KR102214089B1 - Friction roller for maintaining the braking force of the outer ring body of ball bearings used in conveyors - Google Patents

Abstract

The present invention relates to a friction roller for maintaining braking force of an outer wheel of a ball bearing applied to a conveyor. A motor (3) and shafts (4) rotated by interlocking between a chain (5) and a sprocket (6) are arranged on a pair of horizontal frames (2) provided in parallel to each other at a predetermined interval, and the friction roller (100) is fixated on an outer circumferential surface of the shaft (4) to be rotated to transfer an upper side weight (8).

Description

Friction roller for maintaining the braking force of the outer ring body of ball bearings used in conveyors}

The present invention relates to a friction roller for maintaining the braking force of an outer ring body of a ball bearing employed in a conveyor, and more particularly, an outer ring body that rubs against a heavy object when a load such as stop of a heavy object is applied while a heavy object is transported by a conveyor. Maintaining the braking force of the outer ring body of the ball bearing used in the conveyor to efficiently prevent the transmission of overload to the drive motor and shaft by continuously rotating the inner ring body fixed to the shaft while maintaining a constant braking force of the shaft. It relates to a dragon friction roller.

In general, a conveyor is used to transport parts, finished products, or heavy goods such as pallets for loading in manufacturing plants and distribution warehouses, and such conveyors are transported by riding a plurality of transport rollers or transport belts connected to a drive motor and a shaft.

In addition, a stopper is provided on the conveying path in order to carry out the heavy object one by one at the end point of the heavy object, and the conveyor is controlled to wait in a stopped state when the heavy object is detected.

However, if the drive motor of the conveyor stops every time the heavy object reaches the end point, the power consumption is large when restarting, so it is inefficient and severe wear and damage of the device occurs.In general, even if the heavy object stops, the drive motor and shaft continue to A rotating friction roller is applied.

Looking at the conveyor in which the friction roller of the conventionally disclosed Patent No. 10-1241077 is installed, the friction roller is a bevel gear through which rotational power is transmitted, a shaft fixedly coupled to the bevel gear, and passed through and transferred by the shaft. A roller in direct contact with the object to be made, a bush formed on the end face of the roller, a spring that applies a pushing force to the bush, a level block that adjusts the elastic force of the spring, and the position of the level block being fitted to the shaft It is composed of a fixing pin to fix it.

At this time, the friction roller is configured to push the spring by the level block and push the bush with the elastic force of the spring to transmit the rotational force of the shaft toward the roller. The spring is twisted by the friction and the bush and the spring are damaged, as well as the elastic force of the spring is manually adjusted by using a level block, so that the elastic force of the spring can be adjusted from time to time depending on the degree of wear of the bush and the weight of the object. There was a problem that the hassle to reset and the setting time increased.

Accordingly, the applicant of the present invention is entitled to Patent No. 10-1507295 “Friction roller for maintaining the braking force of the outer ring body of ball bearings employed in conveyors” and Patent No. 10-1956477 “Friction roller for maintaining the braking force of the outer ring body of ball bearings used in conveyors” We have suggested a way to solve the above problems through ”.

Registered Patent No. 10-1241077 Registered Patent No. 10-1507295 Registered Patent No. 10-1956477

Accordingly, the present invention was invented to eliminate the above problems, and when a load such as stopping of a heavy object is applied while a heavy object is being transported by a conveyor, it is fixed to the shaft while maintaining a constant braking force of the outer ring body rubbing against the heavy object. The technology is focused on the friction roller for maintaining the braking force of the outer ring body of the ball bearing used in the conveyor to efficiently prevent the transmission of overload to the drive motor and shaft by continuously rotating the resulting inner ring body along the rotation of the shaft. It was completed as an assignment.

