TW202041960A - A speed reduction device and wire winding device using the same - Google Patents

Abstract

A speed reduction mechanism comprises a housing, a moving element, a rotating element and a damper. The moving element is movably arranged in spiral rail formed on first surface of the housing. The rotating element roatably coupled to the housing has an actuating element formed on second surface opposite to the first surface. The actuating element is abutted against the moving element for driving the moving element to move along the spiral rail when the rotating element is rotated. The damper selectively arranged at the rotating element is corresponding to speed reduction segment of the spiral rail. When the moving element enters the speed reduction segment, a friction force is generated between the damper and the moving element for reducing speed of rotating element. In one embodiment, the speed reduction mechanism is utilized to form a wire winding device for reducing the winding speed when the wire is reversely retracted.

Description

Speed reduction mechanism and its winding device

The present invention is a technology for winding and drawing wire, in particular to a speed reduction mechanism and a wire winding device with wire winding speed control.

Please refer to Figure 1, which is a schematic diagram of the relationship between video output and input in a conventional conference room. In conventional technologies, taking the conference room 13 as an example, there are generally multimedia output devices, such as projectors or flat-panel displays, and multimedia input devices, such as computers, DVD players, or portable computers. In this application scenario, the signal input terminal of the projector 11 in FIG. 1 will use a signal wire as a connection medium to facilitate the connection with the user's portable computer. However, since users in different locations in the conference room can connect to the signal cables, long signal cables must be used.

In Figure 1, one end of the signal cable 12 is connected to the projector 11, and the other end extends through the ceiling to the ground. The user connects the signal connector on the other end of the signal cable on the ground to the portable computer, making it possible to The multimedia signal of the portable computer can be output to the projector via the signal wire 12 to project a picture. In the situation of Figure 1, due to the long signal wire, the ground wire is often messy, and sometimes it may even kick the wire accidentally. Of course, the usage scenario of FIG. 1 is not limited to when the projector device is on the ceiling. In other scenarios, such as when the projector is placed on a table or a flat-panel display is fixed on a wall, the same problems may also occur.

In order to solve the above-mentioned problems, in the conventional technology, the manufacturer of the audio and video signal cable part of the conference room will make an automatic winding device, and set it on the conference table for users to use. In this way, the user can pull one end of the signal wire from the conference table and connect it to the computer. Although this method can solve the aforementioned problem of messy ground wires and sometimes even kicking wires accidentally, another problem arises.

For example, after the user has finished using it, in order to recover the wire smoothly, most of this type of wire winding device will increase the force of winding the wire. Although this can ensure that the wire is recycled into the reeling device, but when the signal wire is recycled, when the end of the wire is closer to the reeling device, if you are not careful, it is easy to cause the user to be hit by the end of the signal wire, or because of the recycling speed If it is too fast, one end of the wire will hit the winding device and generate a loud noise, which will startle the user.

For this reason, in view of the lack of conventional technology, a deceleration mechanism and its winding device are proposed to improve the lack of conventional methods.

The present invention provides a deceleration mechanism. During the rotation, when the rotation reaches a specific area, through the setting of damping, friction force against rotation is generated, thereby reducing the rotation speed. The area of the damping setting can be determined according to the needs of the user to control the location of the deceleration and the length of the deceleration time.

The invention provides a wire winding mechanism. Through the setting of the deceleration mechanism, the winding speed of the wire can be controlled during the winding process, especially when the wire is recycled to a specific stage, the winding speed of the wire is reduced, so as to prevent the user from being accidentally caught by the wire. Hit one end, or to avoid the sound problem caused by the impact during or after the recovery of the wire.

In one embodiment, the present invention provides a speed reduction mechanism, which includes a housing, a moving part, a rotating part, and a damping part. The shell has a first surface, and the first surface is provided with a spiral track. The moving part is movably arranged on the spiral track. The rotating member is rotatably connected to the housing, the rotating member has a second surface opposite to the first surface, the rotating member includes an actuating portion, and the actuating portion is disposed on the second surface and can Abutting with the moving part, when the rotating part rotates relative to the housing, the actuating part drives the moving part to move in the spiral track. The damping part is selectively arranged on the rotating part and corresponds to a deceleration section of the spiral track, wherein when the moving part enters the deceleration section, the damping part presses the moving part to reduce the rotation The rotational speed of the piece relative to the housing.

In one embodiment, the present invention provides a wire winding device including a signal wire and a speed reduction mechanism. The deceleration mechanism includes a housing, a moving part, a winding shaft and a damping part. The shell has a first surface, and the first surface is provided with a spiral track. The moving part is movably arranged on the spiral track. The spool body is rotatably connected to the housing, the spool body has a second surface opposite to the first surface, the spool body includes an actuating portion that is disposed on the second surface, and It can abut with the moving part. When the spool body rotates relative to the casing, the actuating part drives the moving part to move in the spiral track, and the spool body is wound with the signal wire. The damping part is selectively arranged on the bobbin and corresponds to a deceleration section of the spiral track. When the moving part enters the deceleration section, the damping part presses the moving part to lower the The rotation speed of the spool body relative to the housing.

