CN219859934U - High-frequency voltage device cable storage structure - Google Patents

Abstract

The utility model discloses a cable containing structure of a high-frequency voltage device, which relates to the technical field of voltage device accessories. According to the utility model, through the arrangement of the reciprocating screw rod, the rack, the first gear ring sleeve, the first friction wheel, the first ratchet wheel and the first pawl, the output end drives the reciprocating screw rod to rotate after the motor is started, the first friction wheel, the second friction wheel and the driven wheel are driven to translate through the linkage frame after the reciprocating screw rod rotates so as to facilitate wiring, meanwhile, the first gear ring sleeve and the second gear ring sleeve are meshed with the rack to drive the first friction wheel and the second friction wheel to rotate, so that a cable is sent into the shell for storage, and the cable storage is realized in a bending stacking mode, so that the cable heating phenomenon aggravated caused by vortex generation is avoided, and the cable is convenient to store and has higher safety.

Description

High-frequency voltage device cable storage structure

Technical Field

The utility model relates to the technical field of voltage ware accessories, in particular to a high-frequency voltage ware cable containing structure.

Background

The voltage device is mainly used for voltage conversion, the principle is that the voltage is increased or decreased by utilizing the electromagnetic induction principle through a coil and an iron core, and the high-frequency voltage device refers to a voltage device with the working frequency exceeding 10kHZ and is mainly divided into a 10kHz-50kHz voltage device, a 50kHz-100kHz voltage device, a 100 kHz-500 kHz voltage device, a 500 kHz-1 MHz voltage device and the like.

When the high-power high-frequency voltage device is installed, a power line of equipment and a line of a power grid are connected into the voltage device, a long cable is reserved between the equipment and the power grid and the high-power high-frequency voltage device, so that subsequent maintenance is facilitated, otherwise, the length of the cable which is remained after the subsequent line is damaged and cut off is difficult to connect the equipment and the power grid with the high-power high-frequency voltage device, the cable which is remained is long, the phenomena that the cable shakes, beats and winds mutually and the like easily occur, so that the cable is damaged, and a cable containing structure is required to be arranged for containing and protecting the cable.

The existing high-power high-frequency voltage device is used for accommodating the cable in a winding mode through the rotation of the roller when accommodating the remained cable, so that the structure is simple, the operation is convenient, the cable after winding is easy to form vortex so that the cable heats although the resistance value of the cable does not change, the low-power high-frequency voltage device is not greatly influenced by the use of the low-power high-frequency voltage device, the heating phenomenon is serious due to the fact that the high-power high-frequency voltage device is large in current, meanwhile, the cable winding is mutually attached and attached to the roller, the heat dissipation area of the cable is reduced, the heat of the cable is difficult to dissipate, and the cable insulation leather can be melted when serious.

Disclosure of Invention

Accordingly, the present utility model is directed to a cable housing structure for a high frequency voltage device, which solves the technical problem that a winding manner is easy to heat up a cable and reduces a heat dissipation surface.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a high frequency voltage ware cable storage structure, includes the casing, casing side-mounting has the motor, the motor output is connected with reciprocating screw, reciprocating screw surface connection has the linkage frame, the linkage frame surface has run through first friction wheel, second friction wheel and from the driving wheel respectively, first friction wheel outside has cup jointed first ring gear, first ring gear inner circle is connected with first ratchet, it has first pawl to run through on the first friction wheel, second ring gear outer has cup jointed second ring gear, second ring gear inner circle is connected with the second ratchet, it has the second pawl to run through on the second friction wheel, all be connected with the spring in first pawl and the second pawl, be connected with the rack behind the casing.

Through adopting above-mentioned technical scheme, the motor starts back output drive reciprocating screw and rotates, and the reciprocating screw is rotatory back through first friction wheel of link frame drive, second friction wheel and follow driving wheel translation so that the wiring, simultaneously through first ring gear cover and second ring gear cover and rack meshing drive first friction wheel and second friction wheel rotation with the cable send into the casing in accomodate.

