CN117613600A - Antistatic device for dual-mode test assembly line and application method thereof - Google Patents

Abstract

An antistatic device for a dual-mode test assembly line and a use method thereof belong to the field of communication equipment. Comprises a shell; the shell is provided with a perforation, and a connecting cylinder communicated with the perforation is fixedly connected inside the shell; a data interface is fixedly connected in the connecting cylinder; the outer side of the shell is fixedly connected with a grounding wire; a vertical chute I is arranged on the inner wall of the through hole, and a chute II is arranged on the inner wall of the chute I; the sliding groove I and the sliding groove II are in sliding fit with the sealing device. The invention can expand the plug interface through the rotating plate, is convenient for plug insertion, can reduce dust entering the plug interface, and is also convenient for cleaning dust.

Description

Antistatic device for dual-mode test assembly line and application method thereof

Technical Field

The invention relates to an antistatic device for a dual-mode test assembly line and a use method thereof, belonging to the field of communication equipment.

Background

When dual-mode (high-speed carrier HPLC+high-speed wireless HRF) testing is carried out, various communication equipment is needed, a data transmission line is needed to be used for transmission in the transmission process of part of communication equipment, static electricity cannot be quickly released when the plug interface of the existing equipment is connected with the data transmission line, dust cannot be effectively prevented from entering the plug interface of the equipment, manual cleaning is needed, time is wasted, and a plug of the data transmission line is easy to loosen after being collided by external force, so that data transmission is influenced, and improvement is needed.

Disclosure of Invention

The invention aims to solve the problems in the prior art and provides an antistatic device for a dual-mode test assembly line and a use method thereof.

The invention achieves the above purpose, adopts the following technical scheme:

an antistatic device for a dual-mode test assembly line comprises a shell; the shell is provided with a perforation, and a connecting cylinder communicated with the perforation is fixedly connected inside the shell; a data interface is fixedly connected in the connecting cylinder; the outer side of the shell is fixedly connected with a grounding wire; a vertical chute I is arranged on the inner wall of the through hole, and a chute II is arranged on the inner wall of the chute I; the sliding groove I and the sliding groove II are in sliding fit with the sealing device.

An antistatic device for a dual-mode test assembly line is characterized in that one side of a sliding block, facing an elastic telescopic rod I, is provided with an inclined plane; after the movable plate rotates by 90 degrees, the elastic telescopic rod I is stressed and contracted, and the limiting plate is driven to move downwards to contact with the inclined surface of the sliding block.

An application method of an antistatic device for a dual-mode test assembly line, the application method comprises the following steps:

step one: pushing the plug into the connecting cylinder along the inclined plane of the rotating plate; until the plug is inserted into the data interface;

step two: pushing the movable plate to rotate, and pulling out the plug;

step three: the rotating plate is pulled in a direction away from the shell to clean dust.

Compared with the prior art, the invention has the beneficial effects that: the invention can expand the plug interface through the rotating plate, is convenient for plug insertion, can reduce dust entering the plug interface, and is also convenient for cleaning dust.

Drawings

FIG. 1 is a front view of an antistatic device for a dual mode test line of the present invention;

FIG. 2 is a cross-sectional view taken along the direction A-A in FIG. 1;

FIG. 3 is a cross-sectional view taken in the direction B-B in FIG. 2;

FIG. 4 is a schematic diagram of the position of a movable device of an antistatic device for a dual-mode test line according to the present invention;

FIG. 5 is a schematic structural view of a sealing device of an antistatic device for a dual-mode test line according to the present invention;

FIG. 6 is a side view of a slider of an antistatic device for a dual mode test line of the present invention;

FIG. 7 is a schematic diagram of the connection structure of the shaft and the sleeve of the antistatic device for the dual-mode test line;

FIG. 8 is a schematic diagram of a movable device of an antistatic device for a dual-mode test line according to the present invention;

FIG. 9 is a schematic diagram showing the movement state of a rotating plate during the insertion of a plug of an antistatic device for a dual-mode test line according to the present invention;

FIG. 10 is a second schematic diagram of the movement state of the rotating plate during the insertion of the plug of the antistatic device for a dual-mode test line.

Detailed Description

The technical solutions of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is apparent that the described embodiments are only some embodiments of the invention, but not all embodiments, and all other embodiments obtained by those skilled in the art without making creative efforts based on the embodiments of the present invention are all within the protection scope of the present invention.

The first embodiment is as follows: as shown in fig. 1-10, this embodiment describes an antistatic device for a dual-mode test line, comprising a housing 1; the shell 1 is provided with a perforation, and a connecting cylinder 7 communicated with the perforation is fixedly connected inside the shell 1; a data interface 6 is fixedly connected in the connecting cylinder 7; the outside of the shell 1 is fixedly connected with a grounding wire 8; a vertical chute I55 is arranged on the inner wall of the through hole, and a chute II 56 is arranged on the inner wall of the chute I55; the sliding grooves I55 and II 56 are in sliding fit with the sealing device 3.