Hereinafter, various exemplary embodiments may be more fully described with reference to the accompanying drawings, and some exemplary embodiments are shown in the accompanying drawings. However, the inventive concept may be embodied in many different forms and should not be construed as being limited to the exemplary embodiments set forth herein. To be precise, the provision of these exemplary embodiments will make the present invention detailed and complete, and will fully convey the scope of the concept of the present invention to those skilled in the art. Similar numbers always indicate similar components. The speed reduction mechanism and its winding device will be described below with various embodiments in conjunction with the drawings. However, the following embodiments are not intended to limit the present invention.

Please refer to FIG. 2, which is an exploded schematic diagram of the speed reduction mechanism of the present invention. In this embodiment, the speed reduction mechanism 2 includes a housing 20, a moving part 21, a rotating part 22 and a damping part 23. The housing 20 has a first surface 200 on which a spiral track 24 is provided. The movable member 21 is arranged in the spiral track 24 and can roll along the spiral track 24. In this embodiment, the moving element 21 is a sphere, and its material is not particularly limited. The ball 21 in this embodiment is a ball made of steel. There is at least one opening 240 on the spiral track 24. In this embodiment, the opening 240 is a partial segment corresponding to the circumferential direction of the spiral track 24 to form a slot-shaped opening and penetrate the housing 20. The section of the opening 240 in the spiral track 24 serves as a deceleration section of the moving part in the spiral track 24. In this embodiment, the number of openings 240 is 4, but this number is not limited. The parameters such as the number, the opening position, and the length are determined according to the degree of deceleration of the moving member 21, such as time and speed.

The housing 20 has a rotating shaft 201 in the center. The rotating member 22 is rotatably coupled with the rotating shaft 201, so that the rotating member 22 can rotate the rotating shaft 201. In this embodiment, the rotating shaft 201 has a disc structure, but this shape is not limited, and the user can design the shape of the rotating member 22 according to requirements. Please refer to FIG. 2 and FIG. 3A at the same time. FIG. 3A is a schematic diagram of an embodiment of the rotating member of the present invention. The rotating member 22 has a second surface 220 opposite to the first surface 200. The rotating member 22 has a shaft hole 221 in the center of the rotating member 22 for pivoting with the rotating shaft 201 so that the rotating member 22 rotates with the rotating shaft 201 as the axis. The rotating member 22 further includes an actuating portion 25, the actuating portion 25 is disposed on the second surface 220 and abuts against the actuating member 21, so that the actuating member 21 is restrained in the actuating portion 25. In this embodiment, the actuating portion 25 has a groove structure, and a part of the moving element 21 is accommodated in the groove. When the rotating element 22 rotates, the edge of the groove abuts against the moving element 21. When the rotating member 22 rotates relative to the housing 20, the actuating portion 25 drives the moving member 21 to move in the spiral track 24. It should be noted that, in another embodiment, the groove structure of the actuating portion 25 can also penetrate the housing 20. In another embodiment, as shown in FIG. 3B, the actuating portion 25a is composed of a pair of parallel convex portions, and a part of the moving member 21 is located between the parallel convex portions. During the rotating movement, one of the A convex part abuts on the moving part 21.

Returning to FIGS. 2 and 3A, the damping portion 23 is selectively disposed at a specific position of the rotating member 22. The specific position in this embodiment is that the rotating member 22 can correspond to at least one deceleration zone of the spiral track 22 when the rotating member 22 rotates. segment. When the moving part 21 enters one of the deceleration sections, the damping part 23 presses against the moving part 21 to reduce the rotation speed of the rotating part 22 relative to the housing 20. In this embodiment, the damping portion 23 has a cantilever 231 along the circumferential direction of the rotating member 22. There is a resistance elastic pad 232 at the end of the damping part 23, which can choose a material with a high friction coefficient, so that when the movable member 21 moves to a position corresponding to the resistance elastic pad 232, it contacts with the resistance elastic pad 232 and penetrates the movable member 21. The friction force between 21 and the resistance elastic pad 232 reduces the rolling speed of the movable member 21. It should be noted that the purpose of the cantilever 232 is to prevent the movable member 21 from getting stuck in the deceleration section due to insufficient clearance. The upward swing of the cantilever 232 provides space for the movable member 21 to roll, so that the movable member 21 In the deceleration section, it can decelerate while maintaining the state of motion. In addition, the damping portion 23 is not limited to be arranged in the circumferential direction. For example, in another embodiment, as shown in FIG. 3C, the damping portion 23a has a cantilever 231a along the radial direction of the rotating member 22.

