JPH0729332Y2 - V belt - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION (Industrial field of application) The present invention relates to an improved technique for a V-belt for high load transmission used in a transmission of an automobile or the like.

(Prior Art) Conventionally, a gear type or a fluid type is generally widely used as a transmission in an automobile or a combine machine, an agricultural machine such as a tractor, etc., but in recent years, improvement in operability at the time of shifting, Belt type continuously variable transmissions are being developed for the purpose of improving fuel efficiency.

However, the belt used in this belt type continuously variable transmission requires an extremely high torque transmission capability, and conventional conventional V belts made of rubber cannot withstand a high lateral pressure and cause buckling deformation. Can not do it.

Therefore, conventionally, various high load transmission belts have been known in order to satisfy such requirements (see, for example, JP-A-46-48).
61, JP-A-55-27595, JP-A-56-76745, JP-A-SHO
59-77147).

In addition, the applicant basically has a large number of endless tension bands, a fitting part to which the tension bands fit, and a sliding contact part that is in sliding contact with the groove surface of the pulley on the left and right side surfaces. And a mating groove portion and a ridge corresponding to each other are formed on the upper and lower surfaces of the tension band and on the upper and lower surfaces of the fitting portion of each block, and Proposed is a V-belt having a structure in which the ridges of the block are engaged with each other and the block is locked and fixed to the tension band in the belt longitudinal direction (JP-A-60-49151 and JP-A-61151). −206847
(See Japanese Utility Model Publication No. 62-54348).

(Problems to be solved by the invention) By the way, the V composed of the tension band and the block as described above is used.
In the belt, in order to prevent the lower half portions of the blocks from interfering with each other when the V-belt goes around the pulleys, each block is provided with a predetermined length in the belt longitudinal direction between adjacent blocks with respect to the tension band. It is possible to arrange them at intervals.

However, in the V-belt in which the spaces are provided between the blocks as described above, the following problems occur in connection with the transmission pulley around which the V-belt is wound.

That is, the above-mentioned speed change pulley is constructed by arranging a frustoconical movable shape and a fixed shape having the same angle so as to face each other. Normally, as shown in FIG. When each block b locked to a enters into the belt groove of the speed change pulley c and engages with the belt groove surface c ₁ , the block b stands vertically with respect to the tension band a (of the block b). With the center line aligned with the radial direction of the speed change pulley c), the side surface of the block b as shown in FIG.
It is set so that there is no gap between b ₁ and the belt groove surface c ₁ . In the figure, the tension band a is shown by the center line of its core.

However, when the V-belt enters the pulley C and winds around it, a speed difference occurs between the upper and lower parts of each block b with the tension band a as a boundary, and the upper part of the block b is in the speed increasing state. Since the lower part is in the deceleration state, the block b upper part is acted on by backward force to accelerate, and the lower part b is acted on by backward force to decelerate. Power to defeat works. On the other hand, on the side where the V-belt exits from the pulley c, a force opposite to that at the time of entry is applied, and the block b has a force that tilts the upper part forward. At this time, since the blocks b are arranged at a predetermined interval so as not to interfere with each other, these forces cause the blocks b to easily tilt in the front-rear direction on the entry side and the removal side of the pulley c. As a result, the block b swings.

Along with this swing, heat generation and wear due to friction occur between the block b and the tension band a, and as the wear progresses, rattling occurs in the locking and fixing state of the block b with respect to the tension band a. The rocking of is further promoted. For this reason, normally, as shown in FIG. 18, each block b enters in a state in which it is perpendicular to the pulley center, whereas the rattling of the block b with respect to the tension band a causes the block b to tilt. It becomes easy to enter in the state. When the upper part of the block b is inclined forward in the pulley rotation direction as shown in FIG. 19 (a), or as shown in FIG. 20 (a).
When the lower part of the pulley is inclined forward in the direction of rotation of the pulley, as shown in Fig. 19 (b) and Fig. 20 (b), respectively, the opening angle of the pulley (the angle formed by the belt groove surfaces c ₁ , c ₁ ) On the other hand, the angle of the block b (the angle formed by the side surfaces b ₁ and b ₁ ) apparently becomes large, and only the upper part of the block b comes into contact with the belt groove surface c ₁ of the pulley c, and the belt only at its upper part. Lateral pressure is received from the groove surface c _1, and the side surface b _{1 of the} block b is originally
The side pressure that should be received as a whole is concentrated only on the upper end portion, and the block b is chipped, causing early damage.

