CN110212318B

CN110212318B - Direct terminal of large-wire-diameter wire

Info

Publication number: CN110212318B
Application number: CN201910427885.6A
Authority: CN
Inventors: 陈国华; 王峰; 许建辉; 李秋君
Original assignee: Phoenix Contact Asia Pacific Nanjing Co Ltd
Current assignee: Phoenix Contact Asia Pacific Nanjing Co Ltd
Priority date: 2019-05-22
Filing date: 2019-05-22
Publication date: 2024-04-05
Anticipated expiration: 2039-05-22
Also published as: EP3975341A1; EP3975341A4; WO2020233399A1; CN110212318A

Abstract

The invention discloses a direct terminal of a large-wire-diameter wire, which comprises a shell, a sliding module, a wire pressing module and a wire connecting module, wherein the sliding module, the wire pressing module and the wire connecting module are all arranged in the shell; the wiring module is used for accommodating wires entering the terminal; the sliding module is provided with a working position and a sliding position, and can slide back and forth along the shell; when the wire is in the sliding position, the wire is convenient to enter the wiring module; when in the working position, the wire pressing module is used for making contact with the wires entering the wiring module; the wire pressing module is connected with the sliding module, can move up and down along the surface perpendicular to the plane where the sliding module is located, has an upper limit position and a lower limit position in the moving process, and is in contact with a wire entering the wiring module when being in lower limit position, and is fixedly connected with the wire in the wiring module; when the wire pressing module is in the upper limit, the wire pressing module is separated from the wire, so that the wire entering the wiring module can be withdrawn, and the terminal is powered off; the invention can realize the wire feeding.

Description

Direct terminal of large-wire-diameter wire

Technical Field

The invention belongs to the field of a wiring terminal with wires, and particularly relates to a direct terminal of a large-wire-diameter wire.

Background

Along with the annual development of the photovoltaic industry market, the pressure of cost is continuously increased, and the aluminum wire is economical and light in weight, and the conductivity is close to that of copper, so that the aluminum wire starts to replace the copper wire year by year in the photovoltaic industry. Under extremely severe working conditions on site, the conventional aluminum conductor is usually processed in a manner customary in the industry, namely a conventional wire inlet manner with side insertion is adopted, then screw crimping is adopted, the working hours on site are high, the operation is difficult, and crimping tools are heavy to wear. Particularly, when a plurality of wires are required to be crimped, when one wire is inserted, the other wire is difficult to be inserted from the side end, and thus the crimping is difficult. Meanwhile, the side end is in pressure connection, so that the pressure connection length cannot be observed, and the pressure connection length cannot be standardized and visualized.

Disclosure of Invention

The invention aims to provide a direct terminal of a large-wire-diameter wire, which is used for realizing wire connection in a wire-feeding mode.

The technical solution for realizing the purpose of the invention is as follows:

a direct terminal of a large-wire-diameter wire comprises a shell, a sliding module, a wire pressing module and a wiring module; the sliding module, the wiring module and the line pressing module are all arranged in the shell;

the wiring module is used for accommodating wires entering the terminal;

the sliding module is provided with a working position and a sliding position, can slide back and forth along the shell and is used for realizing conversion between the working position and the sliding position; when in the sliding position, the wires are convenient to enter the wiring module; when in the working position, the wire pressing module is used for contacting with the wires entering the wiring module;

the wire pressing module is connected with the sliding module, the wire pressing module can move up and down along the surface perpendicular to the plane where the sliding module is located, the wire pressing module is provided with an upper limit position and a lower limit position in the moving process, and when the wire pressing module is in the lower limit position, the wire pressing module is contacted with a wire entering the wiring module and used for fixing the wire connected into the wiring module so as to realize the electrifying of the terminal; when the wire pressing module is in the upper limit, the wire pressing module is separated from the wire entering the wiring module and used for realizing the withdrawal of the wire entering the wiring module, and the terminal is powered off at the moment.

Compared with the prior art, the invention has the remarkable advantages that:

(1) According to the invention, the line pressing module is driven to horizontally slide by the sliding block module, so that line feeding in a line feeding mode is realized, and meanwhile, the line pressing module is adjusted to move up and down, so that the installation of the guide of different line diameters can be satisfied.

