CN214280790U - Cable protection device - Google Patents

Abstract

The utility model provides a cable protection device, this cable protection device includes: a sleeve provided with a cable tube; a locking barrel configured to be sleeved outside the cable tube; the end part of the cable tube is provided with a pressing arm and an open slot adjacent to the pressing arm; the inner wall of the locking barrel is provided with a pressing lug which can penetrate through the opening groove, and the pressing lug is constructed to rotate to the outer side of the pressing arm along with the locking barrel so as to press the pressing arm to move inwards. Through the utility model discloses, solved the cable and taken place the displacement easily in cable protection device, lead to the technical problem that the cable broke down.

Description

Cable protection device

Technical Field

The utility model relates to an electrical assembly's technical field especially relates to a cable protection device.

Background

In electrical assembly, cable sheaths are typically used to secure and protect the cables. For example, when a plurality of cables are in butt joint connection, the cable connection part is arranged in the cable sheath, so that personnel and other equipment can be prevented from directly contacting the cable connection part, and the electric shock risk is reduced; when the cable needs to be arranged on a vehicle, the cable sheath can be installed on the vehicle body, and the cable penetrates through the cable sheath to limit and protect the cable. The cable sheath is applied to the electrical assembly of new energy automobile, mainly plays the guard action of fixed and protection pencil, has fire-retardant, waterproof, prevents that the pencil from being destroyed by external force's function.

After the cable was worn out from the cable sheath, the cable can receive external force effect sometimes, leads to the cable to take place the displacement for the cable sheath, probably causes the cable to break away from the fixed connection position, arouses circuit fault. If the cable is a high-voltage wire harness, the high-voltage wire harness is displaced, the end position of the high-voltage wire harness and the length of one end of the high-voltage wire harness extending out of the cable sheath are changed, and interference is caused to the function and assembly of the high-voltage wire harness. For automobiles, the requirement on the reliability of cables is high, and the cables break down to cause adverse effects on the safety of the whole automobile.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a cable protection device to solve the cable and take place the displacement easily in cable protection device, lead to the technical problem that the cable broke down.

The above object of the present invention can be achieved by the following technical solutions:

the utility model provides a cable protection device, include:

a sleeve provided with a cable tube;

a locking barrel configured to be sleeved outside the cable tube;

the end part of the cable tube is provided with a pressing arm and an open slot adjacent to the pressing arm;

the inner wall of the locking barrel is provided with a pressing lug which can penetrate through the opening groove, and the pressing lug is constructed to rotate to the outer side of the pressing arm along with the locking barrel so as to press the pressing arm to move inwards.

In a preferred embodiment, the cable protection device comprises at least one locking lug and at least one locking groove; the at least one locking lug is arranged on the outer wall of the cable tube, and the at least one locking groove is arranged on the locking barrel; and/or at least one locking lug is arranged on the inner wall of the locking barrel, and at least one locking groove is arranged on the cable tube; the locking tab is configured to be inserted into the locking slot to define a position of the locking barrel on the cable tube.

In a preferred embodiment, the locking groove comprises a circumferential groove portion extending along a planar circumferential line around the axis of the cable tube; the locking lug is configured to be rotatably embedded in the circumferential groove portion.

In a preferred embodiment, the locking groove comprises an axial groove portion communicating with the circumferential groove portion, the axial groove portion being configured for guiding the locking lug into the circumferential groove portion.

In a preferred embodiment, an end portion of the circumferential groove portion has a lock portion configured such that a side wall of the lock portion presses the lock projection inward.

In a preferred embodiment, the locking groove comprises a helical groove portion extending along a helix about the axis of the cable tube.

In a preferred embodiment, the locking groove is a circumferential clamping groove, the locking protrusion is a first locking fixture block, the first locking fixture block is configured to be clamped in the circumferential clamping groove to prevent the locking cylinder from moving relative to the cable tube along the axial direction of the cable tube, and the first locking fixture block can rotate in the circumferential clamping groove.

In a preferred embodiment, the first locking latch comprises a latch riser, and the latch riser is configured to abut against an inner wall of the circumferential latch groove.

In a preferred embodiment, the first locking latch comprises a latch rib, and the latch rib is connected to the latch upright plate.

In a preferred embodiment, the locking groove is an axial clamping groove, the locking protrusion is a second locking clamping block, and the axial clamping groove and the second locking clamping block are configured to be clamped in the axial clamping groove by the second locking clamping block so as to prevent the locking cylinder from rotating around the axis of the cable tube relative to the cable tube.

