US10385947B2

US10385947B2 - Belt attachment tool

Info

Publication number: US10385947B2
Application number: US15/515,247
Authority: US
Inventors: Yasuhito Aoki
Original assignee: Mitsuboshi Belting Ltd
Current assignee: Mitsuboshi Belting Ltd
Priority date: 2014-09-30
Filing date: 2015-09-29
Publication date: 2019-08-20
Also published as: US20170211665A1; EP3203113A1; CN107076280B; JP6145145B2; EP3203113B1; EP3203113A4; CN107076280A; JP2016070492A

Abstract

The present invention relates to a belt attachment tool used for further winding a belt, which is wound on a first pulley (1) and a second pulley (2), on a third pulley (3), the belt attachment tool containing a side surface part (10), an attaching part (11), a first belt holding part (14), and a second belt holding part (15), and the second belt holding part (15) is arranged so that a point (F) of intersection between a first extension line (L1) extending the belt wound on the first belt holding part (14) from an outer periphery of the second pulley (2) and a second extension line (L2) extending the belt wound on the second belt holding part (15) from an outer periphery of the first pulley (1) is located to a front side in a rotation direction (A) of the third pulley (3) with respect to a center line (L3) connecting a center (1S) of the first pulley (1) with a center (3S) of the third pulley.

Description

CROSS REFERENCE TO RELATED APPLICATIONS

This is a U.S. National Phase Application under 35 U.S.C. § 371 of International Application No. PCT/JP2015/077617, filed Sep. 29, 2015, which claims priority to Japanese Application Nos. 2014-201007, filed Sep. 30, 2014 and 2015-178450, filed Sep. 10, 2015, and which was published Under PCT Article 21(2), the entire contents of which are incorporated herein by reference.

TECHNICAL FIELD

The present invention relates to a belt attachment tool used in the case of winding a belt on a plurality of (three or more) pulleys.

BACKGROUND ART

Generally, a belt power transmission mechanism configured to wind a belt on a plurality of pulleys has specifications where high tension is applied to the belt by making a circumferential length of the belt shorter than a circumferential length of a layout between the pulleys that are mounting targets for surely transmitting power between the pulleys.

In the case where such a belt power transmission mechanism described above has no tension pulley or the like capable of adjusting a shaft center position of the pulley, when a belt with the circumferential length shorter than the circumferential length of the layout between the plurality of pulleys is attached to the plurality of pulleys with all distances between mutual shafts fixed, one pulley is left lastly and the belt is previously wound on the other pulleys and tension is applied to the belt wound on the other pulleys, and a belt attachment tool for attaching the belt to outer peripheral surfaces of the pulleys while rotating the lastly left pulley is used.

For example, Patent Document 1 discloses a belt attachment tool used in the case of winding a belt on three pulleys. In a layout (see FIG. 2 etc. of Patent Document 1) of the three pulleys P1, P2 and P3, the belt attachment tool is mounted to the pulley P1 with the largest diameter and a long wound belt portion, and tension is applied to the belt V wound on the pulleys P2 and P3 other than the pulley P1, and the pulley P1 is rotated to thereby attach the belt to the three pulleys by using the belt attachment tool. Thus, in the case of attaching a belt to a plurality of pulleys by using the belt attachment tool, the pulley P1 with the largest diameter and a long wound belt portion tends to be selected as the pulley to which the belt attachment tool is mounted for a reason that “it is easier to attach a belt by lastly winding the belt on the pulley with a longer wound belt portion (it is easier to do winding work)”.

However, for reasons that “it may be preferable in some cases to first wind a belt on the pulley with the largest diameter and a long wound belt portion since a misalignment is increased when the belt is lastly wound on the pulley with the largest diameter and a long wound belt portion”, or “a component causing a barrier is present in the vicinity of the pulley with the largest diameter and a long wound belt portion and it may be physically difficult to do attaching work”, there are cases where the pulley with the largest diameter and a long wound belt portion cannot be selected as the pulley to which the belt attachment tool is mounted.

In such cases, a pulley (a pulley with a diameter smaller than that of the large-diameter pulley: hereinafter called a small-diameter pulley) other than the pulley with the largest diameter (hereinafter called a large-diameter pulley) has to be selected as the pulley to which a belt attachment tool is mounted.

PRIOR ART DOCUMENT Patent Document

Patent Document 1: JP-A-2014-29191

SUMMARY OF THE INVENTION Problems that the Invention is to Solve

When a belt attachment tool is mounted to such a small-diameter pulley and the belt is lastly wound thereon, a belt portion wound on the small-diameter pulley becomes shorter than that of the large-diameter pulley. Therefore, belt tension at the time of lastly winding the belt on the small-diameter pulley becomes high and, for example, the belt attachment tool and the small-diameter pulley run idle or are inversely rotated and thus, it may become difficult to do winding work of the belt as compared to the case of mounting the belt attachment tool to the large-diameter pulley and lastly winding the belt thereon.

Hence, the present invention has been made to solve the problem as described above, and provides a belt attachment tool capable of smoothly doing winding work of a belt by preventing the belt attachment tool and a pulley from running idle or being inversely rotated due to tension of the belt at the time of winding the belt on a plurality of (three or more) pulleys.

Means for Solving the Problems

A belt attachment tool of the present invention for solving the problem described above is a belt attachment tool used for further winding a belt, which is wound on a first pulley and a second pulley and is stretchable in a direction of a circumferential length, on a third pulley by using rotation of the third pulley,

the belt attachment tool containing:

a side surface part installed on a side of one side surface of the third pulley,

an attaching part installed along an outer peripheral part of the third pulley,

a first belt holding part formed along an outer periphery of the side surface part, and

a second belt holding part formed on the side surface part,

in which the second belt holding part is formed on the side surface part so as to satisfy, when the belt is wound on the first pulley, the second pulley, the first belt holding part, and the second belt holding part, a first arrangement condition where the second belt holding part is arranged so that a point of intersection between a first extension line extending the belt wound on the first belt holding part from an outer periphery of the second pulley and a second extension line extending the belt wound on the second belt holding part from an outer periphery of the first pulley is located to a front side in a rotation direction of the third pulley with respect to a center line connecting a center of the first pulley with a center of the third pulley.

According to the configuration described above, the side surface part of the belt attachment tool is installed on the one side surface of the third pulley and the attaching part is arranged along the outer peripheral part of the third pulley and thus, the belt attachment tool can stably be installed on the third pulley.

