JP3102819U - Structure of a cable winder having a plurality of wheels coaxially - Google Patents

Abstract

An object of the present invention is to provide a structure of a cable winder having a plurality of wheels coaxially so that a stable braking effect is provided during operation and a cable can be smoothly taken in and out.
A rotating wheel having both left and right wheels is provided, and a center hole of the rotating wheel is rotatably connected to a single shaft portion. The cable S is divided into an upper cable S3 and a lower cable S4 by being wound around the left and right wheels 11, 13, and at least one or more sliding grooves 15 are provided on a side wall surface of the wheel 10, The ball 15 is further accommodated in the groove 15, and when the ball 20 rolls in the movable space 153 in the sliding groove 15, it acts as a bearing to rotate the wheel 10 in the forward and reverse directions. When the ball 20 is located in the narrow restricted space 151, the ball 20 provides a braking action.
[Selection diagram] Fig. 1

Description

The present invention relates to a structure of a cable winder having a plurality of wheels coaxially, and in particular, a plurality of concentrating wheels provided inside are rotated coaxially, so that the cable can be smoothly inserted and removed. The present invention relates to a structure of a cable winder having high stability due to having a braking effect.
Taiwan Patent No.509449

A known general cable winder has a device in which a cable is divided into an upper part and a lower part, which can be pulled out or collected, and a cable mainly used for electric products such as earphones. is there.
This mainly has large and small wheels for accommodating cables, and these are installed rotatably around one shaft. When the wheel is rotated using the shaft, both the upper and lower cables respectively housed in each wheel are pulled out or collected, and a brake structure using the elasticity of a spring is provided. This provides a structure for positioning the cable when the cable is pulled or collected.

11 and 12, a left wheel A1 and a right wheel A2 having the same diameter are provided on a rotating wheel A, as shown in FIGS. An annular groove A3 is formed on one side wall surface of the wheel A, and the wheel A is further rotatably disposed on a fixed shaft B.
A single continuous cable C is wound around the left cable A1 and the right cable A2 in different directions, so that the upper cable C1 and the lower cable C2 are separated from each other. The pulling or withdrawing force causes the wheel A to rotate clockwise or counterclockwise, so that the length of the upper and lower cables C1 and C2 is equal or equal.
Further, with respect to the brake of the wheel A, the braking action is achieved by positioning the ball D in the localization groove A4 in the annular groove A3.

However, the structure of the above-mentioned known cable winders has the following disadvantages.
First, a major drawback of the known general cable winder is that the spring is rapidly deteriorated by fatigue.
On the other hand, a drawback of the improved type is that one ball slides in the annular groove, so that the force is concentrated on the side wall surface of the wheel, and the stability of the rotation of the wheel is increased. And inferior positioning stability due to braking. At the same time, when the brake is applied to the wheel, the ball is not applied unless it returns to the stereotactic groove at any fixed position in the annular groove.
In view of the above-mentioned drawbacks, the present invention provides a structure of a cable winder having a plurality of coaxial wheels so as to provide a stable braking effect at the time of operation and at the same time to smoothly pull out and recover a cable. I do.

  By providing a rotating wheel having at least both right and left wheels on the surface, connecting the center hole of the rotating wheel to one shaft movably, and winding one cable around the left and right wheels in different directions, The cable is divided into an upper cable and a lower cable, and at least one or more sliding grooves are provided on a side wall surface of the wheel, and a ball is further provided in the sliding groove, and the ball is inserted into a space in the sliding groove. When rolling, it acts as a bearing to rotate the wheel in the forward and reverse directions, and when the ball is in the restricted space, the ball provides a braking action, thereby reducing the rotation of the wheel. It will be smoother and more stable, while at the same time increasing stability when braking.

  According to the present invention, the stability of the rotation and the brake of the cable is improved, and at the same time, the length of the cable to be pulled out can be accurately controlled by instantaneously applying a brake to the cable by the structure of a plurality of wheels.