In a preferred embodiment, the cable protection device includes a plurality of locking projections and a plurality of locking grooves, the plurality of locking projections are disposed on an outer wall of the cable tube, and the plurality of locking grooves are disposed on the locking barrel; at least one of the locking grooves comprises a circumferential groove portion extending along a planar circumferential line around an axis of the cable tube; at least one of the locking tabs is rotatable within the circumferential groove; at least one locking groove is a circumferential clamping groove, at least one locking lug is a first locking fixture block, the first locking fixture block can be clamped in the circumferential clamping groove to prevent the locking cylinder from moving relative to the cable pipe along the axial direction of the cable pipe, and the first locking fixture block can rotate in the circumferential clamping groove.

In a preferred embodiment, the pressing projection has a projection slope for overlapping the pressing arm, and the locking cylinder is rotated, and the projection slope guides the pressing projection to rotate to the outer side of the pressing arm.

In a preferred embodiment, the inner wall of the pressing arm is provided with an arm protrusion.

The utility model discloses a characteristics and advantage are:

by using the cable protection device, the locking barrel is sleeved on the cable tube, and one end of the cable penetrates out of the cable tube and passes through the locking barrel. When the cable is arranged in a penetrating mode, the pressing lug on the locking barrel penetrates through the open slot, as shown in fig. 4, the pressing arm is not pressed by the pressing lug, the size of the hole in the end portion of the cable tube is large, resistance between the cable tube and the cable when the cable moves is reduced, and the cable can conveniently penetrate through the cable tube. After the position of cable is accomplished the adjustment, rotate a locking section of thick bamboo, drive and compress tightly the lug and rotate to the outside that compresses tightly the arm, compress tightly the lug and inwards oppress and compress tightly the arm, compress tightly the arm and move to the inboard, make the size in the hole of the tip of cable pipe reduce, compress tightly the arm and compress tightly in the outer wall of cable, can prevent that the cable pipe from producing the displacement, make the position of cable remain stable, reduced the risk that the cable breaks away from the fixed connection position, reduce the cable trouble.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic structural diagram of a cable protection device provided by the present invention;

FIG. 2 is a schematic view of a first perspective of a locking barrel of the cable protection device of FIG. 1;

FIG. 3 is a schematic view of a second perspective of the locking barrel of the cable protection device of FIG. 1;

FIG. 4 is a right side view of the cable protection device shown in FIG. 1 in a first state;

FIG. 5 is a right side view of the cable protection device shown in FIG. 1 in a second state;

FIG. 6A is a schematic view of a sleeve of the cable protection device of FIG. 1;

FIG. 6B is a partial enlarged view of the portion A in FIG. 6A;

fig. 7 is a schematic structural view of another embodiment of a sleeve in the cable protection device according to the present invention;

fig. 8 is a schematic view of a cable mounted to the cable protection device.

The reference numbers illustrate:

10. a sleeve; 101. an accommodating cavity; 102. butting the cylinders; 103. accommodating the cylinder; 104. a cable;

11. a cable tube; 12. an open slot; 13. a pressing arm; 131. an arm projection;

20. a locking barrel; 21. compressing the bump; 211. a bump bevel; 22. a handle;

30. a locking groove; 40. a locking projection;

31. a circumferential groove portion; 32. an axial slot portion; 33. a lock section; 34. positioning a groove; 41. a positioning column;

36. a circumferential clamping groove; 42. a first locking clip; 421. a fixture block vertical plate; 422. and a rib plate of the clamping block.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The utility model provides a cable protection device, as shown in figure 1, figure 2, figure 6A and figure 6B, this cable protection device includes: the locking device comprises a sleeve 10 and a locking barrel 20, wherein the sleeve 10 is provided with a cable tube 11; the locking cylinder 20 is configured to be sleeved outside the cable tube 11; the end part of the cable tube 11 is provided with a pressing arm 13 and an open slot 12 adjacent to the pressing arm 13; the inner wall of the locking cylinder 20 is provided with a pressing projection 21 capable of being inserted into the opening groove 12, as shown in fig. 4 and 5, the pressing projection 21 is configured to rotate with the locking cylinder 20 to the outside of the pressing arm 13 to press the pressing arm 13 to move inward.

With the cable protection device, the locking cylinder 20 is firstly sleeved on the cable tube 11, and one end of the cable 104 penetrates out of the cable tube 11 and passes through the locking cylinder 20. When the cable 104 is inserted, the pressing projection 21 on the locking cylinder 20 is inserted into the opening groove 12, as shown in fig. 4, the pressing arm 13 is not pressed by the pressing projection 21, the size of the hole at the end of the cable tube 11 is large, the resistance between the cable tube 11 and the cable 104 when the cable 104 moves is reduced, and the cable 104 can conveniently pass through the cable tube 11. After the position of the cable 104 is adjusted, the locking cylinder 20 is rotated to drive the pressing lug 21 to rotate to the outer side of the pressing arm 13, the pressing lug 21 presses the pressing arm 13 inwards, the pressing arm 13 moves inwards, the size of a hole in the end of the cable tube 11 is reduced, the pressing arm 13 presses the outer wall of the cable 104, the cable tube 11 can be prevented from displacing, the position of the cable 104 is kept stable, the risk that the cable 104 is separated from a fixed connection position is reduced, and the fault of the cable 104 is reduced.