Also, in the present belt attachment tool, the first belt holding part and the second belt holding part are formed on the side surface part, and the first belt holding part is arranged along the outer periphery of the side surface part, and the second belt holding part is arranged so that, in a state where the belt is wound on the first pulley, the second pulley, the first belt holding part and the second belt holding part, the point of intersection between the first extension line extending the belt wound on the first belt holding part from the outer periphery of the second pulley and the second extension line extending the belt wound on the second belt holding part from the outer periphery of the first pulley is located to the front side in the rotation direction of the third pulley with respect to the center line connecting the center of the first pulley with the center of the third pulley (first arrangement condition).

If the second belt holding part is arranged so that the point of intersection between the first extension line and the second extension line is located to a back side in the rotation direction of the third pulley with respect to the center line connecting the center of the first pulley with the center of the third pulley, there are cases where the third pulley is inversely rotated (tension in a direction toward the second pulley is applied to the belt) or the belt attachment tool itself is slid on the third pulley to run idle and thus the belt cannot be wound on the outer periphery of the third pulley. However, the second belt holding part is arranged so that the point of intersection between the first extension line and the second extension line is located to the front side in the rotation direction of the third pulley with respect to the center line connecting the center of the first pulley with the center of the third pulley and thus, the third pulley can be prevented from being inversely rotated since tension is applied to the belt in a forward rotation direction of the third pulley (tension is applied to the belt in a direction toward the first pulley).

Also, in the belt attachment tool as one aspect of the present invention, it is preferable that the second belt holding part is formed on the side surface part so as to further satisfy, when the belt is wound on the first pulley, the second pulley, the first belt holding part, and the second belt holding part, a second arrangement condition where the second belt holding part is arranged to a front side in the rotation direction of the third pulley with respect to a center line connecting a center of the second pulley with the center of the third pulley.

According to the configuration described above, the second belt holding part is arranged to the front side in the rotation direction of the third pulley with respect to the center line connecting the center of the second pulley with the center of the third pulley (the second arrangement condition) and thus, tension applied to the whole belt at the time of winding the belt on the first pulley, the second pulley, the first belt holding part and the second belt holding part can be decreased as compared with the case where the second belt holding part is located in the back side in the rotation direction of the third pulley with respect to the center line connecting the center of the second pulley with the center of the third pulley. Accordingly, rotation of the third pulley in the rotation direction (the direction toward the first pulley) at the time of winding the belt on the outer periphery of the third pulley can be facilitated.

Also, in the belt attachment tool as one aspect of the present invention, it is preferable that the side surface part includes an installation part brought into contact with at least a part of the one side surface of the third pulley, and a protection part which does not come into contact with the one side surface of the third pulley and covers at least a part of the one side surface, and

the protection part covers at least a part of a portion with the longest distance in a vertical direction from a plane defined by a portion with which the installation part comes into contact in the one side surface, in a region inward the portion with which the installation part comes into contact in the one side surface of the third pulley.

According to the configuration described above, the protection part covers at least a part of the portion with the longest distance in the one side surface of the third pulley (including the case where the distance from the plane defined by the portion with which the installation part comes into contact in the one side surface of the third pulley is zero) in the vertical direction from the plane defined by the portion with which the installation part comes into contact, in the region inward the portion with which the installation part comes into contact in the one side surface of the third pulley. Therefore, interference between the belt and the portion with the longest distance in the one side surface of the third pulley in the vertical direction from the plane defined by the portion with which the installation part comes into contact can be prevented from occurring at the time of winding the belt on the third pulley, to thereby protect the belt and the portion with the longest distance in the one side surface of the third pulley in the vertical direction from the plane defined by the portion with which the installation part comes into contact.

Also, in the belt attachment tool as one aspect of the present invention, it is preferable that the installation part is coupled to the protection part in a stepped manner.

According to the configuration described above, the protection part is coupled to the installation part in a stepped manner, and thus a gap is formed by the step between the protection part and the portion with the longest distance in the one side surface of the third pulley in the vertical direction from the plane defined by the portion with which the installation part comes into contact. Therefore, the protection part can surely cover the portion without making contact with the portion with the longest distance in the one side surface of the third pulley in the vertical direction from the plane defined by the portion with which the installation part comes into contact.

Also, in the belt attachment tool as one aspect of the present invention, a part of the first belt holding part may be projected outwardly from the outer periphery of the side surface part.

According to the configuration described above, a part of the first belt holding part is projected outwardly from the outer periphery of the side surface part. Therefore, the belt can be spaced from the outer periphery of the side surface part (the outer periphery of the third pulley) at the time of winding it on the first belt holding part. As a result, it becomes easy to wind the belt on the outer periphery of the third pulley from the first belt holding part, and the belt can smoothly be shifted to the outer periphery of the third pulley.

Also, in the belt attachment tool as one aspect of the present invention, a portion of the first belt holding part on which the belt is wound may have a substantially circular arc shape.

According to the configuration described above, the portion of the first belt holding part on which a belt is wound is formed in a substantially circular arc shape. Therefore, a load on the belt at the time of winding the belt on the first belt holding part can be reduced.

Also, in the belt attachment tool as one aspect of the present invention, a portion of the first belt holding part on which the belt is wound may have a substantially involute curve shape, and the first belt holding part and the second belt holding part may be arranged in a straight line.

According to the configuration described above, the portion of the first belt holding part on which a belt is wound is formed in a substantially involute curve shape and thus, the belt can efficiently be wound without applying excessive tension at the time of winding the belt on the first belt holding part. Also, since the first belt holding part and the second belt holding part are arranged in a straight line, the length of the belt at the time of winding the belt on the first belt holding part and the second belt holding part can be set in the shortest length to thereby minimize a force by which the belt is stretched. As a result, a workload of winding the belt on the third pulley by using the belt attachment tool can be reduced.

In the belt attachment tool as one aspect of the present invention, it is preferable that the first belt holding part is formed integrally with the second belt holding part.

According to the configuration described above, the first belt holding part is formed integrally with the second belt holding part. Therefore, strength can be increased as compared with the case where the first belt holding part is formed separately from the second belt holding part.

In the belt attachment tool as one aspect of the present invention, it is preferable that in the first belt holding part and the second belt holding part that are integrally formed, a portion on which the belt is wound has a substantially circular arc shape.

According to the configuration described above, the portion of the integrally formed first belt holding part and second belt holding part on which the belt is wound is formed in a substantially circular arc shape. Therefore, a load on the belt at the time of winding the belt can be reduced.