In the present invention, as shown in FIGS. 1 and 2, a rotating wheel 10 including at least two wheels such as left and right wheels 11 and 13 is provided on the surface, and a center hole 12 is formed by one shaft portion. 30 is formed so as to be rotatable.
The inner end 81 of the spiral spring 80 is connected to the shaft 30, and the outer end 82 is connected to the rotating wheel 10.
Appropriate positions of one continuous signal cable S are engaged on the rotating wheel 10 to be localized, and the signal cable S is separated into an upper cable S3 and a lower cable S4 by the localized portion. The upper cable S3 and the lower cable S4 are wound on the left wheel 11 and the right wheel 12, respectively, in opposite directions.
At least one or more sliding grooves 15 are provided at locations along the circumference of the center hole 12 on the side wall surface of the rotating wheel 10.
At least one or more balls 20 are inserted to slide into the sliding groove 15 so as to roll in the sliding groove 15, and are housed and positioned by an appropriate position in the sliding groove 15 and the surface of the shaft 30. Is done.

As shown in FIGS. 3 and 4, at the groove end of the sliding groove 15 in the rotating wheel 10, a limited space 151 is provided, and the inner diameter of the limited space 151 is designed to be smaller than the outer diameter of the ball 20. When the ball 20 rolls into the limited space 151, the surface of the ball 20 is fitted by the brakes formed on the upper groove wall 152 and the surface of the shaft 30, respectively, of the limited space 151. In this case, the rotating wheel 10 is braked.
3 and 4, the sliding groove 15 in the rotating wheel 10 has a movable space 153 having the same inner diameter, and the outer diameter of the ball 20 is smaller than the inner space of the movable space 153 in the inner diameter direction. The ball 20 rolls in the movable space 153, and the rotating wheel 10 rotates with respect to the shaft portion 30.

As shown in FIGS. 1 and 2, the shaft 30 protrudes and is fixed to the inner wall surface of the right outer shell 40, and a connection hole 52 provided in the left outer shell 50 is mutually connected to the shaft 30. The upper and lower ends of the left and right outer shells 50 and 40 are provided with a shaft pin 54 and an insertion hole 44, respectively. The left and right outer shells 50, 40 are formed with a positioning groove 60 on the side surfaces thereof with an interval therebetween (see FIGS. 3 and 4).
As shown in FIG. 1, the extreme ends of the upper and lower cables S3 and S4 are connected to an electric product 70 that outputs an electric signal, and the electric product 70 is connected to an earphone or a microphone, a plug or an outlet, or a circuit board. Including.
As shown in FIGS. 7 and 8, the left and right wheels 11 and 13 of the rotating wheel 10 can be designed so that their outer diameters (D, d) are equal or different.
As shown in FIGS. 1 and 2, a ring 19 is provided on both left and right wheels 11 and 13 of the rotating wheel 10 so as to divide the cable S into upper and lower portions, thereby separating the winding positions of the upper and lower cables S3 and S4. You may.

As shown in the rotating wheel 10 of FIG. 9, the first embodiment of the present invention has a rotating wheel 10 provided with a main wheel 14 on its surface, and these center holes 12 are movable to one shaft 30. It is installed in a state.
The inner end 81 of the spiral spring 80 is connected to the shaft 30 and the outer end 82 is connected to the rotating wheel 10.
Appropriate portions of one continuous signal cable S are located on the rotating wheel 10 so that the upper and lower cables S3 and S4 are separated from each other on the main wheel 14 by separating the upper cable S3 and the lower cable S4. Wrapped around.
At least one sliding groove 15 is provided on a side surface of the rotating wheel 10 at a position along the circumference of the center hole 12.
Further, at least one or more balls 20 are put in the sliding groove 15 and roll in the sliding groove 15, and are fitted to an appropriate position in the sliding groove 15 and the surface of the shaft portion 30. Is localized.

First, as shown in FIGS. 1 and 2, the spiral spring 80 is fitted into the receiving recesses 16 on both wall surfaces of the rotating wheel 10, and its outer end 82 is connected to the rotating wheel 10. The inner end portion 81 is located in the fitting groove 31 of the shaft portion 30, and serves as a portion for providing resilience when the rotating wheel 10 receives a rotating force. The signal cable S fits an appropriate portion as a boundary on the holding groove 101 having a depressed state in the rotating wheel 10, and one end of the signal cable S is pierced from a hole 17 of the rotating wheel 10. The other end is pierced from another perforation 18 of the rotating wheel 10, the upper cable S 3 is wound around the right wheel 13, and the lower cable S 4 is wound on the left wheel 11, separating the upper and lower cables S 3 and S 4. Rolled up.
As shown in FIG. 3, when the upper and lower cables S3 and S4 are released (due to being pulled), they are in a state suitable for use, and the rotation generated when the upper cable S3 or the lower cable S4 is pulled. Due to the force, the rotating wheel 10 rotates, and the rotating wheel 10 rotates about the shaft 30. At this time, the ball 20 just rolls in the movable space 153, and the outer diameter of the ball 20 is Since the ball 20 is smaller than the inner diameter space of the movable space 153, the ball 20 rolls in the movable space 153, and the ball 20 plays a role of a bearing, and the rotating wheel 10 rotates by being twisted, and is smoothly and stably. Rotate.

