CN117937160A - Power cable connecting device - Google Patents

Abstract

The present invention relates to the field of cable connections. The invention discloses a power cable connecting device, which aims to solve the problems that the existing cable connecting device has complex operation for connecting cables, various crimping and clamping tools are needed, and the processing of connecting nodes consumes more time; in addition, the accurate execution of the connection process standard is difficult to control, so that the connection quality of the connection node is difficult to realize effective control. The invention consists of a lock sleeve mechanism, a lock sub mechanism and a collision sealing piece. This power cable connecting device forms the ring body between four second sealing blocks after expanding through four first sealing blocks card on the first pipe, increases the leakproofness after sleeve inner wall and the sleeve pipe connection, finally through the L shape on the pipe conflict pinion rack one end first spring telescopic link card go into between taper arc board and the baffle, fixes sleeve pipe and sleeve after the butt joint, simple to operate.

Description

Power cable connecting device

Technical Field

The invention relates to the field of cable connection, in particular to a power cable connection device.

Background

Cables are a common tool in communications engineering, typically in the form of a rope of stranded wires or groups of wires, each group of wires being insulated from each other and often twisted about a center. The cable is sometimes subjected to connection processing as required during use.

The traditional cable connection mode is very simple, only the corresponding connection node of the cable is fixed by adopting a clamp or a lantern ring, and some cables are wrapped outside by using aluminum foil paper or insulating materials, so that the effect of sealing the connection node is achieved, but the following defects exist in the following modes: the connection operation is complex, various crimping and clamping tools are needed, and the processing of the connection nodes consumes more time; in addition, the accurate execution of the connection process standard is difficult to control, so that the connection quality of the connection node is difficult to realize effective control.

Disclosure of Invention

The invention aims to provide a power cable connecting device, which solves the problems that the prior cable connecting device proposed in the background technology is complex in cable connecting operation, various crimping and caliper tools are needed, and the processing of connecting nodes consumes more time; in addition, the accurate execution of the connection process standard is difficult to control, so that the connection quality of the connection node is difficult to realize effective management and control.

In order to achieve the above purpose, the present invention provides the following technical solutions: the power cable connecting device comprises a first fixed pipe and a second fixed pipe, wherein a lock sleeve mechanism is arranged on the first fixed pipe, a lock sub-mechanism is arranged on the second fixed pipe, and the first fixed pipe is connected with the lock sub-mechanism on the second fixed pipe through the lock sleeve mechanism on the first fixed pipe, so that two cables in the first fixed pipe and the second fixed pipe are connected;

the lock sleeve mechanism comprises a sleeve fixedly sleeved on the outer wall of the first fixed pipe, and a ring groove is formed in the left side of the inner wall of the sleeve;

the right side of sleeve outer wall is provided with a thread, the right end inner wall of sleeve is provided with a slot, and the inner wall of sleeve is fixedly connected with a fixed circular tube.

Preferably, the left end of the outer wall of the sleeve is rounded.

Preferably, the lock sub mechanism comprises a sleeve fixedly sleeved on the outer wall of the second fixed pipe, the outer wall of the sleeve is fixedly connected with a convex block, and the convex block is inserted in the slot to prevent the sleeve from rotating relative to the sleeve;

An L-shaped through groove is formed in the inner wall of the sleeve, an L-shaped abutting toothed plate is slidably arranged in the L-shaped through groove, one end of the L-shaped abutting toothed plate extends into the first fixed pipe and is fixedly connected with a first spring telescopic rod, and one end of the first spring telescopic rod, facing the central axis of the sleeve, is an inclined plane;

The outer wall of the sleeve is rotationally connected with a nut sleeve, the nut sleeve is connected to the right end face of the outer wall of the sleeve through threads, the right end face of the nut sleeve is rotationally connected with an internal thread pipe, a rotary gear is meshed in the internal thread pipe, the rotary gear is rotationally connected in an L-shaped through groove, and the rotary gear is meshed with an L-shaped abutting toothed plate;

the inner wall of the sleeve is provided with a collision sealing piece.

