KR20120039424A - Power transmitting apparatus - Google Patents

Abstract

PURPOSE: A power transferring apparatus is provided to prevent the transferring of torque to an input side due to the reaction force caused reversely rotation of an output side after the transferring of power is stopped. CONSTITUTION: A power transferring apparatus includes a case(11), an output disk(13), an input disk(16), an input shaft(15), an elastic member(14), and a cover(17). A hollow part is formed in the case. The output disk is loaded in the hollow part, and a ridge(131) is formed at one side of the output disk. The input disk is arranged at the upper side of the output disk. The input shaft is expanded from the input disk. The elastic member is arranged between the input disk and the output disk. The cover is combined with the case and covers the input disk.

Description

Power transmitting apparatus

The present invention relates to a power transmission device.

The power transmission device transmits a rotational force generated by an electric motor or a user's attraction to an object.

The rotational force is provided in one direction, for example, clockwise or counterclockwise, and the subject makes a linear or rotational motion by the provided rotational force, while the subject moves in a reverse direction due to the reaction force generated from the object's own weight or other causes. There is an active research into the device to block the.

In other words, in a structure in which one end of the power transmission shaft is connected to a drive motor and the object is connected to the other end, the power transmission shaft rotates only in the rotational direction of the drive motor, and the power shaft is caused by reaction force generated from the object. Power units in the form of blocking reverse rotation are widely used in various fields. Examples thereof include a power transmission device used for opening and closing a cover of a vinyl house, a means for opening and closing a window, and the like.

However, the power transmission device widely used in the above fields is mainly applied worm gear, Geneva mechanism. Such a conventional mechanism requires a minimum rotation ratio and has a disadvantage in that the input shaft and the output shaft are hardly arranged on the same line.

In addition, although a mechanism using a ratchet mechanism using a friction force and a coil through ring is applied, there are disadvantages such as deterioration in reliability of operation and occurrence of backlash. That is, there is a disadvantage in that a deviation occurs between a setting position to stop the object and the actual stop position.

An object of the present invention is to provide a power transmission device that has improved the above disadvantages.

In detail, it is an object of the present invention to provide a power transmission device that stops the rotational force from being transmitted to the input side by rotating the output side by the reaction force generated by the weight or other cause of the object after the power transmission is stopped.

In addition, an object of the present invention is to provide a power transmission device to remove the phenomenon that the object is stopped after the reverse rotation by the backlash at the time when the power transmission is stopped, so that the object is stopped at the position at the time when the power transmission is stopped. do.

Power transmission device according to an embodiment of the present invention for achieving the above object, a case in which a hollow portion is formed therein; an output disk seated in the hollow portion, a ridge formed on one surface; and interlocked with the output disk An output disk penetrating the case; an input disk disposed on an upper side of the output disk; an input shaft extending from the input disk; positioned between the input disk and the output disk and provided in close contact with an inner circumferential surface of the case. An elastic member that prevents rotation of the disk; a cover coupled to the case to cover the input disk, and when a rotational force is applied to the input shaft, the input disk rotates together with one end of the elastic member, and the elastic member And frictional force between the case and the case, and when the rotational force acts on the output side, the ridge Wherein the elastic member to the one end parts of the pressure, characterized in that it acts to the friction force between the elastic member and the case increases.

By the power transmission device according to an embodiment of the present invention having the configuration described above, the number of parts is less than the conventional power transmission device, the production of the product by implementing the power transmission device using the case itself without having a separate case The cost can be reduced, the assembly process can be simplified, and the volume of the product can be reduced.

In addition, since the rotational force at the output side is not transmitted to the input side, it is possible to prevent the power transfer from the output side to the input side not intended by the user.

In addition, since the phenomenon in which the object is moved in the reverse direction by the reaction force caused by the object's own weight or other causes when the power transmission is stopped, there is an advantage that the safety is secured.

1 is a perspective view of a power transmission device according to an embodiment of the present invention.
2 is a rear perspective view of the power transmission device.
3 is an exploded perspective view of the power transmission device.
4 is a perspective view of an output disk according to an embodiment of the present invention.
5 is a rear perspective view of the output disk.
6 is a perspective view of an input disk according to an embodiment of the present invention.
7 is a rear perspective view of the input disk.
8 is a plan view of the power transmission device with the cover removed.
9 is an operational state diagram showing how the input disk rotates clockwise.
10 is an operating state diagram showing the state in which the input disk has stopped rotating.