Advantageous Effect of the Invention

A belt attachment tool capable of smoothly doing winding work of a belt while preventing, at the time of winding the belt on the plurality of pulleys, the belt attachment tool and a pulley from running idle or being inversely rotated due to the tension of the belt can be provided.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a perspective view of a belt attachment tool according to the present embodiment.

FIG. 2 is six orthogonal views of a belt attachment tool according to the present embodiment.

FIG. 3 is a layout of a first pulley, a second pulley and a third pulley, according to the present embodiment.

FIG. 4A is an explanatory diagram of a third pulley according to the present embodiment.

FIG. 4B is an explanatory diagram of a third pulley according to the present embodiment.

FIG. 4C is an explanatory diagram of a third pulley according to the present embodiment.

FIG. 5A is an explanatory diagram describing the first arrangement condition and the second arrangement condition of a first belt holding part and a second belt holding part according to the present embodiment.

FIG. 5B is an explanatory diagram of a region in which the first arrangement condition of a first belt holding part and a second belt holding part is satisfied.

FIG. 5C is an explanatory diagram of a region in which the first arrangement condition and the second arrangement condition of a first belt holding part and a second belt holding part are satisfied.

FIG. 6A is a diagram describing a relation among tension of a V-ribbed belt, a first belt holding part and a second belt holding part according to the present embodiment.

FIG. 6B is a diagram describing a relation among tension of a V-ribbed belt, a first belt holding part and a second belt holding part according to the present embodiment.

FIG. 7 is a cross-sectional view in the case of attaching a belt attachment tool according to the present embodiment to a third pulley.

FIG. 8A is a first explanatory diagram of a method for using a belt attachment tool according to the present embodiment.

FIG. 8B is a first explanatory diagram of a method for using a belt attachment tool according to the present embodiment.

FIG. 8C is a first explanatory diagram of a method for using a belt attachment tool according to the present embodiment.

FIG. 8D is a second explanatory diagram of a method for using a belt attachment tool according to the present embodiment.

FIG. 8E is a second explanatory diagram of a method for using a belt attachment tool according to the present embodiment.

FIG. 9 is six orthogonal views of a belt attachment tool according to another embodiment.

FIG. 10 is six orthogonal views of a belt attachment tool according to another embodiment.

FIG. 11 is six orthogonal views of a belt attachment tool according to another embodiment.

FIG. 12A is an explanatory diagram of a method for using a belt attachment tool according to another embodiment.

FIG. 12B is an explanatory diagram of a method for using a belt attachment tool according to another embodiment.

FIG. 12C is an explanatory diagram of a method for using a belt attachment tool according to another embodiment.

FIG. 12D is an explanatory diagram of a method for using a belt attachment tool according to another embodiment.

FIG. 12E is an explanatory diagram of a method for using a belt attachment tool according to another embodiment.

FIG. 13 is six orthogonal views of a belt attachment tool according to another embodiment.

MODE FOR CARRYING OUT THE INVENTION Embodiment

An embodiment of the present invention will hereinafter be described with reference to the drawings. A belt attachment tool 9 (see FIG. 1) according to the present embodiment is used in the case of winding a belt (a V-ribbed belt 4) stretchable in a direction of a circumferential length on a first pulley 1, a second pulley 2 and a third pulley 3 as illustrated in FIG. 3.

In a layout of an automobile engine, as illustrated in FIG. 3, the first pulley 1 connected to a crankshaft of an engine or the like, the second pulley 2 for driving a water pump and the third pulley 3 connected to a shaft of a compressor of an air conditioner or the like are supported rotatably at predetermined distances between shafts. And, the V-ribbed belt 4 is wound on the first pulley 1, the second pulley 2 and the third pulley 3, and power of the crankshaft of the engine or the like is transmitted to a shaft of the water pump through the first pulley 1 and the second pulley 2, and the water pump is driven. Also, the power of the crankshaft of the engine or the like is transmitted to the shaft of the compressor through the first pulley 1, the second pulley 2 and the third pulley 3, and the compressor is rotated. In the present embodiment, the distances between the respective shafts of the first pulley 1, the second pulley 2 and the third pulley 3 are fixed (cannot be changed). Also, the so-called auto tensioner (tension applying means) for applying tension to the V-ribbed belt 4 is not installed.

(Structures of First Pulley 1, Second Pulley 2 and Third Pulley 3)

The first pulley 1 has a pulley groove (a groove formed in an outer peripheral part of the first pulley 1) capable of being fitted into a rib 4 a formed in an inner peripheral surface of the V-ribbed belt 4. Also, a crankshaft of an engine or the like is inserted into a boss part 1 c formed in a central part of the first pulley 1.

Like the first pulley 1, the second pulley 2 has a pulley groove (a groove formed in an outer peripheral part of the second pulley 2) capable of being fitted into the rib 4 a formed in the inner peripheral surface of the V-ribbed belt 4. Also, a shaft interlocked with a water pump is inserted into a boss part 2 c formed in a central part of the second pulley 2.

On the other hand, as illustrated in FIG. 4A to FIG. 4C, the third pulley 3 contains a compressor pulley 3 a, a clutch hub 3 b arranged on one side surface of the compressor pulley 3 a, and a stator 3 c arranged on the other side surface of the compressor pulley 3 a. The compressor pulley 3 a and the stator 3 c are rotatably fitted into a shaft of a compressor, and the clutch hub 3 b is fixed to the shaft of the compressor. In addition, the clutch hub 3 b of the third pulley 3 is arranged so as to be projected from a side surface 3 g of the compressor pulley 3 a as illustrated in FIG. 4C.

The third pulley 3 has a mechanism in which when the compressor is not driven, only the compressor pulley 3 a is rotated; whereas for example, when a switch of the air conditioner is turned on, a current flows in a coil embedded in the stator 3 c and it becomes a powerful magnet to strongly attract the clutch hub 3 b, the clutch hub 3 b is pressed to the compressor pulley 3 a and as a result, the clutch hub 3 b, the compressor pulley 3 a and the stator 3 c are integrated and the rotation of the compressor pulley 3 a is transmitted from the integrated clutch hub 3 b to the shaft of the compressor to rotate the compressor.