Preferably, the abutting sealing piece comprises a first circular tube fixedly connected to the left end face of the sleeve, the first circular tube is slidably sleeved on the outer wall of the fixed circular tube, four arc-shaped pushing plates are fixedly connected to the outer wall of the first circular tube, one end of each arc-shaped pushing plate is hinged with two first deflection plates, a second spring telescopic rod is hinged between the left side of each first deflection plate and the outer wall of each arc-shaped pushing plate, and one end, far away from each arc-shaped pushing plate, of each first deflection plate is hinged with a first sealing block;

The inner sides of the four arc-shaped pushing plates are slidably provided with second round pipes, fixed spring telescopic rods are connected between the second round pipes and the first round pipes, second deflection plates are hinged to the outer walls of the second round pipes, third spring telescopic rods are hinged between the second deflection plates and the outer walls of the second round pipes, second sealing blocks are hinged to one ends, far away from the second round pipes, of the second deflection plates, and the four second sealing blocks are in staggered and abutting contact with the four first sealing blocks to form a ring body and are in abutting contact with the ring groove;

The outer wall of the second circular tube is fixedly connected with a spring shrinkage tube, the outer wall of the spring shrinkage tube is fixedly connected with a conical arc plate, the conical arc plate is attached to and slides on the outer wall of the second circular tube, the outer wall of the second circular tube is fixedly connected with a baffle plate, the baffle plate is arranged on the right side of the conical arc plate, and the left side of the baffle plate is abutted against one side of the first spring expansion link;

and the first sealing block is provided with a plug locking piece.

Preferably, the plug locking piece comprises an arc-shaped hollow block fixed on the right side of the second sealing block, the inner wall of the arc-shaped hollow block is fixedly connected with a power spring telescopic rod, and the left side and the right side of the power spring telescopic rod are fixedly connected with inclined plane pushing plates;

the left side and the right side in the arc-shaped hollow block are hinged with fourth spring telescopic rods, an L-shaped inserting rod is hinged between the two fourth spring telescopic rods, one end of the L-shaped inserting rod extends to the outer wall of the arc-shaped hollow block, one end of the L-shaped inserting rod, which is positioned on the outer wall of the arc-shaped hollow block, is wrapped with a connecting arc block, the connecting arc block is fixed on the right side of the first sealing block, and four connecting arc blocks and four arc-shaped hollow blocks are staggered to form a ring body;

The clamping plate is hinged to the inner wall of the arc-shaped hollow block, one end of the clamping plate is clamped on the L-shaped inserted link, the other end of the clamping plate is hinged to the return spring telescopic link, one end of the return spring telescopic link, far away from the clamping plate, is hinged to the inner wall of the arc-shaped hollow block, one end of the clamping plate, far away from the L-shaped inserted link, is hinged to the deflection plate, and a tension spring is connected between the deflection plate and one end of the clamping plate;

One side of the deflection plate is lapped with a trigger rod, and one end of the trigger rod extends to the outside of the arc-shaped hollow block and is fixed on the connecting arc block.

Preferably, one end of the trigger rod far away from the connecting arc block is subjected to corner cutting treatment.

Preferably, two arc-shaped tangential planes are formed at the outer edges of the first sealing block and the second sealing block, and the left ends of the first sealing block and the second sealing block are abutted against the end face of the inner wall of the sleeve.

Preferably, the left side of the baffle plate is provided with a cambered surface for accommodating the conical cambered plate.

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

According to the invention, the convex blocks on the outer side of the sleeve are clamped into the slots to finish the butt joint of the sleeve and the sleeve, then the four first sealing blocks on the first circular tube are clamped between the four unfolded second sealing blocks to form the ring body, the tightness of the inner wall of the sleeve after the sleeve is connected with the sleeve is improved, and finally the sleeve and the sleeve after the butt joint are fixed through the first spring telescopic rod on one end of the L-shaped abutting toothed plate clamped between the conical arc plate and the baffle, so that the installation is simple and convenient.

