CN117134168A - Multi-form cable splice connector - Google Patents

Abstract

The invention relates to the field of cable connectors, and provides a multi-form cable splicing connector which comprises a connecting wire, wherein one side of the connecting wire is provided with a steering structure, and one side of the steering structure is provided with a deformation structure; according to the invention, through the steering structure and the deformation structure, the wiring terminal of the device can move in multiple angles and multiple directions, so that the device can be connected with cables at different angles, and the flexibility of cable connection is greatly enhanced; the first sliding block and the second sliding block are clamped by the mutual matching of the fixing blocks and the connecting balls, and compared with a heavy filling method in the prior art, the fixing mode of the fixing device is convenient to operate, has a rich form change effect, can connect cables in most directions of space, and breaks the limitation of the existing fixing device on the form and angle of the connector.

Description

Multi-form cable splice connector

Technical Field

The invention relates to the field of cable connectors, in particular to a multi-form cable splicing connector.

Background

The cable is an electric energy or signal transmission device, and is usually composed of several or several groups of wires, wherein each group of wires are mutually insulated and are twisted around a central framework, and the whole outer surface of the cable is covered with a high-insulation covering layer; the cable has the characteristics of internal power supply and external insulation, and can be divided into a power cable, a control cable, a compensation cable, a shielding cable, a high-temperature cable, a computer cable, a signal cable, a coaxial cable, a fire-resistant cable, a marine cable, a mining cable, an aluminum alloy cable and the like according to purposes, wherein the cable consists of single-strand or multi-strand wires and an insulating layer and is used for connecting circuits, electric appliances and the like.

The connector is a functional element which enables a circuit to be connected, disconnected or switched by means of electric signals or mechanical force and is used for transmitting electric signals or electronic energy, and the connector can be found wherever an electronic system exists; in large electronic systems, it is often required to use thousands of connectors, which are one of the key elements to ensure proper and safe operation of various electronic systems.

Splicing generally refers to mechanical splicing, which refers to precisely aligning and securing two or more cables in place by a mechanical assembly; it should be noted that the cables spliced together mechanically are not permanently connected; the whole process of mechanical splicing is relatively simple and quick, and is generally used under the condition of limited time and technical skills.

Existing cable splice connectors are mainly of two types: one is small-sized connector with fewer interfaces, the number of connecting cables is controlled in a multi-group assembling mode, the connector is simple to operate and convenient to carry, the connector is very suitable for quick connection of the cables, but the shape of the connector is relatively fixed, and the connector cannot adapt to a multi-angle connection mode; the connector is also provided with a plurality of interfaces and complex in shape, the interfaces with a plurality of different angles are arranged, so that the connection of cables with different numbers in different directions is realized, the connector has extremely strong adaptability, the problem of complex cable connection can be solved, the problem that a plurality of interfaces are empty when the connector is used often exists, and the connector is damaged due to the fact that the empty cable interfaces are easy to enter ash and water when certain resource is wasted.

The Chinese patent bulletin number is: CN112909637a, a multi-butt connector for communication cable, said invention discloses a multi-butt connector for communication cable, belonging to cable connector field, including connecting disk, several sub-cable connectors, several auxiliary sector blocks; the connecting disc is provided with a main cable connecting fan block which is fixed on the connecting disc; a guide annular groove is formed in the connecting disc, and a guide block which is in sliding fit with the guide annular groove is arranged on one side of each sub cable connector and one side of each auxiliary sector block; the main cable connection fan blocks and the two sides of the sub cable connectors are respectively provided with a conducting reed, and the sub cable connectors, the auxiliary fan blocks and the main cable connection fan blocks are tightly connected with each other to form a circular ring; the number of the sub-cable connectors is selected according to the requirements, and auxiliary sector blocks are arranged at other positions which do not need to be connected, so that a closed ring shape is finally formed, the connection number of cables can be conveniently selected, and meanwhile, the connectors can be kept in a closed environment to avoid entering dust or water; however, the above-described invention uses the connection disc as a main structure, limits the shape of the connector to a disc shape, and can only control the cable connection angle of the side surface of the connection disc, thereby failing to realize a more complex connector shape.