Also, as illustrated in FIG. 4A and FIG. 4C, the compressor pulley 3 a of the third pulley 3 has a pulley groove 3 d (a groove formed in an outer peripheral part 3 j of the third pulley 3) capable of being fitted into the rib 4 a formed in the inner peripheral surface of the V-ribbed belt 4, and contains a pair of

pulley flanges

3 e and 3 f for sandwiching the pulley groove 3 d in an axial direction of the pulley. The pulley flanges 3 e and 3 f are formed so as to be slightly projected from the pulley groove 3 d in a radial outward direction of the third pulley 3 in side view of FIG. 4C. Also, the shaft of the compressor is inserted into a boss part 5 of the third pulley 3 and is fixed to the clutch hub 3 b.

Numerals

3 g and 3 h indicate side surfaces of the third pulley 3.

In the present embodiment, as illustrated in FIG. 3, the first pulley 1 is the pulley with the largest diameter among the three pulleys (first pulley 1, second pulley 2 and third pulley 3), and the third pulley 3 is the pulley with the second largest diameter, and the second pulley 2 is the pulley with the smallest diameter.

(V-Ribbed Belt 4)

The V-ribbed belt 4 is a so-called low modulus belt that is slightly stretchable in a circumferential length direction. The low modulus belt has a relatively low modulus of elasticity by employing a polyamide fiber as a tension member, and prevents a sudden decrease in tension as compared with one having a high modulus of elasticity (so-called high modulus belt).

An arrow V of a thick line in FIG. 3 indicates a running direction of the V-ribbed belt 4, and a rotation direction of the third pulley 3 at the time when the V-ribbed belt 4 runs in this running direction is defined as a rotation direction A, and a direction opposite to this rotation direction A is defined as an inverse rotation direction B.

(Configuration of Belt Attachment Tool 9)

Next, a configuration of the belt attachment tool 9 according to the present embodiment will be described with reference to FIG. 1 and FIG. 2.

As illustrated in FIG. 1 and FIG. 2, the belt attachment tool 9 contains, as main components, an attaching part 11 attached along the outer peripheral part 3 j of the third pulley 3, a side surface part 10 including an installation part 12 brought into contact with a portion of the pulley flange 3 e of one side surface 3 g of the third pulley 3 and a protection part 13 for covering the clutch hub 3 b of the third pulley 3, a first belt holding part 14 formed along an outer periphery of the installation part 12, and a second belt holding part 15 formed on the protection part 13.

The attaching part 11 is formed in a circular arc shape (a curved shape) along the outer peripheral part 3 j of the compressor pulley 3 a of the third pulley 3. Also, an inner peripheral surface side of the attaching part 11 is provided with a rib 11 a fitted into the pulley groove 3 d formed in the outer peripheral part 3 j of the compressor pulley 3 a of the third pulley 3.

The rib 11 a is constructed of one protruding rib along a longitudinal direction of the inner peripheral surface of the attaching part 11. The belt attachment tool 9 can accurately be fixed to the outer peripheral part 3 j of the compressor pulley 3 a by fitting the rib 11 a into the pulley groove 3 d of the compressor pulley 3 a when the belt attachment tool 9 is attached to the third pulley 3. The present embodiment is configured to provide only one rib 11 a, but may be configured to provide a plurality of ribs 11 a since at least one protruding rib has only to be present in the case of forming the rib 11 a.

The installation part 12 constructing the side surface part 10 extends from one end of the attaching part 11 toward the boss part 5 of the third pulley 3. The installation part 12 performs the function of stabilizing the belt attachment tool 9 to the third pulley 3 by abutting on or coming into close contact with the pulley flange 3 e formed on the compressor pulley 3 a of the third pulley 3 when the belt attachment tool 9 is attached to the third pulley 3.

The protection part 13 is, as illustrated in FIG. 2, provided with a partially notched part 13 b from a circular shape and has a shape having a step 13 a with respect to the installation part 12. That is, in the present embodiment, the installation part 12 is coupled to the protection part 13 in a stepped manner through the step 13 a. The step 13 a of the protection part 13 performs the function of preventing the protection part 13 from coming into contact with the clutch hub 3 b by forming a gap 13 c between the protection part 13 and the clutch hub 3 b of the third pulley 3 when the belt attachment tool 9 is attached to the third pulley 3 as illustrated in FIG. 7. Thus, the protection part 13 performs the function of covering the clutch hub 3 b while avoiding the contact with the clutch hub 3 b. In the present embodiment, the step 13 a is formed between the installation part 12 and the protection part 13, but it may be formed in a shape continuously curved by forming the installation part 12 integrally to the protection part 13 without forming the step 13 a.

Here, the protection part 13 is formed so as to cover, in a region inward the portion with which the installation part 12 comes into contact in the one side surface 3 g (side surface of the side covered with the protection part 13) of the third pulley 3, at least a part of a portion with the longest distance (clutch hub 3 b) in a vertical direction from a plane defined by a portion 3 k (see FIG. 7) with which the installation part 12 comes into contact in the one side surface 3 g of the third pulley 3. That is, in the present aspect, the protection part 13 is formed so as to cover at least a part of the clutch hub 3 b that is a protrusion protruding most outwardly in an axial direction in a region inward the pulley flange 3 e. The protection part 13 preferably covers at least substantially the center of the side surface 3 g of the third pulley 3. That is, in this aspect, the boss part 5 is preferably covered. As a coverage ratio, the side surface part 10 preferably covers, for example, one-half or more of the side surface 3 g (side surface of the side covered with the protection part 13) of the third pulley 3. That is, the side surface part 10 preferably covers from 50 to 100% of the side surface 3 g of the third pulley 3. In the case where the coverage ratio is smaller than 50%, strong interference between the V-ribbed belt 4 and the third pulley 3 may occur to cause damage at the time of winding the V-ribbed belt 4 on the belt attachment tool 9.

Also, since the size of the gap 13 c is properly set according to characteristics (misalignment limit etc.) of the applied pulley or the like, it is not particularly limited, but is preferably, for example, more than 0 and about 3.5 mm or less.

Also, portions of the attaching part 11, the installation part 12 and the protection part 13 in contact with the V-ribbed belt 4 are chamfered to have curved surface shapes. They are formed in order to prevent the V-ribbed belt 4 from being damaged at the time of winding the V-ribbed belt 4 on the third pulley 3 by using the belt attachment tool 9.

The first belt holding part 14 is projected along the outer periphery of the installation part 12 astride the installation part 12 and the protection part 13 as illustrated in FIG. 2. The first belt holding part 14 could be arranged on the side surface part 10 so as to be located in the side of the outer peripheral part 3 j of the compressor pulley 3 a when the belt attachment tool 9 is attached to the third pulley 3. This first belt holding part 14 performs the function of temporarily holding the V-ribbed belt 4 at the time of winding the V-ribbed belt 4 on the third pulley 3.