Further, as described above, when heat is generated due to friction between the block b and the fitting portion of the tension band a due to the swing,
There is a problem that the temperature of the block b and the tension band a locally rises, heat of the rubber forming the tension band a is deteriorated, a crack is generated in the tension band a, and the tension band a is cut early.

Further, because the blocks are spaced from each other as described above, it is not limited to the case where the block b is inclined with respect to the radial direction of the pulley when the block b is engaged with the speed change pulley c. Belt groove surface c ₁ of pulley c when standing
There is a problem that cannot be ignored even when engaging with. That is,
When the block b is engaged with the pulley c, it is rare that vertical and horizontal portions of the block sides b ₁ is in contact with the belt groove surface c ₁ at the same time, more or less time lag to contact timing in those parts occurs. Also at this time, the block b is in the tension band a.
In contrast, it receives an unbalanced force and swings easily. As a result, similarly to the above, a local temperature rise due to friction between the block b and the fitting portion of the tension band a causes cracks in the tension band a, leading to early cutting.

The present invention has been made in view of the above points, and an object thereof is to provide means for suppressing the swing of the blocks when the V-belts provided with intervals between the blocks engage with the speed change pulleys. Thus, it is intended to prevent abrasion and heat generation due to friction between the block and the tension band due to the swing of the block, and effectively reduce the occurrence of cracks in the tension band or damage to the block.

(Means for Solving the Problem) In order to achieve this object, the solving means of the present invention appropriately specifies the dimensional relationship of the fitting portion between the tension band and each block to which the tension band fits, By allowing the tension band to be fitted to the block fitting part in a state of compression elastic deformation, the fitting strength between the tension band and each block is increased to increase the frictional resistance between them and prevent interference between blocks. Even if a space for use is provided, the increase in the frictional resistance suppresses the swing of the block.

Specifically, the present invention has an endless tension band made of rubber in which a core extending in the longitudinal direction is embedded, and a fitting portion to which the tension band fits, and a groove of the pulley on the left and right side surfaces. Consisting of a large number of blocks that have sliding contact parts that are in sliding contact with the surface,
On the upper and lower surfaces of the tension band, concave groove portions extending in the belt width direction are formed side by side in the longitudinal direction, respectively, while on the upper and lower surfaces of the fitting portion of each block, the tension band is formed. A ridge is formed that engages with the groove on the upper and lower surfaces, and the engagement between the groove on the tension band and the ridge on each block causes each block to move between adjacent blocks to the tension band. It is assumed that the V-belt is locked and fixed at a predetermined interval in the belt longitudinal direction.

Then, the minimum thickness in the vertical groove portion of the tension band is formed to be larger than the maximum interval between the vertical convex stripe portions in each block, and the vertical groove portion of the tension band is compressed and elastically deformed. The upper and lower convex groove portions of each block are fitted in the upper and lower concave groove portions.

(Operation) According to this configuration, in the present invention, the minimum thickness of the tension band in the vertical groove is larger than the maximum distance between the vertical projections of each block, and the vertical groove of the tension band is elastically deformed. Since the upper and lower ridges of each block are fitted in the upper and lower concave groove parts in the locked state, when the tension band is fitted to the fitting part of the block, the tension band is pressed against the fitting part of the block. As a result, the fitting strength between the block and the tension band is increased, the frictional resistance against the block swing is increased, and the block is firmly locked and fixed to the tension band in the state where the block swing is restricted. . Therefore, even if there is a gap between the blocks to prevent mutual interference between the blocks when the V-belt goes around the pulleys, the tension of each block is increased in the straight running state before the belt is wound around the speed change pulley. The belt is always held in a substantially vertical shape, and even when the pulley is engaged, the block is engaged in a state of being aligned in the radial direction of the pulley, and the vibration of the block on the pulley is suppressed.

In addition, since the block is firmly fixed to the tension band, even when the block engages with the pulley without tilting, the imbalance due to the time lag between when the side surface of the block starts to hit the belt groove surface of the pulley and when it hits the entire surface It is difficult for the block to oscillate with various forces.