The sleeve 10 is provided with a receiving cavity 101 for receiving and carrying a wire. The open slot 12 can receive the pressing lug 21, the pressing lug 21 is arranged in the open slot 12 in a penetrating mode, the pressing lug 21 can move in the open slot 12 along the longitudinal direction of the cable tube 11, the pressing lug 21 is matched with the open slot 12 to play a positioning role, and in the process of sleeving the locking barrel 20 on the cable tube 11, the pressing lug 21 and the open slot 12 guide the locking barrel 20 to move along a bus of the cable tube 11. As shown in fig. 7 and 8, a plurality of cable tubes 11 may be provided on the sleeve 10, and the multi-strand cables 104 may be respectively passed out of the respective cable tubes 11, and the locking barrels 20 connected to the respective cable tubes 11 may respectively limit the displacement of the respective strand cables 104. As shown in fig. 8, the cable protection device includes a plurality of sleeves 10, the sleeves 10 are connected in a butt joint manner, the cable 104 passes through the butted sleeves 10, the locking cylinders 20 at the two ends lock the positions of the two ends of the cable 104 respectively, so that the displacement of the cable 104 can be reduced, the cable 104 in the cable protection device is kept stable, the connection position of the stranded cable 104 can be arranged in the cable protection device, the stranded cable 104 is prevented from being separated, and the reliability of the connection of the cable 104 is guaranteed.

The pressing projection 21 presses the pressing arm 13 inward, the pressing arm 13 deforms inward, and the pressing arm 13 presses the cable 104, so that a friction force is generated between the pressing projection 21 and the pressing arm 13, and the friction force can prevent the locking cylinder 20 from moving relative to the cable tube 11. In one embodiment of the present invention, the cable protection device includes at least one locking protrusion 40 and at least one locking groove 30; at least one locking lug 40 is arranged on the outer wall of the cable tube 11, and at least one locking groove 30 is arranged on the locking barrel 20; and/or, at least one locking lug 40 is arranged on the inner wall of the locking barrel 20, and at least one locking groove 30 is arranged on the cable tube 11; the locking projection 40 is configured to be embedded in the locking groove 30 to define the position of the locking barrel 20 on the cable tube 11, which is beneficial to keep the position of the locking barrel 20 on the cable tube 11 stable, and both keep the state shown in fig. 5, and the pressing arm 13 presses the cable 104 inwards under the pressing of the pressing projection 21.

As shown in fig. 2, 3, 6A, 6B and 7, the locking projection 40 is provided on the outer wall of the cable tube 11, and the locking groove 30 is provided on the locking barrel 20. Compare and set up locking lug 40 in the inboard, locking lug 40 locates the outer wall of cable pipe 11, changes in the shaping, has reduced this cable protection device's the manufacturing degree of difficulty. The position of the locking barrel 20 on the cable tube 11 is defined by the locking groove 30 cooperating with the locking projection 40. The locking groove 30 and the locking projection 40 are not limited to the arrangement as shown in fig. 2, 3, 6A, 6B and 7, but as another embodiment, the locking projection 40 is provided on the inner wall of the locking cylinder 20 and the locking groove 30 is provided on the cable tube 11. As another embodiment, at least one locking protrusion 40 is provided on the inner wall of the locking cylinder 20, and a mating locking groove 30 is provided on the cable tube 11; and, at least one locking protrusion 40 is provided on an outer wall of the cable tube 11, and a mating locking groove 30 is provided on the locking barrel 20.

The locking projection 40 is configured to be inserted into the locking groove 30, and the locking groove 30 may be a through groove or a groove. When the locking groove 30 is provided in the locking cylinder 20, it is preferable that the locking groove 30 is a through groove as shown in fig. 2 for easy manufacturing.

In one embodiment, the locking groove 30 includes a circumferential groove portion 31, the circumferential groove portion 31 extending along a planar circumferential line around the axis of the cable tube 11; the locking projection 40 is configured to be rotatably fitted in the circumferential groove portion 31. As shown in fig. 2 and 3, the locking protrusion 40 rotates in the circumferential groove 31 along a plane circumferential line around the axis of the cable tube 11, so that the locking cylinder 20 does not move axially while rotating, and the cable 104 can be pressed and locked by moving the pressing protrusion 21 to the outer wall of the pressing arm 13 through a small angle of rotation of the locking cylinder 20.

Further, the locking groove 30 includes an axial groove portion 32 communicating with the circumferential groove portion 31, the axial groove portion 32 being configured to guide the locking projection 40 into the circumferential groove portion 31. When the locking barrel 20 is sleeved on the cable tube 11, the locking protrusion 40 firstly enters the axial groove portion 32, and the locking protrusion 40 moves into the circumferential groove portion 31 along the axial groove portion 32, so that the locking barrel 20 can be conveniently and smoothly installed.