Also, the first belt holding part 14 and the second belt holding part 15 are arranged in a straight line, and a holding surface 14 a (see FIG. 2) by which the V-ribbed belt 4 is held has a substantially involute curve shape in the shape viewing the belt attachment tool 9 from an upper surface. The holding surface 14 a of the first belt holding part 14 is not limited to the substantially involute curve shape, and may have a substantially circular arc shape, a trapezoidal shape or a polygonal shape. Also, a substantially columnar shape may be employed as the shape of the first belt holding part 14 itself.

The first belt holding part 14 performs the function of bending and arranging the V-ribbed belt 4 along the outer peripheral part 3 j of the compressor pulley 3 a at the time of winding the V-ribbed belt 4 on the third pulley 3.

The second belt holding part 15 has a substantially columnar shape, and is projected on the protection part 13 as illustrated in FIG. 2. As a detailed position, as illustrated in FIG. 5A, at the time of winding the V-ribbed belt 4 on the first pulley 1, the second pulley 2, the first belt holding part 14, and the second belt holding part 15 with the belt attachment tool 9 installed on the third pulley 3, the second belt holding part 15 is formed on the side surface part 10 so that a point F (a vertex position of a resultant force of belt tension) of intersection between a first extension line L1 extending the V-ribbed belt 4 wound on the first belt holding part 14 from the outer periphery of the second pulley 2 and a second extension line L2 extending the V-ribbed belt 4 wound on the second belt holding part 15 from the outer periphery of the first pulley 1 is located to the front side in the rotation direction A of the third pulley 3 with respect to a center line L3 connecting the center 1S of the first pulley 1 with the center 3S of the third pulley 3 (a first arrangement condition) (see an area (oblique line) in FIG. 5B, in which the first arrangement condition is satisfied).

In the present invention, “at the time of winding the V-ribbed belt 4 on the first pulley 1, the second pulley 2, the first belt holding part 14, and the second belt holding part 15” refers to a state in which the V-ribbed belt 4 is wound on the first pulley 1, the second pulley 2, the first belt holding part 14, and the second belt holding part 15 along a running direction thereof and a stretch of the belt is minimized.

Furthermore, in the present embodiment, as illustrated in FIG. 5A, at the time of winding the V-ribbed belt 4 on the first pulley 1, the second pulley 2, the first belt holding part 14, and the second belt holding part 15 with the belt attachment tool 9 installed on the third pulley 3, the second belt holding part 15 is formed on the side surface part 10 so as to be located to the front side in the rotation direction A of the third pulley 3 with respect to a center line L4 connecting the center 2S of the second pulley 2 with the center 3S of the third pulley 3 (a second arrangement condition) (see an area (oblique line) in FIG. 5C, in which the first arrangement condition and the second arrangement condition are satisfied).

In the present embodiment, the shape of the second belt holding part 15 is formed in a substantially columnar shape, and this is because the V-ribbed belt 4 is prevented from being damaged at the time of winding the V-ribbed belt 4 on the second belt holding part 15. Also, the shape of the second belt holding part 15 may have a substantially semicircular shape, a substantially crescent shape or a substantially polygonal shape.

(Meaning of Forming First Belt Holding Part 14 and Second Belt Holding Part 15)

As illustrated in FIG. 6A, in the case where a conventional belt attachment tool in which the second belt holding part 15 is not formed and only the first belt holding part 14 is formed is attached to the third pulley 3, a point F2 (a vertex position of a resultant force of belt tension) of intersection between the first extension line L1 extending the V-ribbed belt 4 wound on the first belt holding part 14 from the outer periphery of the second pulley 2 and a third extension line L5 extending the V-ribbed belt 4 wound on the first belt holding part 14 from the outer periphery of the first pulley 1 is located to the back side in the rotation direction A of the third pulley 3 with respect to the center line L3 connecting the center 1S of the first pulley 1 with the center 3S of the third pulley 3. In this case, as illustrated in FIG. 6A, a force (a force, G in the drawing, by which the belt is stretched) balanced with the resultant force of belt tension (a resultant force of tension (T1 in the drawing) in a direction toward the first pulley 1 and tension (T2 in the drawing) in a direction toward the second pulley 2) does not exceed the tension in the direction toward the second pulley 2, and a rotation force of the first pulley 1 is not transmitted to the belt attachment tool and the third pulley 3 through the V-ribbed belt 4. Therefore, there are cases where the belt attachment tool and the third pulley 3 cannot be rotated (running idle or being rotated in the inverse rotation direction B).

In order to solve the problem described above, that is, in order that the force by which the belt is stretched exceeds the tension in the direction toward the second pulley 2, it is necessary to locate the intersection point F2 (the vertex position of the resultant force of the belt tension) to the front side in the rotation direction A of the third pulley 3 with respect to the center line L3 connecting the center 15 of the first pulley 1 with the center 3S of the third pulley 3.

Hence, like the belt attachment tool 9 of the present embodiment, the second belt holding part 15 is further formed in addition to the first belt holding part 14, and the second belt holding part 15 is arranged in the position in which the first arrangement condition described above is satisfied. As a result, the force by which the belt is stretched can exceed the tension in the direction toward the second pulley 2 by being constructed so as to locate the intersection point F (the vertex position of the resultant force of the belt tension) to the front side in the rotation direction A of the third pulley 3 with respect to the center line L3 connecting the center 1S of the first pulley 1 with the center 3S of the third pulley 3 as illustrated in FIG. 6B. Accordingly, tension is applied in the direction toward the first pulley 1, and the belt attachment tool 9 and the third pulley 3 can be prevented from being rotated in the inverse rotation direction B.

(Method for Using Belt Attachment Tool 9)

Next, a method for using the belt attachment tool 9 will be described with reference to FIG. 7 to FIG. 9. The first pulley 1 can be rotated manually freely by coupling a wrench to the boss part 1 c of the first pulley 1.

First, as illustrated in FIG. 7, the belt attachment tool 9 is attached to the third pulley 3 so that the attaching part 11 is arranged along the outer peripheral part 3 j of the compressor pulley 3 a of the third pulley 3. At this time, the rib 11 a formed on the attaching part 11 is fitted into the pulley groove 3 d of the compressor pulley 3 a, and the installation part 12 is abutted on the pulley flange 3 e formed on the compressor pulley 3 a of the third pulley 3. Accordingly, the protection part 13 is in a state covering the clutch hub 3 b while forming the gap 13 c with the clutch hub 3 b (see FIG. 7).