Further, since the tension band is fitted in the block in a state of being compressed and elastically deformed, even if the deformation or abrasion of the rubber material forming the tension band progresses with time, the compression is performed as described above. The rattling between the block and the tension band is delayed by that amount, and rattling does not occur in a short period of time. Therefore, the rocking or tilting of the block is delayed and the durability of the belt is improved. .

In addition, the minimum thickness of the vertical groove of the tension band is set to be larger than the maximum distance between the vertical projections of each block, and the vertical groove of the tension band is compressed and elastically deformed. Since the upper and lower ridges of each block are fitted in the groove, it is possible to obtain an appropriate compression margin by making use of the characteristics of each tension band and each member of the block, without applying excessive stress to both the block and tension band. The swing of the block in the power transmission state can be suppressed. That is, an excessive compressive force deviating from each member characteristic does not act between the upper and lower concave groove portions of the tension band and the upper and lower convex stripe portions of each block, and in the tension band, the rubber portion forming the tension band is separated from the block. The block is permanently deformed by receiving an excessive compression force, or conversely, an excessive force acts in the direction of separating the upper and lower surfaces of the fitting part from each other due to the excessive compression force from the tension band generated in the fitting part. There is no risk of the block being damaged.

Embodiment An embodiment of the present invention will be described below with reference to the drawings.

1 to 6 show a V-belt A _{1 according} to the first embodiment of the present invention.
Indicates. This belt A ₁ has a plurality of cords inside the shape-retaining layer 1b.
A pair of left and right endless tension bands 1 and 1 made of rubber in which 1a, 1a, ... (Core bodies) are arranged in parallel and embedded, and the tension bands 1 on the left and right sides can be detached from the width direction. Notch-shaped fitting grooves 2 and 2 as fitting parts to be fitted are provided, and sliding contact parts 3 and 3 which are in sliding contact with the groove surface P ₁ of the pulley P on the left and right side surfaces.
, Which have a plurality of blocks 4, 4, ..., In which the tension bands 1, 1 are fitted into the fitting grooves 2, 2 of each block 4, respectively, the blocks 4, 4 ,. It is fixed to the tension bands 1 and 1 with a predetermined interval in the belt longitudinal direction between the four.

In this V-belt A ₁ , concave grooves 5, 5, ... With a constant pitch extending in the width direction corresponding to each block 4 are provided on the upper surface of each tension band 1, and the concave groove portions 5, 5 are formed on the lower surface. Corresponding to, ..., Grooves 6, 6 ... With a constant pitch extending in the axial direction are formed. On the other hand, the fitting groove 2 of each block 4
On the upper wall surface, the convex ridges 7 that fit into the concave groove portions 5 on the upper surface of the tension band 1, and on the lower wall surface of the fitting groove 2 are the convex ridge portions 8 that fit into the concave groove portions 6 on the lower surface of the tension band 1. Are formed respectively, and the ridges 7 and 8 of the blocks 4 are fitted into the groove grooves 5 and 6 of the tension band 1 to lock and fix the blocks 4, 4, ... In the belt longitudinal direction. Has been done.

As a feature of the present invention, the minimum thickness of the upper and lower concave groove portions 5 and 6 of the tension band 1 is set so that the blocks 4 are compressed and locked to the tension band 1 from above and below. t
Is set to be larger (1 <t / s) than the maximum interval s between the upper and lower ridges 7 and 8 in each block 4, and the upper and lower concave groove portions 5 and 6 of the tension band 1 are compressed and elastically deformed. In this state, the upper and lower ridges 7 and 8 of each block 4 are fitted into each other. Also,
Ratio t / s of the minimum thickness t of the vertical groove portions 5 and 6 of the tension band 1 to the maximum distance s between the vertical convex portions 7 and 8 of each block 4.
In order to prevent the rubber portion of the tension band 1 from being permanently deformed and to prevent the block 4 from receiving excessive force and being damaged by the compressive force generated in the fitting portion, t / s ≦ 1.2.
It is desirable to set the relationship.