Further, the end portion of the circumferential groove portion 31 has a lock portion 33, and the lock portion 33 is configured such that the side wall of the lock portion 33 presses the lock projection 40 inward. As shown in fig. 3, the size of the locking portion 33 is reduced compared to the groove width of the initial section of the circumferential groove portion 31, and after the locking protrusion 40 enters the locking portion 33, the side wall of the locking portion 33 presses the locking protrusion 40, so that resistance against the locking protrusion 40 to prevent the locking protrusion 40 from retracting can be generated, and the locking protrusion 40 can be limited to the locking portion 33. Preferably, the locking protrusion 40 is cylindrical, the locking portion 33 is matched with the locking protrusion 40 in shape, the locking portion 33 may be a circular hole, the side wall of the locking portion 33 surrounds the locking protrusion 40, and the locking portion 33 is provided with an opening for the locking protrusion 40 to enter the locking portion 33, which is smaller than the locking protrusion 40 in a natural state, so that the locking protrusion 40 is prevented from exiting from the locking portion 33 after the locking protrusion 40 enters the locking portion 33. As shown in fig. 3, the axial groove portion 32, the circumferential groove portion 31, and the lock portion 33 are connected in this order to constitute a positioning groove 34; the locking projection 40 forms a positioning column 41, the positioning column 41 moves in the positioning groove 34, the smoothness of the movement of the locking cylinder 20 is guaranteed, and when the positioning column 41 moves to the locking part 33, locking is achieved.

In another embodiment, the locking groove 30 includes a spiral groove portion extending along a spiral line of the axis of the cable tube 11, the locking protrusion 40 moves along the spiral groove portion, and the locking protrusion 40 moves along the spiral line of the axis of the cable tube 11, so that rotating the locking barrel 20 can drive the pressing protrusion 21 to rotate to the outer side of the pressing arm 13, and the locking protrusion 40 is in threaded fit with the spiral groove portion, rotating the locking barrel 20 can generate a friction force between the locking protrusion 40 and the spiral groove portion, and the position of the locking barrel on the cable tube 11 can be kept stable by the friction force.

In still another embodiment, as shown in fig. 2, 3, 6A, 6B and 7, the locking groove 30 is a circumferential locking groove 36, the locking protrusion 40 is a first locking latch 42, the first locking latch 42 is configured to be locked to the circumferential locking groove 36 to prevent the locking cylinder 20 from moving relative to the cable tube 11 along the axial direction of the cable tube 11, and the first locking latch 42 can rotate in the circumferential locking groove 36. The axial position of the locking cylinder 20 on the cable tube 11 is limited through the circumferential clamping groove 36 and the first locking fixture block 42; meanwhile, the first locking dog 42 is rotatable in the circumferential catch groove 36 to allow the locking barrel 20 to rotate on the cable tube 11.

As shown in fig. 6A, 6B and 7, the first locking latch 42 includes a latch standing plate 421, and the latch standing plate 421 is configured to abut against an inner wall of the circumferential latch groove 36, so that the first locking latch 42 is latched to the circumferential latch groove 36. In an embodiment, the first locking latch 42 includes a latch rib 422, the latch rib 422 is connected to the latch standing plate 421, and the latch rib 422 increases the strength of the first locking latch 42, so that the first locking latch 42 is not easily deformed. Specifically, the latch rib 422 may be provided along the longitudinal extension of the cable tube 11.

As another embodiment, the locking groove 30 is an axial locking groove, the locking protrusion 40 is a second locking block, and the axial locking groove and the second locking block are configured to be locked in the axial locking groove to prevent the locking cylinder 20 from rotating around the axis of the cable tube 11 relative to the cable tube 11. The locking barrel 20 is sleeved outside the cable tube 11, the locking barrel 20 is rotated, and the second locking fixture block enters the axial clamping groove to prevent the locking barrel 20 from rotating, so that the position of the locking barrel 20 is limited. Preferably, the locking cylinder 20 is provided with an axial locking groove and a circumferential groove portion 31, and the locking cylinder 20 is locked by the cooperation of the axial locking groove and the axial groove portion 32, so that the advantages of accurate positioning and reliable locking are achieved.

