JPH0645152U - Rotation transmission device that can rotate output shaft by input shaft - Google Patents

Abstract

(57) [Summary] [Object] To provide a rotation transmission device in which an output shaft can be rotated only by an input shaft. [Structure] The output shaft 22 and the input shaft 21 have the same center line. A rotated body 23 is provided at the inner end of the output shaft 22. Lock pin 26 that exerts a restoring force outward in the radial direction
An internal gear-shaped lock ring 27 having a valley portion 27 a in which a is bited outward in the radial direction is fixed to a casing 28. Rotating disk 29 at the inner end of the input shaft 21
In addition, a substantially mountain-shaped transmission hole 30 into which the lock pin 26a is inserted is provided in the same number as the lock pin 26a.
The rotating body 23 and the rotating disk 29 are assembled in the casing 28, and the rotation of the casing 28 is stopped. [Effect] The operation of the device is simplified, and smooth rotational movement and performance reliability are exhibited even after long-term use.

Description

[Detailed description of the device]

[0001]

[Industrial applications]

 This invention is, for example, as a means for rotationally driving a sheet winding shaft of a covering sheet opening / closing device that winds a covering sheet of a vinyl house around the sheet winding shaft to open and close it, or like the above-described sheet winding shaft, when the output shaft is loaded by load or the like. The present invention relates to a rotation transmission device, which is widely used in applications where it is difficult to rotate in either forward or reverse directions, and whose output shaft can be rotated only by an input shaft.

[0002]

[Prior art]

 Conventionally, a rotation transmission device which is used for a seat opening / closing device of a vinyl house and which can rotate an output shaft only by an input shaft is disclosed in the above-mentioned JP-A-1-266359. In this rotation transmission device, as illustrated in FIGS. 5 and 6, the output shaft 2 and the input shaft 1 are arranged so that their center lines coincide with each other, and the driven body 3 is attached to the shaft end portion of the output shaft 2. It is provided. A lock body receiving portion in which a lock body push wall 4b is formed in a radial direction of the rotated body 3 and a lock body receiving bottom 4a having an appropriate wedge angle is formed in a tangential direction on an outer peripheral surface of the rotated body 3. 4 are provided in a combination of 2 adjacent to each other in the front and back. Further, a convex portion receiving portion 10 for accommodating a rotation transmitting convex portion 6 described later is formed in the circumferential direction so that the front and rear two lock body receiving bottoms 4a are continuous. A roller 5 having substantially the same diameter as the deepest part of the lock body receiving bottom 4a is installed in the lock body receiving portion 4 as a lock body. On the other hand, a rotary disk 9 is provided at the shaft end of the input shaft 1. The rotation disk 9 is provided with a rotation transmitting convex portion 6 located in the convex portion receiving portion 10 of the rotating body 3 so as to project in the axial direction, and the roller 5 is located in the lock body receiving portion 4. It is said to be in contact with. The rotating body 3 and the rotating disk 9 are butted against each other in a cylindrical casing 8'having an inner diameter substantially equal to the outer diameter of the rotating body 3, and the rotation transmitting convex portion 6 receives the convex portion of the rotating body 3. It is assembled with a structure that has entered the storage section 10. The rotation of the casing 8'is stopped.

In this rotation transmission device, when the output shaft 2 tries to rotate in either forward or reverse direction, the lock body receiving bottom 4a of the lock body receiving portion 4 having a wedge angle in the tangential direction functions as a lock body. The roller 5 is pushed up and bites like a wedge between the roller 5 and the inner peripheral surface of the casing 8 ', and it is stopped by a strong frictional force and cannot rotate. On the contrary, when the input shaft 1 rotates in either forward or reverse direction, the rotation transmitting convex portion 6 of the input shaft 1 pushes the roller 5 on the front side in the rotational direction to push the roller 5 into the lock body receiving portion 4. The rotation is transmitted to the rotated body 3 and the output shaft 2 by pressing the lock body pushing wall 4b in the front while being positioned in the area. At this time, the roller 5 on the rear side in the rotation direction of the rotation transmitting convex portion is moved by being pushed by the lock body pushing wall 4b of the rotated body 3, but is located in the loose area in the lock body receiving portion 4. It is still done. Therefore, the input shaft 1 freely rotates in the forward and reverse directions in a one-to-one relationship with the output shaft 2.

