic portion 22a (the outer peripheral portion of the outer hub) has a substantially hexagonal shape.
Here, the durability of the cylindrical elastic portion 22a with respect to the rotational strain varies depending on the radial strain of the cylindrical elastic portion 22a, and the durability against the rotational strain is increased as the cylindrical elastic portion 22a is distorted by being pulled in the radial direction. On the contrary, the durability against strain in the rotational direction increases as the pressure is squeezed and distorted in the radial direction.
Further, since the cylindrical elastic portion 22a is sandwiched between the outer hub 23 and the inner hub 21 and is molded at a high temperature, when the cylindrical elastic portion 22a contracts as it cools, the bonding surface of the outer hub 23 and the inner hub 21 becomes the cylindrical elastic portion. 22a is pulled in the radial direction.
That is, as described above, by performing the drawing process, the strain can be relieved by the tensile stress in the radial direction of the cylindrical elastic portion 22a, and the strain in the rotational direction of the cylindrical elastic portion 22a of the elastic member 22 for torque transmission can be reduced. Durability can be ensured.

  14-17 is a figure explaining the power transmission device of 7th Embodiment. When the hub-side engagement portion 24 and the pulley-side engagement portion 12 are concavo-convexly fitted and power is transmitted through the concavo-convex engagement portion, torque caused by the compression force generated by the compressor when operated with an excessive load Due to the fluctuation, there is a problem that the uneven portion of the hub side engaging portion 24 made of an elastic member rubs abnormally or the uneven portion is destroyed. Therefore, in the seventh embodiment, the shapes of the concavo-convex portions of the hub side engaging portion 24 and the pulley side engaging portion 12 are improved from three viewpoints.

  FIG. 14A is a main part front view for explaining the power transmission device of the seventh embodiment viewed from the first viewpoint, and FIG. 14B is a key diagram showing another embodiment for comparison. FIG. That is, as shown in FIG. 14B, the maximum width HW of the concavo-convex convex portion 241 of the hub side engaging portion 24 is larger than the maximum width PW of the concavo-convex convex portion 121 of the pulley side engaging portion 12. When it is set to be small, there is a problem in the durability of the hub side engaging portion 24. Therefore, the first viewpoint is to improve the width of the convex portion 241 of the hub side engaging portion 24.

  In FIG. 14A, in the concave / convex fitting between the pulley side engaging portion 12 and the hub side engaging portion 24, the concave / convex portion of the hub side engaging portion 24 is substantially divided into six parts. Six slits 25 are provided, and three convex portions 241 and two concave portions 242 are formed between the slits 25. On the other hand, the pulley side engaging portion 12 corresponds to the hub side engaging portion 24, and a rib 11c is provided for the slit 25, and two convex portions 121 and three concave portions 122 are formed between the ribs 11c. Has been. In this manner, the hub-side engagement portion 24 and the pulley-side engagement portion 12 are concavo-convexly fitted. In the seventh embodiment, the maximum width HW of the convex portion 241 of the hub-side engaging portion 24 made of an elastic member is HW ≧ PW with respect to the maximum width PW of the convex portion 121 of the pulley-side engaging portion 12. I try to be equal or better. Therefore, the strength of the hub side engaging portion 24 can be efficiently improved in a physique with a limited width of the elastic member.

  FIG. 15A is a front view of a main part for explaining the power transmission device of the seventh embodiment from the second viewpoint, and FIG. 15B is a key diagram showing another embodiment for comparison. FIG. That is, as shown in FIG. 15 (b), when the tip portion 241 a of the convex portion 241 of the hub side engaging portion 24 and the bottom portion 122 a of the concave portion 122 of the pulley side engaging portion 12 are in contact, sliding Thus, the convex portion 241 of the hub side engaging portion 24 made of an elastic member is worn. In general, the hub 2 and the pulley 1 generate a slight displacement when an excessive torque is transmitted. However, when the two are in contact with each other as described above, the hub 2 and the pulley 1 are slid. Wear.

  Therefore, in the seventh embodiment, as shown in FIG. 15A, between the tip portion 241 a of the convex portion 241 of the hub side engaging portion 24 and the bottom portion 122 a of the concave portion 122 of the pulley side engaging portion 12. A gap g of at least 0.001 mm is provided. In this way, by providing the gap g between the tip portion 241a of the convex portion 241 of the hub side engaging portion 24 made of an elastic member and the bottom portion 122a of the concave portion 122 of the pulley side engaging portion 12, contact between the two is possible. It is intended to prevent wear due to.