The present invention to achieve the above technical problem, the shaft 4 rotated by the interlocking of the motor 3, the chain 5 and the sprocket 6 on a pair of horizontal frames 2 provided in parallel is constant In the friction roller 100 arranged at intervals, fixed on the outer periphery of the shaft 4 and rotated to transfer the heavy object 8 on the upper side, the inner ring on the outer periphery of the shaft 4 A ball bearing consisting of a sieve 10, a rotating ball 30 and an outer ring body 20 is provided, and a plurality of rotating balls 30 provided in the space between the inner ring body 10 and the outer ring body 20 The support 42 of the retainer 40 is inserted in each interval to be closely fixed to the inner ring body 10, and the receiving groove portion of the fixing cover 50 facing the retainer 40 with the front surface of the support 42 52), the first fixing pin 85 is inserted into the groove 86 formed in the support 42 and the outer surface of the first fixing pin 85 is formed on the outside of the fixing cover 50 While in close contact with 54, the retainer 40 and the fixing cover 50 are closely fixed, so that the inner ring body 10, the retainer 40 and the fixing cover 50 are integrally fixed to the outside of the shaft 4 When the heavy object 8 is stopped by a stopper 9 provided on the transfer line of the heavy object 8 that is located above the outer ring body 20 and is transported by being fixed on the periphery, the weight of the heavy object 8 Even if the rotation of the outer ring body 20 is stopped by the load, the inner ring body 10 is caused by the sliding rotation of the rotating ball 30 provided between the inner ring body 10 and the outer ring body 20. It provides a friction roller for maintaining the braking force of the outer ring body of the ball bearing employed in the conveyor, characterized in that configured to rotate continuously along the rotation.

At this time, a snap ring 75 having an opening portion 75a is fixedly provided in the receiving portion 76 formed outside the retainer 40, and a groove 72 is formed on the shaft 4, and the groove The second fixing pin 71 is inserted into 72 so that the second fixing pin 71 protrudes to the outside, so that the retainer 40 is inserted onto the shaft 4 while the opening 75a of the snap ring 75 becomes the second fixing pin ( 71), and then rotating the snap ring 75 so that the closing portion 75b of the snap ring 75 is in close contact with the second fixing pin 71, whereby the second fixing pin 71 is inserted. To prevent separation of the retainer 40 on the shaft 4, locking grooves 75c are formed at both ends of the snap rings 75 on both sides of the opening 75a, respectively, so that the locking grooves ( 75c) is characterized in that it is configured to rotate by inserting a sharp tool.

In another aspect of the present invention, shafts 4 rotated by interlocking motors 3, chains 5 and sprockets 6 are arranged at regular intervals on a pair of horizontal frames 2 provided in parallel. In the friction roller 100 for transporting the weight 8 on the upper side while being fixed and rotated on the outer periphery of the shaft 4,

A ball bearing consisting of an inner ring body 10, a rotating ball 30, and an outer ring body 20 is provided on the outer periphery of the shaft 4, and between the inner ring body 10 and the outer ring body 20 The support 42 of the retainer 40 is inserted between the plurality of rotating balls 30 provided in the space, and the front surface of the support 42 accommodates the fixing cover 50 facing the retainer 40 The first fixing pin 85 is inserted into the groove 86 formed in the support member 42 and in close contact with the groove 52, and the outer surface of the first fixing pin 85 is formed on the outside of the fixing cover 50. While in close contact with the friction jaw 54, the retainer 40 and the fixing cover 50 are closely fixed, and the rear side of the retainer 40 is fixed to the sprocket 6, and the inner periphery of the retainer 40 is the shaft 4 ) In close contact with the ball bearing 97 fixed on the outer periphery of the sprocket 6 to rotate according to the rotation of the sprocket 6, and the inner ring body 10 is attached to the elastic spring 91 fixed to the inner surface of the sprocket 6 The inner part is fixed by the supported inner contact body 92 and the outer part is fixed on the shaft 4 by the outer contact body 95 supported by the snap ring 98 fastened and fixed on the shaft 4 The rotating ball 30 is configured to be rotated by the rotation of the shaft 4, so that the rotating ball 30 is rotated according to the rotation of the retainer 40 and receives additional rotational force by the rotation of the inner ring body 10. The rotational force of is increased, and the rotational force is further transmitted to the outer ring body 20 provided on the outside of the rotation ball 30, and the outer ring body located outside the inner ring body 10 and the rotation ball 30 By further adding a rotational force by the position and diameter of (30), the rotational force of the outer ring body 20 is increased 1.5 to 1.6 times compared to the rotational force of the inner ring body 10, and the upper portion of the outer ring body 20 When the heavy object 8 is stopped by the stopper 9 provided in the transfer line of the heavy object 8 to be located and transferred, even if the rotation of the outer ring body 20 is stopped by the load of the heavy object 8, the inner ring body ( 10) and the sliding rotation power of the rotating ball 30 provided between the outer ring body 20 There is provided a friction roller for maintaining the braking force of the outer ring body of a ball bearing employed in a conveyor, characterized in that the inner ring body 10 is configured to continuously rotate along the rotation of the shaft 4.