The sealing device 3 comprises a sliding block 33, a shaft rod 34, a sleeve 35, a linkage rod 36, a rotating plate 37, a transmission block 38, a limiting block 312 and a spring I314; the sliding block 33 is in sliding fit with the sliding groove I55, and a rectangular block 315 in sliding fit with the sliding groove II 56 is fixedly connected to the side surface of the sliding block 33; a shaft lever 34 is fixedly connected between the two sliding blocks 33 positioned on the same side of the perforation, and a limiting block 312 is fixedly connected on the outer circular surface of the shaft lever 34; the sleeve 35 is sleeved on the corresponding shaft lever 34, and a limiting groove 313 which is in sliding fit with the limiting block 312 is formed in the inner wall of the sleeve 35; a spring I314 is fixedly connected between the limiting groove 313 and the limiting block 312; the rotating plates 37 are fixedly connected to the outer circular surfaces of the corresponding sleeves 35, and the opposite surfaces of the two rotating plates 37 are fixedly connected with transmission blocks 38; a linkage rod 36 is fixedly connected between the two sliding blocks 33 positioned at the two sides of the perforation; the inner wall of the transmission is provided with a notch 12 which is in sliding fit with the linkage rod 36; two grooves 71 are symmetrically arranged on the inner wall of the connecting cylinder 7, and the rotating plate 37 is in sliding fit with the corresponding grooves 71.

The outer side of the shell 1 is fixedly connected with a lower baffle plate 2, and the lower baffle plate 2 is positioned at the lower end of the perforation.

A slide way I39 is arranged on one side of the rotating plate 37 close to the corresponding sleeve 35, a connecting block 311 which is in sliding fit with the slide way I39 is arranged in the slide way I39, and the connecting block 311 is fixedly connected with the corresponding sleeve 35; and a spring II 310 is fixedly connected between the connecting block 311 and the inner wall of the slideway I39.

A slide way I39 is arranged on one side of the rotating plate 37 close to the corresponding sleeve 35, a connecting block 311 which is in sliding fit with the slide way I39 is arranged in the slide way I39, and the connecting block 311 is fixedly connected with the corresponding sleeve 35; and a spring II 310 is fixedly connected between the connecting block 311 and the inner wall of the slideway I39.

One end of the rotating plate 37 located outside the shell 1 is fixedly connected with a fixing plate 31, and one end of the fixing plate 31 away from the rotating plate 37 is provided with an arc-shaped groove 32 for fixing a wire.

Slide ways II 11 are arranged on two sides of the through hole of the shell 1; the slide II 11 is internally provided with a movable device 5.

The movable device 5 comprises a sliding block 54, a limiting plate 51, an elastic telescopic rod I52 and an elastic telescopic rod II 53; the sliding grooves I55 and II 56 are arranged on the side face of the sliding block 54, and the sliding block 54 is in sliding fit with the sliding way II 11; the fixed end of the elastic telescopic rod I52 is fixedly connected to the bottom surface of the slideway II 11, the side surface of the free end of the elastic telescopic rod I52 is fixedly connected with a limiting plate 51, and the free end of the elastic telescopic rod I52 is exposed above the slideway II 11; one end of the elastic telescopic rod II 53 is fixedly connected to the side face of the fixed end of the elastic telescopic rod I52, and the other end of the elastic telescopic rod II 53 is fixedly connected to the side face of the sliding block 54; the upper end of the perforation of the shell 11 is hinged with a movable plate 4; the sealing means 3 and the moving means 5 are both made of metal.

The side of the sliding block 54 facing the elastic telescopic rod I52 is provided with an inclined plane; after the movable plate 4 rotates by 90 degrees, the elastic telescopic rod I52 is stressed and contracted, and the limiting plate 51 is driven to move downwards to contact with the inclined surface of the sliding block 54.

An application method of an antistatic device for a dual-mode test assembly line, the application method comprises the following steps:

step one: pushing the plug into the connecting cylinder 7 along the inclined surface of the rotating plate 37; until the plug is inserted into the data interface 6;

step two: pushing the movable plate 4 to rotate, and pulling out the plug;

step three: pulling the rotating plate 37 in a direction away from the housing 1 cleans the dust.