  FIG. 16 and FIG. 17 (a) are main part front views for explaining the power transmission device of the seventh embodiment from the third viewpoint, and FIG. 17 (b) is another embodiment for comparison. It is a principal part front view which shows. That is, as shown in FIG. 17B, a large tensile stress F is generated in the R1 portion 242d, which is the corner portion on the rotational direction side of the bottom portion 242a of the concave portion 242 of the hub side engaging portion 24, due to excessive torque. Therefore, when the radius of curvature r of the R1 portion 242d is small, the stress F may not be endured and may be damaged.

Therefore, in the seventh embodiment, as shown in FIGS. 16 and 17A, out of the R1 portion 242d and the R2 portion 242e provided on both sides of the bottom portion 242a of the concave portion 242 of the hub side engaging portion 24, The curvature radius r of the R1 portion 242b located on the rotation direction side (front side) is made larger than the curvature radius r of the R2 portion 242e located on the counter rotation direction side (rear side). As a result, the tensile stress S generated at the R1 portion (corner portion) 242d (the root portion of the convex portion 241) of the bottom portion 242a of the concave portion 242 of the hub side engaging portion 24 due to excessive torque is alleviated, and the durability of the power transmission device is increased. Can be improved. Note that if the radius of curvature r of the R1 portion 242d and the R2 portion 242e on both the rotation direction side and the counter rotation direction side is increased, the width of the convex portion 121 of the pulley-side engagement portion 12 is increased, and the pulley is large as a whole. In the seventh embodiment, it is preferable to increase the radius of curvature r of only the R1 portion 242d on the rotation direction side.
Therefore, the concave portion 242 of the hub side engaging portion 24 is asymmetric between the rotational direction side and the counter rotational direction side.

  Thus, in the seventh embodiment, (1) the maximum width HW of the convex portion 241 of the hub side engaging portion 24 is equal to or greater than the maximum width PW of the convex portion 121 of the pulley side engaging portion 12. Thus, the strength of the convex portion 241 of the hub side engaging portion 24 is improved, and (2) the tip portion 241a of the convex portion 241 of the hub side engaging portion 24 and the bottom of the concave portion 122 of the pulley side engaging portion 12 are achieved. A gap g is provided between the portion 122a and the wear of the convex portion 241 of the hub side engaging portion 24, and (3) corner portions on both sides of the bottom portion 242a of the concave portion 242 of the hub side engaging portion 24. Among the R1 part 242d and R2 part 242e, the tensile stress generated in the R1 part 242d by making the curvature radius r of the R1 part 242d on the rotation direction side larger than the curvature radius r of the R2 part 242e on the counter-rotation direction side Relief of F, etc. By improving the section shape is obtained by improving the durability of the power transmission device.

  FIGS. 18-19 (a) is a principal part front view explaining the power transmission device of 8th Embodiment. In the eighth embodiment, the positions of the transmission surfaces of both the concave and convex portions that transmit the torque of the concave and convex fitting portions of the hub side engaging portion 24 and the pulley side engaging portion 12 are improved. That is, as shown in FIG. 19 (b), when the uneven portions of the pulley-side engaging portion 12 of the pulley 1 and the hub-side engaging portion 24 of the hub 2 have an uneven shape composed of a spline profile, The side surfaces 122b and 122c of the concave portion 122 of the engaging portion 12 and the side surfaces 241b and 241c of the convex portion 241 of the hub side engaging portion 24 are in contact with each other for power transmission and form a torque transmission surface TF. The torque transmission surface TF is formed at a position shifted by an α angle with respect to the rotation direction (normal direction). For this reason, when an excessive torque is generated or a torque fluctuation is generated, the uneven fitting portion is twisted by the pulley 1 and the rotary shaft 3 of the compressor, and is shown in FIG. There is a risk that the torque transmission surface TF of the concavo-convex portion of the hub-side engagement portion 24 made of an elastic member will be abnormally worn.

