CN117134174B

CN117134174B - High altitude cable joint crimping connection structure

Info

Publication number: CN117134174B
Application number: CN202311393397.0A
Authority: CN
Inventors: 马彦彬; 李晓冬; 刘金国; 徐猛; 支清壮; 赵国威; 张昱琦; 窦立坤; 刘亚帅; 陈飞虎; 倪建委; 张春生; 赵蛟; 王瑞雪; 李心言
Original assignee: State Grid Shandong Electric Power Co Qingyun County Power Supply Co
Current assignee: State Grid Shandong Electric Power Co Qingyun County Power Supply Co
Priority date: 2023-10-26
Filing date: 2023-10-26
Publication date: 2024-01-19
Anticipated expiration: 2043-10-26
Also published as: CN117134174A

Abstract

The invention discloses a high-altitude cable joint crimping connection structure, which relates to the field of cable connection and comprises a fixed bottom plate, wherein a supporting vertical frame is fixedly arranged behind the upper end of the fixed bottom plate, a pressing cross beam is movably arranged at the top of the supporting vertical frame, an air cylinder mounting block is movably arranged behind the inner side of the supporting vertical frame, and a pressing air cylinder is fixedly arranged at the lower end of the air cylinder mounting block. According to the high-altitude cable joint crimping connection structure, the crimping top block cannot block the upper portion of the crimping bottom block, the positioning guide wheel guides and positions the cable, the cable is more convenient to put in and take out, winding and locking of the ends of the multi-strand cable after crimping are achieved, loose falling of the ends of the cable is prevented, the firmness of compression connection is improved, long-term use of the cable is facilitated, a two-end crimping fixing structure is formed, the wound locking wire is positioned, and the cable is more firm in resistance to pulling.

Description

High altitude cable joint crimping connection structure

Technical Field

The invention belongs to the technical field of cable connection, and particularly relates to a high-altitude cable connector crimping connection structure.

Background

The high-altitude cable connector crimping connection structure is an installation structure for compacting and fixing the cable connector on the cable end, and after the high-altitude cable is laid, in order to enable the high-altitude cable to form a continuous line, all the high-altitude cables are connected, so that all the sections of cables are connected through the cable connector, the functions of locking and fixing the incoming and outgoing lines can be achieved, and the high-altitude cable crimping connection structure is an indispensable structure part in the process of conducting connection of the cables;

the chinese patent with publication No. CN111613955B discloses a crimping device of cable connector, which comprises a supporting plate, the top of backup pad leans on the rear side to be equipped with cable locating component, cable locating component includes locating plate one and locating plate two and realizes fixing a position to many cables simultaneously, the top of backup pad leans on the front side to be equipped with connector locating component ", although can play" can realize simultaneously with a plurality of joints spiral suit to accomplish the cable of skinning in advance on, and realize simultaneously with these joints crimping to the cable, compared with traditional manual work suit and crimping cable connector one by one, manpower cost and time consumption have been saved greatly, simultaneously the effect of crimping effect and crimping efficiency "has effectively been guaranteed, but current empty cable connector is when carrying out the crimping, the extrusion is carried out to the joint mainly through the mode of going up and down, make the inside firm laminating with the end of cable connector, realize cable connector's crimping fixed, and the mode of going up and down the extrusion is inconvenient for the cable wire put into and take out, and cable wire part is usually by the stranded constitution, when the end extrusion, the structure of stranded receives the extrusion and takes place to deform and produce the space after compressing down, consequently, the cable connector is pressed down and is taken place and is pressed down easily, cable wire connection only and is pulled firmly when only by the cable wire connection, the cable wire connection is not used, and cable connection is not good for long-term.

Disclosure of Invention

The invention aims to solve the technical problem of overcoming the defects in the prior art and providing a high-altitude cable connector crimping connection structure.