Therefore, in the above-described embodiment, the minimum thickness t of the upper and lower concave groove portions 5 and 6 of the tension band 1 is equal to the upper and lower convex stripe portions of each block 4.
It is set to be larger than the maximum interval s between 7, 8 and the upper and lower concave groove portions 5, 6 of the tension band 1 are compressed and elastically deformed, and the upper and lower concave groove portions 5, 6 of the upper and lower concave groove portions of the respective blocks 4 Since 7, 8 are fitted, in a state where the tension band 1 is fitted in the fitting grooves 2, 2 of the block 4, the tension band 1 is brought into close contact with the fitting groove 2 of the block 4 to be in contact with the block 4. The fitting strength with the tension band 1 is increased, and the frictional resistance against the swing of the block 4 is significantly increased.
The block 4 is firmly locked and fixed to the tension band 1 in a state where the swing of the block 4 is restricted. Therefore, each block 4,
Blocks 4 and 4 when V belt A ₁ goes around pulley P between 4
Even if a predetermined interval is provided to prevent mutual interference, each block 4 is always held substantially perpendicular to the tension band 1 in a straight running state before the belt A ₁ is wound around the speed change pulley P. Even when the block 4 is engaged with the pulley P, the block 4 is engaged in a state of being aligned with the radial direction of the pulley P, and the swing of the block 4 on the pulley P can be suppressed.

Further, since the block 4 is strongly fixed to the tension band 1, even when the block 4 is engaged with the pulley P without being tilted as described above, each side surface (sliding contact portion 3) of the block 4 has the pulley P. It is possible to prevent the block 4 from swinging due to an unbalanced force that accompanies the time lag between the time when the belt groove surface P ₁ partially starts to the time when the belt groove surface P ₁ entirely contacts.

Since the rocking of each block 4 is suppressed in this way, it is possible to suppress the local temperature rise due to the frictional heat generated between the block 4 and the tension band 1 accompanying the rocking of the block 4, and the thermal deterioration due to the temperature rise. Generation of cracks in the tension band 1 is suppressed, and early cutting of the tension band 1 can be prevented.

Further, since the tension band 1 is fitted to the block 4 in a state of being compressed and elastically deformed, even if the rubber material forming the tension band 1 is deformed or deteriorated due to wear or the like, it is still compressed. Only, it is possible to delay the occurrence of backlash between them, that is, the rocking or tilting of the block 4 due to the backlash.
As a result, the durability of the belt A ₁ can be improved.

Further, the ratio t between the minimum thickness t of the vertical groove portions 5 and 6 of the tension band 1 and the maximum distance s between the vertical convex portions 7 and 8 of each block 4 is t.
Since / s is set to 1 <t / s, and the upper and lower concave groove portions 5 and 6 of the tension band 1 are compressed and elastically deformed, the upper and lower convex strip portions 7 and 8 of the respective blocks 4 are fitted to each other. , An appropriate compression margin is obtained by utilizing the respective member characteristics of the tension band 1 and the block 4, and the swing of the block 4 in the transmission state is suppressed without giving an excessive stress to both the block 4 and the tension band 1. be able to. That is, an excessive compressive force deviating from each member characteristic does not act between the vertical concave groove portions 5 and 6 of the tension band 1 and the vertical convex line portions 7 and 8 of each block 4 to form the tension band 1. The rubber portion does not receive an excessive compressive force from the block 4 to cause permanent deformation, and conversely, the block 4 receives an excessive force and is damaged by the excessive compressive force from the tension band 1 generated in the fitting portion. There is no fear of doing it.

FIG. 7 to FIG. 11 show the second embodiment (note that FIG. 1 to FIG. 6).
The same parts as those in the figure are denoted by the same reference numerals and detailed description thereof will be omitted), and they are applied to other types of V-belts A ₂ .

That is, in this embodiment, the tension band 1 is composed of one endless belt. On the other hand, each block 4'provided with a predetermined space in the longitudinal direction of the belt with respect to the tension band 1.
Is the left and right block portions 4'in the center portion on the left and right.
It is divided into two parts, a and 4'a, and both block parts 4 '
a and 4'a are butted against each other. Fitting grooves 2'notched in the outward direction of the block 4 '(direction toward the sliding contact portion 3) are formed in the end faces of the block portions 4'a which face each other, from substantially the upper and lower central portions thereof. Block 4'a,
Due to the fitting grooves 2'and 2'of the 4'a, a penetrating fitting hole 9 as a fitting portion is formed in the central portion of the block 4 '.

Further, in the left and right block portions 4'a, 4'a, the upper coupling portions 4'c, 4'c above the respective fitting grooves 2'replace the upper coupling portions 4'c, 4'c. Due to the upper joint reinforcing member 10 arranged so as to surround, the lower joint portions 4'd, 4'd below each fitting groove 2'surround both lower joint portions 4'd, 4'd. Are integrally joined by the lower joining reinforcing members 11 arranged in the.