According to the invention, after the four first sealing blocks are clamped between the four unfolded second sealing blocks, the trigger rod on the right end face of the first sealing block is inserted into the arc-shaped hollow block along the insertion opening formed in the surface of the arc-shaped hollow block, and is abutted against one end of the deflection plate far away from the inclined plane push plate, the deflection force of the deflection plate on the L-shaped insertion rod is relieved through the deflection of the deflection plate, at the moment, the L-shaped insertion rod extends out of the inside of the arc-shaped hollow block under the action of the pushing force of the fourth spring telescopic rod and is inserted into the insertion opening formed in the end face of the connecting arc-shaped hollow block, so that the locking of the contact end face of the connecting arc-shaped block and the arc-shaped hollow block is completed, the dislocation between the connecting arc-shaped block and the arc-shaped hollow block is avoided, and the stability of the connection between the connecting arc-shaped hollow block and the arc-shaped hollow block is ensured.

According to the invention, the L-shaped pushing toothed plate is driven to rotate by rotating the internal threaded pipe to pull the rotary gear to move left, so that the L-shaped inserting rod is pulled out from the connecting arc block and moves towards the direction close to the power spring telescopic rod, when the inclined plane pushing plate is separated from the L-shaped inserting rod, the L-shaped inserting rod is pushed against one end of the clamping plate far away from the trigger rod and is pushed against the outer wall of the conical arc plate in the process of moving left of the L-shaped pushing toothed plate, when the L-shaped pushing toothed plate moves left, the first spring telescopic rod on the left end of the L-shaped pushing toothed plate is compressed and moves to the left side of the conical arc plate, the nut sleeve is rotated to separate from threads on the outer wall of the sleeve, and then a user pulls the sleeve left, so that the first spring telescopic rod on the left end of the sleeve extrudes the conical arc plate to move right to be clamped in the cambered surface groove on the left side of the baffle, and the first spring telescopic rod is guaranteed to move right to the right of the baffle, and separation of the sleeve and the sleeve is completed.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a cross-sectional view of a three-dimensional structure of the present invention;

FIG. 3 is a cross-sectional view of a three-dimensional expanded structure of the present invention;

FIG. 4 is a cross-sectional view of a three-dimensional expanded structure of the present invention;

FIG. 5 is a schematic perspective view of a conflicting seal of the present invention;

FIG. 6 is a schematic perspective view of a second embodiment of a conflicting seal;

FIG. 7 is a schematic view of a partial perspective view of a interference seal and plug lock of the present invention;

FIG. 8 is a schematic view of a three-dimensional deployment of the interference seal of the present invention;

FIG. 9 is a cross-sectional view of a three-dimensional expanded structure of the arcuate hollow block of the present invention;

Fig. 10 is a schematic perspective view of the plug lock of the present invention.

In the figure: 1. a first fixed tube; 2. a second fixed tube; 3. a lock sleeve mechanism; 31. a sleeve; 32. a ring groove; 33. a thread; 34. a slot; 35. fixing the round tube; 4. a lock mechanism; 41. a sleeve; 42. a bump; 43. an L-shaped through groove; 44. l-shaped abutting toothed plates; 45. a first spring telescoping rod; 46. a nut sleeve; 47. an internally threaded tube; 48. a rotary gear; 5. a conflicting seal; 51. a first round tube; 52. an arc push plate; 53. a first deflector plate; 54. a second spring telescoping rod; 55. a first sealing block; 56. a second round tube; 57. a second deflector plate; 58. a third spring telescoping rod; 59. a second sealing block; 510. a spring shrink tube; 511. a conical arc plate; 512. a baffle; 513. a fixed spring telescopic rod; 6. a plug-in locking piece; 61. arc hollow blocks; 62. a power spring telescopic rod; 63. an inclined plane pushing plate; 64. a fourth spring telescoping rod; 65. an L-shaped insert rod; 66. connecting arc blocks; 67. a clamping plate; 68. a return spring telescoping rod; 69. a deflector plate; 610. a trigger lever.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which are obtained by a worker of ordinary skill in the art without creative efforts, are within the protection scope of the present invention based on the embodiments of the present invention.