In this state, the V-ribbed belt 4 is first wound on the first pulley 1 and the second pulley 2. Then, as illustrated in FIG. 8A, after the V-ribbed belt 4 is arranged along the outer peripheral part 3 j of the compressor pulley 3 a of the third pulley 3, it is further arranged along the holding surface 14 a of the first belt holding part 14 astride the attaching part 11, bent in an involute curve shape, and wound so that an inner peripheral surface of the V-ribbed belt 4 abuts on the holding surface 14 a of the first belt holding part 14, and is further wound on the second belt holding part 15. At this time, as illustrated in FIG. 8A, the V-ribbed belt 4 bent by the first belt holding part 14 is in a state in which the V-ribbed belt 4 passes on the protection part 13, and is wound on the second belt holding part 15 in a straight shape and wound on an outer peripheral part of the first pulley 1 from this second belt holding part 15. Since the second belt holding part 15 of the belt attachment tool 9 satisfies the first arrangement condition described above at this time, the belt attachment tool 9 and the third pulley 3 are not rotated in the inverse rotation direction B even when the V-ribbed belt 4 is wound on the belt attachment tool 9.

Then, as illustrated in FIG. 8B, the first pulley 1 is rotated in the rotation direction A using by the wrench. Since the second belt holding part 15 of the belt attachment tool 9 satisfies the second arrangement condition described above at this time, tension applied to the V-ribbed belt 4 can be decreased as compared with the case where the second belt holding part 15 is located in the back side in the rotation direction A with respect to the center line L4. Accordingly, rotation of the third pulley 3 in the rotation direction A is facilitated.

Specifically, the first pulley 1, the second pulley 2 and the third pulley 3 are first rotated in the rotation direction A so as to shift from the state of FIG. 8A to the state of FIG. 8B. Then, the first belt holding part 14 on which the V-ribbed belt 4 is wound is moved to a position of the center line L3. Then, when the first belt holding part 14 is moved to the position of the center line L3, the V-ribbed belt 4 is unwound from the second belt holding part 15. In other words, the state (winding state) in which the V-ribbed belt 4 is held in the second belt holding part 15 is maintained until the first belt holding part 14 goes over the center line L3 to the front side in the rotation direction A.

The V-ribbed belt 4 is stretched to thereby generate high tension. Since the V-ribbed belt 4 crosses on the attaching part 11, this tension serves as a pressing action pressing the attaching part 11 against the outer peripheral part 3 j of the third pulley 3, and thus, the belt attachment tool 9 is more strongly fixed to the third pulley 3.

When the first pulley 1, the second pulley 2 and the third pulley 3 are then rotated in the rotation direction A so as to shift from the state of FIG. 8B to the state of FIG. 8C, the V-ribbed belt 4 on the side surface part 10 is slid to the outer peripheral side of the belt attachment tool 9 according to the rotation. On the other hand, the V-ribbed belt 4 wound on the first belt holding part 14 is moved on the outer peripheral part 3 j of the compressor pulley 3 a. Specifically, when the third pulley 3 is rotated in the rotation direction A, an area in which the rib 4 a of the V-ribbed belt 4 is fitted into the pulley groove 3 d of the compressor pulley 3 a of the third pulley 3 is gradually increased.

Furthermore, the first pulley 1, the second pulley 2 and the third pulley 3 are rotated in the rotation direction A so as to shift from the state of FIG. 8C to the state of FIG. 8E through the state of FIG. 8D. Then, the V-ribbed belt 4 remaining on the side surface part 10 is moved away from the side surface part 10, and is completely moved to the outer peripheral part 3 j of the compressor pulley 3 a of the third pulley 3. After this movement, the belt attachment tool 9 is recovered from the third pulley 3.

Through the procedures described above, the V-ribbed belt 4 can be wound on the first pulley 1, the second pulley 2 and the third pulley 3 as illustrated in FIG. 3.

According to the configuration described above, the side surface part 10 of the belt attachment tool 9 is installed on one side surface 3 g of the third pulley 3 and the attaching part 11 is arranged along the outer peripheral part 3 j of the third pulley 3. Therefore, the belt attachment tool 9 can stably be installed on the third pulley 3.

Also, the first belt holding part 14 and the second belt holding part 15 are formed on the side surface part 10, and the first belt holding part 14 is arranged along the outer periphery of the side surface part 10. In addition, the second belt holding part 15 is arranged so that, at the time of winding the V-ribbed belt 4 on the first pulley 1, the second pulley 2, the first belt holding part 14 and the second belt holding part 15, the point F of intersection between the first extension line L1 extending the V-ribbed belt 4 wound on the first belt holding part 14 from the outer periphery of the second pulley 2 and the second extension line L2 extending the V-ribbed belt 4 wound on the second belt holding part 15 from the outer periphery of the first pulley 1 is located to the front side in the rotation direction A of the third pulley 3 with respect to the center line L3 connecting the center 1S of the first pulley 1 with the center 3S of the third pulley 3 (the first arrangement condition).

If the second belt holding part 15 is arranged so that the point F of intersection between the first extension line L1 and the second extension line L2 is located to the back side in the rotation direction A of the third pulley 3 with respect to the center line L3 connecting the center 1S of the first pulley 1 with the center 3S of the third pulley 3, there are cases where the third pulley 3 is inversely rotated (tension in the direction toward the second pulley 2 is applied to the V-ribbed belt 4) or the belt attachment tool 9 itself slides on the third pulley 3 to run idle and thus the V-ribbed belt 4 cannot be wound on the outer periphery of the third pulley 3. However, since the second belt holding part is arranged so as to satisfy the first arrangement condition described above, the tension in the rotation direction A is applied to the V-ribbed belt 4 (the tension in the direction toward the first pulley 1 is applied to the V-ribbed belt 4) and the third pulley 3 can be prevented from being inversely rotated (rotated in the inverse rotation direction B).