Please refer to FIG. 2 and FIG. 4A at the same time, a lifting structure 26 is further provided on the other side of the housing 20 relative to the rotating member 22. In this embodiment, the lifting structure 26 is a plate-shaped structure and is disposed on the third surface 202 of the housing 20. The third surface 202 and the first surface 200 correspond to each other and are located on both sides of the housing. The lifting structure 26 has a fourth surface 260 corresponding to the third surface 202, and there is at least one protrusion 261 thereon, the number of which is not limited, and can be designed according to the number 240 of openings of the spiral track 24. Each protrusion 261 corresponds to and penetrates through the spiral track 24 as the opening 240 of the deceleration section. The lifting structure 26 has an action surface 262 on one side corresponding to the fourth surface 260, on which there is at least one first actuation structure 263, the number of which is not limited and can be determined according to design requirements. The first braking structure 263 protrudes from the acting surface 262 and has an inclined surface 264. By pushing the first actuation structure 263, the lifting structure 26 can perform an ascending movement or a descending movement at the opposite opening 240. In addition, in one embodiment, there is an elastic restoring element S between the fourth surface 260 of the lifting structure 26 and the third surface 202 of the housing 20. In this embodiment, a spring is used to generate the thrust required for the descending movement. It should be noted that the elastic recovery element S is not an essential element. In the embodiment without the elastic recovery element S, the descending movement of the lifting structure 26 can be implemented by gravity.

The deceleration mechanism 2 further includes a driving structure 27 connected to the lifting mechanism 26 and moving between the first state and the second state to drive the lifting structure 26 to perform ascending or descending motion. When the driving mechanism 27 moves from the first state to the second state, the driving mechanism 27 pushes the first actuating structure 263 to control the protrusion 261 to protrude from the opening 240. When the moving member 21 moves to the corresponding protrusion in the spiral track 22 In the deceleration area where the portion 261 protrudes, the movable member 21 is pushed by the protruding portion 261 and abuts against the damping portion 23, thereby reducing the rotational speed of the rotational motion. When the driving mechanism 27 returns to the first state, the protrusion portion 261 returns to the original position, so that the movable member 21 is released from the state of abutting against the damping portion 23.

As shown in FIGS. 2 and 4A-4B, in this embodiment, the driving structure 27 includes a pushing element 270 and a guide rod 271. The pushing element 270 is arranged on the outer side of the action surface 262 so that the lifting mechanism 26 is located between the housing 20 and the pushing element 270. The pushing element 270 includes a second actuating structure 272, an extension portion 273, and a buckle structure 274. The actuation structure 272 is arranged corresponding to the first actuation structure 263 and abuts against each other. In this embodiment, the second actuating structure 272 has a slope 275 protruding from the surface of the pushing element 270 corresponding to the acting surface 262 and abuts against the slope 264 of the first actuating structure 263.

The extension portion 273 protrudes from one end of the pushing element 270 toward the slot 204 of the first surface 200 of the housing 20, and the buckle structure 274 is connected to the end portion of the extension portion 273 protruding from the first surface 200. The guide rod 271 is received in the guide groove 205 on the first surface 200 of the housing 20, and one end of the guide rod 271 is connected to the buckle structure 274. In this embodiment, the first end of the guide rod 271 is provided with a through hole 276 penetrating the body of the guide rod 271, and a buckle structure 274 is provided to pass through and be clamped with the guide rod 271. The second end of the guide rod 271 is provided with a second combination part 277 for connecting with the pressing element 28. In this embodiment, the second combination part 277 is an opening. In this embodiment, a support body 206 protrudes from the first surface 200 of the housing 20, and the pressing element 28 has a pressing body 283, and a groove 280 is opened therein. The pressing element 28 is disposed on the first surface 200, wherein the support body 206 is accommodated in the groove body 280. In addition, an elastic restoring element 281 is arranged in the groove body 280. In this embodiment, it is a spring, one end of which abuts against the support body 206, and the other end abuts against the wall surface of the groove body 280. There is a first combination portion 282 on the end of the pressing element 28, which is a convex body in this embodiment, and is combined with the second combination portion 277 on the guide rod 271.

The aforementioned deceleration mechanism can be used in various application scenarios requiring deceleration. For example, please refer to FIG. 5, which is an exploded schematic diagram of an embodiment of the winding device of the present invention. In this embodiment, in addition to the decelerating mechanism 2 of FIG. 2, the winding device 3 further includes a winding shaft 30 on which a signal wire 90 is wound, such as: video and audio signal wire, network signal wire, or power signal wire Etc., but not limited by this. The bobbin body 30 is connected to the rotating member 22. A winding spring (not shown in the figure) is provided between the rotating member 22 and the rotating shaft 201 on the housing 20, such as a spiral spring, which is used when the rotating member 22 performs the first rotation direction. Turning clockwise is to accumulate the opposite second direction of rotation. In this embodiment, turning clockwise is the power required for turning. The spring used for winding is a well-known element to those skilled in the art, and will not be repeated here. It should be noted that although the spool body 30 and the rotating member 22 in this embodiment are two separate components, in another embodiment, the spool body 30 and the rotating member 22 can also be implemented in an integral manner. .