Referring to fig. 1 to 10, the present invention provides a technical solution: the utility model provides a power cable connecting device, includes first fixed pipe 1 and second fixed pipe 2, is provided with lock sleeve mechanism 3 on the first fixed pipe 1, is provided with lock sub-mechanism 4 on the second fixed pipe 2, is connected with lock sub-mechanism 4 on the second fixed pipe 2 through lock sleeve mechanism 3 on the first fixed pipe 1, connects two cables in the fixed pipe 1 of first and the fixed pipe 2 of second.

The lock sleeve mechanism 3 comprises a sleeve 31 fixedly sleeved on the outer wall of the first fixed pipe 1, and a ring groove 32 is formed in the left side of the inner wall of the sleeve 31. The right side of sleeve 31 outer wall has offered screw thread 33, has offered slot 34 on the right-hand member inner wall of sleeve 31, fixedly connected with fixed pipe 35 on the inner wall of sleeve 31.

In this embodiment, as shown in fig. 1 and 4, the left end of the outer wall of the sleeve 31 is rounded.

In this embodiment, as shown in fig. 1,2, 3 and 4, the lock mechanism 4 includes a sleeve 41 fixedly sleeved on the outer wall of the second fixed tube 2, a protruding block 42 is fixedly connected to the outer wall of the sleeve 41, and the protruding block 42 is inserted into the slot 34 to prevent the sleeve 41 from rotating relative to the sleeve 31.

An L-shaped through groove 43 is formed in the inner wall of the sleeve 41, a vertical groove of the L-shaped through groove 43 is formed in the outer wall of the sleeve 41, a transverse groove of the L-shaped through groove 43 is formed in the left end face of the sleeve 41, an L-shaped abutting toothed plate 44 is slidably arranged in the L-shaped through groove 43, one end of the L-shaped abutting toothed plate 44 can slide in the L-shaped through groove 43, the end of the L-shaped abutting toothed plate 44 extends to the inside of the first fixed pipe 1 and is fixedly connected with a first spring telescopic rod 45, and one end of the first spring telescopic rod 45, facing the central axis of the sleeve 41, is an inclined plane.

The outer wall of the sleeve 41 is rotationally connected with a nut sleeve 46, the nut sleeve 46 is connected to the right end face of the outer wall of the sleeve 31 through threads 33, the right end face of the nut sleeve 46 is rotationally connected with an internal thread pipe 47, a rotary gear 48 is meshed in the internal thread pipe 47, the rotary gear 48 is rotationally connected in the L-shaped through groove 43, the rotary gear 48 is meshed with the L-shaped abutting toothed plate 44, further, the rotary gear 48 is provided with a worm wheel, and the internal thread pipe 47 and the rotary gear 48 are combined into a worm and gear mechanism; the inner wall of the sleeve 41 is provided with a interference seal 5.

In this embodiment, as shown in fig. 2,3, 4, 5, 6, 7 and 8, the abutting seal 5 includes a first circular tube 51 fixedly connected to the left end face of the sleeve 41, the first circular tube 51 is slidably sleeved on the outer wall of the fixed circular tube 35, four arc push plates 52 are fixedly connected to the outer wall of the first circular tube 51, one end of the arc push plate 52 is hinged with two first deflection plates 53, a second spring expansion link 54 is hinged between the left side of the two first deflection plates 53 and the outer wall of the arc push plate 52, and one end of the two first deflection plates 53 far away from the arc push plate 52 is hinged with a first seal block 55.

The inner sides of the four arc pushing plates 52 are slidably provided with second round pipes 56, fixed spring telescopic rods 513 are connected between the second round pipes 56 and the first round pipes 51, second deflection plates 57 are hinged to the outer walls of the second round pipes 56, third spring telescopic rods 58 are hinged between the second deflection plates 57 and the outer walls of the second round pipes 56, second sealing blocks 59 are hinged to one ends, far away from the second round pipes 56, of the second deflection plates 57, and the four second sealing blocks 59 are in staggered and abutting contact with the four first sealing blocks 55 to form a ring body and are in abutting contact with the ring groove 32; the second sealing block 59 and the first sealing block 55 are arc-shaped, and two arc-shaped tangential planes are arranged on one sides of the first sealing block 55 and the second sealing block 59, which are far away from the fixed circular tube 35, so that the first sealing block 55 and the second sealing block 59 can be better clamped into the annular groove 32. Sealing rubber is arranged on the arc-shaped tangential surfaces of the first sealing block 55 and the second sealing block 59.