Hereinafter, a power transmission apparatus according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a perspective view of a power transmission device according to an embodiment of the present invention, Figure 2 is a rear perspective view of the power transmission device, Figure 3 is an exploded perspective view of the power transmission device.

1 to 3, a power transmission device 10 according to an embodiment of the present invention includes a case 11, an output disk 13 rotatably provided inside the case 11, An input disk 16 rotatably seated on an upper surface of the output disk 13 and an input shaft 15 inserted into a through hole 164 of the input disk 16 to transmit rotational force to the input disk 16. And a cover 17 which is fastened to an upper surface of the case 11 and covers the output disk 13 and the input disk 16 and is inserted in a contracted state while contacting an inner circumferential surface of the case 11. And a member 14. A reduction gear 12 may be provided between the case 11 and the output disk 13 to reduce the rotation of the output disk 13.

In detail, the case 11 is a cylindrical shape having a hollow portion formed therein, an upper portion thereof is opened, and a through hole through which the transmission shaft 115 penetrates is formed in the bottom surface thereof. On the lower surface of the case 11, the bottom 111 is rotatably seated. Since the bottom part 111 is not formed integrally with the case 11 and is provided separately, the bottom part 111 may be rotated in the case 11 separately from the case 11. A gear shaft 114 to which the reduction gear 12 is coupled protrudes from one surface of the bottom 111. The other surface of the bottom 111 is provided with a transmission shaft 115 that can transmit the rotational force to the object. The transmission shaft 115 may also be referred to as an output shaft. The transmission shaft 115 penetrates the through hole of the lower surface of the case 11 and is exposed to the outside of the case 11.

The reduction gear 12 is correspondingly coupled to the gear shaft 114. In this embodiment, three reduction gears 12 have been shown to be coupled, but are not limited thereto.

A rack 113 is formed on the inner circumferential surface of the cylindrical portion 112 so that the reduction gear 12 and the rack 113 are engaged with each other. A handle 117 extends to a predetermined length on one side of the outer circumferential surface of the cylindrical portion 112. A fastening flange 116 protrudes from an upper end of the cylindrical portion 112, and a fastening flange 172 of the cover 18. Combined with.

The output disk 13 is seated on the reduction gear 12. One side of the upper surface of the output disk 13 may be provided with a bulge 131 for pressing the elastic member 14 when a rotational force is applied to the transmission shaft 115. A boss 134 into which the lower boss 163 of the input disk 16 is inserted may be provided at the center of the upper surface of the output disk 13. In addition, a guide part 132 may be provided at one side of the upper surface of the output disk 13 to prevent the elastic member 14 from being separated. A lower portion of the output disk 13 is provided with an output shaft 135 which rotates in engagement with the reduction gear 12.

An elastic member 14 is positioned in the case 11. The elastic member 14 may be positioned above the output disk 13 while contacting the inner circumferential surface of the case 11. The elastic member 14 has bent portions 141 that are bent inwardly of the elastic member 14 at both ends. The bent portion 141 may be pressed by the ridge 131 or the arm 161. The elastic member 14 is provided in the case 11 in a state in which the diameter is reduced from a normal state, that is, in a state having elastic restoring force in a direction in which the diameter is to be enlarged. For example, when the elastic member 14 is a circular spring, the diameter of the spring is reduced and inserted into the case 11 than the diameter when no external force is applied to the spring. Accordingly, the spring has an elastic restoring force in a direction pushing the inner circumferential surface of the case 11. Due to the restoring force, a strong friction force exists between the spring and the inner circumferential surface of the case 11, so that the spring is fixed in the case 11. The number of times the spring is wound is irrelevant, but the diameter in the normal state of the spring is larger than the diameter of the case 11, and is fully inserted into the case 11 with the diameter of the spring being reduced.

Hereinafter, as an embodiment according to the present invention will be described a case in which the elastic member 14 is a circular spring with both ends separated. However, the elastic member 14 is not limited to the circular spring can be any shape, such as a spring wound multiple times in the spiral form.

The input disk 16 is seated on the output disk 13. A boss protrudes from the center of the input disk 16, and the boss includes an upper boss 162 extending from an upper surface of the input disk 16, and a lower boss 163 extending from a bottom surface thereof. The input shaft 15 is inserted through the lower boss 163 toward the upper boss 172.