As shown in FIG. 6, it is a schematic cross-sectional view of an embodiment of the bobbin body of the present invention. The spool body 30 is connected to the rotating member 22 through a fixing element 300, such as a screw. The bobbin body 30 has a first bobbin 301 and a second bobbin 302, the first bobbin 301 has a first diameter D1, the second bobbin has a second diameter D2, the first diameter D1 is smaller than the second diameter D2. In this embodiment, part of the signal wire 90 is wound on the first bobbin 301, and the other part is wound on the second bobbin 302. The first end of the signal wire 90 is discharged through the second bobbin 302 , And the second end goes out through the first winding 301 axis. The first and second ends respectively have signal connection interfaces, where the signal connection interface of the first end is connected to the device side, such as computers, multimedia players, etc., and the signal connection interface of the second end is connected to the fixed desk, On the electrical connection seat of the wall or floor.

Refer again to FIGS. 5 and 7, where FIG. 7 is a perspective view of the first embodiment of the swing arm of the present invention. The winding device 3 further has a first swing arm 31 and a stopper 32. The first swing arm 31 is rotatably connected to the housing 20. In this embodiment, the first swing arm 31 passes through the shaft hole 310 and the housing 20. The upper shaft seat 207 is coupled together, and there is a spring that can generate accumulated elastic force between the first swing arm 31 and the shaft seat 207, such as a torsion spring or a coil spring, so that the first swing arm 31 is forced to swing at one end At the time, the elastic force can be accumulated, and when the force disappears, the reverse swing power is generated. The first swing arm 31 has a first end and a second end, wherein the first end is coupled to the guide rod 271, and the second end is connected to the stopper 32. In this embodiment, a pair of clamping plates 312 and 313 are provided on the first end, and a clamping slot 311 is provided on the clamping plate. The end of the guide rod 271 has a convex part 278, and the end of the guide rod 271 is embedded between the clamping plates 312 and 313, so that the convex part 278 is combined with the clamping groove 311 on the clamping plate to produce a fixing effect. The action effect of the first swing arm 31 will be described later.

Please refer to FIG. 5 and FIG. 8. FIG. 8 is a perspective view of a second embodiment of the swing arm of the present invention. The winding device 3 further has a second swing arm 33 rotatably and pivotally connected to the housing 20. In this embodiment, the second swing arm 33 has a shaft hole 330 to couple with the shaft seat 208 on the housing 20, and there is a spring between the second swing arm 33 and the shaft seat 208 that can generate accumulated elastic force, such as torsion force. The spring or the coil spring makes the second swing arm 33 accumulate elastic force when it swings under a force at one end, and when the force disappears, a reverse swing power is generated. Both ends of the second swing arm 33 respectively have a braking end 331 and a release end 332. The braking end 331 abuts against the positioning body 284 of the pressing element 28 after the pressing element 28 is pressed by force to position the pressing element 28 in the pressing status. The release end 332 is after the signal wire is recovered, the signal connection interface of the signal wire abuts on the release portion 332, causing the second swing arm 33 to rotate counterclockwise to release the braking end 331 from the positioning body 284, so that the pressing element 28 is restored Bit.

Next, the operation mode of the speed reduction mechanism of the present invention will be explained. Take the wire winding device as an example. As shown in FIGS. 9A and 9B, the wire winding device 3 is set on a conference table, and the signal wire 90 has signal connection interfaces 900 and 901. In this embodiment, the signal connection interfaces 900 and 901 It is an HDMI connector, but not limited by this. In FIG. 9A, the signal connection interface 901 is electrically connected to the fixed signal connector 91 on the conference table. For example, 901 is a male HDMI interface, and the fixed signal connector 91 is a female HDMI interface. In addition, it should be noted that the fixed signal connector 91 is not necessarily set on the conference table, for example, it can also be set on the floor or the wall, depending on the requirements of use. When the user wants to use the signal cable 90, as shown in the notebook computer 92 in Figure 9B as an example, the user stretches the signal connection interface 900 of the signal cable and connects the signal connection interface 900 to the HDMI interface of the notebook computer on. Of course, the application of the deceleration mechanism of the present invention is not limited to this, and it can be applied to a winding device in any venue.