In order to achieve the above purpose, the present invention is realized by adopting the following technical scheme:

the utility model provides a high altitude cable joint crimping connection structure, includes the fixed baseplate, fixed mounting has the support grudging post in upper end rear of fixed baseplate, the top movable mounting of support grudging post has the push down crossbeam, the inboard rear movable mounting of support grudging post has the cylinder installation piece, the lower extreme fixed mounting of cylinder installation piece has the cylinder that pushes down, the upper end movable mounting of the piston rod of cylinder pushes down has the connecting block, the front end movable mounting of push down crossbeam has the swing joint axle, the lower extreme fixed mounting of swing joint axle has the installation roof, the lower extreme fixed mounting of installation roof has two crimping kicking blocks, the inboard bottom of crimping kicking block is equipped with top rotatory briquetting and top snap ring, and the rotatory briquetting in top is located one side of top snap ring, the inboard integrated into one piece of the rotatory briquetting in top has the top lug; the upper end of the fixed bottom plate is positioned in front of the supporting vertical frame and is fixedly provided with a bottom supporting frame, the upper end of the bottom supporting frame is fixedly provided with two compression joint bottom blocks, the top of the inner side of each compression joint bottom block is provided with a bottom rotary pressing block and a bottom clamping ring, the bottom rotary pressing block is positioned on one side of the bottom clamping ring, the inner side of each bottom rotary pressing block is integrally formed with a bottom convex block, the lower end of each compression joint bottom block is fixedly provided with a compression cylinder, and the upper end of a cylinder rod of each compression cylinder is fixedly provided with a compression block; one side fixed mounting of bottom sprag frame has motor frame, motor frame's upper end fixed mounting has rotating electrical machines and revolution mechanic, and the rotating electrical machines is located one side of rotating electrical machines, be equipped with the joint main part between crimping kicking block and the crimping backing block, the one end integrated into one piece of joint main part has the joint connecting plate, the outside of joint main part is equipped with two and compresses tightly the groove, the other end fixed mounting of joint main part has the locking line, the one end fixed mounting who connects the main part is kept away from to the locking line has the holding ring, the bottom of holding ring is equipped with the location indent, be equipped with the cable conductor between crimping kicking block and the crimping backing block.

Preferably, an oblique angle support frame is fixedly arranged at one side of the upper end of the fixed bottom plate, which is positioned at the bottom support frame, a guide wheel frame is fixedly arranged at the upper end of the oblique angle support frame, two positioning guide wheels are movably arranged at the upper end of the guide wheel frame, and a cable is lapped above the positioning guide wheels.

Preferably, the connecting block is movably connected with the rear inside of the pressing cross beam.

Preferably, the crimping top block is located the top of crimping bottom block and is connected rather than laminating, and the rotatory briquetting of top is connected and overlaps in the outside of connecting the main part with the rotatory briquetting laminating of bottom, and the top snap ring is connected and overlaps in the outside of holding ring with the laminating of bottom snap ring, and the rotatory briquetting of top and bottom is around the inside rotary motion of crimping top block and crimping bottom block.

Preferably, the end of the cable is inserted into the connector body through the locking wire and the locating ring, and the pressing block is pressed into the locating pressing groove upwards through the bottom clamping ring.

Preferably, the top lug and the bottom lug are pressed into the pressing groove, and the locking wires are arranged in a spiral mode.

Preferably, the rotating structure comprises a rotating gear, a synchronous belt, a joint rotating frame and a butt joint column, wherein the synchronous belt is in meshed transmission connection with the two rotating gears, the two joint rotating frames are respectively and fixedly arranged on one sides of the two rotating gears, and the butt joint column is fixedly arranged at the upper end of the joint rotating frame.

Preferably, the rotating shaft of the rotating motor is fixedly connected with the rotating gear in front, and the two rotating gears synchronously rotate through the synchronous belt.

Preferably, the butt-joint column is placed above the joint rotating frame, and penetrates through the joint connecting plate.

Compared with the prior art, the invention has the beneficial effects that:

1. the pressing top block moves upwards and backwards simultaneously when the pressing top block is separated from the pressing bottom block by rotating the pressing cross beam to press and lift the pressing top block to match with the guide of the positioning guide wheel, so that the pressing top block cannot block the upper part of the pressing bottom block, and the positioning guide wheel guides and positions the cable, thereby being more convenient for the placement and the taking-out of the cable;

2. through the rotation of the butt joint main body, when the butt joint main body is put in, the operation of the rotary motor is utilized to drive the joint connecting plate and the butt joint main body to rotate, the butt joint main body drives the end of the cable to rotate, so that the end of the multi-strand cable is wound and locked after crimping, and the end of the cable is prevented from loosening and falling;