  Therefore, in the eighth embodiment, the position of the torque transmission surface TF is improved. As shown in FIG. 18A, the side surfaces 241b and 241c of the convex portion 241 of the hub side engaging portion 24 (the slit 25 is regarded as a concave portion of the hub side engaging portion 24) and the pulley side engaging portion 12 (the rib 11c is Side surfaces 122b and 122c of the concave portion 122 of the pulley-side engaging portion 12) are in contact with each other to form a torque transmission surface TF. In the eighth embodiment, the torque transmission surface TF is arranged on the normal line NL of the pulley 1 (in other words, a straight line perpendicular to the circumference of an arbitrary circle centered on the rotation axis and the radial direction). The concave and convex portions of the hub side engaging portion 24 and the pulley side engaging portion 12 are formed. FIG. 18B is a front view of the uneven portion of the pulley side engaging portion 12. The side surfaces 121b and 121c (also the side surfaces 122b and 122c of the concave portion 122) of the convex portion 121 of the pulley-side engaging portion 12 (including the rib 11c) are torque transmission surfaces TF, and all the torque transmission surfaces TF are pulleys. 1 on the normal line NL. FIG. 18C is a front view of the uneven portion of the hub side engaging portion 24. The side surfaces 241b and 241c (also side surfaces 242b and 242c of the concave portion 242) of the convex portion 241 of the hub side engaging portion 24 (including the slit 25) are torque transmission surfaces TF, and all the torque transmission surfaces TF are pulleys. 1 on the normal line NL.

  FIG. 19A shows a modification of the eighth embodiment, and the torque transmission surface TF may be shifted by a predetermined angle β in the rotational direction with reference to the normal line NL of the pulley 1. There is no problem even if the predetermined angle β is shifted up to about 10 degrees in the rotation direction or about 45 degrees in the counter rotation direction (−45 degrees from the rotation direction) with respect to the normal line NL.

In the eighth embodiment, even if the two torque transmission surfaces TF formed by the rotation-side side surface 121b and the counter-rotation-side side surface 121c of the convex portion 121 of the pulley-side engagement portion 12 are substantially parallel. Good (see FIG. 18B). In this case, the two torque transmission surfaces TF formed by the side surface 11c ₁ on the rotation side and the side surface 11c ₂ on the counter rotation side of the rib 11c may be substantially parallel. When viewed from the hub 2 side, the two torque transmission surfaces TF formed by the rotation side surface 242b and the counter rotation side surface 242c of the recess 242 of the hub side engaging portion 24 are substantially parallel. This means that it may be possible (see FIG. 18C). Similarly, it means that the two torque transmission surfaces TF formed by the side surface on the rotation side and the side surface on the non-rotation side of the slit 25 may be substantially parallel.

  As described above, in the eighth embodiment, the torque transmission surface TF that is a surface for transmitting torque formed by the uneven portions of the pulley side engagement portion 12 and the hub side engagement portion 24 is disposed on the normal line NL. It is possible to suppress the occurrence of minute slip SL on the uneven portion due to excessive torque operation or torque fluctuation, and to avoid abnormal wear of the uneven portion.

  FIG. 20 is a front view of a main part for explaining the power transmission device of the ninth embodiment. In the present invention, a power transmission structure between the pulley 1 and the hub 2 is proposed by engaging the pulley-side engaging portion 12 of the pulley 1 and the hub-side engaging portion 24 of the hub 2 in an uneven manner. When operated with a load, or due to torque fluctuation due to the compression force generated by the compressor, the uneven portion of the hub side engaging portion 24 made of an elastic member may be abnormally worn or the concave portion may be destroyed. Therefore, in the ninth embodiment, a material (low friction coefficient material) 26 having excellent wear resistance is connected to the surface of the concavo-convex portion of the hub side engaging portion 24 made of an elastic member, and coating or surface treatment is performed. By doing so, the wear resistance of the hub side engaging portion 24 is improved.

  That is, as shown in FIG. 20, for example, the concave and convex portion of the hub side engaging portion 24 is substantially divided into six, that is, six slits 25 are provided, and two convex portions 241 and three concave portions 242 are provided between the slits 25. Is formed. FIG. 20 shows only the uneven portion sandwiched between the slits 25. On the other hand, the pulley-side engaging portion 12 is provided with ribs 11c corresponding to the hub-side engaging portion 24 with respect to the slit 25, and three convex portions 121 and two concave portions 122 are provided between the ribs 11c. Is formed. In this way, the concave-convex fitting between the hub side engaging portion 24 and the pulley side engaging portion 12 is performed, and the power is transmitted. Since excessive torque is applied to the concave and convex portions, the torque transmission surface TF (the side surfaces 241b and 241c of the convex portion 241), the bottom portion 242a of the concave portion 242, and the convex portion are formed. In order to prevent the tip portion 241a of the portion 241 from being abnormally worn, a material (low friction coefficient material) 26 having excellent wear resistance is adhered to the surface of the concavo-convex portion of the hub side engagement portion 24, or the wear resistance The wear resistance of the surface of the concavo-convex portion is improved by coating the material 26 excellent in the above or by performing a surface treatment.