[0004]

[Problems to be solved by the present invention]

 In the case of the conventional rotation transmission device shown in FIGS. 5 and 6, the roller 5 is wedged between the roller 5 and the inner peripheral surface of the casing 8'by being pushed up by the lock body receiving bottom 4a of the lock body receiving portion 4. Since the rotation of the output shaft 2 is prevented by the biting operation as described above, the operation is complicated and the inner peripheral surface of the roller 5 and the inner peripheral surface of the casing 8'are rattlingly scratched by repeated use for a long time. It is difficult to expect smooth operation. In addition, as a measure to increase the productivity and reduce the manufacturing cost of this rotation transmission device, the driven body 3 of the output shaft 2 and the rotating disk 9 of the input shaft 1 are formed as an aluminum die cast product or a forged product. In general, however, a draft will always occur, and since it is long in the axial direction, it is likely to cause a movement disorder. On the other hand, the roller 5 as a lock body, the lock body pushing wall 4b, the lock body receiving bottom 4a in the rotated body 3 of the output shaft 2, the rotation transmitting convex portion 6 of the input shaft and the casing 8'are included in the number of parts. It is not easy to assemble because there are many cases.

Therefore, an object of the present invention is to be composed of parts that can be easily processed, the number of parts is small, the assembly is easy, the operation of the device is relatively simple, and the smooth rotational movement can be achieved even after long-term use. It is an object of the present invention to provide an improved rotation transmission device having a structure capable of maintaining reliability in performance.

[0006]

[Means for Solving the Problems]

 As a means for solving the above-mentioned problems of the prior art, in a rotation transmission device capable of rotating an output shaft according to the present invention by an input shaft, an output shaft 22 and an input shaft 21 are arranged in a series so that their center lines coincide with each other. The rotating body 23 is provided on the inner end portion of the output shaft 22, and the rotating body 23 is provided with a lock pin 26a that projects in the axial direction and exerts a restoring force outward in the radial direction. An inner gear-shaped lock ring 27 having a trough 27a into which the axially protruding lock pin 26a engages outward in the radial direction, the outer periphery of which is fixed to a casing 28; A rotary disk 29 is provided at the inner end of the input shaft 21. A hole into which the lock pin 26a, which penetrates the lock ring 27 and projects in the axial direction, is inserted into the rotary disc 29, has a bottom 31 having a substantially mountain shape with an arc in the rotational direction of the rotary disc 29. The same number of transmission holes 30 as the lock pins 26a are provided, the rotated body 23 and the rotating disk 29 are assembled in the casing 28, and the rotation of the casing 28 is stopped. And

[0007]

[Action]

 When the input shaft 21 is stopped, the lock pin 26a is located at the radially outer apex 32a in the transmission hole 30 of the rotary disk 29 and is engaged with the trough 27a of the lock ring 27. Therefore, even if the output shaft 22 is rotated, the lock pin 26a is strongly locked by being caught in the valley portion 27a of the lock ring 27, so that the rotation of the output shaft 22 is not allowed to be forward or reverse. It is possible.

On the other hand, when the rotary disk 29 is rotated by the input shaft 21, the lock pin 26 a slides on the oblique side 33 of the transmission hole 30 and reaches the rear bottom side vertex 32 b or 32 c, during which the lock pin 26 a moves. It is moved inward in the radial direction and released from the valley 27a of the lock ring 27. Therefore, the lock pin 26a and the output shaft 22 can rotate. The rotation of the input shaft 21 and the rotary disk 29 is transmitted from the lock pin 26a to the output shaft 22 via the rotating body 23, and the output shaft 22 is rotated in the same direction as the input shaft 21 at the same speed.