In summary, the present invention provides a multi-mode cable splice connector to solve the above-mentioned problems.

Disclosure of Invention

The invention provides a polymorphic cable splicing connector, which controls a wiring terminal through arranging a steering structure and a deformation structure, so that the shape of the connector is flexible and controllable, and the problems of single shape and the like of the connector in the prior art are solved.

The specific technical scheme of the invention is as follows:

the utility model provides a polymorphic cable splice connector, includes the connecting wire, one side of connecting wire is provided with turns to the structure, one side of turning to the structure is provided with deformation structure, turn to the structure and include adjust knob one, adjust knob two and adjust knob three, adjust knob one side rotation connection at the connecting wire, one side fixedly connected with turn to the board three of adjust knob one, adjust knob two sets up on one side that adjust knob one is close to turn to the board three, adjust knob two and turn to the board three rotation connection, adjust knob two is kept away from one side fixedly connected with turn to the board two, adjust knob three sets up on one side that adjust knob two is close to turn to the board two, one side fixedly connected with turn to the board one is kept away from to adjust knob three, one end rotation that turn to the board two is kept away from adjust knob two is connected with the board two, one end rotation that turn to the board three is kept away from adjust knob one, turn to the structure is mainly used for keeping away from the connecting ball and waiting to connect the port of cable as close as possible.

The preferred technical scheme, deformation structure includes base, sliding block one, fixed block and connecting ball, the base inserts to be connected on the one end of connecting wire, sliding block one rotation is connected on one side of the center of base, the connecting ball sets up on one side of keeping away from the base at sliding block one, the fixed block can dismantle the side of connecting at the connecting ball, deformation effect is realized mainly through the position and the quantity of control sliding block one and sliding block two on the connecting ball to deformation structure.

According to the technical scheme, a communicating reed is arranged on the side face of the connecting ball, a sliding reed is arranged on one side, close to the connecting ball, of the sliding block I, the sliding reed is matched with the communicating reed in size, and the sliding reed of the sliding block I is tightly attached to the communicating reed.

According to the technical scheme, a second sliding block is arranged on one side, far away from the first sliding block, of the connecting ball, a connecting terminal is arranged on one side, far away from the connecting ball, of the second sliding block, a sliding reed is arranged on one side, close to the connecting ball, of the second sliding block, and the sliding reed of the second sliding block is tightly attached to the communicating reed.

According to the preferred technical scheme, a locking screw is arranged in the center of the fixed block and used for controlling the distance between the fixed block and the connecting ball.

According to the technical scheme, four groups of fixing blocks and connecting balls form two mutually perpendicular circular sliding grooves, the sizes of the circular sliding grooves are matched with those of the first sliding block and the second sliding block, the first sliding block and the second sliding block are arranged on the circular sliding grooves, and the circular sliding grooves are used for sliding the first sliding block and the second sliding block.

In a preferred technical scheme, the first sliding block and the second sliding block are arranged on different circular sliding grooves, and the first sliding block and the second sliding block can rotate on the respective circular sliding grooves.

According to the technical scheme, the first sliding block and the second sliding block are arranged on the same circular sliding groove, the other circular sliding groove is empty, the movement range of the first sliding block and the second sliding block is reduced at the same time, and the fixing effect of the fixing block on the second sliding block is enhanced.

According to the technical scheme, the second sliding block and the first sliding block are arranged on the same circular sliding groove, the other second sliding block is arranged on the other circular sliding groove, the movement range of each second sliding block is reduced by the second sliding block, and the device can be connected with two cables to be connected at the same time.

According to the technical scheme, the sliding blocks II and the sliding blocks I are arranged on the same circular sliding groove, the other circular sliding groove is empty, the sliding blocks I are provided with a steering structure and a deformation structure, the stability of the device in space is greatly improved under the condition of reducing the flexibility of the device, and meanwhile the problem that multiple groups of connecting wires are simultaneously connected with a cable to be connected can be solved.

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

1. according to the invention, through the steering structure and the deformation structure, the wiring terminal of the device can move in multiple angles and multiple directions, so that the device can be connected with cables at different angles, and the flexibility of cable connection is greatly enhanced.