Examples of the material 26 having excellent wear resistance include resin films typified by cross-linked ethylene tetrafluoride (PTFE) and polyamide-based films, such as Nomex (trademark), Conex (trademark), and Kevlar (trademark). A woven or non-woven fabric woven with a material such as metal flakes and the like is preferable.
As the coating, a material containing a fluorine compound such as graphite, molybdenum disulfide, tetrafluoroethylene (PTFE), and PFA as a low friction coefficient material is suitable.
Surface treatment includes chlorinated butyl rubber, which is a material containing double bonds, an elastic member made of an ethylene / propylene / diene copolymer, and an elastic member made of an acrylic / ethylene copolymer elastic member. It is valid.

It is a front view of the power transmission device of a 1st embodiment of the present invention. It is sectional drawing in the AA of FIG. It is a perspective view of the hub of a 1st embodiment. It is sectional drawing of the pulley in 2nd Embodiment. It is principal part sectional drawing of the hub of 3rd Embodiment. It is principal part sectional drawing of the hub of 4th Embodiment. It is an upper half front view of the power transmission device of 4th Embodiment. It is a figure which shows the modification (a), (b), (c) of 4th Embodiment. It is (a) sectional drawing and (b) front view of the modification of 4th Embodiment. It is upper half sectional drawing of the power transmission device of 5th Embodiment. It is upper half sectional drawing which shows other embodiment for the comparison with 5th Embodiment. It is sectional drawing of the power transmission device of 6th Embodiment. It is the front view (a) and sectional drawing (b) which show the example of a process of drawing. (A) is a principal part front view explaining the power transmission device of 7th Embodiment, (b) is a principal part front view which shows other embodiment for a comparison. (A) is a principal part front view explaining the power transmission device of 7th Embodiment, (b) is a principal part front view which shows other embodiment for a comparison. It is a principal part front view explaining the power transmission device of 7th Embodiment. (A) is a principal part front view of the hub side engaging part in 7th Embodiment, (b) is a principal part front view of the hub side engaging part of other embodiment for a comparison. (A) is a principal part front view explaining the power transmission device of 8th Embodiment, (b) is a principal part front view of the pulley side engaging part in 8th Embodiment, (c) is. FIG. 10 is a front view of a main part of a hub side engaging portion in an eighth embodiment. (A) is a principal part front view of the power transmission device in the modification of 8th Embodiment, (b) is a principal part front view which shows other embodiment for a comparison. It is a principal part front view explaining the power transmission device of 9th Embodiment. Cross-sectional views (a), (b), and (c) of three prior art power transmission devices are shown.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Pulley 11 Recessed part 11a Inner surface 11b Outer surface 11c Rib 12a First pulley side engaging part 12b Second pulley side engaging part 121 Convex part 122 Concave part 2 Hub 21 Inner hub 21a Cylindrical part 21b Intermediate part 21c Flange Part 22 Damper rubber (elastic member for torque transmission)
22a Cylindrical elastic part 23 Outer hub 23a Reinforcing part 23b Exposed upper surface 23c Stepped part 24 Hub side engaging part 24a First hub side engaging part 24b Second hub side engaging part 241 Convex part 241a Tip part 242 Concave part 242a Bottom portion 25 Slit 26 Low friction coefficient material 3 Rotating shaft 31 Tip 4 Housing 41 Cylindrical portion 5 Bearing device 9 Balancer weight A Center of axial direction of cylindrical elastic portion B Center of axial direction of hub side engaging portion F Tensile stress SL Sliding g Clearance NL Normal line TF Torque transmission surface

Claims (21)