The upper and lower wall surfaces of the fitting hole 9 (each block portion 4'a
Ridges 7 ', 8'to be fitted with the concave groove portions 5, 6 on the upper and lower surfaces of the tension band 1, respectively, are formed in the fitting groove 2'of the upper and lower ridges 7', 8 '. 'The above-mentioned coupling reinforcing member 1 covered with
The relationship between the distance s between 0 and 11 and the thickness t between the bottoms of the tension bands 1 and 6 is set to 1 <t / s, and the vertical grooves 5 and 6 of the tension band 4 ′ are The upper and lower concave groove portions in a state of being compressed and elastically deformed
The upper and lower ridges 7 ', 8'of each block 4'are fitted in 5,6.

Therefore, also in this embodiment, the same operational effect as that of the first embodiment can be obtained.

12 to 17 show third to fifth embodiments of the present invention. First, in the third embodiment shown in FIGS. 12 and 13, the block 4'is provided with a fitting groove 2'notched downward from the upper surface thereof.
Are formed. The tension band 1 is fitted in the bottom of the fitting groove 2 ', and the pin 12 is inserted between the left and right sliding contact parts 3, 3 of the block 4'to prevent the tension band 1 from coming off. . In the case of this embodiment, the lower portion of the pin 12 serves as the upper protruding portion of the block 4'and the bottom surface of the fitting groove 2 'serves as the lower protruding portion. The thickness t between the upper and lower concave groove portions 5 and 6 of the tension band 1 is set to be larger than the distance s between and.

In the fourth embodiment shown in FIGS. 14 and 15, the block 4'is vertically divided into upper and lower block portions 4'e, 4'f, and both block portions 4'e, 4 ' ′ F is integrally fixed by a fastening material 13 such as a rivet or a screw.
A fitting groove 2'is formed in the upper surface of the lower block portion 4'f, and the tension band 1 is fitted in the fitting groove 2 '. In this case, the thickness t between the upper and lower concave groove portions 5 and 6 bottom of the tension band 1 is determined by the protrusion 7'on the bottom surface of the upper block portion 4'e and the bottom surface of the fitting groove 2'in the lower block portion 4'f. Ridge 8 '
It is set to be larger than the interval s between and.

Further, in the fifth embodiment shown in FIGS. 16 and 17, the block 4'is fitted with the lower block portion 4'f having the fitting groove 2'on its upper surface and the lower block portion 4'f. Separated from the upper block portion 4'e fitted in the groove 2 ', the tension band 1 fitted in the fitting groove 2'of the lower block portion 4'f is prevented from coming off by the upper block portion 4'e. And the upper block portion 4'e
Is fixedly connected to the lower block portion 4'f by a pin 12 '. The thickness t between the upper and lower concave groove portions 5, 6 of the tension band 1 is determined by the ridge 7'of the bottom surface of the upper block portion 4'e.
Is set to be larger than the interval s between the lower block portion 4'f and the convex strip portion 8'on the bottom surface of the fitting groove 2 '.

Therefore, also in these embodiments, it is possible to achieve the same effects as the first embodiment.

(Effects of the Invention) As described above, according to the present invention, a tension band formed by arranging recessed groove portions corresponding to the upper and lower sides in the longitudinal direction, and a fitting to which the tension band is fitted. And a plurality of blocks each having a ridge portion formed on the upper and lower surfaces of the fitting portion to engage with the groove portions on the upper and lower surfaces of the tension band,
Due to the engagement of the concave groove of the tension band and the ridge of each block,
V is formed by locking each block between adjacent blocks with respect to the tension band with a space for preventing interference in the belt longitudinal direction.
In the belt, the minimum thickness at the vertical groove of the tension band is set so that each block is locked and fixed to the tension band by compressing the tension band from the vertical direction, Since the upper and lower concave groove portions of the tension band are compressed and elastically deformed to fit with the upper and lower ridge portions of each block, excessive compression causes permanent deformation of the rubber portion of the tension band or block. Without causing damage to
Since the tension band is fitted in the fitting part of the block in a compressed state, the fitting strength between the block and the tension band increases and the frictional resistance against the block swing increases, so that the block swings in the tension band. It can be firmly locked and fixed in the state of being regulated. Therefore, the blocks can be engaged with each other in the radial direction of the pulley when the belt engages with the speed change pulley while preventing the mutual interference of the blocks when the V-belt goes around the pulley. It is possible to suppress the rocking of the block on the pulley even with respect to the unbalanced force caused by the deviation of the contact time of the pulley with the belt groove surface, and to prevent the rattling caused by the rocking of the block.
It is possible to prevent premature damage to the block due to the concentration of pulley side pressure on the upper end of the block and premature disconnection of the tension band due to frictional heat generation. Furthermore, the rubber material that composes the tension band as much as it is fitted by compression. It is possible to delay the deformation such as deformation and wear of the belt, and the occurrence of backlash associated therewith, thereby improving the durability of the belt.