The outer wall of the second circular tube 56 is fixedly connected with a spring shrinkage tube 510, the outer wall of the spring shrinkage tube 510 is fixedly connected with a conical arc plate 511, the conical arc plate 511 is attached to and slides on the outer wall of the second circular tube 56, the outer wall of the second circular tube 56 is fixedly connected with a baffle 512, the baffle 512 is arranged on the right side of the conical arc plate 511, and the left side of the baffle 512 is abutted against one side of the first spring expansion link 45.

The first sealing block 55 is fitted with a plug lock 6.

In this embodiment, as shown in fig. 3, 6, 7, 8, 9 and 10, the plug-in locking piece 6 includes an arc-shaped hollow block 61 fixed on the right side of the second sealing block 59, the inner wall of the arc-shaped hollow block 61 is fixedly connected with a power spring telescopic rod 62, and both the left and right sides of the power spring telescopic rod 62 are fixedly connected with inclined push plates 63; the side of the inclined push plate 63 remote from the power spring telescoping rod 62 is an inclined surface.

The left side and the right side in the arc-shaped hollow block 61 are hinged with fourth spring telescopic rods 64, an L-shaped inserting rod 65 is hinged between the two fourth spring telescopic rods 64, one end of the L-shaped inserting rod 65 extends to the outer wall of the arc-shaped hollow block 61, one end of the L-shaped inserting rod 65, which is positioned on the outer wall of the arc-shaped hollow block 61, is wrapped with a connecting arc block 66, the connecting arc block 66 is fixed on the right side of the first sealing block 55, and four connecting arc blocks 66 and four arc-shaped hollow blocks 61 are staggered to form a ring body; the L-shaped inserting rod 65 is provided with a bulge at one end far away from the connecting arc block 66, and the bulge is extruded by the movement of the inclined-plane pushing plate 63 to drive the L-shaped inserting rod 65 to move to one side close to the power spring telescopic rod 62.

A clamping plate 67 is hinged to the inner wall of the arc-shaped hollow block 61, one end of the clamping plate 67 is clamped on the L-shaped inserting rod 65, the other end of the clamping plate 67 is hinged to a return spring telescopic rod 68, one end of the return spring telescopic rod 68, which is far away from the clamping plate 67, is hinged to the inner wall of the arc-shaped hollow block 61, one end of the clamping plate 67, which is far away from the L-shaped inserting rod 65, is hinged to a deflection plate 69, and a tension spring is connected between the deflection plate 69 and one end of the clamping plate 67; and the deflector plate 69 rotates a maximum angle of one hundred eighty degrees on the card 67. The user pulls sleeve 41 to the left for the first spring telescopic link 45 of sleeve 41 left end extrudees cone arc board 511, and cone arc board 511 moves the card to the right behind the cambered surface inslot of baffle 512 left side, guarantees behind the compression of first spring telescopic link 45 move to the right, slides to the right side of baffle 512 along the outside of baffle 512, accomplishes sleeve 41 and sleeve 31's separation, and extrudes deflection plate 69 deflection when simultaneously trigger lever 610 shifts out from arc hollow piece 61, guarantees that trigger lever 610 can stable follow the shifting out in the arc hollow piece 61.

One side of the deflection plate 69 is overlapped with the trigger lever 610, and one end of the trigger lever 610 extends to the outside of the arc-shaped hollow block 61 and is fixedly connected with the arc block 66.

In this embodiment, as shown in fig. 3, 6, 7, 8, 9 and 10, the end of the trigger rod 610 far from the connecting arc block 66 is subjected to corner cutting, the trigger rod 610 is composed of a cross rod and an L-shaped rod, and the trigger rod 610 can be pulled out from the arc-shaped hollow block 61.