3. through the winding to the locking line, when the joint main body and the cable wire end rotate, the locating ring is clamped by the top clamping ring and the bottom clamping ring and can not rotate, so that the joint main body simultaneously drives the locking line to rotate, the locking line is contracted and wound on the cable wire end to be firmly connected, the locking line is utilized to form a structure for wrapping the cable wire, the cable wire is firmly and comprehensively connected with the joint main body in a winding manner, the firmness of pressing connection is improved, and the long-term use of the cable wire is facilitated;

4. through compressing tightly to the holding ring, after the locking line winding is on the end of cable conductor, upwards pass the bottom snap ring by the messenger's compact heap and press to the bottom of holding ring to the bottom that makes the holding ring forms the constant head tank and carries out the crimping with the end of cable conductor and fix, forms two-end crimping fixed knot and constructs, and fixes a position the locking line after the winding, more firm anti-drag.

Drawings

FIG. 1 is a schematic diagram of the overall structure of a crimp connection structure of a high-altitude cable connector according to the present invention;

FIG. 2 is a rear view of a crimp connection of a high-altitude cable connector according to the present invention;

FIG. 3 is a raised view of a crimping jack in a high-altitude cable connector crimping connection structure of the present invention;

FIG. 4 is an enlarged view of the pressure joint top block and the pressure joint bottom block in the pressure joint connection structure of the high-altitude cable joint of the present invention;

FIG. 5 is a bottom view of a crimping top block in a high-altitude cable connector crimping connection structure according to the present invention;

FIG. 6 is a disassembled view of the connector body in the high-altitude cable connector crimping structure of the present invention;

FIG. 7 is a schematic view of a pressure joint block in a pressure joint connection structure of a high-altitude cable joint according to the present invention;

fig. 8 is a sectional view of a connector body in a crimp connection structure for a high-altitude cable connector according to the present invention.

In the figure: 1. a fixed bottom plate; 2. a bevel angle support; 3. a guide wheel frame; 4. positioning a guide wheel; 5. a supporting stand; 6. pressing down the cross beam; 7. a cylinder mounting block; 8. a pressing cylinder; 9. a piston rod; 10. a connecting block; 11. a movable connecting shaft; 12. installing a top plate; 13. crimping the top block; 14. a top rotary press block; 15. a top bump; 16. a top snap ring; 17. a bottom support frame; 18. crimping the bottom block; 19. a rotary pressing block at the bottom; 20. a bottom bump; 21. a bottom clasp; 22. a compacting cylinder; 23. a compaction block; 24. a motor frame; 25. a rotating electric machine; 26. a rotary gear; 27. a timing belt; 28. a joint rotating frame; 29. butt-joint columns; 30. a joint body; 31. a joint connection plate; 32. a compaction groove; 33. locking the wire; 34. a positioning ring; 35. positioning and pressing grooves; 36. a cable; 38. and (5) rotating the structure.

Detailed Description

The invention will now be further illustrated by means of specific examples in connection with the accompanying drawings.

Example 1:

as shown in fig. 1-8, a high-altitude cable joint crimping connection structure comprises a fixed bottom plate 1, a supporting vertical frame 5 is fixedly installed behind the upper end of the fixed bottom plate 1, a pressing cross beam 6 is movably installed at the top of the supporting vertical frame 5, a cylinder installation block 7 is movably installed behind the inner side of the supporting vertical frame 5, a pressing cylinder 8 is fixedly installed at the lower end of the cylinder installation block 7, a connecting block 10 is movably installed at the upper end of a piston rod 9 of the pressing cylinder 8, a movable connecting shaft 11 is movably installed at the front end of the pressing cross beam 6, a mounting top plate 12 is fixedly installed at the lower end of the movable connecting shaft 11, two crimping top blocks 13 are fixedly installed at the lower end of the mounting top plate 12, a top rotary pressing block 14 and a top clamping ring 16 are arranged at the inner side bottom of the crimping top rotary pressing block 13, a top lug 15 is integrally formed at the inner side of the top rotary pressing block 14; the upper end of the fixed bottom plate 1 is positioned in front of the supporting vertical frame 5 and is fixedly provided with a bottom supporting frame 17, the upper end of the bottom supporting frame 17 is fixedly provided with two compression joint bottom blocks 18, the top of the inner side of each compression joint bottom block 18 is provided with a bottom rotary pressing block 19 and a bottom clamping ring 21, the bottom rotary pressing block 19 is positioned on one side of each bottom clamping ring 21, the inner side of each bottom rotary pressing block 19 is integrally formed with a bottom protruding block 20, the lower end of each compression joint bottom block 18 is fixedly provided with a compression cylinder 22, and the upper end of a cylinder rod of each compression cylinder 22 is fixedly provided with a compression block 23; the motor frame 24 is fixedly mounted on one side of the bottom supporting frame 17, the rotating motor 25 and the rotating structure 38 are fixedly mounted on the upper end of the motor frame 24, the rotating motor 25 is located on one side of the rotating structure 38, the joint main body 30 is arranged between the press-connection top block 13 and the press-connection bottom block 18, the joint connecting plate 31 is integrally formed at one end of the joint main body 30, two pressing grooves 32 are formed in the outer portion of the joint main body 30, the locking wire 33 is fixedly mounted at the other end of the joint main body 30, the positioning ring 34 is fixedly mounted at one end, far away from the joint main body 30, of the locking wire 33, the positioning pressing groove 35 is formed in the bottom of the positioning ring 34, and the cable 36 is arranged between the press-connection top block 13 and the press-connection bottom block 18.

Example 2:

a high-altitude cable joint crimping connection structure is characterized in that an oblique angle support frame 2 is fixedly arranged on one side, located on the bottom support frame 17, of the upper end of a fixed bottom plate 1, a guide wheel frame 3 is fixedly arranged at the upper end of the oblique angle support frame 2, two positioning guide wheels 4 are movably arranged at the upper end of the guide wheel frame 3, and a cable 36 is lapped above the positioning guide wheels 4. The cable 36 is positioned by being placed above the positioning guide wheel 4, and is drawn by the rotation of the positioning guide wheel 4.

The connecting block 10 is movably connected with the inner rear of the pressing cross beam 6. In the embodiment, the piston rod 9 is driven to ascend by the operation of the pressing cylinder 8, and the piston rod 9 presses the pressing cross beam 6 to rotate around the supporting stand 5 through the connecting block 10, so that the front end of the pressing cross beam 6 moves downwards.

The crimping top block 13 is located above the crimping bottom block 18 and is in laminating connection with the crimping bottom block, the top rotary pressing block 14 is in laminating connection with the bottom rotary pressing block 19 and is sleeved on the outer side of the joint main body 30, the top clamping ring 16 is in laminating connection with the bottom clamping ring 21 and is sleeved on the outer side of the positioning ring 34, and the top rotary pressing block 14 and the bottom rotary pressing block 19 rotate around the inside of the crimping top block 13 and the crimping bottom block 18. In this embodiment, when the pressing top block 13 and the pressing bottom block 18 are combined, the top rotating pressing block 14 and the bottom rotating pressing block 19 and the top clamping ring 16 and the bottom clamping ring 21 are simultaneously driven to be combined.

The end of the cable 36 is inserted into the joint body 30 through the locking wire 33 and the positioning ring 34, the pressing block 23 is pressed into the positioning pressing groove 35 upward through the bottom clamping ring 21, and the pressing block 23 presses the positioning ring 34 upward to form the positioning pressing groove 35.

The top bump 15 and the bottom bump 20 are pressed into the pressing groove 32, the locking wires 33 are arranged in a spiral shape, and the top bump 15 and the bottom bump 20 press the joint body 30 to form the pressing groove 32.

The rotating structure 38 comprises a rotating gear 26, a synchronous belt 27, a joint rotating frame 28 and a butt joint column 29, wherein the synchronous belt 27 is in meshed transmission connection with the two rotating gears 26, the two joint rotating frames 28 are respectively and fixedly arranged on one sides of the two rotating gears 26, and the butt joint column 29 is fixedly arranged at the upper end of the joint rotating frames 28.

The rotating shaft of the rotating motor 25 is fixedly connected with the rotating gear 26 in front, the two rotating gears 26 synchronously rotate through the synchronous belt 27, the rotating motor 25 drives the rotating gears 26 to rotate, and the synchronous belt 27 synchronously drives.