At this time, provided with a pair of ball bearings having a pair of inner ring body 10, rotating ball 30 and outer ring body 20 on the shaft 4, and on the outer periphery of each of the outer ring bodies 20 It characterized in that the roller member 61 is fixedly mounted to rub against the heavy object 8.

In addition, it is characterized in that it is configured to be used in the form of a single roller by inserting the tube body 65 integrally with the outer periphery of the pair of roller members 61 on both sides.

According to the present invention, the inner ring body fixed to the shaft maintains a constant braking force of the outer ring body rubbing against the heavy object when a load such as stopping the heavy object is applied while the heavy object is transported by the conveyor. By continuously rotating, there is an effect of efficiently preventing overload transmission to the drive motor and shaft side.

1 is an exemplary view showing the rotational state of the outer ring body of the friction roller according to the present invention
Figure 2 is an exemplary view showing a state in which the outer ring body of the friction roller is stopped by the stop of the weight body according to the present invention
3 is an exemplary diagram illustrating a state in which a friction roller is installed on the outer periphery of the shaft according to the present invention
4 is an exemplary view illustrating a state in which the inner ring body of the ball bearing according to the present invention is fixed on the shaft by a retainer.
Figure 5 is an exemplary view of a state in which the tubular roller is mounted on the outside of the friction roller according to the present invention
6 is an exemplary view illustrating a state in which the inner ring body of the ball bearing according to the present invention is fixed on the shaft by an elastic spring
7 is an exemplary view illustrating a state in which the friction roller is fixed on the shaft by the first fixing pin and the snap ring according to the present invention.

Hereinafter, with reference to the accompanying drawings, specific details for the implementation of the present invention will be described in more detail.

In the present invention, the inner ring body fixed to the shaft continuously rotates along the rotation of the shaft while maintaining a constant braking force of the outer ring body rubbing against the heavy object when a load such as stopping the heavy object is applied while the heavy object is being transported by a conveyor. It relates to a friction roller for maintaining the braking force of the outer ring body of a ball bearing employed in a conveyor that can effectively prevent the transmission of overload to the drive motor and the shaft side, and the inner ring body 10 to be described later with reference to FIGS. 1 to 7 ), a ball bearing having a rotating ball 30 and an outer ring body 20, and a coupling structure of the retainer 40 and the fixed cover 50.

In order to implement the present invention, the shaft 4 rotated by the interlocking of the motor 3, the chain 5 and the sprocket 6 on a pair of horizontal frames 2 provided in parallel as in FIGS. 1 and 2 ) Are arranged at regular intervals and fixed on the outer periphery of the shaft 4 and rotated, and a friction roller 100 for transferring the weight 8 on the upper side is provided.