Further, a cable main body is arranged in the shell, and one ends of the first friction wheel, the second friction wheel and the driven wheel are connected with a sliding plate.

Through adopting above-mentioned technical scheme, the first friction wheel of linkage frame drive after the motor starts, second friction wheel and follow driving wheel translation so that with cable main part evenly distributed in the casing, support first friction wheel, second friction wheel and follow the driving wheel other end through the slide simultaneously.

Furthermore, the linkage frame and the sliding plate are movably connected with the shell, and the linkage frame is in threaded connection with the reciprocating screw rod.

Through adopting above-mentioned technical scheme, the motor starts back output drive reciprocating screw and rotates, and the first friction wheel of back through the linkage frame drive, second friction wheel and follow driving wheel translation in order to evenly distributed with the cable in the casing after the reciprocating screw is rotatory.

Further, two driven wheels are arranged, the two driven wheels, the first friction wheels and the second friction wheels are distributed in a rectangular array shape, and the first friction wheels and the second friction wheels are arranged diagonally.

Through adopting above-mentioned technical scheme, when first friction wheel initiative rotation, second friction wheel and two follow driving wheel passive rotation assist first friction wheel push the cable into the casing, and when second friction wheel initiative rotation, first friction wheel and two follow driving wheel passive rotation assist second friction wheel push the cable into the casing.

Further, the first ratchet wheel is arranged in a mirror image mode with the second ratchet wheel, and the first pawl is arranged in a mirror image mode with the second pawl.

Through adopting above-mentioned technical scheme, when first tooth ring cover and second tooth ring cover clockwise rotation first friction wheel initiative rotation pushes the cable into the casing in, when first tooth ring cover and second tooth ring cover anticlockwise rotation second friction wheel initiative rotation pushes the cable into the casing.

Further, the first pawl is movably connected with the first friction wheel, and the second pawl is movably connected with the second friction wheel.

Through adopting above-mentioned technical scheme, second tooth ring cover and rack engagement clockwise rotation, the second ratchet promotes the second pawl and compresses the spring and do not drive the second friction wheel rotation this moment, and first tooth ring cover and rack engagement anticlockwise rotation, and first ratchet promotes first pawl and compresses spring and do not drive first friction wheel rotation this moment.

Further, two racks are arranged, and the first toothed ring sleeve and the second toothed ring sleeve are respectively meshed with the two racks.

Through adopting above-mentioned technical scheme, the rotatory back of reciprocating screw passes through first friction wheel of link drive, second friction wheel and follow driving wheel translation so that the wiring, simultaneously through first tooth ring cover and second tooth ring cover and rack meshing drive first friction wheel and second friction wheel rotation with the cable send into the casing in accomodate.

In summary, the utility model has the following advantages:

according to the utility model, through the arrangement of the reciprocating screw rod, the rack, the first gear ring sleeve, the first friction wheel, the first ratchet wheel and the first pawl, the output end drives the reciprocating screw rod to rotate after the motor is started, the first friction wheel, the second friction wheel and the driven wheel are driven to translate through the linkage frame after the reciprocating screw rod rotates so as to facilitate wiring, meanwhile, the first gear ring sleeve and the second gear ring sleeve are meshed with the rack to drive the first friction wheel and the second friction wheel to rotate, so that a cable is sent into the shell for storage, and the cable storage is realized in a bending stacking mode, so that the cable heating phenomenon aggravated caused by vortex generation is avoided, and the cable is convenient to store and has higher safety.

Drawings

FIG. 1 is a schematic view of the rear view of the housing of the present utility model;

FIG. 2 is a schematic cross-sectional view of a housing according to the present utility model;

FIG. 3 is a schematic view of a linkage frame structure according to the present utility model;

FIG. 4 is a schematic view of a rear-view exploded structure of the first toothed annulus of the present utility model;

fig. 5 is a schematic view of a rear-view exploded structure of the second toothed ring sleeve of the present utility model.