Please refer to FIGS. 10A to 10E. When the signal connection interface 900 of the signal wire 90 has not been pulled out from the housing 20, the position of the movable member 21 is as shown in FIG. 10A. At this time, the lifting structure 26 is protruding The portion 261 has not yet protruded from the opening 240 of the spiral track 24. When the user pulls the signal connection interface 900 out of the housing 20, because the signal connection interface 901 has been connected to the fixed signal connector 91, the spool body 30 will start to rotate when the signal wire 90 is stretched. The rotating member 22 is driven to rotate, and in this embodiment, it rotates counterclockwise. After the rotating member 22 starts to rotate, the actuating portion 25 on the rotating member 22 will drive the rotating member 21 to follow the rotation, and the state shown in FIG. 10B is shown. It should be noted that during the stretching process, because the protrusion 261 does not protrude from the spiral track 24, when the mover 21 moves on the deceleration area (the area with the protrusion 261 on the spiral track 24), it will not be affected. The protruding part 261 pushes up and generates frictional resistance with the damping part 23, so that it can move smoothly. When the signal wire 90 is stretched to the position, the bobbin body 30 does not continue to rotate, and the moving member 21 stops moving, and assumes the state shown in FIG. 10C.

In addition, since the spool body 30 accumulates elastic force as the reverse rotation energy required for the winding during the stretching and rotation of the signal wire 90, it passes through the stopper 32 of the first swing arm 31 inside the housing 20 Leaning against the signal wire 90 can generate resistance on the signal wire 90. During the stretching process of the signal wire 90 or when it is stretched to position, the signal wire 90 is prevented from being reversed due to the elastic restoring force accumulated by the winding shaft body 30. Rotate to pull the signal wire 90 pulled out. It should be noted that although the stopper 32 on the first swing arm 31 will abut the signal wire 90, the signal wire 90 is pulled by the outward pulling force P when the signal wire 90 is stretched. In this case, the outward pulling force pushes the first swing arm 31 to rotate counterclockwise, so that the first swing arm 31 separates from the signal wire 90. Once the signal wire 90 stops pulling or is pulled to the position, the first swing arm 31 rotates back to position, so that the stopper 32 abuts the signal wire 90 again, which generates resistance to prevent the signal wire 90 from pulling back.

As shown in FIGS. 11A-11F, when the user does not use the signal wire 90, when the originally stretched signal wire 90 is to be retracted to the wire winding device 3, the user generates a pressing force F on the pressing element 28. At this time, the pressing element 28 moves downward, pushing the elastic recovery element 281, and accumulates energy for the pressing element 28 to spring back to the original position in the future. After the pressing element 28 is pressed to a position, the braking end 331 of the second swing arm 33 will abut the positioning body 284 on the side of the pressing element 28 by the first turning (clockwise rotation) of the second swing arm 33. The pressing element 28 is positioned in a pressed state.

During the pressing process of the pressing element 28, the driving structure 27 will change from the first state to the second state. In the first state, since the pressing element has not yet been pressed, the guide rod 271 of the driving structure 27 stays in the state shown in FIG. 10E. Once the pressing element 28 starts to move downward, one end of the pressing element 28 pushes the push rod 271 so that the push rod 271 moves downward. When the pressing element 28 is pressed to the positioning of FIG. 11B, the guide rod 271 moves downward to the second state as shown in FIG. 11C. At this time, the end of the guide rod 271 pushes the first swing arm 31 so that the first swing arm 31 rotates counterclockwise, and also drives the stopper 32 away from the signal wire 90 to release the resistance to the signal wire 90.

At the same time, as shown in FIG. 11D, because the guide rod 271 is also connected to the pushing element 270, when the guide rod 271 moves downward, in addition to pushing the first swing arm to rotate 31, it will also drive the pushing element 270 in one direction. Move in the X direction as shown in Figure 11D. When the pushing element 270 moves along the X direction, the second actuation structure 272 will also move along the X direction. Since the second actuation structure 272 and the first actuation structure 263 are abutted together, when the second actuation structure 272 moves along the X direction, the inclined surface 275 on it will follow the inclined surface of the first actuation structure 263. 264, so that the first actuating structure 263 generates power to move in the second direction, as shown in the Z direction in FIG. 11D. When the first actuating structure 263 is pushed in the second direction, it also causes the entire lifting structure 26 to move upward, so that 261 protrudes from the opening 240 of the spiral track 24, and the spiral track 24 is changed in the area corresponding to the protrusion 261, The height of the track in the Z direction. At this time, the top end of the second actuation structure 272 abuts on the first actuation structure 263, so that the first actuation structure 263 maintains a protruding state.