In addition, the input disk 16 is formed with an arm 161 that can press the bent portion 141 of the elastic member (14). The arm 161 presses the bent portion 141 in a direction opposite to the direction in which the ridge 131 presses the bent portion 141. As shown in FIG. 3, when the elastic member 14 is a circular spring, the bent portion 141 is disposed to be located at both side surfaces of the ridge 131. In this case, as the gap between the bent portion 141 and the ridge 131 is smaller, the transmission shaft 115 can be prevented from being missed by the rotational force applied to the output shaft 135. When the ridge 131 presses the bent portion 141 as the output disk 13 rotates, a force is applied in a direction in which the diameter of the spring increases. Even if the ridge 131 presses the bent portion 141, the ridge 131 stops in place because the diameter of the spring can no longer be increased by the inner circumferential surface of the case 11. In other words. The rotational force provided to the output disk 13 cannot be transmitted to the input disk 16.

In addition, the arms 161 may be positioned at both inner sides of the bent portion 141 at predetermined intervals. When the arm 161 is applied with a rotational force to the input disk 16, the arm 161 moves without any resistance at a predetermined interval, and then comes into contact with the bent portion 141. If the rotation force is continuously applied after contacting the bent portion 141, the arm 161 presses the bent portion 141. At this time, since the arm 161 presses the bent portion 141 in a direction in which the diameter of the spring decreases, the friction force between the spring and the inner circumferential surface of the case 11 is reduced. Therefore, when a rotational force is continuously applied to the arm 161, the arm 161 may rotate in the case 11 together with the spring and the ridge 131 while pressing the bent portion 141. have.

The lower boss 163 of the input disk 16 is seated so that the rotation center coincides with the boss 134 of the output disk 13.

The upper boss 162 of the input disk 16 passes through the through hole 171 formed in the cover 17 and is exposed to the outside of the cover 17. The upper boss 162 of the input disk 16 is formed with a through hole 162 into which the input shaft 15 is inserted. The input shaft 15 is inserted into the upper boss 162 from the lower boss 163. The input shaft 15 passes through the through hole 162 of the input disk 16 so that the upper end is exposed to the outside of the upper boss 162, and the lever 18 is coupled to the exposed one end.

The cover 17 is seated on the input disk 16. The cover 17 has a through hole 171 formed at a position corresponding to the upper boss 162. A fastening flange 172 protrudes from an edge of the cover 17 along an outer circumferential surface of the cover 17, and the fastening flange 172 is in close contact with the fastening flange 116 of the case 11, and a screw The cover 17 is fixed to the case 17 by a fastening member such as.

The lever 18 is connected to the upper end of the input shaft 15. A through hole 182 is formed at one end of the lever 18 to allow the input shaft 15 to penetrate. In addition, the washer and nut member are fitted to the upper end of the input shaft 15 so that the lever 18 is not separated from the input shaft 15. A handle 181 is provided at the other end of the lever 18 so that a user can hold the handle 181 and rotate the lever 18 clockwise or counterclockwise.

4 is a perspective view of an output disk according to an embodiment of the present invention, Figure 5 is a rear perspective view of the output disk.

Referring to FIG. 4, a boss 134 is formed on an upper surface of the output disk 13 so that an inner surface of the boss 134 and an outer surface of the lower boss 163 of the input disk 16 contact each other. An input disk 16 may be seated on the output disk 13. Also

In addition, at least one guide portion 132 is formed on the upper surface of the output disk 13, so that the elastic member 14 is pressed out of the position of the elastic member 14 on the output disk 13 or the elastic member The phenomenon such as 14 being deformed is prevented. For example, when the elastic member 14 is a circular spring, the guide portion 132 is provided at a predetermined distance from the inner peripheral surface of the spring. When the bent portion 141 of the spring is pressed by the arm 161 of the input disk 16, the spring is contracted. As the spring contracts, the diameter of the spring is smaller than the inner diameter of the case 11 so that the spring can move, and since the spring is contracted by a force in one direction, the spring may be twisted or deformed. have. The guide part 132 may prevent the above phenomenon from occurring, and may prevent a phenomenon such as detachment or deformation even when the spring is contracted.

Referring to FIG. 5, an output shaft 135 is provided on a lower surface of the output disk 13 to rotate in engagement with the reduction gear 12.

6 is a perspective view of an input disk according to an embodiment of the present invention, Figure 7 is a rear perspective view of the input disk.