[Brief description of drawings]

1 to 6 show a first embodiment of the present invention. FIG. 1 is a side view of a V-belt, FIG. 2 is a side view of a tension band, FIG. 3 is a side view of a block, and FIG. Is a perspective view partially showing the V-belt, and FIGS. 5 and 6 are sectional views taken along the lines AA and BB of FIG. 1, respectively. 7 to 11 show a second embodiment, FIG. 7 is a view corresponding to FIG. 1, FIG. 8 is a view corresponding to FIG. 4, and FIG. 9 is a sectional view taken along the line CC of FIG. Figures 10 and 11
The drawings are sectional views taken along lines DD and EE in FIG. 7, respectively. FIG. 12 is a view corresponding to FIG. 6 of the third embodiment, and FIG.
It is the FF sectional view taken on the line of FIG. FIG. 14 is the sixth of the fourth embodiment.
FIG. 15 is a sectional view taken along line GG in FIG. First
FIG. 16 is a view corresponding to FIG. 6 of the fifth embodiment, and FIG. 17 is H of FIG.
It is a -H line sectional view. FIG. 18 is a schematic explanatory view showing a state where the block of the belt stands perpendicular to the tension band and engages with the pulley, and FIG. 19 shows a state where the upper part of the block of the belt is inclined with respect to the pulley rotation direction and engages with the pulley. Schematic explanatory diagram showing
FIG. 20 is a schematic explanatory view showing a state in which the lower part of the belt block is inclined in the pulley rotation direction and is engaged with the pulley. A ₁ to A ₅ ... V belt, 1 ... tension band, 2,2 '... fitting groove, 3 ... sliding part, 4,4' ... block, 5,6 ... recessed groove, 7 , 7 ', 8,8' ... Ridge, 9 ... Mating hole.

Continuation of the front page (56) Reference JP-A-61-103029 (JP, A) JP-A-61-21447 (JP, A) JP-A-59-117936 (JP, A) Actually developed JP-A-62-146033 (JP , U) Actually open 61-64543 (JP, U) Actually open 60-123446 (JP, U)

Claims (3)

[Scope of utility model registration request] 1. An endless tension band made of rubber in which a core extending in the longitudinal direction is embedded, and a fitting portion into which the tension band fits, and the left and right side surfaces are in sliding contact with the groove surface of the pulley. A plurality of blocks each having a sliding contact portion are formed. On the upper and lower surfaces of the tension band, concave groove portions extending in the belt width direction are formed side by side in the longitudinal direction, respectively. On the upper and lower surfaces of the fitting portion, there are formed ridges which engage with the concave groove portions on the upper and lower surfaces of the tension band, respectively, and by the engagement of the concave groove portion of the tension band and the ridge portion of each block, The blocks are locked and fixed between adjacent blocks with respect to the tension band at a predetermined interval in the longitudinal direction of the belt.
In the belt, the minimum thickness of the above-mentioned tension band at the upper and lower concave groove portions is formed to be larger than the maximum distance between the upper and lower convex rib portions of each block, and the upper and lower concave groove portions of the tension band are elastically deformed by compression. In the state, the V-belt is characterized in that the upper and lower convex groove portions of the respective blocks are fitted in the respective upper and lower concave groove portions. 2. The tension band is a pair of right and left, and the fitting portion of each block is a notch-shaped fitting groove into which the pair of tension bands are removably fitted in the lateral width direction of the block. V-belt according to claim (1) of the utility model registration claim. 3. The V-belt according to claim 1, wherein the fitting portion of each block is formed in a penetrating shape in the central portion of the block.