Since the stopper 32 on the first swing arm 31 is separated from the signal wire 90, the elastic force accumulated by the spring of the spool body 30 is released, so that the spool body 30 performs a reversing and take-up rotation movement to gradually reduce the signal wire 90 The retracted into the housing 20. When the spool body 30 reverses and takes up the thread, the rotating member 22 also reverses. During the reverse rotation of the rotating member 22, the actuating portion 25 drives the moving member 21 to move in the reverse direction along the spiral track 24 again. As shown in FIG. 11E, when the moving member 21 enters the deceleration area, that is, the area corresponding to the protrusion 261 shown in the figure, the protrusion 261 protrudes, reducing the space of the spiral track 24, so that the moving member 21 enters After the deceleration area, it is pushed out by the protrusion 261, and abuts against the elastic resistance pad 232 of the damping portion 23 on the rotating member 21, resulting in a deceleration effect until the end of the winding. As shown in FIG. 11F, when the spool body 30 retracts the signal wire 90 to the spool body 30 by rotating motion, the signal connection interface 900 of the signal wire 90 pushes against the release end of the second swing arm 32 due to the speed of the recovery. 332 causes the second swing arm 32 to swing in a second steering (counterclockwise) opposite to the first steering (clockwise), so that the braking end 331 leaves the positioning body 284. At this time, the restoring force of the elastic restoring element 281 pushes the pressing element 28 to move upward, and then pulls the guide rod 271 to move back. When the guide rod 271 moves back, the guide rod 271 drives the pushing element 270 back to the original position. At this time, because the pushing element 270 returns to the original position, the top end of the second actuating structure 272 no longer bears against the first position. The actuating structure 263 causes the lifting structure 260 to descend, thereby driving the protrusion 261 to descend back to the state shown in FIG. 10D. Finally, the recovery of the signal wire 90 is completed, and the state shown in FIG. 9A is formed.

Through the deceleration mechanism provided by the present invention, during the rotation process, when the rotation reaches a specific area, through the damping setting, friction force against rotation is generated, thereby reducing the rotation speed. The area of the damping setting can be determined according to the needs of the user to control the location of the deceleration and the length of the deceleration time. In the application of the winding mechanism, because of the setting of the deceleration mechanism, the winding speed of the wire can be controlled during the winding process, especially when the wire is recycled to a specific stage, the winding speed of the wire is reduced to prevent the user from being careless. It is hit by one end of the wire, or to avoid the sound problem caused by the impact during or after the recycling of the wire.

The above descriptions only describe the preferred implementations or examples of the technical means adopted by the present invention to solve the problems, and are not used to limit the scope of implementation of the patent of the present invention. That is to say, all the equivalent changes and modifications made in accordance with the scope of the patent application of the present invention or made in accordance with the scope of the patent of the present invention are covered by the scope of the present patent.

2: Deceleration mechanism 20: housing 200: first surface 202: third surface 201: rotating shaft 204: slotting 205: guide groove 206: support body 207: shaft seat 208: shaft seat 21: moving part 22: rotating part 220 : Second surface 221: shaft hole 23, 23a: damping part 231, 231a: cantilever 232: resistance elastic pad 24: spiral track 240: opening 25, 25a: actuation part 26: lifting structure 260: fourth surface 261: protrusion Part 262: Acting surface 263: First actuation structure 264: Inclined surface S: Elastic recovery element 27: Drive structure 270: Push element 271: Guide rod 272: Second actuation structure 273: Extension 274: Snap structure 275: Inclined surface 276: piercing 277: second combination part 278: convex part 28: pressing element 280: groove body 281: elastic recovery element 282: first combination part 283: pressing body 284: positioning body 3: winding device 30: winding shaft Body 300: fixed element 301: first bobbin 302: second bobbin 31: first swing arm 310: shaft hole 311: clamping groove 312, 313: splint 32: stop 33: second swing arm 330: shaft Hole 331: brake end 332: release end 90: signal cable 900, 901: signal connection interface 91: fixed signal connector 92: laptop

Figure 1 is a schematic diagram of the relationship between video output and input in a conventional conference room. Figure 2 is an exploded schematic diagram of the speed reduction mechanism of the present invention. Figure 3A is a schematic diagram of an embodiment of the rotating member of the present invention. Fig. 3B is a schematic diagram of another embodiment of the rotating member of the present invention. FIG. 3C is a schematic diagram of another embodiment of the damping part of the present invention. 4A is a schematic cross-sectional view of an embodiment of the lifting structure of the present invention. 4B is a perspective view of an embodiment of the driving structure and housing assembly of the present invention. Fig. 5 is an exploded perspective view of an embodiment of the winding device of the present invention. 6 is a schematic cross-sectional view of an embodiment of the bobbin body of the present invention. Figure 7 is a perspective view of a first embodiment of the swing arm of the present invention. Figure 8 is a perspective view of a second embodiment of the swing arm of the present invention. 9A and 9B are schematic diagrams of an embodiment of the use situation of the winding device of the present invention. 10A to 10E are schematic diagrams showing the actions of the main components in the winding device when the signal wire in the winding device of the present invention is stretched. 11A to 11F are schematic diagrams of the actions of the main components in the winding device when the signal wire in the winding device of the present invention is about to be retracted.