In this embodiment, as shown in fig. 2,3, 4, 5, 6, 7, 8 and 9, two arc-shaped tangential planes are respectively provided at the outer edges of the first sealing block 55 and the second sealing block 59, and the left ends of the first sealing block 55 and the second sealing block 59 are respectively abutted against the end surface of the inner wall of the sleeve 31.

In this embodiment, as shown in fig. 2,3, 4,5, 6, 7, 8 and 9, a cambered surface groove for accommodating the conical cambered plate 511 is formed on the left side of the baffle 512.

The operation process of the using method of the power cable connecting device is as follows:

As shown in fig. 1,2,3,4, 5, 6, 7, 8, 9, and 10: when the device is used for connecting cables, two cables are respectively fixed in the first fixed pipe 1 and the second fixed pipe 2, then the sleeve 41 is held to insert the abutting sealing piece 5 on the sleeve into the sleeve 31, and at the moment, the sleeve 41 is clamped into the slot 34 through the lug 42 at the outer side of the sleeve 41, so that the butt joint of the sleeve 41 and the sleeve 31 is completed;

So that the four second sealing blocks 59 abutting against the sealing member 5 firstly enter the sleeve 31 and are sleeved on the outer side of the fixed circular tube 35, when the four second sealing blocks 59 abut against the left end face of the inner wall of the sleeve 31, the second circular tube 56 continues to move left to drive the left end face of the four second sealing blocks 59 to slide and spread on the left end face of the inner wall of the sleeve 31 and abut against the inner wall of the annular groove 32.

Then, the first round tube 51 on the sleeve 41 is pushed to move towards the inside of the sleeve 31, at this time, since the second sealing blocks 59 are clamped on the inner wall of the ring groove 32, the first round tube 51 is pushed to move left to press and fix the spring telescopic rod 513 to shrink, and the first sealing blocks 55 on the left end of the first round tube are driven to move left and are pushed to slide and spread on the left end face of the inner wall of the sleeve 31, so that the four first sealing blocks 55 on the first round tube 51 are clamped between the four spread second sealing blocks 59 to form a ring body, and the tightness of the inner wall of the sleeve 31 after being connected with the sleeve 41 is increased.

And when the four first sealing blocks 55 are clamped between the four expanded second sealing blocks 59, the first spring telescopic rod 45 driving one end of the L-shaped abutting toothed plate 44 on the sleeve 41 is clamped between the conical arc plate 511 and the baffle 512, the sleeve 41 and the sleeve 31 after being abutted are fixed, and then the sleeve 31 and the sleeve 41 are connected through threads by rotating the nut sleeve 46, namely, the connection of the sleeve 31 and the sleeve 41 is completed.

After the four first sealing blocks 55 are clamped between the four unfolded second sealing blocks 59, a trigger rod 610 on the right end face of the first sealing block 55 is inserted into the arc-shaped hollow block 61 along a socket formed in the surface of the arc-shaped hollow block 61, and abuts against one end of a deflection plate 69 far away from the inclined plane push plate 63, the abutting force of the deflection plate 69 on the L-shaped inserting rod 65 is relieved through the deflection of the deflection plate 69, at the moment, the L-shaped inserting rod 65 extends out of the inside of the arc-shaped hollow block 61 under the action of the pushing force of the fourth spring telescopic rod 64 and is inserted into a socket formed in the end face of the arc-shaped hollow block 66, locking of the contact end face of the arc-shaped hollow block 66 and the arc-shaped hollow block 61 is completed, dislocation between the arc-shaped hollow block 66 and the arc-shaped hollow block 61 is avoided, and stability of connection between the arc-shaped hollow block 66 and the arc-shaped hollow block 61 is ensured.