Referring to FIG. 6, an arm 161 is formed on the input disk 16 to press the bent portion 141 of the elastic member 14. The arms 161 are respectively positioned at both sides of the bent portion 141 so that the bent portion 141 can be pressed when the input shaft 15 is rotated clockwise or counterclockwise. Therefore, the arm 161 may be two or more. A predetermined interval is formed between the arm 161 and the bent portion 141, so that even if the user rotates the input shaft 15, the rotation force is not transmitted to the output disk 13 at a predetermined interval so that the transmission is performed. The axis 115 does not rotate.

The upper boss 162 formed on the upper surface of the input disk 16 may be exposed to the outside through the through hole 164 of the cover 17 seated on the input disk 16.

Referring to FIG. 7, the lower boss 162 formed on the lower surface of the input disk 16 is inserted into the boss 134 of the output disk 13.

An input shaft 15 may be inserted into the through hole 164 formed through the upper boss 162 from the lower boss 162. The opening of the lower boss 162 in which the head 151 of the input shaft 15 is located may be formed in a polygon or other shape according to the shape of the head 152. The body 152 of the input shaft 15 passes through the through hole 164 and one end thereof is exposed to the outside of the upper boss 162 to be coupled to the through hole 182 of the lever 18.

Hereinafter, the operation of the power transmission device according to the present invention will be described.

FIG. 8 is a plan view of the power transmission device with the cover removed, and FIG. 9 is an operating state diagram showing the state in which the input disk rotates clockwise, and FIG. 10 is a state in which the input disk has stopped rotating. It is a working state diagram showing.

Referring to FIG. 8, the position of the bulge 131, the arm 161, and the bent portion 141 of the elastic member 14 when the power transmission device does not receive force from the outside is shown. The elastic member 14 has a diameter larger than the inner diameter of the case 11, and is inserted into the case 11 while the elastic restoring force is accumulated while the diameter is reduced. Therefore, the elastic restoring force F of the elastic member 14 acts as a friction force between the elastic member 14 and the inner wall of the case 11. The ridge 131 is positioned between both bent portions 141 of the elastic member 14, and is located in a direction in which the diameter of the elastic member 14 increases when the bent portion 141 is pressed by rotation. . The arm 161 is positioned at a predetermined distance (A) from the bent portion 141, and is located in a direction in which the diameter of the elastic member 14 decreases when the arm 161 is pressed by rotation. . In the state that no external force is applied, the elastic member 14 may be fixed so that the input disk 16 or the output disk 13 does not rotate by friction with the inner wall of the case 11.

Referring to FIG. 9, the input shaft 15 is rotated along with the input shaft 15 when the input shaft 15 receives a clockwise rotational force. When the input disk 16 rotates in the clockwise direction, the arm 161 on the input disk 16 moves as much as A without transmitting rotational force to the transmission shaft 115. If the arm 161 continues to receive the rotational force even after contacting the bent portion 141 of the elastic member 14, the elastic member 14 is subjected to a force in a direction of decreasing diameter, the case ( 11) friction between the inner wall and the elastic member 14 is reduced. As the frictional force between the inner wall of the case 11 and the elastic member 14 decreases, the elastic member 14 is continuously pushed in the direction in which the force is applied, and the ridges contacting the catching part 141 ( 131 is rotated together. That is, the arm 161 rotates together with the locking portion 141 and the ridge 131. Accordingly, as the ridge 131 rotates, the output disk 13 rotates, and the output shaft 135 below the output disk 13 rotates to rotate the reduction gear 12. As the reduction gear 12 rotates, the bottom portion 111 of the case 11 having the gear shaft 114 to which the reduction gear 12 is coupled rotates, so that the bottom portion 111 is coupled to the bottom portion 111. The transmission shaft 115 is rotated. As a result, the rotational force applied to the input shaft 15 is transmitted to the transmission shaft 115. The input shaft 15 is similar to the above in the case of receiving a counterclockwise rotational force.

Referring to FIG. 10, the counterclockwise rotational force transmitted from the transmission shaft 115 is transmitted to the output disk 13 through the reduction gear 12 and the output shaft 135. When the output disk 13 receives a rotational force, the ridge 131 provided on the upper surface of the output disk 13 rotates in a counterclockwise direction and comes into contact with the bent portion 141 of the elastic member 14. . If the ridge 131 continues to receive the rotational force even after contacting the bent portion 141, the elastic member 14 receives a force in a direction in which the diameter increases. Therefore, since the frictional force between the elastic member 14 and the inner wall of the case 11 is further increased, the elastic member 14 is fixed in place and transmits rotational force to the adjacent arm 161. I never do that. That is, the arm 161 is not affected by the force that the bulge 131 presses the bent portion 141 with a predetermined distance from the bent portion 141. As a result, the rotational force applied from the transmission shaft 115 is not transmitted to the input disk 16. The case where the ridge 131 rotates clockwise is similar to the above.