A pulley (1) rotatably mounted on the housing (4);
A hub (2) provided at a distal end portion of the rotating shaft (3) projecting outward from the housing and rotating integrally with the rotating shaft,
The hub (2)
An inner hub (21) fixed to the rotating shaft and disposed inside the torque transmitting elastic member (22);
An outer hub (23) disposed outside the torque transmitting elastic member (22) and connected to a front side end face of the pulley (1);
In the power transmission device comprising the elastic member for torque transmission (22) interposed between and held by the inner hub (21) and the outer hub (23),
A hub side engaging portion (24) made of an elastic material such as rubber or resin provided on the inner peripheral surface side or outer peripheral surface side or inner and outer peripheral surface side of the outer hub, and the outer side of the front end surface of the pulley. A torque transmission structure between the hub (2) and the pulley (1) is formed by engaging a pulley side engaging portion (12) provided at a position corresponding to the hub. Power transmission device.   The power transmission device according to claim 1, wherein the pulley (1) is made of a resin material.   3. The power according to claim 1, wherein outer shapes of the hub side engaging portion (24) and the pulley side engaging portion (12) are irregular shapes such as involute splines and trochoids. Transmission device.   4. The power transmission device according to claim 1, wherein the hub-side engaging portion and the pulley-side engaging portion have a fitting structure.   The power transmission device according to any one of claims 1 to 4, wherein the hub side engaging portion (24) is provided on the outer hub (23) by integral molding or adhesion.   The power transmission device according to any one of claims 1 to 5, wherein the hub side engaging portion (24) constitutes a part of the torque transmitting elastic member (22).   The plurality of slits (25) are formed in the hub side engaging portion (24) and the rear side portion of the outer hub (23) at intervals in the circumferential direction. The power transmission device according to claim 6.   At least the inner or outer surface (11a, 11b) of the first or second hub side engaging portion (24a, 24b) of the hub side engaging portion (24) or the recess (11) of the pulley (1). Either one is formed in the substantially taper shape, The power transmission device as described in any one of Claims 1-7 characterized by the above-mentioned.   The power transmission device according to claim 1, wherein the outer hub (23) is an outer ring (23) separate from the hub side engaging portion (24).   The entire surface of the outer ring (23) is covered with an elastic material such as rubber or resin forming the elastic member for torque transmission (22) or the hub side engaging portion (24). 9. The power transmission device according to 9.   The power transmission device according to claim 9 or 10, wherein the outer ring (23) is provided with a reinforcing portion (23a) protruding inside the hub side engaging portion (24).   The power transmission device according to claim 9, 10 or 11, wherein the outer ring (23) is made of metal.   The hub side engaging portion (24) is offset to the base side of the rotating shaft (3) as compared with the torque transmitting elastic member (22), and the metal outer ring (23) is arranged in the radial direction. The power transmission device according to claim 12, wherein the power transmission device is formed by being compressed from the outside.   The hub side engaging part (24) is offset to the base side of the rotating shaft (3) compared to the torque transmitting elastic member (22), and the front side of the hub side engaging part (24). 13. The power transmission device according to claim 9, wherein a balancer weight (9) attached to the inner hub (21) or the rotating shaft (3) is arranged.   The maximum width HW of each convex portion (241) of the hub side engaging portion (24) is equal to or greater than the maximum width PW of each convex portion (121) of the pulley side engaging portion (12). The power transmission device according to claim 3.   Between the front end part (241a) of the convex part (241) of the hub side engaging part (24) and the bottom part (122a) of the concave part (122) of the pulley side engaging part (12), which are unevenly fitted. The power transmission device according to claim 3, wherein a gap g of 0.001 mm or more is provided.   R1 part (242d) and R2 part (242e) are formed on both sides of the bottom part (242a) of the concave part (242) of the hub side engaging part (24), and the R1 part (242d) on the rotational direction side is formed. The power transmission device according to claim 3, wherein the power transmission device has an R shape having a diameter larger than that of the R2 portion (242e) on the counter-rotating direction side.   The torque transmission surface TF comes into contact with the side surfaces of the convex portions (241) of the hub side engaging portion (24) and the side surfaces of the concave portions (122) of the pulley side engaging portion (12), which are engaged with each other. The power transmission device according to claim 3, wherein the torque transmission surface TF is disposed on a normal line NL of the pulley (1).   19. The power transmission device according to claim 18, wherein the torque transmission surface TF is shifted from the normal line NL by a predetermined angle in the rotational direction of the pulley (1).   The torque transmission surface TF comes into contact with the side surfaces of the convex portions (121) of the pulley-side engaging portion (12) and the side surfaces of the concave portions (242) of the hub-side engaging portion (24), which are concave and convex. The torque transmission surface TF on the rotation side and the torque transmission surface TF on the counter-rotation side of each convex portion (121) of the pulley side engagement portion (12) are substantially parallel to each other. The power transmission device according to claim 3.   The power transmission device according to any one of claims 1 to 20, wherein a low-friction coefficient material (26) is provided on the surface of the hub-side engagement portion (24) by adhesion, coating, surface treatment, or the like. .

Images