2. According to the invention, the first sliding block and the second sliding block are clamped by mutually matching the fixed blocks and the connecting balls, and compared with a heavy filling method in the prior art, the fixing mode is convenient to operate, has a rich form change effect, can connect cables in most directions of space, and breaks the limitation of the existing fixing device on the form and angle of the connector.

Drawings

Fig. 1 is a schematic diagram of the overall structure of the present invention.

Fig. 2 is a schematic side view of the steering structure of the present invention.

Fig. 3 is a schematic front view of the steering structure of the present invention.

Fig. 4 is a three schematic views of the steering plate of the present invention.

FIG. 5 is a schematic view of a steering plate according to the present invention.

Fig. 6 is a schematic view of a deflector plate according to the present invention.

Fig. 7 is a schematic diagram of a variation of the present invention.

FIG. 8 is a schematic diagram of a second embodiment of the present invention.

Fig. 9 is a schematic diagram of an embodiment of the present invention.

Fig. 10 is a schematic diagram of an embodiment of the present invention.

In the figure:

1. a connecting wire; 2. a steering structure; 3. a deformed structure; 21. an adjusting knob I; 22. an adjusting knob II; 23. an adjusting knob III; 24. a steering plate I; 25. a steering plate II; 26. a steering plate III; 27. rotating the first plate; 28. a second rotating plate; 29. rotating the third plate; 31. a base; 32. a first sliding block; 33. a fixed block; 34. a connecting ball; 35. a connecting reed; 36. a second sliding block; 331. locking a screw; 361. and a connection terminal.

Detailed Description

Embodiments of the present invention are described in further detail below with reference to the accompanying drawings and examples. The following examples are illustrative of the invention but are not intended to limit the scope of the invention.

As shown in fig. 1-10, the invention provides a polymorphic cable splice connector, which comprises a connecting wire 1, one side of the connecting wire 1 is provided with a steering structure 2, one side of the steering structure 2 is provided with a deformation structure 3, the steering structure 2 comprises an adjusting knob one 21, an adjusting knob two 22 and an adjusting knob three 23, the adjusting knob one 21 is rotationally connected to the side surface of the connecting wire 1, one side of the adjusting knob one 21 is fixedly connected with a steering plate three 26, the adjusting knob two 22 is arranged on one side of the adjusting knob one 21, which is close to the steering plate three 26, the adjusting knob two 22 is rotationally connected with the steering plate three 26, one side, which is far from the adjusting knob two 22, of the adjusting knob two is fixedly connected with a steering plate two 25, one side, which is far from the adjusting knob two 22, of the adjusting knob three 23 is fixedly connected with a steering plate one 24, one end, which is far from the adjusting knob three 23, of the steering plate one end is rotationally connected with a rotating plate 27, one end, which is far from the adjusting knob two end 25, is far from the steering plate two, is rotationally connected with a rotating plate 28, which is far from the steering plate two end is far from the adjusting knob two 22, is rotationally connected with a main cable 34, which is far from the steering plate three, and is rotationally connected with the steering plate three, and the rotating end is required to be connected with the steering structure.

As an embodiment of the present invention, the deformation structure 3 includes a base 31, a first slider 32, a fixed block 33, and a connection ball 34, wherein the base 31 is inserted and connected to one end of the connection wire 1, the first slider 32 is rotatably connected to a central side of the base 31, the connection ball 34 is disposed on a side of the first slider 32 away from the base 31, the fixed block 33 is detachably connected to a side of the connection ball 34, and the deformation structure 3 achieves a deformation effect mainly by controlling positions and numbers of the first slider 32 and the second slider 36 on the connection ball 34.

As an embodiment of the present invention, the communicating reed 35 is disposed on the side of the connecting ball 34, the sliding reed is disposed on the side of the first sliding block 32 close to the connecting ball 34, the sliding reed is matched with the communicating reed 35 in size, the sliding reed of the first sliding block 32 is closely attached to the communicating reed 35, and the current between the sliding reed and the communicating reed 35 is communicated.