The friction roller 100 has a structure including a structure of a ball bearing, and the inner ring body 10 provided on the inner side is fixed on the shaft 4 to be rotated by the rotation of the shaft 4, and the outer side The outer ring body 20 provided in the outer ring body 20 is configured to be rotated by receiving the rotational force of the rotating ball 30 by the rotation of the inner ring body 10, but to be stopped when receiving the load of the heavy object 8, the outer ring body When the heavy object 8 is stopped by the stopper 9 provided in the transfer line of the heavy object 8 that is located on the upper part of 20 and is transferred, the rotation of the outer ring body 20 is caused by the load of the heavy object 8 Even when stopped, the inner ring body 10 is configured to rotate continuously along the rotation of the shaft 4 by the sliding rotational force of the rotating ball 30 provided between the inner ring body 10 and the outer ring body 20.

To this end, as an embodiment, first, a ball bearing including an inner ring body 10, a rotating ball 30, and an outer ring body 20 is provided on the outer periphery of the shaft 4.

Then, as shown in FIG. 4, the support 42 of the retainer 40 is inserted between the plurality of rotating balls 30 provided in the space between the inner ring body 10 and the outer ring body 20, 42) so that the inner ring body 10 is tightly fixed to the inner surface.

And, the front surface of the support (42) is in close contact with the receiving groove (52) of the fixing cover (50) facing the retainer (40), the first fixing pin in the groove (86) formed in the support (42) (85) is inserted, and the outer surface of the first fixing pin 85 is in close contact with the friction jaw 54 formed on the outside of the fixing cover 50 so that the retainer 40 and the fixing cover 50 are The inner ring body 10, the retainer 40, and the fixing cover 50 are configured to be fixed on the outer periphery of the shaft 4 in a state in which the inner ring body 10, the retainer 40, and the fixing cover 50 are integrally fixed.

At this time, as an embodiment for fixing on the outer periphery of the shaft 4 in a state in which the inner ring body 10, the retainer 40 and the fixing cover 50 are integrally fixed, as shown in FIGS. 4 and 6 A snap ring 75 having an opening 75a is fixed in the receiving portion 76 formed on the outside of the retainer 40, and a groove 72 is formed on the shaft 4, and the groove 72 ) Is provided so that the second fixing pin 71 protrudes to the outside, and the opening portion 75a of the snap ring 75 is inserted into the second fixing pin 71 while inserting the retainer 40 onto the shaft 4 Then, the snap ring 75 is rotated so that the closing portion 75b of the snap ring 75 is in close contact with the second fixing pin 71, so that the second fixing pin 71 is inserted into the shaft ( 4) It is configured to prevent separation of the retainer 40 from the top.

At this time, it is preferable to form a locking groove (75c) on both ends of the snap ring (75) on both sides of the opening (75a) to rotate by inserting a sharp tool into the locking groove (75c) when rotating the snap ring (75). .

And, although not shown, in order to secure a firm fixing force of the snap ring 75 on the second fixing pin 71, the snap ring 75 on the second fixing pin 71 facing the closing portion 75b of the snap ring 75 ) By forming an insertion seating groove into which the closing portion 75b of) is inserted, and may be configured to rotate while inserting the closing portion 75b of the snap ring 75 on the insertion seating groove.

Looking at the operation of the friction roller 100 configured as described above with reference to FIG. 2, by a stopper 9 provided on the transfer line of the heavy object 8 that is located and transferred above the outer ring body 20 When the heavy object 8 is stopped, the rotation of the outer ring body 20 is gradually stopped by the load of the heavy object 8, and at this time, the inner ring body 10, the retainer 40 and the fixed cover 50 are formed by the shaft ( 4) Since it is integrally fixed on the top, the inner ring body 10 and the rotating ball 30 are continuously rotated by the rotation of the shaft 4, but the rotating ball 30 is a heavy object 8 ), the outer ring body 20 is sliding without interfering with the stopped outer ring body 20, so that even if the outer ring body 20 is stopped, the inner ring body 10 continues to rotate while the shaft 4 and its shaft 4 ), the overload is not transmitted to the drive motor (3) that rotates.