In the figure: 1. a housing; 2. a cable body; 3. a motor; 4. a reciprocating screw rod; 5. a rack; 6. a linkage frame; 7. a first toothed ring sleeve; 8. a second toothed ring sleeve; 9. a first friction wheel; 10. a second friction wheel; 11. driven wheel; 12. a slide plate; 13. a first ratchet; 14. a first pawl; 15. a spring; 16. a second ratchet; 17. and a second pawl.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

Hereinafter, an embodiment of the present utility model will be described in accordance with its entire structure.

1, 2, 3, 4 and 5, including casing 1, casing 1 inside below is provided with cable main part 2, casing 1 one side top installs motor 3, send line work in the wiring, motor 3 output is connected with reciprocating lead screw 4, reciprocating lead screw 4 surface is connected with linkage frame 6, make cable main part 2 evenly distributed, the both sides of linkage frame 6 surface are run through respectively first friction wheel 9, second friction wheel 10 and follow driving wheel 11, conveniently push cable main part 2 into casing 1, first friction wheel 9, second friction wheel 10 and follow driving wheel 11 front end all are connected with slide 12, linkage frame 6 and slide 12 all with casing 1 sliding connection, and linkage frame 6 and reciprocating lead screw 4 threaded connection, first ring gear 7 has been cup jointed to first friction wheel 9 outside, the inner circle of the first gear ring sleeve 7 is connected with a first ratchet wheel 13, four first pawls 14 penetrate through the outer circle of the first friction wheel 9 respectively, the cable main body 2 is pushed into the shell 1 when the linkage frame 6 moves rightwards, the second gear ring sleeve 8 is sleeved outside the second friction wheel 10, the inner circle of the second gear ring sleeve 8 is connected with a second ratchet wheel 16, four second pawls 17 penetrate through the outer circle of the second friction wheel 10 respectively, springs 15 are connected inside the four first pawls 14 and the four second pawls 17 respectively, the cable main body 2 is pushed into the shell 1 when the linkage frame 6 moves leftwards, two racks 5 are connected above the back of the shell 1, the first gear ring sleeve 7 and the second gear ring sleeve 8 are meshed with the two racks 5 respectively, and the cable is stored in a bending and stacking mode to avoid the cable heating phenomenon caused by vortex.

Referring to fig. 2, 3, 4 and 5, in the above embodiment, two driven wheels 11 are provided, and the two driven wheels 11, the first friction wheel 9 and the second friction wheel 10 are distributed in a rectangular array, the first friction wheel 9 and the second friction wheel 10 are diagonally arranged, the first ratchet wheel 13 and the second ratchet wheel 16 are mirror-image arranged, the first pawl 14 and the second pawl 17 are mirror-image arranged, the first pawl 14 is slidably connected with the first friction wheel 9, and the second pawl 17 is slidably connected with the second friction wheel 10, and the cable displacement is driven while the wiring is reciprocally displaced left and right.

The implementation principle of the embodiment is as follows: firstly, when the cable main body 2 remains longer, a worker turns on the motor 3, the output end drives the reciprocating screw rod 4 to rotate after the motor 3 is started, and the reciprocating screw rod 4 drives the linkage frame 6, the first friction wheel 9, the second friction wheel 10 and the driven wheel 11 to reciprocate left and right in the shell 1 after rotating, so that the cable main body 2 is uniformly distributed inside the shell 1;

the first friction wheel 9 is fed, the viewing angles of the four and five views are opposite, when the linkage frame 6 is shifted rightwards, the first toothed ring sleeve 7 is meshed with the rack 5 to rotate clockwise, at the moment, the first pawl 14 props against the first ratchet wheel 13 to enable the first toothed ring sleeve 7 to drive the first friction wheel 9 to rotate clockwise so as to push the cable main body 2 into the shell 1, meanwhile, the second toothed ring sleeve 8 is meshed with the rack 5 to rotate clockwise, at the moment, the second ratchet wheel 16 pushes the second pawl 17 to compress the spring 15 so as not to drive the second friction wheel 10 to rotate, so that the second toothed ring sleeve 8 idles, and the cable main body 2 is prevented from being pushed upwards by the second friction wheel 10;