As an embodiment of the present invention, a second slider 36 is disposed on a side of the first slider 34 away from the first slider 32, a connection terminal 361 is disposed on a side of the second slider 36 away from the first slider 34, a sliding reed is disposed on a side of the second slider 36 close to the first slider 34, the sliding reed of the second slider 36 is tightly attached to the communication reed 35, and current between the sliding reed and the communication reed 35 is communicated.

As an embodiment of the present invention, a locking screw 331 is disposed at the center of the fixed block 33, and the locking screw 331 is used for controlling the distance between the fixed block 33 and the connection ball 34, so as to achieve the fixing effect on the first sliding block 32 and the second sliding block 36.

As an embodiment of the present invention, the four sets of the fixing blocks 33 and the connecting balls 34 form two mutually perpendicular circular sliding grooves, the dimensions of the circular sliding grooves are matched with those of the first sliding block 32 and the second sliding block 36, the first sliding block 32 and the second sliding block 36 are arranged on the circular sliding grooves, and the circular sliding grooves can be used for sliding the first sliding block 32 and the second sliding block 36, and can also be used for clamping and fixing the first sliding block 32 and the second sliding block 36 through the mutual matching of the fixing blocks 33 and the connecting balls 34.

As an embodiment of the present invention, the first slider 32 and the second slider 36 are disposed on different circular sliding grooves, and the first slider 32 and the second slider 36 can both rotate on the respective circular sliding grooves, so that the connection terminal 361 on the second slider 36 can be connected with the cables to be connected in almost all directions.

As an embodiment of the present invention, the first sliding block 32 and the second sliding block 36 are disposed on the same circular chute, and the other circular chute is empty, so that the movement ranges of the first sliding block 32 and the second sliding block 36 are reduced at the same time, but the fixing effect of the fixing block 33 on the second sliding block 36 is enhanced, so that the stability of the device is stronger when the device is applied to a scene with frequent vibration.

As an embodiment of the present invention, the second sliding block 36 and the first sliding block 32 are disposed on the same circular chute, the second sliding block 36 is disposed on the other circular chute, and the second sliding blocks 36 reduce the movement range of the second sliding blocks 36, but make the device capable of being connected with two cables to be connected simultaneously, so as to solve the problem that one connecting wire 1 is connected with multiple groups of cables to be connected simultaneously.

As an embodiment of the present invention, the second sliding block 36 and the first sliding block 32 are disposed on one circular chute, the other circular chute is empty, and both the first sliding blocks 32 are provided with the steering structure 2 and the deforming structure 3, so that the stability of the device in space is greatly improved under the condition of reducing the flexibility of the device, and the problem that multiple groups of connecting wires 1 are simultaneously connected with cables to be connected can be solved.

Example 1: as shown in fig. 1-7, when the present embodiment is connected with a cable, the connecting wire 1 is first passed through the centers of the first adjusting knob 21, the second adjusting knob 22 and the third adjusting knob 23, and one end of the connecting wire 1 is inserted into the base 31 for connection; then observing the position relation between the cable to be connected and the connecting ball 34, and controlling the first adjusting knob 21, the second adjusting knob 22 or the third adjusting knob 23 to enable the base 31 to rotate; when the first adjusting knob 21 is rotated, the first adjusting knob 21 drives the third steering plate 26 to rotate, so that the third rotating plate 29 rotationally connected with the third steering plate 26 rotates, and further one side of the base 31 rotates in a direction approaching to the third rotating plate 29; at this time, since one end of the first rotating plate 27 is rotatably connected to the base 31, the end of the first rotating plate 27 close to the base 31 moves along with the base 31 and rotates relative to the base 31, the end of the first rotating plate 27 close to the first steering plate 24 rotates around the first steering plate 24, and the force applied to the first steering plate 24 by the rotation of the first rotating plate 27 is insufficient to drive the first steering plate 24 to move, so the first steering plate 24 keeps a static state; meanwhile, as one end of the second rotating plate 28 is rotationally connected with the base 31, one end of the second rotating plate 28, which is close to the base 31, moves along with the base 31 and rotates relative to the base 31, one end of the second rotating plate 28, which is close to the second steering plate 25, rotates around the second steering plate 25, and the force applied to the second steering plate 25 by the rotation of the second rotating plate 28 is insufficient to drive the second steering plate 25 to move, so that the second steering plate 25 keeps a static state; therefore, the base 31 does not deflect transversely to the direction of the first steering plate 24 and the second steering plate 25, but deflects longitudinally only to the direction of the movement of the third steering plate 29, so that the deflection angle of the base 31 is accurately controlled by the rotation amplitude of the first adjusting knob 21; similarly, rotating the second adjusting knob 22 deflects the base 31 in the direction of the second rotating plate 28, and rotating the third adjusting knob 23 deflects the base 31 in the direction of the first rotating plate 27.