The resistance transmitted to the outer ring body 20 varies depending on the load of the heavy object 8, and any heavy object 8 within the range of the appropriate load causes an overload toward the drive motor 3 that rotates the inner ring body 10. In order to stop the outer ring body 20 by the heavy object 8 under the condition that it is not transmitted, it is preferable to automatically maintain the resistance constant even if the load of the heavy object 8 changes.

As another embodiment of the friction roller 100, as shown in FIG. 7, a ball bearing composed of an inner ring body 10, a rotating ball 30, and an outer ring body 20 is provided on the outer periphery of the shaft 4 However, the support 42 of the retainer 40 is inserted between each of the plurality of rotating balls 30 provided in the space between the inner ring body 10 and the outer ring body 20, and the front of the support body 42 The first fixing pin 85 is inserted into the recessed groove 86 formed in the support member 42 and closely adhered to the receiving groove 52 of the fixing cover 50 facing the retainer 40, and the first fixing pin As the outer surface of 85 is in close contact with the friction jaw 54 formed on the outside of the fixed cover 50, the retainer 40 and the fixed cover 50 are configured to be in close contact with each other.

At this time, the rear side of the retainer 40 is fixed to the sprocket 6, and the inner periphery of the retainer 40 is in close contact with the ball bearing 97 fixed on the outer periphery of the shaft 4 to rotate the sprocket 6 The inner ring body 10 is fixed by an inner contact body 92 supported by an elastic spring 91 fixed to the inner surface of the sprocket 6 and fastened on the shaft 4 The outer portion is fixed by the outer contact body 95 supported by the fixed snap ring 98 and fixedly supported on the shaft 4 to be rotated by the rotation of the shaft 4.

Looking at the operation of the friction roller 100 configured as described above with reference to FIG. 6, by the stopper 9 provided in the transfer line of the heavy object 8 is located on the upper portion of the outer ring body 20 to be transferred. When the heavy object 8 is gradually stopped, the rotation of the outer ring body 20 is stopped by the load of the heavy object 8, and at this time, the inner ring body 10 is rotated while being fixed to the shaft 4, The rotating ball 30 is fixed to the retainer 40 and the fixed cover 50 and rotated independently from the inner ring body 10 above.

Looking at this structure in more detail, the rotating ball 30 is different from the above embodiment in which the inner ring body 10, the retainer 40 and the fixing cover 50 are integrally formed, the rotating ball 30 is The rotational force of the rotating ball 30 is increased by being rotated according to the rotation of the retainer 40 and receiving the rotational force due to the rotation of the inner ring body 10, thereby increasing the rotational force of the rotating ball 30, and thus the outer ring body ( 20), while further transmitting the rotational force to the inner ring body 10 and the rotational ball 30, the rotational force is further added by characteristics such as the position and diameter of the outer ring body 30 located outside the inner ring body 10 and the rotation ball 30. Compared to the rotational force of the sieve 10, the rotational force of the outer ring body 20 is increased by about 1.5 to 1.6 times, and accordingly, the outer ring body 20 rotates 1.5 to 1.6 times faster even if the inner ring body 10 is slowly rotated. Since it can be made, it is possible to move the heavy object 8 at a high speed with a small force, thereby increasing work efficiency.

In addition, the inner ring body 10 and the rotating ball 30 are continuously rotated by the rotation of the shaft 4, and the retainer 40 and the fixing cover 50 are fixed to the sprocket 6 Is rotated by the rotation of the sprocket 6, that is, the sprocket 6 and the shaft 4 are rotated simultaneously, and accordingly, the retainer 40 and the fixing cover 50 and the inner ring body 10 And the rotating ball 30 is continuously maintained in a rotating state, but the rotating ball 30 is slidably rotated without interfering with the outer ring body 20 stopped by the load of the heavy object 8, in the end, the outer ring Even if the sieve 20 is stopped, the inner ring body 10 is continuously rotated and the overload is not transmitted to the shaft 4 and the drive motor 3 rotating the shaft 4.