The butt-joint column 29 is placed above the joint rotating frame 28, the butt-joint column 29 penetrates through the joint connecting plate 31, and the butt-joint column 29 is used for connecting the joint connecting plate 31 to drive the joint connecting plate 31 to rotate.

When the connector is used, as shown in fig. 3, the compression top block 13 and the compression bottom block 18 are in a separated state, the connector main body 30 is firstly placed into the compression bottom block 18, meanwhile, the connector main body 30 is positioned in the bottom rotary pressing block 19, the positioning ring 34 also falls into the inner side of the bottom clamping ring 21 to be connected in a matched manner, the end of the cable 36 passes through the locking wire 33 and the positioning ring 34 to be inserted into the connector main body 30, the piston rod 9 is driven to rise by the operation of the lower pressure cylinder 8, the piston rod 9 drives the front end of the lower pressure cross beam 6 to rotate and press downwards through the connecting block 10, so that the compression top block 13 at the front end of the lower pressure cross beam 6 is combined with the compression bottom block 18, the top rotary pressing block 14 at the inner side of the compression top block 13 is combined with the bottom rotary pressing block 19, the top convex block 15 and the bottom convex block 20 are extruded with the bottom rotary pressing block 19 to form the compression groove 32 by the extrusion of the connector main body 30, so that the inner wall of the connector main body 30 is protruded and is connected with the end of the cable 36 in a compression manner, and the connector main body 30 is compressed and connected with the end of the cable 36 in a compression manner;

the pressing cross beam 6 is rotated, pressed and lifted by the rotation of the pressing cross beam 6, the pressing cross beam 6 is rotated by taking the top of the supporting vertical frame 5 as a fulcrum, so that the front end of the pressing cross beam 6 is rotated, pressed and lifted, and when the pressing top block 13 is separated from the pressing bottom block 18, the pressing top block 13 moves upwards and also moves backwards at the same time, so that the pressing top block 13 cannot block the upper part of the pressing bottom block 18;

through the rotation of the joint main body 30, when the joint main body 30 is put in, the butt-joint column 29 is placed above the joint rotating frame 28, the butt-joint column 29 penetrates through the joint connecting plate 31, so when the joint main body 30 is crimped by the top rotating press block 14 and the bottom rotating press block 19, the rotating gear 26 and the joint rotating frame 28 are driven by the rotating motor 25 to rotate, the butt-joint column 29 drives the joint connecting plate 31 and the joint main body 30 to rotate, meanwhile, the top rotating press block 14 and the bottom rotating press block 19 rotate in the crimping top block 13 and the crimping bottom block 18, and when the joint main body 30 rotates, the positioning ring 34 is clamped by the top clamping ring 16 and the bottom clamping ring 21 and cannot rotate, and therefore the joint main body 30 drives the locking wire 33 to rotate, and the locking wire 33 is contracted and wound on the end of the cable 36 to be firmly connected;

through compressing the positioning ring 34, after the locking wire 33 is wound on the end of the cable 36, the compressing block 23 is driven to ascend by the operation of the compressing cylinder 22, so that the compressing block 23 passes through the bottom clamping ring 21 upwards to be compressed to the bottom of the positioning ring 34, and the bottom of the positioning ring 34 forms a positioning pressing groove 35, so that the protrusion of the inner wall of the positioning ring 34 is in compression joint and fixation with the end of the cable 36, a secondary fixing structure is formed, and the wound locking wire 33 is positioned.