  As shown in FIG. 4, at the point where the upper and lower cables S3 and S4 are braked, the user first pulls the upper and lower cables S3 and S4 to an appropriate length, and then temporarily stops the pulling operation. As a result, the rotating wheel 10 rotates in the reverse direction, the ball 20 turns in the opposite direction in the sliding groove 15 and rolls into the restricted space 151, and the surface of the ball 20 is positioned in the upper groove of the restricted space 151. The ball 20 is engaged with the wall 152 and the surface of the shaft portion 30 to act as a brake, and the rotating wheel 10 is braked and positioned. In this way, the upper and lower cables S3 and S4 are quickly positioned. This is because the length of the sliding groove 15 gradually decreases, that is, the distance between the movable space 153 and the restricted space 151 becomes shorter. By doing so, the difference between the length of the upper and lower cables S3 and S4 from the length that is pulled and extended until the brake is applied is reduced, and the length of the upper and lower cables S3 and S4 is reduced. The purpose of precisely controlling the setting of the height is achieved.

  As shown in FIG. 5, in a state in which the upper and lower cables S3 and S4 are housed, the user pulls the already pulled out upper and lower cables S3 and S4 while adjusting the amount of force, and gradually reduces the force. When the rotating wheel 10 is loosened, the rotating wheel 10 receives the winding force of the spiral spring 80, collects the upper and lower cables S3 and S4, and while the cables are being collected, the ball 20 is continuously moved in the movable space 153. Continue rolling at. When the collecting operation is completed, the electric product 70 connected to the extreme ends of the upper and lower cables S3 and S4 is localized at the slot of the localization groove 60 (see FIG. 6).

As shown in FIG. 7, the outer diameter d of the left wheel 11 of the rotating wheel 10 is smaller than the outer diameter D of the right wheel 13, so that when the rotating wheel 10 rotates by The length of the lower cable S4 released (or collected) of the cable 11 is shorter than the length of the upper cable S3 released (or collected) of the right wheel 13.
As shown in FIG. 8, when the outer diameter of the left wheel 11 of the rotating wheel 10 is equal to the outer diameter D of the right wheel 13, the upper cable S3 and the lower cable S4 on the left and right wheels 11, 24 are pulled. (Or recovered) lengths are equal.

As shown in FIGS. 9 and 10, in another embodiment of the present invention, unlike the above-described embodiment in the main wheel 14, an appropriate portion of the signal cable S is connected to the fitting portion 141 of the rotating wheel 10. The upper and lower cables S3 and S4 are positioned and overlapped and wound on the main wheel 14, and are released when the outer end of the upper cable S3 (or the lower cable S4) receives the pulling force, and the pulling force is lost. Thereafter, the upper and lower cables S3 and S4 are wound back on the main wheel 14.
Also, as shown in FIGS. 1 and 6, the electric product 70 connected to the outer ends of the upper and lower cables S3 and S4 in the present invention includes various plugs and outlets, earphones and microphones, electric circuits and other parts. .

FIG. 3 is an exploded view of the present invention. FIG. 3 is another exploded view of the present invention. FIG. 4 is a cross-sectional view showing a state in which the upper and lower cables of the present invention are released. FIG. 4 is a cross-sectional view showing a state in which the upper and lower cables of the present invention are braked and localized. FIG. 4 is a cross-sectional view showing a state in which the upper and lower cables of the present invention are housed. It is a rear view showing the state where the upper and lower cables of the present invention were accommodated. FIG. 4 is a side view of the rotary wheel according to the present invention, which is designed with different outer diameters of the left and right wheels. It is a side view at the time of designing the outer diameter of the right and left wheels of the rotating wheel of this invention equal. FIG. 4 is an exploded view of another embodiment of the present invention. FIG. 4 is a cross-sectional view of another embodiment of the present invention. It is a three-dimensional exploded view in a known cable winder. It is sectional drawing in a well-known cable winder.