As described above, the friction roller 100 has been described in one embodiment and another embodiment, and in addition to this, in the present invention, a heavy object 8 may be used to rub on the outer periphery of the outer ring body 20, 4 and 6, a pair of ball bearings having a pair of inner ring bodies 10, rotating balls 30, and outer ring bodies 20 on the shaft 4 are provided, and each of the outer ring bodies 20 ) On the outer periphery of the roller member 61 can be fixedly mounted to rub against the heavy object 8. At this time, the roller member 61 is formed as a tube body and fitted on the outer periphery of the outer ring body 20, and may be formed of any material such as a metal material or a synthetic resin material (including a urethane material).

In addition, as shown in FIG. 5, a tubular body 65 made of a metal material or synthetic resin material (including urethane material) is integrally inserted into the outer periphery of the pair of roller members 61 on both sides of the roller member 61 to be used in the form of a single roller.

According to the friction roller for maintaining the braking force of the outer ring body of the ball bearing employed in the conveyor of the present invention as described above, the outer ring body rubbing against the heavy object when a load such as stop of the heavy object is applied while the heavy object is being transported by the conveyor. While maintaining a constant braking force, the inner ring body fixed to the shaft is continuously rotated along with the rotation of the shaft, so that the transmission of overload to the drive motor and the shaft side can be efficiently prevented.

The present invention described above has been described with reference to an embodiment shown in the drawings, but this is only exemplary, and various modifications and other equivalent embodiments are possible from those of ordinary skill in the art. Should be clarified. Accordingly, the true technical protection scope of the present invention should be interpreted by the appended claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

2: horizontal frame 3: motor
5: chain 6: sprocket
8: heavy object 10: inner ring body
20: outer ring body 30: rotating ball
40: retainer 42: support
50: fixed cover 52: receiving groove
54: friction jaw 85: first fixing pin
86: groove 100: friction roller

Claims (5)