Claims

1. A high altitude cable joint crimping connection structure, its characterized in that: the device comprises a fixed bottom plate (1), a supporting vertical frame (5) is fixedly arranged at the rear of the upper end of the fixed bottom plate (1), a pressing cross beam (6) is movably arranged at the top of the supporting vertical frame (5), an air cylinder mounting block (7) is movably arranged at the rear of the inner side of the supporting vertical frame (5), a pressing air cylinder (8) is fixedly arranged at the lower end of the air cylinder mounting block (7), a connecting block (10) is movably arranged at the upper end of a piston rod (9) of the pressing air cylinder (8), a movable connecting shaft (11) is movably arranged at the front end of the pressing cross beam (6), an installation top plate (12) is fixedly arranged at the lower end of the movable connecting shaft (11), two pressing top blocks (13) are fixedly arranged at the lower end of the installation top plate (12), a top rotary pressing block (14) and a top clamping ring (16) are arranged at the bottom of the inner side of the pressing top rotary pressing block (13), and a top protruding block (15) is integrally formed at the inner side of the top rotary pressing block (14); the upper end of the fixed bottom plate (1) is positioned in front of the supporting vertical frame (5) and is fixedly provided with a bottom supporting frame (17), the upper end of the bottom supporting frame (17) is fixedly provided with two compression joint bottom blocks (18), the top of the inner side of each compression joint bottom block (18) is provided with a bottom rotating press block (19) and a bottom clamping ring (21), the bottom rotating press block (19) is positioned on one side of each bottom clamping ring (21), the inner side of each bottom rotating press block (19) is integrally provided with a bottom bump (20), the lower end of each compression joint bottom block (18) is fixedly provided with a compression cylinder (22), and the upper end of a cylinder rod of each compression cylinder (22) is fixedly provided with a compression block (23); a motor frame (24) is fixedly arranged on one side of the bottom supporting frame (17), a rotating motor (25) and a rotating structure (38) are fixedly arranged at the upper end of the motor frame (24), the rotating motor (25) is positioned on one side of the rotating structure (38), a joint main body (30) is arranged between the crimping top block (13) and the crimping bottom block (18), a joint connecting plate (31) is integrally formed at one end of the joint main body (30), two compression grooves (32) are formed in the outer part of the joint main body (30), a locking wire (33) is fixedly arranged at the other end of the joint main body (30), a positioning ring (34) is fixedly arranged at one end, far away from the joint main body (30), of the locking wire (33), a positioning pressing groove (35) is formed at the bottom of the positioning ring (34), and a cable wire (36) is arranged between the crimping top block (13) and the crimping bottom block (18);

an oblique angle support frame (2) is fixedly arranged at one side of the bottom support frame (17) at the upper end of the fixed bottom plate (1), a guide wheel frame (3) is fixedly arranged at the upper end of the oblique angle support frame (2), two positioning guide wheels (4) are movably arranged at the upper end of the guide wheel frame (3), and a cable (36) is arranged above the positioning guide wheels (4); the rotating structure (38) comprises rotating gears (26), a synchronous belt (27), joint rotating frames (28) and a butt joint column (29), wherein the synchronous belt (27) is in meshed transmission connection with the two rotating gears (26), the two joint rotating frames (28) are respectively and fixedly arranged on one sides of the two rotating gears (26), and the butt joint column (29) is fixedly arranged at the upper end of the joint rotating frames (28);

the rotating shaft of the rotating motor (25) is fixedly connected with the rotating gear (26) in front, and the two rotating gears (26) synchronously rotate through a synchronous belt (27); the butt-joint column (29) is arranged above the joint rotating frame (28), and the butt-joint column (29) penetrates through the joint connecting plate (31).

2. The high-altitude cable joint crimping structure according to claim 1, wherein: the connecting block (10) is movably connected with the rear part of the inner side of the pressing cross beam (6).

3. The high-altitude cable joint crimping structure according to claim 2, wherein: the crimping ejector block (13) is located the top of crimping bottom block (18) and is connected with laminating, and top rotatory briquetting (14) are connected with bottom rotatory briquetting (19) laminating and cover in the outside of connecting main part (30), and top snap ring (16) are connected with bottom snap ring (21) laminating and cover in the outside of holding ring (34), and the inside rotatory activity of top rotatory briquetting (14) and bottom rotatory briquetting (19) around crimping ejector block (13) and crimping bottom block (18).

4. A high-altitude cable joint crimping connection structure according to claim 3, characterized in that: the end of the cable (36) passes through the locking wire (33) and the locating ring (34) to be inserted into the joint main body (30), and the compression block (23) passes through the bottom clamping ring (21) upwards to be pressed into the locating pressing groove (35).

5. The high-altitude cable joint crimping structure according to claim 4, wherein: the top protruding block (15) and the bottom protruding block (20) are pressed into the pressing groove (32), and the locking wires (33) are arranged in a spiral mode.