Claims (16)

A case in which a hollow part is formed therein;
An output disk seated in the hollow portion and having a raised portion formed on one surface thereof;
An output shaft interworking with the output disk and penetrating the case;
An input disk placed above the output disk;
An input shaft extending from the input disk;
An elastic member positioned between the input disk and the output disk and provided in close contact with an inner circumferential surface of the case to prevent rotation of the output disk;
A cover coupled to the case and covering the input disk;
When a rotational force acts on the input shaft, the input disk rotates together with one end of the elastic member, so that the friction force between the elastic member and the case is reduced,
When the rotational force is applied to the output shaft, the bulge is pressed to one end of the elastic member, the power transmission device, characterized in that to act to increase the friction force between the elastic member and the case. The method of claim 1,
The friction force between the elastic member and the case is reduced while the diameter of the elastic member is reduced by the rotation of the input disk. The method of claim 1,
When a rotational force acts on the output shaft, the ridge presses the elastic member in a direction in which the diameter of the elastic member increases.
And a frictional force between the elastic member and the case is increased to suppress rotation of the output disk. The method of claim 1,
The elastic member is a power transmission device comprising a spring wound in a plurality of times in the form of a spiral spring or spiral with both ends separated. The method of claim 4, wherein
Both ends of the elastic member is formed with bent portions that are bent inwardly,
And when the input disc rotates, any one of the bent portions is caught by the input disc and rotates together. The method of claim 4, wherein
And when the output disk rotates, the ridge presses the bent portion to transmit a force in a direction in which the diameter of the elastic member increases. The method of claim 4, wherein
The elastic member has a diameter larger than the diameter of the case,
The diameter is reduced and inserted into the case in a state in which elastic restoring force is accumulated,
The elastic restoring force of the elastic member is a power transmission device, characterized in that acting as a frictional force on the inner peripheral surface of the case and the contact surface of the elastic member. The method of claim 1,
An output shaft provided at the center of the bottom surface of the output disk;
A plurality of reduction gears engaged with the output shaft,
A bottom portion provided on the bottom of the case for supporting the plurality of reduction gear,
The output shaft is coupled to the bottom of the bottom portion, the power transmission device, characterized in that to rotate in one body with the bottom portion. The method of claim 8,
The inner peripheral surface of the case is a power transmission device characterized in that the rack is engaged with the reduction gear. The method of claim 1,
The upper surface of the output disk is a power transmission device characterized in that the guide portion is formed to prevent the deformation and separation of the elastic member. The method of claim 1,
A boss is formed on a bottom surface of the output disk, and a lower boss provided on the bottom surface of the input disk is inserted. The method of claim 1,
An upper boss is formed on the upper surface of the input disk and is exposed to the outside through the through hole formed in the cover.
A through hole is formed through the upper boss from the lower boss, and the input shaft is inserted therein.
One end of the input shaft is exposed to the outside of the upper boss upper power transmission device. The method of claim 12,
A power transmission device, characterized in that the lever is coupled to one end of the input shaft. The method of claim 13,
A washer is inserted into an upper end of the input shaft such that the lever does not fall from the input shaft. The method of claim 1,
The fastening flange is formed on the upper end of the cylindrical portion of the case,
The fastening flange is in close contact with the fastening flange formed on the outer peripheral surface edge of the cover power transmission device, characterized in that coupled by a fastening member. A cylindrical case having at least one side open;
An output disk rotatably received in the case and having a ridge formed on one surface thereof;
An output shaft connected to the output disk and rotating with the output disk;
An elastic member seated inside the case in a contracted state and having a bent portion formed at least at one end thereof to be in contact with the ridge;
An input disk rotatably seated on the output disk and having an arm formed to press the bent portion according to a rotation operation to reduce friction between the elastic member and the inner circumferential surface of the case;
A cover covering the input disk and fixedly coupled to the case; And
And an input shaft penetrating the cover to the input disk to rotate with the input disk.
When a rotational force is applied to the output disk, the ridge prevents the rotation of the output disk by pressing the bent portion to increase the friction force between the elastic member and the inner peripheral surface of the case,
And when the rotational force is applied to the input disk, the output disk rotates by causing the arm to pull the bent portion so that the frictional force between the elastic member and the inner wall of the case is reduced.

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