[0009]

【Example】

 Hereinafter, the illustrated embodiment of the present invention will be described. In the rotation transmission device shown in FIG. 1, reference numeral 21 is an input shaft and 22 is an output shaft. The input shaft 21 and the output shaft 22 are arranged so as to face each other in series so that their center lines coincide with each other.

At the shaft end of the output shaft 22, a rotated body 23 including a pin receiving disc 24, a pin pushing disc 25, and a lock pin 26a is integrally provided. As shown in FIG. 2, the lock pin 26a is composed of two semi-circular wire springs 26, both ends of which are bent and protruded in the axial direction, and the pin receiving disk 24 fixed to the output shaft 22. The wire spring 26 is sandwiched by the pin pressing disk 25. Due to the flexural deformation of the semicircular wire spring 26, a restoring force radially outward is applied to the lock pin 26a. The pin pressing disc 25 has a through hole 25a for allowing the lock pin 26a to penetrate therethrough in the axial direction. The through hole 25a is a long and narrow slit-shaped hole which allows the radial displacement of the lock pin 26a. The number of lock pins 26a is the same as that of the lock pins 26a, and the lock pins 26a can be moved in the radial direction. In addition to the case where the two lock pins 26a are integrally formed via the wire spring 26 as described above, they are installed independently of each other and a restoring spring is installed separately. The rotating body 23 may be provided with a structure in which an outward restoring force works. Further, the number of the lock pins 26a is not limited to two and may be one or more.

The two lock pins 26a projecting in the axial direction axially penetrate the hollow portion of the lock ring 27 shown in FIG. 3 and engage with the valley portions 27a of the inner peripheral surface. The lock ring 27 is an internal gear-shaped quadrangular plate having a continuous wave-shaped trough portion 27a and a ridge portion 27b, and its outer peripheral portion is fixed to a rectangular tubular casing 28 by means such as welding. . Since the lock pin 26a is always provided with a restoring force outward in the radial direction, when the input shaft 21 is stationary, the lock pin 26a is always caught in the trough 27a of the lock ring 27. In order to ensure this, it is advantageous that the peak portion 27b of the lock ring 27 has a chevron shape. Therefore, even if the output shaft 22 tries to rotate under the action of a load or an external force, the lock pin 26a is locked in the trough 27a and is strongly locked, so that the output shaft 22 cannot rotate in either forward or reverse directions.

The input shaft 21 and the output shaft 22 are installed in a casing 28 via a bearing bush 34, and the casing 28 is stopped by a fixing means (not shown) from rotating. The casing 28 of the present embodiment is formed in a rectangular tube shape for convenience of stopping the rotation of the rectangular lock ring 27. The pin receiving disk 24, the pin pressing disk 25, and the lock ring 27 described above are manufactured at low cost by press working.

On the other hand, at the inner end of the input shaft 21, a disc-shaped rotating disk 29 that rotates in the casing 28 is integrally provided. This rotary disk 29 is also manufactured at low cost by press working. As shown in FIG. 4, the rotary disc 29 is provided with two transmission holes 30 through which the lock pins 26a penetrating the lock ring 27 are inserted. The transmission hole 30 has a mountain shape having an isosceles triangle as a basic shape, and its bottom side 31 is an arc in the rotation direction of the rotating disk 29. The vertices 32a on the outer side in the radial direction and the vertices 32b, 32c on the bottom side are curved surface finishes having a radius that allows the lock pin 26a to be housed therein, and the two front and rear hypotenuses 33 are finished so that the lock pin 26a can slide smoothly. The radius from the rotation center of the apex 32 a on the radially outer side of the transmission hole 30 is the same as or slightly larger than the radius to the bottom of the valley 27 a of the lock ring 27. Further, the radii of the bottom side vertices 32b and 32c from the rotation center are formed to be the same as or slightly smaller than the radius of the crest portion 27b of the lock ring 27. Therefore, when the rotation of the input shaft 21 is stopped, the lock pin 26a is positioned at the apex 32a on the radially outer side of the transmission hole 30 of the rotating disk 29 by the action of the restoring force in the radially outward direction. That is, the lock ring 27 bites into the valley portion 27a.