2: Deceleration mechanism

20: shell

200: first surface

201: Shaft

204: Slotting

205: Guide groove

206: Support

21: moving parts

22: Rotating parts

23: Damping part

24: spiral track

240: opening

26: Lifting structure

260: Fourth Surface

261: protrusion

S: Elastic recovery element

27: Drive structure

270: Push components

271: guide rod

272: second actuation structure

273: Extension

274: snap structure

276: piercing

277: The second combination department

28: pressing element

280: tank

281: Elastic recovery element

282: The first combination department

283: Press the body

Claims (26)

A deceleration mechanism, including: A housing having a first surface, and the first surface is provided with a spiral track; A moving part movably arranged on the spiral track; A rotating member is rotatably connected to the housing, the rotating member has a second surface opposite to the first surface, the rotating member includes an actuating portion, and the actuating portion is disposed on the second surface and interacts with The moving part abuts, when the rotating part rotates relative to the housing, the actuating part drives the moving part to move in the spiral track; and A damping part is selectively arranged on the rotating part and corresponding to a deceleration section of the spiral track, wherein when the moving part enters the deceleration section, the damping part is pressed against the moving part to reduce the rotation The rotational speed of the piece relative to the housing. The deceleration mechanism described in item 1 of the scope of the patent application further includes a lifting structure, which penetrates an opening of the housing through an opening of the deceleration section, and performs an ascending movement or a descending movement relative to the opening. As for the speed reduction mechanism described in item 2 of the scope of patent application, the damping part is a cantilever along the radial or circumferential direction of the rotating member. As described in item 2 of the scope of patent application, the lifting structure is arranged on a third surface of the housing opposite to the first surface, and the lifting structure has a first surface corresponding to the third surface. Four surfaces with at least one protruding portion, each protruding portion corresponding to one of the openings, the lifting structure has an action surface on the side corresponding to the fourth surface, and a first actuating structure thereon . According to the deceleration mechanism described in item 4 of the scope of patent application, the lifting structure further includes an elastic recovery element disposed between the plate body and the third surface. For example, the deceleration mechanism described in item 4 of the scope of patent application further includes a driving structure connected to the lifting mechanism and moving between a first state and a second state. When the driving mechanism moves from the first state to In the second state, the driving mechanism pushes the first actuating structure to control the protruding part to protrude from the opening and push the moving part, so that the moving part and the damping part abut against each other, thereby reducing the rotation At the rotating speed of the movement, when the driving mechanism returns to the first state, the protruding portion returns to the original position, so that the movable member is out of the state of abutting against the damping portion. As the speed reduction mechanism described in item 6 of the scope of patent application, the driving structure includes: A pushing element is arranged on the outer side of the action surface so that the lifting mechanism is located between the casing and the pushing element. The pushing element includes a second actuating structure, an extension and a buckle structure, wherein the The second actuation structure is arranged corresponding to the first actuation structure and abuts against each other, the extension portion protrudes from an end of the pushing element to the first surface, and the buckle structure is connected to the extension portion; and A guide rod accommodated in a guide groove on the first surface of the housing, one end of the guide rod is connected with the buckle structure, and the other end of the guide rod has a pressing element; Wherein, the pressing element is forced to move the guide rod in the guide groove, and the guide rod pushes the extension portion to push the second actuation structure against the first actuation structure, so that the lifting structure rotates along the The rotating shaft of the piece moves in the direction, thereby driving the protruding portion to protrude from the spiral track from the opening. For example, the speed reduction mechanism described in item 7 of the scope of patent application has a first swing arm and a stopper. The first swing arm is rotatably connected to the housing and the first swing arm has a A first end and a second end, wherein the first end is connected to the guide rod, and the second end is connected to the stopper. When the driving structure is in the first state, the stopper abuts against a signal On the wire, and when the driving structure is in the first state, the stopper separates from the signal wire. For example, the deceleration mechanism described in item 7 of the scope of patent application has a second swing arm which is rotatably connected to the housing. Both ends of the second swing arm are respectively provided with a brake End and a release end, the brake end abuts against a positioning body of the pressing element by a swing of a first turning after the pressing element is pressed, and the release end of the second swing arm is supported by a signal wire Pushing makes the second swing arm produce a second steering swing opposite to the first steering, so that the braking end leaves the positioning body, so that the pressing element returns to its original position. The deceleration mechanism described in item 1 of the scope of patent application further includes an elastic element coupled to the rotating member to generate power for driving the rotating member to perform a rotational movement. As described in the first item of the scope of patent application, the actuating portion is a groove, and a part of the moving element is accommodated in the groove. When the rotating movement is in progress, the edge of the groove abuts In the moving part. For the deceleration mechanism described in item 1 of the scope of patent application, the actuating part is a pair of parallel bosses, and a part of the moving part is located between the pair of parallel bosses. When the rotating movement is in progress, One of the bosses abuts against the moving part. A winding device includes: A signal wire; and A deceleration mechanism, wherein the deceleration mechanism includes: A housing having a first surface, and the first surface is provided with a spiral track; A moving part movably arranged on the spiral track; A spool body is rotatably connected to the housing, the spool