Further, the cable protection device comprises a plurality of locking lugs 40 and a plurality of locking grooves 30, wherein the locking lugs 40 are all arranged on the outer wall of the cable tube 11, and the locking grooves 30 are all arranged on the locking barrel 20; as shown in fig. 2, 3, 6A, 6B and 7, the at least one locking groove 30 includes a circumferential groove portion 31, the circumferential groove portion 31 extending along a planar circumferential line around the axis of the cable tube 11; at least one locking lug 40 is rotatable within the circumferential groove 31; at least one locking groove 30 is circumferential clamping groove 36, and at least one locking lug 40 is first locking fixture block 42, and first locking fixture block 42 can joint in circumferential clamping groove 36 to prevent locking section of thick bamboo 20 relative to cable pipe 11 along cable pipe 11's axial displacement, and, first locking fixture block 42 can be at circumferential clamping groove 36 internal rotation. The circumferential clamping groove 36 and the circumferential groove part 31 cooperate to lock the position of the locking barrel 20, and the locking barrel has the advantages of accurate positioning and reliable locking.

As shown in fig. 2, the pressing projection 21 has a projection slope 211 for overlapping the pressing arm 13, and the locking cylinder 20 is rotated, and the projection slope 211 guides the pressing projection 21 to rotate to the outside of the pressing arm 13. At the beginning, the pressing lug 21 is arranged in the opening groove 12 in a penetrating manner, the lug inclined plane 211 is in contact with the side wall of the pressing arm 13, and when the locking cylinder 20 is rotated, the lug inclined plane 211 plays a guiding role, so that the pressing lug 21 can move towards the outer side of the pressing arm 13 conveniently.

As shown in fig. 1, 6A, 6B and 7, the inner wall of the pressing arm 13 is provided with an arm protrusion 131, and the pressing arm 13 abuts against the cable 104 through the arm protrusion 131, so that the pressing force on the cable 104 is favorably concentrated on the arm protrusion 131, and a larger resistance is favorably generated, thereby better preventing the cable 104 from being displaced and improving the stability of the position of the cable 104.

The sleeve 10 comprises an accommodating cylinder 103 and a butt joint cylinder 102, the accommodating cavity 101 is formed in the accommodating cylinder 103 and the butt joint cylinder 102, the accommodating cylinder 103 and the butt joint cylinder 102 bear wires and protect the wires, and the requirements of flame retardance, difficulty in damage and the like are met.

The cable tube 11 is shaped as a circular profile matching the shape of the wire, and alternative profiles are oval, square, rectangular with rounded corners, triangular, trapezoidal, parallelogram, diamond, polygonal, etc. The diameter of the cable tube 11 is designed according to different specifications of the conducting wire, and can be an integer, such as 10mm in diameter, 20mm in diameter, 30mm in diameter and the like; but may also be non-integer, such as 11.2mm in diameter, 12.2mm in diameter, 13.2mm in diameter, and so forth. The draft angle of the cable tube 11 is designed according to the mold stripping requirement, and is preferably 1 °, or is changed to other angle values according to different lengths, such as 1.5 °, 2 ° or 0.5 °. The cable tube 11 and the accommodating cylinder 103 are vertically connected, so that the strength requirement can be met while materials are saved.

The outer profiles of the accommodating cylinder 103 and the butt joint cylinder 102 are provided with positioning ribs of different shapes as positioning points for assembly according to different assembly requirements. The positioning ribs can be rectangular, triangular or cylindrical. The size (length and thickness) of the positioning rib is designed according to different assembly requirements, and can be an integer (such as 10mm, 20mm, 30mm and the like) or a non-integer (such as 11.2mm, 12.2mm, 13.2mm and the like). The outer profiles of the accommodating cylinder 103 and the docking cylinder 102 are rounded to avoid damage to hand pieces from sharp places to the surrounding environment and damage to personnel from sharp places, and may alternatively be chamfered, and the sizes of the fillet and the bevel are selected according to different specifications, and may be integers (for example, size 1mm, size 2mm, size 3mm, etc.) or non-integers (for example, size 1.2mm, size 2.2mm, size 3.2mm, etc.).

The wall thicknesses of the sleeve 10 and the locking cylinder 20 are set according to different strength requirements and process requirements, and may be an integer (e.g., 1mm wall thickness, 2mm wall thickness, 3mm wall thickness, etc.) or a non-integer (e.g., 1.1mm wall thickness, 2.1mm wall thickness, 3.1mm wall thickness, etc.).

The color of the sleeve 10 and the locking cylinder 20 is orange for warning, and other colors such as red, purple, blue, etc. can be used.

The materials of the sleeve 10 and the locking cylinder 20 are selected from different material types according to different strength requirements and different temperature resistance levels, and different material characteristic requirements, for example, the materials are made of one or a combination of more of polyamide, polyethylene, polypropylene, polystyrene, polymethyl methacrylate, polyvinyl chloride, ethylene propylene diene monomer, nylon, polycarbonate, polytetrafluoroethylene, polyethylene terephthalate, polyformaldehyde, and polyvinyl chloride, and the materials all need to meet the requirements of flame retardancy and strength.