Also, the second belt holding part 15 is arranged to the front side in the rotation direction A of the third pulley 3 with respect to the center line L4 connecting the center 2S of the second pulley 2 with the center 3S of the third pulley 3 (the second arrangement condition). Therefore, tension applied to the whole V-ribbed belt 4 at the time of winding the V-ribbed belt 4 on the first pulley 1, the second pulley 2, the first belt holding part 14, and the second belt holding part 15 can be reduced as compared with the case where the second belt holding part 15 is located in the back side in the rotation direction A of the third pulley 3 with respect to the center line L4. Accordingly, rotation of the third pulley 3 in the rotation direction A (the direction toward the first pulley 1) at the time of winding the V-ribbed belt 4 on the outer peripheral part 3 j of the third pulley 3 can be facilitated.

In addition, the protection part 13 covers at least a part (at least a part of the clutch hub 3 b) of the portion with the longest distance in one side surface 3 g of the third pulley 3 (including the case where the distance from the plane defined by the portion with which the installation part 12 comes into contact in one side surface 3 g of the third pulley 3 is zero) in the vertical direction from the plane defined by the portion with which the installation part 12 comes into contact, in the region inward the portion with which the installation part 12 comes into contact in the one side surface 3 g of the third pulley 3. Therefore, interference between the clutch hub 3 b of the third pulley 3 and the V-ribbed belt 4 can be prevented from occurring at the time of winding the V-ribbed belt 4 on the third pulley 3, to thereby protect the clutch hub 3 b and the V-ribbed belt 4.

Also, since the protection part 13 is coupled to the installation part 12 in a stepped manner and the gap 13 c by the step 13 a is formed between the clutch hub 3 b and the protection part 13, the protection part 13 can surely cover the clutch hub 3 b without making contact therewith.

In addition, since the portion (the holding surface 14 a) of the first belt holding part 14, on which the V-ribbed belt 4 is wound is formed in a substantially circular arc shape, a load on the V-ribbed belt 4 at the time of winding the V-ribbed belt 4 on the first belt holding part 14 can be reduced.

Also, the portion (the holding surface 14 a) of the first belt holding part 14, on which the V-ribbed belt 4 is wound is formed in a substantially involute curve shape. Therefore, the V-ribbed belt 4 can efficiently be wound without applying excessive tension thereto at the time of winding the V-ribbed belt 4 on the first belt holding part 14. Also, since the first belt holding part 14 and the second belt holding part 15 are arranged in a straight line, the length of the V-ribbed belt 4 at the time of winding the V-ribbed belt 4 on the first belt holding part 14 and the second belt holding part 15 can be set in the shortest length, to thereby minimize the force by which the V-ribbed belt 4 is stretched. As a result, a work load of winding the V-ribbed belt 4 on the third pulley 3 by using the belt attachment tool 9 can be reduced.

Other Embodiments

The belt attachment tool 9 in the embodiment described above is configured to provide the rib 11 a on the inner peripheral surface side of the attaching part 11, but may be configured so as not to provide the rib 11 a on the inner peripheral surface side of an attaching part 111 as illustrated in FIG. 9. In this case, since the rib 11 a is not formed, a manufacturing cost can be reduced. Stability at the time of attaching the belt attachment tool 9 to a third pulley 3 can be secured by abutting the attaching part 111 without the rib on an outer peripheral part 3 j of the third pulley 3 and abutting an installation part 12 on a pulley flange 3 e.

Also, as illustrated in FIG. 10, an attaching part 211 of a belt attachment tool 9 may be configured to have such a width as to cover an outer peripheral part 3 j of a compressor pulley 3 a in a width direction (a width of a third pulley 3 in an axial direction). In this case, the attaching part 211 may be provided with an abutting part 211 d for abutting on a pulley flange 3 f of the compressor pulley 3 a. By forming this butting part 211 d, installation of the belt attachment tool 9 on the third pulley 3 can be more stabilized. Also, it may be configured to provide one or more ribs to an inner peripheral surface side of the attaching part 211 illustrated in FIG. 10.

Also, in the belt attachment tool 9 in the embodiment described above, the first belt holding part 14 is arranged along the outer periphery of the installation part 12, but is not limited to this, and a first belt holding part 114 may have a shape in which a part of the first belt holding part 114 is projected outwardly from an outer periphery of an installation part 12 as illustrated in FIG. 11.

In this case, a part of the first belt holding part 114 is projected outwardly from the outer periphery of the installation part 12. Therefore, a V-ribbed belt 4 can be spaced from the outer periphery of the installation part 12 or a pulley flange 3 e of a third pulley 3 at the time of winding on the first belt holding part 114. As a result, it becomes easy to wind the V-ribbed belt 4 on an outer peripheral part 3 j of the third pulley 3 from the first belt holding part 114, and the V-ribbed belt 4 can smoothly be shifted to the outer peripheral part 3 j of the third pulley 3 (see FIG. 12A to FIG. 12E).

Furthermore, like a belt attachment tool 9 illustrated in FIG. 13, it is preferable that a first belt holding part 314 has a projection 314 b projected outwardly from an outer periphery of an installation part 12, and this projection 314 b has a shape projected further outwardly than the portion projected outwardly from the outer periphery of the installation part 12 in the first belt holding part 114 illustrated in FIG. 11. Thus, the projection 314 b of the first belt holding part 314 is formed in the shape projected greatly outwardly from the outer periphery of the installation part 12. Therefore, since the projection 314 b of the first belt holding part 314 is projected greatly outwardly from the outer periphery of the installation part 12, a V-ribbed belt 4 can greatly be spaced from the outer periphery of the installation part 12 or a pulley flange 3 e of a third pulley 3 at the time of winding on the first belt holding part 314. As a result, it becomes easier to wind the V-ribbed belt 4 on an outer peripheral part 3 j of the third pulley 3 from the first belt holding part 314, and the V-ribbed belt 4 can more smoothly be shifted to the outer peripheral part 3 j of the third pulley 3.

Also, like the belt attachment tool 9 illustrated in FIG. 13, a lower part of the projection 314 b of the first belt holding part 314 may have an inclined surface 314 c inclined from a side surface 314 d of the first belt holding part 314 toward the lower side. This inclined surface 314 c performs the function of smoothly sliding the V-ribbed belt 4 wound on the inclined surface 314 c from the inclined surface 314 c to the outer peripheral part 3 j of the third pulley 3 when the V-ribbed belt 4 wound on a holding surface 314 a of the first belt holding part 314 is also wound on the inclined surface 314 c with rotation of the third pulley 3. That is, by providing the inclined surface 314 c on the lower part of the first belt holding part 314, the V-ribbed belt 4 wound on the first belt holding part 314 can easily be routed to the side of the third pulley 3 and the V-ribbed belt 4 can smoothly be shifted from the first belt holding part 314 to the outer peripheral part 3 j of the third pulley 3.