On a pair of horizontal frames (2) provided in parallel, shafts (4) rotated by interlocking of a motor (3), chain (5) and sprocket (6) are arranged at regular intervals, and the shaft (4) In the friction roller 100 for transferring the heavy object 8 on the upper side while being fixed and rotated on the outer periphery of,
A ball bearing composed of an inner ring body 10, a rotating ball 30, and an outer ring body 20 is provided on the outer periphery of the shaft 4,
The support 42 of the retainer 40 is inserted between each of the plurality of rotating balls 30 provided in the space between the inner ring body 10 and the outer ring body 20 to be closely fixed to the inner ring body 10, The front surface of the support 42 is in close contact with the receiving groove 52 of the fixing cover 50 facing the retainer 40, and the first fixing pin 85 is in the groove 86 formed in the support 42 It is inserted and the outer surface of the first fixing pin 85 is in close contact with the friction jaw 54 formed on the outside of the fixing cover 50, and the retainer 40 and the fixing cover 50 are in close contact with each other, and the inner ring body 10 ), the retainer 40 and the fixing cover 50 are configured to be fixed on the outer periphery of the shaft 4 in an integrally fixed state,
When the heavy object 8 is stopped by the stopper 9 provided in the transfer line of the heavy object 8 that is located above the outer ring body 20 and is transported, the outer ring body 20 by the load of the heavy object 8 Even when the rotation of the inner ring body 10 and the outer ring body 20, the inner ring body 10 is continuously rotated along the rotation of the shaft 4 by the sliding rotational force of the rotating ball 30 provided between the inner ring body 10 and the outer ring body 20. Friction roller for maintaining the braking force of the outer ring body of the ball bearing used in the conveyor, characterized in that to configure.
The method of claim 1,
A snap ring 75 having an opening portion 75a is fixedly provided in the receiving portion 76 formed outside the retainer 40,
A groove 72 is formed on the shaft 4, and a second fixing pin 71 is inserted into the groove 72 to protrude to the outside,
Inserting the retainer 40 on the shaft 4 so that the opening portion 75a of the snap ring 75 passes through the second fixing pin 71, and then rotates the snap ring 75 so that the snap ring 75 The closing part (75b) of the second fixing pin (71) is in close contact with the second fixing pin (71) to prevent separation of the retainer 40 on the shaft (4), but the opening ( 75a) Adopted in a conveyor, characterized in that a locking groove (75c) is formed on both ends of the snap ring (75) on both sides, and a sharp tool is inserted into the locking groove (75c) when the snap ring (75) rotates. Friction roller for maintaining the braking force of the outer ring body of ball bearings.
On a pair of horizontal frames (2) provided in parallel, shafts (4) rotated by interlocking of a motor (3), chain (5) and sprocket (6) are arranged at regular intervals, and the shaft (4) In the friction roller 100 for transferring the heavy object 8 on the upper side while being fixed and rotated on the outer periphery of,
A ball bearing composed of an inner ring body 10, a rotating ball 30, and an outer ring body 20 is provided on the outer periphery of the shaft 4,
The support 42 of the retainer 40 is inserted between the plurality of rotating balls 30 provided in the space between the inner ring body 10 and the outer ring body 20, and the front surface of the support member 42 is The first fixing pin 85 is inserted into the groove 86 formed in the support 42 and in close contact with the receiving groove 52 of the fixing cover 50 facing the retainer 40, and the first fixing pin 85 The outer surface of) is in close contact with the friction jaw 54 formed on the outside of the fixed cover 50 so that the retainer 40 and the fixed cover 50 are closely fixed, and the rear side of the retainer 40 is attached to the sprocket 6 In addition to being fixed, the inner periphery of the retainer 40 is in close contact with the ball bearing 97 fixed on the outer periphery of the shaft 4 to rotate according to the rotation of the sprocket 6, and the inner ring body 10 is a sprocket ( 6) The inner part is fixed by the inner contact body 92 supported by the elastic spring 91 fixed to the inner surface of the outer contact body 95 supported by the snap ring 98 fastened on the shaft 4 The outer portion is fixed by the shaft 4 and fixedly supported on the shaft 4 to be rotated by the rotation of the shaft 4,
The rotational ball 30 is rotated according to the rotation of the retainer 40 and receives additional rotational force by the rotation of the inner ring body 10, thereby increasing the rotational force of the rotational ball 30, and the outer side of the rotational ball 30 In addition to further transmitting the rotational force to the outer ring body 20 provided in, the rotational force is further added by the position and diameter of the outer ring body 30 located outside the inner ring body 10 and the rotating ball 30 , Compared to the rotational force of the inner ring body 10, the rotational force of the outer ring body 20 is increased by 1.5 to 1.6 times, and is provided on the transfer line of the heavy object 8 which is located above the outer ring body 20 and is transported. A rotating ball provided between the inner ring body 10 and the outer ring body 20 even if the rotation of the outer ring body 20 is stopped by the load of the heavy object 8 when the heavy object 8 is stopped by the stopper 9 A friction roller for maintaining the braking force of the outer ring body of a ball bearing employed in a conveyor, characterized in that the inner ring body 10 is configured to continuously rotate along the rotation of the shaft 4 by the sliding rotation force of 30.
The method according to any one of claims 2 or 3,
A pair of ball bearings having a pair of inner ring bodies 10, rotating balls 30, and outer ring bodies 20 on the shaft 4, and a roller member on the outer periphery of each outer ring body 20 Friction roller for maintaining the braking force of the outer ring body of a ball bearing employed in a conveyor, characterized in that (61) is fixedly mounted to rub against the heavy object (8).
The method of claim 4,
A friction roller for maintaining the braking force of the outer ring body of a ball bearing used in a conveyor, characterized in that the tube body 65 is integrally fitted to the outer periphery of the pair of roller members 61 and used in a single roller form.

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