body has a second surface opposite to the first surface 200, the spool body includes an actuation portion, and the actuation portion is disposed on the second surface. When the spool body rotates relative to the housing, the actuating part drives the moving part to move in the spiral track, and the spool body is wound with the signal wire; and A damping part is selectively arranged on the bobbin and corresponds to a deceleration section of the spiral track. When the moving part enters the deceleration section, the damping part presses the moving part to lower the The rotation speed of the spool body relative to the housing. The winding device described in item 13 of the scope of patent application further includes a lifting structure, which penetrates an opening of the housing through the deceleration section, and performs an upward movement or a downward movement relative to the opening. The winding device as described in item 14 of the scope of patent application, wherein the damping part is a cantilever along the radial or circumferential direction of the winding shaft body. For the winding device described in item 14 of the scope of patent application, wherein the lifting structure is disposed on a third surface of the housing opposite to the first surface, and the lifting structure has a first surface corresponding to the third surface. The four surfaces have at least one protrusion corresponding to the opening, the lifting structure has an action surface on the other side corresponding to the fourth surface, and a first actuation structure is provided on it. As described in the 16th item of the scope of patent application, the lifting structure further includes an elastic recovery element disposed between the plate body and the third surface. For example, the winding device described in item 16 of the scope of patent application further includes a driving structure connected to the lifting mechanism and moving between a first state and a second state. When the driving mechanism moves from the first state to In the second state, the driving mechanism pushes the first actuating structure to control the protruding part to protrude from the opening and push the moving part, so that the moving part and the damping part abut against each other, thereby reducing the rotation At the rotating speed of the movement, when the driving mechanism returns to the second state, the protruding portion returns to the original position, so that the moving member is out of the state of abutting against the damping portion. The winding device described in item 18 of the scope of patent application, wherein the driving structure includes: A pushing element is arranged on the outer side of the action surface so that the lifting mechanism is located between the casing and the pushing element. The pushing element includes a second actuating structure, an extension and a buckle structure, wherein the The second actuation structure is arranged corresponding to the first actuation structure and abuts against each other, the extension portion protrudes from one end of the pushing element to the first surface, and the buckle structure is connected to the extension portion; and A guide rod accommodated in a guide groove on the first surface of the housing, one end of the guide rod is connected with the buckle structure, and the other end of the guide rod has a pressing element; Wherein, the pressing element is forced to move the guide rod in the guide groove, and the guide rod pushes the extension portion to push the second actuation structure of the push element against the first actuation structure, so that the lifting structure Moving along the direction of the axis of rotation of the rotating member, thereby driving the protrusion to protrude from the opening of the spiral track. For the winding device described in item 19 of the scope of patent application, one side of the guide groove is further provided with a wire groove for accommodating the signal wire connected to the second connecting end and pulled out of the bobbin body. For example, the winding device described in item 19 of the scope of patent application has a first swing arm and a stopper. The first swing arm is rotatably connected to the housing, and the first swing arm has a A first end and a second end, wherein the first end is connected to the guide rod, and the second end is connected to the stopper. When the driving structure is in the first state, the stopper abuts against the On the signal wire, and when the driving structure is in the second state, the stopper separates from the signal wire. For example, the winding device described in item 19 of the scope of patent application has a second swing arm rotatably connected to the housing, and two ends of the second swing arm respectively have a brake end and a release end , The brake end abuts against a positioning body of the pressing element by a swing of a first turning after the pressing element is pressed by force, when the spool body retracts the signal wire to the spool body by the rotating movement Then, the signal connection interface of the signal wire is pushed against the release end of the second swing arm so that the second swing arm generates a second steering swing opposite to the first steering, so that the brake end leaves the positioning body, so that The restoring force of the elastic restoring element drives the guide rod to return to its original position. The winding device described in item 19 of the scope of patent application, wherein the pressing element further has: One press the body; A trough is opened in the pressing body; An elastic recovery element arranged in the groove body, one end of the elastic recovery element abuts against a supporting body on the housing, and the other end abuts against the wall surface of the groove body; A first combination part connected with the guide rod; and A positioning body is arranged on one side of the pressing body. As for the winding device described in item 13 of the scope of patent application, the winding shaft body further has a first winding shaft and a second winding shaft, the first winding shaft has a first diameter, and the second winding shaft has a A second diameter, the first diameter being smaller than the second diameter, wherein the first connecting end is located on the side of the first winding shaft, and the second connecting end is located on the side of the second winding shaft. For the cord winding device described in item 13 of the scope of patent application, wherein the actuating portion is a groove, a part of the moving element is accommodated in the groove, and the edge of the groove abuts when the rotating movement is performed On the moving part. For example, the winding device described in item 13 of the scope of patent application, wherein the actuating part is a pair of parallel bosses, and a part of the moving part is located between the pair of parallel bosses. When the rotating movement is in progress, One of the convex seats abuts on the moving part.

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