On the other hand, when the input shaft 21 is rotated in either forward or reverse directions as shown by the arrow in FIG. 4, for example, a lock pin that is positioned at the apex 32a of the transmission hole 30 as the rotary disk 29 rotates. 26a slides along the hypotenuse 33 and moves to the rear bottom side vertex 32b or 32c. Such movement of the lock pin 26a is eventually a movement inward in the radial direction as indicated by the arrow shown in FIG. 3, and the lock pin 26a is released outside (inward) of the valley portion 27a of the lock ring 27 and released. To be done. The lock pin 26a is positioned inside the top of the mountain portion 27b and is in a rotatable state, and the rotation of the rotary disk 29 is transmitted to the output shaft 22 via the lock pin 26a and the pin pressing disc 25. In this way, the rotations of the input shaft 21 and the rotary disk 29 are transmitted to the output shaft 22 in the same direction in the same direction in the forward and reverse directions through the lock pin 26a.

A known speed reducing mechanism, for example, a planetary gear type speed reducing mechanism may be incorporated between the input shaft 21 and the rotary disk 29 to reduce the rotational load of the input shaft 21 to a fraction. Done. In short, although it is absolutely impossible for the output shaft 22 to rotate due to an external force or a load in both forward and reverse directions, the output shaft 22 can be freely rotated in both forward and reverse directions only by the input shaft 21.

Therefore, this rotation transmission device can be suitably used for applications in which the output shaft 22 does not freely rotate due to a load or the like, or applications in which the rotational position of the output shaft 22 must be reliably determined.

[0017]

[Effects of the present invention]

 The rotation transmitting device according to the present invention, which is capable of rotating the output shaft by the input shaft, is composed of easy-to-process parts such as pressing and bending, has a small number of parts, and is easy to assemble. In addition, the operation of the device is simplified, and even if it is used for a long period of time, it exhibits smooth rotational movement and reliability in performance.For example, rotary drive means for opening and closing skylights and side windows, and cargo handling machines such as hoists and chain blocks. It can be conveniently used for various purposes as a rotation drive means of.

[Brief description of drawings]

FIG. 1 is a sectional view of a rotation transmission device.

FIG. 2 is an exploded perspective view of a rotated body.

FIG. 3 is a front view of the lock ring corresponding to the line AA arrow of FIG.

FIG. 4 is a front view of a rotary disk corresponding to the line BB of FIG.

FIG. 5 is an exploded perspective view showing a conventional example.

FIG. 6 is a sectional view of a conventional example.

[Explanation of symbols]

 21 Input Shaft 22 Output Shaft 23 Rotating Body 26a Lock Pin 27 Lock Ring 27a Valley 28 Casing 29 Rotating Disc 30 Transmission Hole 31 Bottom

Claims (1)

[Scope of utility model registration request] 1. An output shaft and an input shaft are arranged such that their center lines coincide with each other, and a rotating body is provided at an inner end portion of the output shaft. A lock pin that exerts a force is provided on the rotating body, and an inner gear-shaped lock ring having a trough portion in which the lock pin that projects in the axial direction engages outward in the radial direction has an outer peripheral portion. Being fixed to the casing, a rotary disc is provided at the inner end of the input shaft, and the rotary disc has a hole into which the lock pin protruding in the axial direction penetrates the lock ring to enter. Are provided in the same number as the lock pins as substantially mountain-shaped transmission holes that are circular arcs in the rotation direction of the rotating disk, the rotated body and the rotating disk are assembled in the casing, and A rotation transmission device capable of rotating an output shaft by an input shaft, characterized in that rotation is stopped.