Explanation of reference numerals

DESCRIPTION OF SYMBOLS 10 Rotating wheel 101 Holding groove 11 Left wheel 12 Center hole 13 Right wheel 14 Main wheel 141 Fitting part 15 Sliding groove 151 Restricted space 152 Upper groove wall 153 Movable space 16 Housing recessed part 17, 18 Perforation 19 Ring 20 Ball 30 Ball 30 Shaft part 31 Fitting Mating groove 40 Right outer shell 44 Insertion hole 50 Left outer shell 52 Connection hole 54 Shaft pin 60 Orientation groove 70 Electric product 80 Spiral spring 81 Bottom 82 Outer end S Signal cable S3 Upper cable S4 Lower cable
D, d outer diameter
A rotating wheel
A1 Left wheel
A2 Right wheel
A3 annular groove
A4 Orientation groove
B Fixed axis
C cable
C1 Upper cable
C2 Lower cable
D ball

Claims (9)

In a cable winder having a plurality of coaxial wheels, comprising a rotating wheel, a spiral spring, and a cable,
A rotating wheel including a wheel divided into at least two outer peripheral surfaces such as a left wheel and a right wheel, and having a center hole rotatably connected to one shaft;
A spiral spring having an inner end connected to the shaft and an outer end connected to the rotating wheel;
A single continuous cable which is fixed on the rotating wheel at an intermediate position to be separated into an upper part and a lower part, and the upper part and the lower part are respectively wound around the left and right wheels in opposite directions. When,
Having,
At least one or more sliding grooves are provided on the one side wall surface of the rotating wheel along the center hole, and at least one or more balls are loaded in the sliding groove so as to be movable and rotatable. A cable winder having a plurality of coaxial wheels, wherein the ball is positioned and fitted to the shaft surface at an appropriate position in the sliding groove.   A restricted space is provided on one end side of the sliding groove in the rotating wheel, and a space in an inner diameter direction of the restricted space is smaller than an outer diameter of the ball, and when the ball rolls up to the restricted space, 2. The cable having a plurality of coaxial wheels according to claim 1, wherein the surface of the ball fits into the upper groove wall of the restricted space and the surface of the shaft to provide a braking effect to the rotating wheel. Winder structure.   The sliding groove in the wheel includes a ball having an outer diameter smaller than the inner diameter of the movable space, and the rolling wheel rotates in the shaft by rolling the ball in the movable space. The structure of a cable winder having a plurality of coaxial wheels according to claim 1.   2. The structure of a cable winder having a plurality of coaxial wheels according to claim 1, wherein said shaft portion is fixed so as to protrude from an inner wall surface of said right outer shell.   The left outer shell is provided with a connection hole to be connected to the shaft portion, and the upper and lower ends of the left and right outer shells are provided with a shaft pin and an insertion hole, respectively. 2. A cable winder having a plurality of coaxial wheels according to claim 1, wherein said left and right outer shells integrated by being inserted into said insertion holes are formed with stereotactic grooves. .   An electrical product from which an electrical signal is output is connected to each end of the upper cable and the lower cable, and the electrical product includes an earphone, a microphone, a plug, an outlet, a circuit board, and the like. The structure of a cable winder having a plurality of coaxial wheels according to claim 1.   The structure of a cable winder having a plurality of coaxial wheels according to claim 1, wherein the left and right wheels of the rotary wheel have the same outer diameter or different outer diameters.   The structure of a cable winder having a plurality of coaxial wheels according to claim 1, wherein a ring for dividing the cable up and down at the time of collection is separately provided on both the left and right wheels of the rotating wheel. In the structure of a cable winder having a plurality of wheels coaxially constituted by a rotating wheel, a spiral spring, and a cable,
A rotating wheel provided with a main wheel on the outer peripheral surface and having a center hole rotatably connected to one shaft;
A spiral spring having an inner end connected to the shaft and an outer end connected to the rotating wheel;
A continuous piece that is fixed and localized on the rotating wheel at an intermediate position and is separated into an upper part and a lower part, and the upper part and the lower part overlap each other and are wound around the main wheel. Cables and
Having,
At least one or more sliding grooves are provided on a side wall of the rotating wheel along a center hole, and one or more balls are movably loaded so as to roll in the sliding grooves. , And the ball winder having a plurality of coaxial wheels, wherein the ball is fitted and positioned by the shaft surface at an appropriate position in the sliding groove.

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