When two cables are required to be disassembled, the internal thread pipe 47 is rotated to drive the rotary gear 48 to rotate, the L-shaped abutting toothed plate 44 is pulled to move left, the power spring telescopic rod 62 is abutted and pushed to compress when the L-shaped abutting toothed plate 44 moves left, the inclined plane push plate 63 is pushed to move left to squeeze one end of the L-shaped inserting rod 65 when the power spring telescopic rod 62 is compressed, the L-shaped inserting rod 65 is pulled out of the connecting arc block 66 and moves towards the direction close to the power spring telescopic rod 62, and after the inclined plane push plate 63 and the L-shaped inserting rod 65 are separated, the L-shaped inserting rod 65 abuts against one end of the clamping plate 67 far away from the trigger rod 610;

and in the process of moving left the L-shaped abutting toothed plate 44, the abutting is performed on the outer wall of the conical arc plate 511, because the spring shrinkage tube 510 is in the shortest compression length, when the L-shaped abutting toothed plate 44 moves left, the first spring expansion rod 45 on the left end of the L-shaped abutting toothed plate is compressed and moves to the left side of the conical arc plate 511, the nut sleeve 46 is rotated to separate from the threads 33 on the outer wall of the sleeve 31, and then the sleeve 41 is pulled left by a user, so that after the first spring expansion rod 45 on the left end of the sleeve 41 extrudes the conical arc plate 511 to move right and be clamped in the cambered surface groove on the left side of the baffle 512, the first spring expansion rod 45 is guaranteed to move right to the right side of the baffle 512, and the sleeve 41 and the sleeve 31 are separated.

The foregoing has shown and described the basic principles, principal features and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present invention, and are not intended to limit the invention, and that various changes and modifications may be made therein without departing from the spirit and scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (8)

1. Power cable connecting device, including first fixed pipe (1) and second fixed pipe (2), its characterized in that: the first fixed pipe (1) is provided with a lock sleeve mechanism (3), the second fixed pipe (2) is provided with a lock sub-mechanism (4), and the lock sleeve mechanism (3) on the first fixed pipe (1) is connected with the lock sub-mechanism (4) on the second fixed pipe (2) to connect two cables in the first fixed pipe (1) and the second fixed pipe (2);

The lock sleeve mechanism (3) comprises a sleeve (31) fixedly sleeved on the outer wall of the first fixed pipe (1), and a ring groove (32) is formed in the left side of the inner wall of the sleeve (31);

The right side of sleeve (31) outer wall has offered screw thread (33), slot (34) have been seted up on the right-hand member inner wall of sleeve (31), fixedly connected with fixed pipe (35) on the inner wall of sleeve (31).

2. A power cable connection device according to claim 1, characterized in that: the left end of the outer wall of the sleeve (31) is subjected to rounding treatment.

3. A power cable connection device according to claim 1, characterized in that: the lock sub mechanism (4) comprises a sleeve (41) fixedly sleeved on the outer wall of the second fixed pipe (2), a lug (42) is fixedly connected to the outer wall of the sleeve (41), and the lug (42) is inserted into the slot (34) to prevent the sleeve (41) from rotating relative to the sleeve (31);

an L-shaped through groove (43) is formed in the inner wall of the sleeve (41), an L-shaped abutting toothed plate (44) is arranged in the L-shaped through groove (43) in a sliding mode, one end of the L-shaped abutting toothed plate (44) extends into the first fixed pipe (1) and is fixedly connected with a first spring telescopic rod (45), and one end of the first spring telescopic rod (45) facing the central axis of the sleeve (41) is an inclined plane;

The outer wall of the sleeve (41) is rotationally connected with a nut sleeve (46), the nut sleeve (46) is connected to the right end face of the outer wall of the sleeve (31) through threads (33), the right end face of the nut sleeve (46) is rotationally connected with an inner threaded pipe (47), a rotary gear (48) is meshed in the inner threaded pipe (47), the rotary gear (48) is rotationally connected in an L-shaped through groove (43), and the rotary gear (48) is meshed with an L-shaped abutting toothed plate (44);

The inner wall of the sleeve (41) is provided with a collision sealing piece (5).