The surfaces of the sleeve 10 and the locking cylinder 20 are treated with a spark pattern for aesthetic reasons and for enhanced feel, the specifications of the spark pattern being selected according to different specifications, such as ra0.16, ra0.25, ra0.32, etc.

The number of the first locking latches 42 is 2 according to the installation requirement, and may be selected to be other numbers according to different specifications, for example, 3, 5, 6, etc. The first locking fixture blocks 42 are integrally arranged, preferably in an upper and lower manner, according to the installation requirements, so that the stress is uniform during installation, the strength requirement during disassembly prevention is met, and other different arrangement schemes can be used according to different installation requirements, such as 1 in the upper and lower manner, 2 in the upper and lower manner, 3 in the upper and lower manner, and the like.

The overall shape of the first latch 42 is a trapezoid with an inclined surface according to the installation requirement, and alternatively, the overall shape may be a circle, a square, a rectangle, a triangle, a parallelogram, a rhombus, a polygon, or the like. The top surface of the rib 422 of the first locking dog 42 is an inclined surface, which mainly plays a role of assembly guiding when being installed, and the angle between the inclined surface and the axis of the sleeve 10 is selected to be 10 ° according to the installation requirement, and can be changed to other angles according to different specifications, such as 15 °, 20 °, 25 ° and the like.

The shape of the positioning post 41 is selected to be cylindrical according to the installation requirement, and may alternatively be circular, square, rectangular, triangular, parallelogram, diamond, polygonal, etc. The diameter of the positioning post 41 is designed according to different specifications of the lead, and may be an integer (e.g., diameter 10, diameter 20, diameter 30, etc.) or a non-integer (e.g., diameter 11.2mm, diameter 12.2mm, diameter 13.2mm, etc.). The height dimension of the positioning column 41 is designed according to different installation requirements, and can be an integer (for example, dimension 10mm, dimension 20mm, dimension 30mm, etc.) or a non-integer (for example, dimension 11.2mm, dimension 12.2mm, dimension 13.2mm, etc.).

The number of the arm protrusions 131 is preferably 4 according to the installation requirement, and may be changed to other numbers, such as 5, 6, 8, etc., according to different specifications. The width and height of the arm protrusions 131, which are designed according to different installation requirements, may be an integer (e.g., 10mm in size, 20mm in size, 30mm in size, etc.) or a non-integer (e.g., 11.2mm in size, 12.2mm in size, 13.2mm in size, etc.). The shape of the locking surface of the arm protrusion 131 is preferably an isosceles trapezoid, and may alternatively be a circle, a square, a rectangle, a triangle, a parallelogram, a rhombus, a polygon, or the like. The bevel angle of the arm protrusion 131 is selected to be 45 ° according to the installation requirement, and can be changed to other angles according to different specifications, such as 60 °, 30 °, 15 ° and the like.

The circumferential groove 36 is shaped as a rectangular window, and may alternatively be circular, square, rectangular, triangular, parallelogram, rhombus, polygonal, etc. The circumferential groove 36 is configured to have a space for a rotation space of the first locking dog 42 after being assembled, and the size of the space is designed according to the size of the first locking dog 42, and may be an integer (e.g., size 1mm, size 2mm, size 3mm, etc.) or a non-integer (e.g., size 1.2mm, size 2.2mm, size 3.2mm, etc.). The number of the circumferential slots 36 is 2 according to the installation requirement, and may be selected to be other numbers according to different specifications, for example, 3, 5, 6, and so on. Preferably, the circumferential clamping grooves 36 are respectively arranged in an upper and a lower direction by 2 according to installation requirements, the stress is uniform during installation due to the arrangement, the strength requirement during disassembly prevention is met, and other different arrangement schemes can be used according to different installation requirements, such as respectively 1 in the upper direction, respectively 2 in the lower direction, respectively 3 in the upper direction and the lower direction, and the like.

The positioning slot 34 is preferably L-shaped as shown in fig. 3 according to the installation requirement and the rotation requirement, and may alternatively be V-shaped, U-shaped, Z-shaped, etc. The open end of the positioning groove 34 is designed with a lead-in bevel to make the open end of the positioning groove 34 in a funnel shape so as to play a role of assembly lead-in when being installed, the bevel angle is selected to be 45 degrees according to the installation requirement, and can be changed into other angles according to different specifications, such as 60 degrees, 30 degrees, 15 degrees and the like.

The positioning slot 34 is designed for the locking portion 33 according to the rotation requirement, and the locking portion 33 may be a hole, and the shape of the hole is preferably circular, and may alternatively be square, rectangle, triangle, parallelogram, rhombus, polygon, etc. The diameter of the locking portion 33 is designed according to different specifications, and may be an integer (e.g., 10mm in diameter, 20mm in diameter, 30mm in diameter, etc.) or a non-integer (e.g., 11.2mm in diameter, 12.2mm in diameter, 13.2mm in diameter, etc.). The whole overall layout of constant head tank 34 is about each 1 according to rotatory requirement, and the atress is even when this overall layout is helped rotatoryly to and the intensity requirement when satisfying anti-disassembly, can use other different layout schemes according to the installation requirement of difference, for example 1 on the left side, 1 on the left side 2 on the right side, each 2 about and so on.