The working principle of the invention is as follows: when the device is used, as shown in fig. 2, one ends of the rotating plates 37 positioned in the through holes are contacted with each other, the distance between the two rotating plates 37 positioned at the outer ends of the through holes is larger than the width of the through holes, a space is formed by the lower baffle plate 2 and the movable plate 4, when a plug is inserted, the plug is only required to be placed in the space and then force is applied to the through holes, the plug moves inwards along the inclined plane of the rotating plate 37 to the through holes, the length of the through holes is expanded, the plug is convenient to insert, the time consumed for aligning the socket is reduced, when the plug moves into the through holes along the rotating plates 37, the width of the plug is identical with the thickness of the two rotating plates 37 and the width of the through holes, so that the two rotating plates 37 move to the state as shown in fig. 9, then the plug is continuously pushed into the connecting cylinder 7 through wires, because the sliding block 33 is positioned at the upper side end of the sliding groove I55, the rotating plate 37 is positioned below the sleeve 35 and is contacted with the inner wall of the sliding block 54 so that the rotating plate cannot rotate, and the transmission block 38 is blocked at the lower end of the plug, so that when the plug is pushed, the plug drives the rotating plate 37, the sleeve 35, the shaft rod 37 and the sliding block 33 to move downwards together through the transmission block 38, and compresses the spring III 57 positioned between the rectangular block 315 and the sliding groove II 56 until the sliding block 33 moves to the lower end of the side surface of the sliding groove I55, the position of the rotating plate 37 below the sleeve 35 is separated from the inner wall of the sliding block 54 so that the rotating plate 37 can rotate around the shaft rod 37, the sliding block 33 can not move downwards any more, and therefore, after the plug is pushed continuously, the plug drives the rotating plate 37 and the sleeve 35 to rotate around the shaft rod 37 through the inclined surface of the transmission block 38, the lower end of the rotating plate 37 enters the groove 71, the limiting block 312 compresses the spring II 314 so that the transmission block 38 clamps the plug through the elasticity of the spring II 314, preventing the connecting tube 7 from shaking to cause loosening; as the plug is pushed continuously, the plug is finally inserted into the data interface 6 to the state shown in fig. 10, and the plug-in connection is completed; the arc-shaped groove 32 on the fixed plate 31 at the upper end of the rotating plate 37 fixes the lead connected with the plug, so that the plug is prevented from loosening due to the shaking of the lead under the stress;

when a plug is required to be pulled out, the movable plate 4 is rotated upwards in the state shown in fig. 1, the movable plate 4 is rotated by 90 degrees, the free end of the elastic telescopic rod I52 is pushed to move downwards in the process of rotating the movable plate 4, the limiting plate 51 is driven to move downwards together, the limiting plate 51 is enabled to move to be in contact with the inclined surface of the side surface of the sliding block 54, the elastic telescopic rod II 53 is always in a stretching state, after the limiting plate 51 moves downwards, the elastic telescopic rod II 53 is contracted, the two sliding blocks 54 are enabled to move reversely, the two rotating plates 37 are driven to move to a vertical state again, the transmission block 38 is enabled to be separated from the side surface of the plug, pressure is not applied to the transmission block, a worker pulls out the plug through a wire, the movable plate 4 is released after the plug is pulled out, the elastic telescopic rod I52 moves upwards under the action of elasticity, the sliding block 54 is pushed to a home position, after the plug is pulled out, the rotating plate 37 moves to the home position under the action of the spring III and the spring I314, and the connecting cylinder 7 is separated from the outside, and dust is reduced;

when dust is cleaned, the rotating plate 37 is pushed to be positioned at one end of the outer side of the shell 1 so as to move towards the shell 1, the side surface of the rotating plate 37 is contacted with the perforated inner wall, the rotating plate 37 slides relative to the connecting block 311, and the dust on the perforated inner wall is pushed to the upper end of the lower baffle plate 2, so that the dust is cleaned conveniently;

because sealing device 3 and movable device 5 are all made of metal, after the plug contacts with rotating plate 37, the static electricity attached to it will pour into shell 1 along with sealing device 3 and movable device 5 to finally flow out through grounding wire 8, avoiding the static electricity carried on the plug from directly contacting with data interface 6, resulting in burning loss of electronic components connected with data interface 6.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present disclosure describes embodiments, not every embodiment is provided with a separate embodiment, and that this description is provided for clarity only, and that the disclosure is not limited to the embodiments described in detail below, and that the embodiments described in the examples may be combined as appropriate to form other embodiments that will be apparent to those skilled in the art.

Claims (10)

1. An antistatic device for a dual-mode test assembly line is characterized in that: comprises a housing (1); the shell (1) is provided with a perforation, and a connecting cylinder (7) communicated with the perforation is fixedly connected inside the shell (1); a data interface (6) is fixedly connected in the connecting cylinder (7); the outer side of the shell (1) is fixedly connected with a grounding wire (8); a vertical chute I (55) is arranged on the inner wall of the through hole, and a chute II (56) is arranged on the inner wall of the chute I (55); the sliding groove I (55) and the sliding groove II (56) are in sliding fit with the sealing device (3).