The main purpose of controlling the rotation of the base 31 is to bring the distance between the connection balls 34 above the base 31 and the ports of the cables to be connected as close as possible; when the connecting ball 34 is very close to the port of the cable to be connected, the locking screw 331 is loosened, so that the size of a circular chute formed by the fixed block 33 and the connecting ball 34 is increased slightly, and the first sliding block 32 and the second sliding block 36 can slide along the connecting ball 34 through the circular chute, so that the connecting ball 34 and the first sliding block 32 can be controlled to slide relatively, the second sliding block 36 can move in the direction of the circular chute where the first sliding block 32 is positioned, and the second sliding block 36 and the connecting ball 34 can be controlled to slide relatively, so that the second sliding block 36 moves in the direction of the circular chute where the second sliding block 36 is positioned, and the second sliding block 36 can move in four directions along the surface of the connecting ball 34; the first slider 32 can be controlled to rotate relative to the base 31, so that the movement range of the second slider 36 is further enlarged, and the connecting terminal 361 on the second slider 36 can be inserted into and connected with the cable in all directions around the connecting ball 34.

Then, the connecting terminal 361 on the sliding block II 36 is inserted into the port of the cable to be connected, after the connection is confirmed, the locking screw 331 is screwed, the size of a circular chute formed by the fixed block 33 and the connecting ball 34 is reduced, the sliding block I32 and the sliding block II 36 are clamped in the circular chute, so that the sliding block I32 and the sliding block II 36 are relatively fixed, meanwhile, the sliding reeds of the sliding block I32 and the sliding block II 36 are tightly attached to the connecting reed 35, and the connecting ball 34 is in a communicating state with a circuit between the sliding block I32 and the sliding block II 36; at this time, the overall structure of the embodiment is not changed any more, and the cable connection of one form is completed.

Example 2: as shown in fig. 8, this embodiment is basically the same in structure as embodiment 1, except that: the first sliding block 32 and the second sliding block 36 are positioned on the same circular chute; compared with embodiment 1, the second slider 36 and the first slider 32 can only move on one circular chute when the cable connection is performed, so that the movement range of the second slider 36 is limited, and therefore, in a specific application scenario, such as an electric appliance with frequent vibration, the fixing effect of the fixing block 33 on the second slider 36 is enhanced, and the stability of the device is improved.

Example 3: as shown in fig. 9, this embodiment is basically the same in structure as embodiment 2, except that: two sliding blocks II 36 are arranged on the two circular sliding grooves; in the present embodiment, as compared with embodiment 2, one connecting terminal 361 is added to the two second slider blocks 36 when performing cable connection, so that the number of connectable cables in the present embodiment is increased; further, the number of the second sliding blocks 36 on the two circular sliding grooves can be increased continuously, so that the number of the connectable cables in the embodiment is increased continuously to adapt to the connection requirements of a plurality of cables to be connected.

Example 4: as shown in fig. 10, this embodiment is basically the same in structure as embodiment 2, except that: two sliding blocks I32 are arranged on the two circular sliding grooves, namely the embodiment acts on two connecting wires 1 at the same time; compared with embodiment 2, the two first sliding blocks 32, the base 31 associated with the first sliding blocks 32 and the connecting wire are more stable in structure when in use, the fixing effect of the fixing block 33 is further enhanced, and meanwhile, the cable connection problem when a plurality of groups of connecting wires 1 exist is solved.