The number of the pressing protrusions 21 is preferably 4 according to the installation requirement, and may be changed to other numbers, such as 5, 6, 8, etc., according to different specifications. The width and height dimensions of the pressing projection 21 may be an integer (e.g., 10mm, 20mm, 30mm, etc.) or a non-integer (e.g., 11.2mm, 12.2mm, 13.2mm, etc.), depending on different installation requirements. The shape of the pressing projection 21 is preferably an isosceles trapezoid, the side of the isosceles trapezoid is configured as a projection inclined plane 211, the angle of the projection inclined plane 211 is preferably 45 ° according to the installation requirement, and can be changed to other angles according to different specifications, such as 60 °, 30 °, 15 ° and the like. Alternatives are circular, square, rectangular, triangular, parallelogram, diamond, polygonal, etc.

The number of the handles 22 is 2 according to the installation requirement, and can be selected to be other numbers according to different specifications, such as 3, 5, 6, and the like. The handle 22 is integrally arranged into 2 pieces from top to bottom according to the installation requirement, the arrangement is favorable for uniform stress during installation and meets the strength requirement during anti-disassembly, and other different arrangement schemes can be used according to different installation requirements, such as 1 piece from top to bottom, 2 pieces from top to bottom, 3 pieces from top to bottom and the like. The handle 22 is rectangular in shape, and may alternatively be circular, square, rectangular, triangular, parallelogram, diamond, polygonal, and the like. The width and height of the handle 22, designed according to different installation requirements, may be an integer (e.g., dimension 10mm, dimension 20mm, dimension 30mm, etc.) or a non-integer (e.g., dimension 11.2mm, dimension 12.2mm, dimension 13.2mm, etc.).

The overall shape of the locking cylinder 20 is circular, and may alternatively be oval, square, rectangular, triangular, parallelogram, diamond, polygonal, etc.

The working principle of the cable protection arrangement shown in fig. 1 is: the first locking latch 42 and the circumferential slot 36 are guided by the inclined plane of the first locking latch 42, and the clamping function is realized. The positioning column 41 and the positioning groove 34 form an L-shaped track system for guiding and rotational positioning, the axial groove portion 32 is configured as a short side of the L-shaped track, the circumferential groove portion 31 is configured as a long side of the L-shaped track, and a joint of the axial groove portion 32 and the circumferential groove portion 31 is configured as a corner point of the L-shaped track.

When the locking cylinder 20 is assembled, the positioning column 41 is guided into the positioning groove 34 through the guiding oblique angle of the opening end of the positioning groove 34 and moves along the short side of the L-shaped track of the positioning groove 34 to reach the corner point of the L-shaped track, the assembling position is locked, meanwhile, the first locking clamping block 42 and the circumferential clamping groove 36 are clamped in place, and pre-assembly is completed.

After the pre-assembly, the operator holds the handle 22 and performs a rotation operation to rotate the lock cylinder 20 by 45 degrees as a whole. When the positioning post 41 rotates, the positioning post 41 moves along the long side of the L-shaped track of the positioning slot 34, and reaches a predetermined position, the positioning post 41 enters the end point locking portion 33 of the positioning slot 34, and finally the position locking is completed, and the rotation operation is terminated. In this action, the first locking latch 42 and the circumferential latch 36 are always in a latched state, so that the locking cylinder 20 is not disengaged.

Before rotation, the inner side of the arm lug 131 and the outer side of the wire keep a fixed gap value, and at the moment, the wire and the sleeve 10 are in a loose state, so that the installation of the guide and the sleeve 10 can be ensured. Meanwhile, the pressing lug 21 and the outer side of the arm lug 131 are in a staggered state without interference, so that the installation of the locking cylinder 20 and the sleeve 10 can be ensured.

After the rotation, since the locking cylinder 20 is rotated by 45 degrees as a whole, the pressing projection 21 is also rotated by 45 degrees, and since the pressing arm 13 is in a non-rotating state, the inner side of the pressing projection 21 is forced to enter the outer side of the pressing arm 13. Due to the presence of the cam slope 211, the inner side of the pressing cam 21 presses the outer side of the arm cam 131, so that the arm cam 131 is integrally contracted inward. When the arm bump 131 is integrally shrunk inward, the gap between the inner side of the arm bump 131 and the wire is gradually reduced and finally eliminated. At this time, the inner side of the arm protrusion 131 presses the outer side of the wire, so that the axial movement of the wire is limited, and a locking function is realized.