2. The antistatic device for a dual-mode test line according to claim 1, wherein: the sealing device (3) comprises a sliding block (33), a shaft lever (34), a sleeve (35), a linkage rod (36), a rotating plate (37), a transmission block (38), a limiting block (312) and a spring I (314); the sliding block (33) is in sliding fit with the sliding groove I (55), and a rectangular block (315) in sliding fit with the sliding groove II (56) is fixedly connected to the side surface of the sliding block (33); a shaft lever (34) is fixedly connected between the two sliding blocks (33) positioned on the same side of the perforation, and a limiting block (312) is fixedly connected on the outer circular surface of the shaft lever (34); the sleeve (35) is sleeved on the corresponding shaft lever (34), and a limiting groove (313) which is in sliding fit with the limiting block (312) is formed in the inner wall of the sleeve (35); a spring I (314) is fixedly connected between the limiting groove (313) and the limiting block (312); the rotating plates (37) are fixedly connected to the outer circular surfaces of the corresponding sleeves (35), and the opposite surfaces of the two rotating plates (37) are fixedly connected with transmission blocks (38); a linkage rod (36) is fixedly connected between the two sliding blocks (33) positioned at the two sides of the perforation; the inner wall of the transmission is provided with a notch (12) which is in sliding fit with the linkage rod (36); two grooves (71) are symmetrically arranged on the inner wall of the connecting cylinder (7), and the rotating plate (37) is in sliding fit with the corresponding grooves (71).

3. The antistatic device for a dual-mode test line according to claim 2, wherein: the outer side of the shell (1) is fixedly connected with a lower baffle plate (2), and the lower baffle plate (2) is positioned at the lower end of the perforation.

4. The antistatic device for a dual-mode test line according to claim 2, wherein: a slide way I (39) is arranged on one side, close to the corresponding sleeve (35), of the rotating plate (37), a connecting block (311) in sliding fit with the slide way I (39) is arranged in the slide way I, and the connecting block (311) is fixedly connected with the corresponding sleeve (35); a spring II (310) is fixedly connected between the connecting block (311) and the inner wall of the slideway I (39).

5. The antistatic device for a dual-mode test line according to claim 2, wherein: the section of the transmission block (38) is triangular.

6. The antistatic device for a dual-mode test line according to claim 2, wherein: one end of the rotating plate (37) positioned at the outer side of the shell (1) is fixedly connected with a fixing plate (31), and one end of the fixing plate (31) away from the rotating plate (37) is provided with an arc-shaped groove (32) for fixing a wire.

7. The antistatic device for a dual-mode test line according to claim 2, wherein: slide ways II (11) are arranged on two sides of the perforation of the shell (1); a movable device (5) is arranged in the slide way II (11).

8. The antistatic device for a dual-mode test line of claim 7, wherein: the movable device (5) comprises a sliding block (54), a limiting plate (51), an elastic telescopic rod I (52) and an elastic telescopic rod II (53); the sliding chute I (55) and the sliding chute II (56) are arranged on the side face of the sliding block (54), and the sliding block (54) is in sliding fit with the sliding way II (11); the fixed end of the elastic telescopic rod I (52) is fixedly connected to the bottom surface of the slide way II (11), the side surface of the free end of the elastic telescopic rod I (52) is fixedly connected with a limiting plate (51), and the free end of the elastic telescopic rod I (52) is exposed above the slide way II (11); one end of the elastic telescopic rod II (53) is fixedly connected to the side face of the fixed end of the elastic telescopic rod I (52), and the other end of the elastic telescopic rod II (53) is fixedly connected to the side face of the sliding block (54); the upper end of the perforation of the shell (11) is hinged with a movable plate (4); the sealing device (3) and the movable device (5) are both made of metal.

9. The antistatic device for a dual-mode test line of claim 8, wherein: an inclined plane is arranged on one side, facing the elastic telescopic rod I (52), of the sliding block (54); after the movable plate (4) rotates by 90 degrees, the elastic telescopic rod I (52) is stressed and contracted, and the limiting plate (51) is driven to move downwards to contact with the inclined surface of the sliding block (54).

10. The method for using an antistatic device for a dual-mode test line according to claim 9, wherein: the using method comprises the following steps:

step one: pushing the plug into the connecting cylinder (7) along the inclined plane of the rotating plate (37); until the plug is inserted into the data interface (6);

step two: pushing the movable plate (4) to rotate, and pulling out the plug;

step three: the rotating plate (37) is pulled away from the shell (1) to clean dust.