The holding surface 314 a of the first belt holding part 314 of the belt attachment tool 9 illustrated in FIG. 13 has a plane shape (a straight shape in top view), but is not limited to this shape, and may have a curved surface shape (a curved shape in top view).

Also, like the belt attachment tool 9 illustrated in FIG. 13, it is preferred that a second belt holding part 315 is formed so that a position in which the V-ribbed belt 4 is wound is set in a position away from the center 3S (a position corresponding to the center 3S of the third pulley 3) in a radial outward direction. This is because as the position in which the V-ribbed belt 4 is wound on the second belt holding part 315 is set in the position nearer to the center 3S of the third pulley 3, a larger force is required in order to rotate the third pulley 3 and thus the V-ribbed belt 4 cannot be wound smoothly. On the other hand, in the case where the position in which the V-ribbed belt 4 is wound on the second belt holding part 315 is set in the position away from the center 3S of the third pulley 3 in the radial outward direction, the third pulley 3 can be rotated with a relatively small force. Therefore, it is preferable for winding of the V-ribbed belt 4 (a smooth shifting). The second belt holding part 315 of the belt attachment tool 9 illustrated in FIG. 13 is constructed so that the position in which the V-ribbed belt 4 is wound is set in the position further away from the center 3S in the radial outward direction by increasing the diameter of the columnar second belt holding part 15 of the belt attachment tool 9 illustrated in FIG. 2. The second belt holding part 315 may be formed by arranging the second belt holding part 15 of the belt attachment tool 9 illustrated in FIG. 2 in the position further away from the center 3S in the radial outward direction.

Also, in the belt attachment tool 9 in the embodiments described above, the first belt holding part 14 (114, 314) is formed separately from the second belt holding part 15 (315), but the first belt holding part 14 (114, 314) may be formed integrally to the second belt holding part 15 (315). In this case, strength can be increased as compared with the case where the first belt holding part 14 (114, 314) is formed separately from the second belt holding part 15 (315).

Furthermore, in the case where the first belt holding part 14 (114, 314) is formed integrally to the second belt holding part 15 (315), the portion of the integrally formed first belt holding part 14 (114, 314) and second belt holding part 15 (315), on which the V-ribbed belt 4 is wound may be formed in a circular arc shape. In this case, a load on the V-ribbed belt 4 at the time of winding the V-ribbed belt 4 can be reduced.

Also, the embodiments described above describe the case of using the belt attachment tool 9 by attaching to the third pulley 3 having the clutch hub 3 b, but the belt attachment tool 9 can also be installed and used to a pulley in which the distance from the plane defined by the portion with which the installation part 12 comes into contact in the side surface 3 g of the third pulley 3 is “zero”, that is, the first pulley 1 or the second pulley 2 without a portion projected to the side surface of the pulley.

In addition, the embodiments described above describe the case where the number of pulleys is three, but can be applied to the case where the number of pulleys is four or more. In that case, the first pulley, the second pulley and the third pulley are any consecutive pulleys, and the third pulley is the pulley sandwiched between the first pulley and the second pulley.

While the embodiments of the present invention have been described above, the present invention is not limited to the embodiments described above, and can be carried out with various changes within the scope described in the claims.

The present application is based on Japanese patent application No. 2014-201007 filed on Sep. 30, 2014 and Japanese patent application No. 2015-178450 filed on Sep. 10, 2015, and the contents thereof are incorporated herein by reference.

DESCRIPTION OF REFERENCE NUMERALS AND SIGNS

1 First Pulley
2 Second Pulley
3 Third Pulley
3 a Compressor Pulley
3 b Clutch Hub
3 c Stator
4 V-ribbed Belt
9 Belt Attachment Tool
10 Side Surface Part
11 Attaching Part
12 Installation Part
13 Protection Part
14 First Belt Holding Part
15 Second Belt Holding Part
A Rotation Direction

Claims

The invention claimed is:

1. A belt attachment tool used for further winding a belt, which is wound on a first pulley and a second pulley and is stretchable in a direction of a circumferential length, on a third pulley by using rotation of the third pulley,

the belt attachment tool comprising:

an attaching part installed along an outer peripheral part of the third pulley,

a second belt holding part formed on the side surface part,

wherein the second belt holding part is formed on the side surface part so as to satisfy, when the belt is wound on the first pulley, the second pulley, the first belt holding part, and the second belt holding part, a first arrangement condition where the second belt holding part is arranged so that a point of intersection between a first extension line extending the belt wound on the first belt holding part from an outer periphery of the second pulley and a second extension line extending the belt wound on the second belt holding part from an outer periphery of the first pulley is located to a front side in a rotation direction of the third pulley with respect to a center line connecting a center of the first pulley with a center of the third pulley.

2. The belt attachment tool according to claim 1,

wherein the second belt holding part is formed on the side surface part so as to further satisfy, when the belt is wound on the first pulley, the second pulley, the first belt holding part, and the second belt holding part, a second arrangement condition where the second belt holding part is arranged to a front side in the rotation direction of the third pulley with respect to a center line connecting a center of the second pulley with the center of the third pulley.

3. The belt attachment tool according to claim 1,

wherein the side surface part comprises

an installation part brought into contact with at least a part of the one side surface of the third pulley, and

a protection part which does not come into contact with the one side surface of the third pulley and covers at least a part of the one side surface, and

wherein the protection part covers at least a part of a portion with the longest distance in a vertical direction from a plane defined by a portion with which the installation part comes into contact in the one side surface, in a region inward the portion with which the installation part comes into contact in the one side surface of the third pulley.

4. The belt attachment tool according to claim 3,

wherein the installation part is coupled to the protection part in a stepped manner.

5. The belt attachment tool according to claim 1,

wherein a part of the first belt holding part is projected outwardly from the outer periphery of the side surface part.

6. The belt attachment tool according to claim 1,

wherein a portion of the first belt holding part, on which the belt is wound has a substantially circular arc shape.

7. The belt attachment tool according to claim 1,

wherein a portion of the first belt holding part, on which the belt is wound has a substantially involute curve shape, and the first belt holding part and the second belt holding part are arranged in a straight line.

8. The belt attachment tool according to claim 1,

wherein the first belt holding part is formed integrally with the second belt holding part.

9. The belt attachment tool according to claim 8,

wherein in the first belt holding part and the second belt holding part that are integrally formed, a portion on which the belt is wound has a substantially circular arc shape.