Compared with the single connector form in the prior art, the invention enables the connecting terminal 361 of the device to move in multiple angles and multiple directions through the steering structure 2 and the deformation structure 3, thereby enabling the device to be connected with cables in different angles and greatly enhancing the flexibility of cable connection; according to the invention, the first sliding block 32 and the second sliding block 36 are clamped by the mutual matching of the fixed block 33 and the connecting ball 34, and compared with a heavy filling method in the prior art, the fixing mode is convenient to operate, has a rich form change effect, can connect cables in most directions of space, and breaks the limitation of the existing fixing device on the form and angle of the connector.

The embodiments of the present invention have been shown and described for the purpose of illustration and description, it being understood that the above embodiments are illustrative and not to be construed as limiting the invention, and that variations, modifications, alternatives and variations may be made therein by one of ordinary skill in the art without departing from the scope of the invention.

Claims (10)

1. The utility model provides a polymorphic cable splice connector, includes connecting wire (1), its characterized in that, one side of connecting wire (1) is provided with turns to structure (2), one side of turning to structure (2) is provided with deformation structure (3), turn to structure (2) including adjust knob one (21), adjust knob two (22) and adjust knob three (23), adjust knob one (21) rotate and connect in the side of connecting wire (1), one side fixedly connected with turn to board three (26) of adjust knob one (21), adjust knob two (22) set up on one side that adjust knob one (21) is close to turn to board three (26), adjust knob two (22) are connected with turn to board three (26) rotation, one side fixedly connected with turn to board two (25) of adjust knob two (22) are kept away from to adjust knob two (22), one side fixedly connected with turn to board one (24) of adjust knob three (23) is kept away from turn to board one end (24) and is kept away from turn to board one (24), one end of the steering plate II (25) far away from the adjusting knob II (22) is rotationally connected with a rotating plate II (28), and one end of the steering plate III (26) far away from the adjusting knob I (21) is rotationally connected with a rotating plate III (29).

2. A polymorphic cable splice connector as claimed in claim 1, characterized in that the deformation structure (3) comprises a base (31), a first slider (32), a fixed block (33) and a connecting ball (34), the base (31) being inserted and connected to one end of the connecting wire (1), the first slider (32) being rotatably connected to a central side of the base (31), the connecting ball (34) being arranged on a side of the first slider (32) remote from the base (31), the fixed block (33) being detachably connected to a side of the connecting ball (34).

3. A polymorphic cable splice connector as claimed in claim 2, wherein the connecting ball (34) is provided with a communication reed (35) on a side thereof, the slider (32) being provided with a sliding reed on a side thereof adjacent to the connecting ball (34), the sliding reed being sized to match the communication reed (35).

4. A polymorphic cable splice connector as claimed in claim 2, wherein the side of the connection ball (34) remote from the first slider (32) is provided with a second slider (36), the side of the second slider (36) remote from the connection ball (34) is provided with a connection terminal (361), and the side of the second slider (36) close to the connection ball (34) is provided with a sliding reed.

5. A polymorphic cable splice connector as claimed in claim 2, characterized in that the centre of the fixed block (33) is provided with a locking screw (331).

6. A multi-modal cable splicing connector as claimed in claim 4 wherein four sets of said fixed blocks (33) and connecting balls (34) form two mutually perpendicular circular runners sized to mate with first (32) and second (36) sliders, said first (32) and second (36) sliders being disposed on the circular runners.

7. A multi-format cable splice connector as claimed in claim 6, wherein the first slider (32) and the second slider (36) are disposed on different circular slide grooves.

8. A multi-format cable splice connector as claimed in claim 6, wherein said first slider (32) and second slider (36) are disposed on the same circular chute, the other of said circular chutes being empty.

9. A multi-format cable splice connector as claimed in claim 6, wherein said second slider (36) and first slider (32) are disposed on the same circular chute, and the other second slider (36) is disposed on the other circular chute.

10. A multi-format cable splice connector as claimed in claim 6, wherein the second slider (36) and the first slider (32) are disposed on the same circular chute, the other circular chute being free.