4. A power cable connection device according to claim 3, characterized in that: the abutting sealing piece (5) comprises a first circular tube (51) fixedly connected to the left end face of the sleeve (41), the first circular tube (51) is sleeved on the outer wall of the fixed circular tube (35) in a sliding mode, four arc-shaped pushing plates (52) are fixedly connected to the outer wall of the first circular tube (51), two first deflection plates (53) are hinged to one end of each arc-shaped pushing plate (52), a second spring telescopic rod (54) is hinged between the left side of each first deflection plate (53) and the outer wall of each arc-shaped pushing plate (52), and a first sealing block (55) is hinged to one end, far away from each arc-shaped pushing plate (52), of each first deflection plate (53);

The inner sides of the four arc pushing plates (52) are slidably provided with second round pipes (56), fixed spring telescopic rods (513) are connected between the second round pipes (56) and the first round pipes (51), second deflection plates (57) are hinged to the outer walls of the second round pipes (56), third spring telescopic rods (58) are hinged between the second deflection plates (57) and the outer walls of the second round pipes (56), second sealing blocks (59) are hinged to one ends, far away from the second round pipes (56), of the second deflection plates (57), and the four second sealing blocks (59) are in staggered and abutting contact with the four first sealing blocks (55) to form a ring body and are in abutting contact with the ring groove (32);

The outer wall of the second circular tube (56) is fixedly connected with a spring shrinkage tube (510), the outer wall of the spring shrinkage tube (510) is fixedly connected with a conical arc plate (511), the conical arc plate (511) is attached and slides on the outer wall of the second circular tube (56), the outer wall of the second circular tube (56) is fixedly connected with a baffle plate (512), the baffle plate (512) is arranged on the right side of the conical arc plate (511), and the left side of the baffle plate (512) is abutted against one side of the first spring expansion link (45);

The first sealing block (55) is provided with a plug-in locking piece (6).

5. A power cable connection device according to claim 4, wherein: the plug-in locking piece (6) comprises an arc-shaped hollow block (61) fixed on the right side of the second sealing block (59), a power spring telescopic rod (62) is fixedly connected to the inner wall of the arc-shaped hollow block (61), and inclined plane pushing plates (63) are fixedly connected to the left side and the right side of the power spring telescopic rod (62);

The left side and the right side in the arc-shaped hollow block (61) are hinged with fourth spring telescopic rods (64), an L-shaped inserting rod (65) is hinged between the two fourth spring telescopic rods (64), one end of the L-shaped inserting rod (65) extends to the outer wall of the arc-shaped hollow block (61), one end of the L-shaped inserting rod (65) positioned on the outer wall of the arc-shaped hollow block (61) is wrapped with a connecting arc block (66), the connecting arc block (66) is fixed on the right side of the first sealing block (55), and four connecting arc blocks (66) and the four arc-shaped hollow blocks (61) are staggered to form a ring body;

The novel clamping device is characterized in that a clamping plate (67) is hinged to the inner wall of the arc-shaped hollow block (61), one end of the clamping plate (67) is clamped on an L-shaped inserting rod (65), the other end of the clamping plate (67) is hinged to a return spring telescopic rod (68), one end, far away from the clamping plate (67), of the return spring telescopic rod (68) is hinged to the inner wall of the arc-shaped hollow block (61), a deflection plate (69) is hinged to one end, far away from the L-shaped inserting rod (65), of the clamping plate (67), and a tension spring is connected between the deflection plate (69) and one end of the clamping plate (67);

one side of the deflection plate (69) is lapped with a trigger rod (610), and one end of the trigger rod (610) extends to the outside of the arc-shaped hollow block (61) and is fixed on the connecting arc block (66).

6. A power cable connection device according to claim 5, wherein: and one end of the trigger rod (610) far away from the connecting arc block (66) is subjected to corner cutting treatment.

7. A power cable connection device according to claim 4, wherein: two arc-shaped tangential planes are formed at the outer edges of the first sealing block (55) and the second sealing block (59), and the left ends of the first sealing block (55) and the second sealing block (59) are abutted against the end face of the inner wall of the sleeve (31).

8. A power cable connection device according to claim 4, wherein: the left side of the baffle plate (512) is provided with a cambered surface groove for accommodating the conical cambered plate (511).