the second friction wheel 10 is fed, the view from the front view angle is opposite in view angles of four and five, when the linkage frame 6 is shifted leftwards, the second toothed ring sleeve 8 is meshed with the rack 5 to rotate anticlockwise, at the moment, the second pawl 17 props against the second ratchet wheel 16 to enable the second toothed ring sleeve 8 to drive the second friction wheel 10 to rotate anticlockwise to push the cable main body 2 into the shell 1, meanwhile, the first toothed ring sleeve 7 is meshed with the rack 5 to rotate anticlockwise, at the moment, the first ratchet wheel 13 pushes the first pawl 14 to compress the spring 15 to not drive the first friction wheel 9 to rotate, the first toothed ring sleeve 7 idles, and the cable main body 2 is prevented from being pushed upwards by the first friction wheel 9.

Although embodiments of the utility model have been shown and described, the detailed description is to be construed as exemplary only and is not limiting of the utility model as the particular features, structures, materials, or characteristics may be combined in any suitable manner in any one or more embodiments or examples, and modifications, substitutions, variations, etc. may be made in the embodiments as desired by those skilled in the art without departing from the principles and spirit of the utility model, provided that such modifications are within the scope of the appended claims.

Claims (7)

1. The utility model provides a high frequency voltage ware cable accomodates structure, includes casing (1), its characterized in that: the novel gear rack comprises a shell body (1), wherein a motor (3) is arranged on the side face of the shell body (1), the output end of the motor (3) is connected with a reciprocating screw rod (4), the surface of the reciprocating screw rod (4) is connected with a linkage frame (6), a first friction wheel (9), a second friction wheel (10) and a driven wheel (11) are respectively penetrated through the surface of the linkage frame (6), a first toothed ring sleeve (7) is sleeved outside the first friction wheel (9), a first ratchet wheel (13) is connected with an inner ring of the first toothed ring sleeve (7), a first pawl (14) is penetrated through the first friction wheel (9), a second toothed ring sleeve (8) is sleeved outside the second friction wheel (10), a second ratchet wheel (16) is connected with an inner ring of the second toothed ring sleeve (8), a second pawl (17) is penetrated through the second friction wheel (10), springs (15) are respectively connected in the first pawl (14) and the second pawl (17), and a rack (5) is connected behind the shell body (1).

2. The high frequency voltage cable housing structure according to claim 1, wherein: a cable main body (2) is arranged in the shell (1), and one ends of the first friction wheel (9), the second friction wheel (10) and the driven wheel (11) are connected with a sliding plate (12).

3. The high frequency voltage cable housing structure according to claim 2, wherein: the linkage frame (6) and the sliding plate (12) are both movably connected with the shell (1), and the linkage frame (6) is in threaded connection with the reciprocating screw rod (4).

4. The high frequency voltage cable housing structure according to claim 1, wherein: the driven wheels (11) are arranged in two, the driven wheels (11), the first friction wheels (9) and the second friction wheels (10) are distributed in a rectangular array, and the first friction wheels (9) and the second friction wheels (10) are diagonally arranged.

5. The high frequency voltage cable housing structure according to claim 1, wherein: the first ratchet wheel (13) is arranged in a mirror image mode with the second ratchet wheel (16), and the first pawl (14) is arranged in a mirror image mode with the second pawl (17).

6. The high frequency voltage cable housing structure according to claim 5, wherein: the first pawl (14) is movably connected with the first friction wheel (9), and the second pawl (17) is movably connected with the second friction wheel (10).

7. The high frequency voltage cable housing structure according to claim 1, wherein: the racks (5) are two, and the first toothed ring sleeve (7) and the second toothed ring sleeve (8) are respectively meshed with the two racks (5).