The sleeve 10 adopts a precise injection molding process, meets the dimensional requirement of the sleeve 10 by controlling the precision of equipment and the error of a mold, and controls the injection molding process by controlling the mold locking force, the metering precision of an injection position, the injection speed, the injection pressure, the temperature of the mold and the like, so that the dimensional precision requirement of pre-assembly and rotation and the operation requirement of rotating force are met. The specific parameters are as follows: when the mold locking force is zero, the mold locking force is less than 0.03 mm; when the mold locking force is maximum, the thickness is less than 0.005 mm; the precision of the injection position (pressure maintaining termination point) is less than 0.03 mm; the injection speed is more than or equal to 300 mm/s; the injection pressure is more than 25 MPa; the temperature variation of the die is controlled within +/-1 ℃.

The sleeve 10 and the cable tube 11 adopt an automatic assembly process, and the assembly process is controlled through an automatic assembly tool, so that the requirements of pre-assembly force, smooth motion fit of the L-shaped tracks, rotating force, locking force, no wrong assembly, no missing assembly, no reverse assembly and the like are met. Automatic change assembly fixture primary structure: industrial computer, cylinder, lead screw, slide rail, location structure, guiding mechanism, mistake proofing mechanism etc..

The above description is only for the embodiments of the present invention, and those skilled in the art can make various changes or modifications to the embodiments of the present invention according to the disclosure of the application document without departing from the spirit and scope of the present invention.

Claims (13)

1. A cable protection device, comprising:

a sleeve provided with a cable tube;

a locking barrel configured to be sleeved outside the cable tube;

the end part of the cable tube is provided with a pressing arm and an open slot adjacent to the pressing arm;

the inner wall of the locking barrel is provided with a pressing lug which can penetrate through the opening groove, and the pressing lug is constructed to rotate to the outer side of the pressing arm along with the locking barrel so as to press the pressing arm to move inwards.

2. The cable protection device of claim 1, wherein the cable protection device comprises at least one locking tab and at least one locking slot;

the at least one locking lug is arranged on the outer wall of the cable tube, and the at least one locking groove is arranged on the locking barrel;

and/or at least one locking lug is arranged on the inner wall of the locking barrel, and at least one locking groove is arranged on the cable tube;

the locking tab is configured to be inserted into the locking slot to define a position of the locking barrel on the cable tube.

3. The cable protection device of claim 2, wherein the detent groove comprises a circumferential groove portion extending along a planar circumferential line about the axis of the cable tube; the locking lug is configured to be rotatably embedded in the circumferential groove portion.

4. The cable protection device of claim 3, wherein the locking groove includes an axial groove portion in communication with the circumferential groove portion, the axial groove portion configured to guide the locking tab into the circumferential groove portion.

5. The cable protection device of claim 3, wherein an end of the circumferential groove portion has a detent portion configured such that a side wall of the detent portion presses the detent tab inward.

6. The cable protection device of claim 2, wherein the locking groove comprises a helical groove portion that extends along a helix about an axis of the cable tube.

7. The cable protector of claim 2, wherein the locking groove is a circumferential groove, the locking protrusion is a first locking block, the first locking block is configured to be locked to the circumferential groove to prevent the locking cylinder from moving relative to the cable tube in an axial direction of the cable tube, and the first locking block can rotate in the circumferential groove.

8. The cable protection device of claim 7, wherein the first locking dog comprises a dog riser configured to abut against an inner wall of the circumferential slot.

9. The cable protector of claim 8, wherein the first locking tab includes a tab rib, the tab rib being connected to the tab riser.

10. The cable protector of claim 2, wherein the locking groove is an axial locking groove, the locking protrusion is a second locking detent, and the axial locking groove and the second locking detent are configured such that the second locking detent is locked in the axial locking groove to prevent the locking barrel from rotating about the axis of the cable tube relative to the cable tube.

11. The cable protector of claim 2, wherein the cable protector includes a plurality of locking projections and a plurality of locking grooves, the plurality of locking projections being disposed on an outer wall of the cable tube, the plurality of locking grooves being disposed on the locking barrel;

at least one of the locking grooves comprises a circumferential groove portion extending along a planar circumferential line around an axis of the cable tube; at least one of the locking tabs is rotatable within the circumferential groove;

at least one locking groove is a circumferential clamping groove, at least one locking lug is a first locking fixture block, the first locking fixture block can be clamped in the circumferential clamping groove to prevent the locking cylinder from moving relative to the cable pipe along the axial direction of the cable pipe, and the first locking fixture block can rotate in the circumferential clamping groove.

12. The cable protector of claim 1, wherein the compression tab has a tab ramp for engaging the compression arm, and wherein turning the locking barrel directs the compression tab to turn outside of the compression arm.

13. The cable protection device of claim 1, wherein an inner wall of the compression arm is provided with an arm tab.

Images