(2) The invention can realize the compression joint length of the lead through the positioning part, ensure the compression joint length and realize the compression joint length standardization; meanwhile, the contact between the end part of the wire and the positioning part can be observed from top to bottom, and the visualization of wiring is realized.

(3) The locking structure is arranged between the sliding module and the shell, so that the sliding block has a sliding stopping function, the space in the length direction of the shell is maximally utilized, and the accuracy of the sliding position is ensured.

(4) The pressing line module only needs one inner hexagonal wrench for pressing, so that a complicated pressing mode is changed.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is an exploded view of the present invention.

Fig. 3 is a schematic diagram of connection between the support block and the pressing line block.

Fig. 4 is a schematic diagram of a slider structure.

Fig. 5 is a schematic diagram of a reverse spring structure.

Fig. 6 is a schematic view of the first housing structure.

Fig. 7 is a schematic view of a second housing structure.

Fig. 8 is a front view of the present invention.

Fig. 9 is a top view of the present invention.

Fig. 10 is a sectional view of B-B in fig. 8.

Fig. 11 is a cross-sectional view of fig. 8C-C.

Fig. 12 is a cross-sectional view A-A of fig. 9.

Detailed Description

The invention is further described with reference to the drawings and specific embodiments.

Referring to fig. 1-12, the invention provides a direct terminal of a large-diameter wire, which comprises a shell, a sliding module, a wire pressing module and a wire connecting module; the sliding module, the wiring module and the line pressing module are all arranged in the shell;

the wiring module is used for accommodating wires entering the terminal;

Further, a wire clamping frame 4.5 for supporting the wiring module and bearing the reverse acting force of the wire pressing module for pressing the wire is also arranged in the shell; the shell is provided with a notch for accommodating the wire clamping frame 4.5, and the wire clamping frame 4.5 is fixed in the notch; the wiring module extends into the wire clamping frame 4.5; the wire pressing module can slide relative to the wire clamping frame 4.5.

Further, the wire pressing module comprises a fastener 4.1, a supporting block 4.3 and a wire pressing block 4.4; the two sides of the wire clamp frame 4.5 are provided with sliding grooves 4.51; protrusions 4.31 are arranged on two sides of the supporting block 4.3 and are used for being matched with the sliding grooves 4.51 and transmitting clamping force; the fastener 4.1 is used for connecting the support block 4.3, the line pressing block 4.4 and the sliding module into a whole and adjusting the upper and lower positions of the line pressing block 4.4; the fastening piece 4.1 is rotatably connected with the line pressing block 4.4. Because the wire clamp frame 4.5 limits the wire pressing block 4.4, the wire pressing block 4.4 cannot rotate and only can slide up and down, so that the wires are pressed or loosened. The sliding module is used as an upper limit of the line pressing module; the bottom of the wire clamping frame 4.5 is used as the lower limit of the wire pressing module.

Further, the upper end of the supporting block 4.3 is also provided with a reverse spring piece 4.2; the fastener 4.1 passes through the reverse elastic sheet 4.2; the reverse elastic sheet 4.2 is provided with a plurality of guide bulges 4.21 and elastic bulges 4.22, and the guide bulges 4.21 are attached to the wire clamp frame 4.5; the elastic bulge 4.22 is tilted upwards and extends into the chute 4.51. Along the sliding direction, positioning sheets 4.23 are arranged at the two ends of the reverse elastic sheet 4.2; the two end locating pieces 4.23 are used for clamping the two ends of the supporting block 4.3. The elastic bulge 4.22 can play a role in vibration damping.

Further, the wiring module comprises a current bar 3; the shell is internally provided with a supporting part 40 for supporting the current strip 3, one end of the current strip 3 is positioned in the wire clamping frame 4.5, and the other end is used for being connected with the cold pressing head 8. When the slide block 5 slides to the notch sliding position, a wire can be led in from the upper end of the wire clamping frame 4.5 and is arranged at the upper part of one end of the current strip 3. When the sliding block 5 slides to the notch working position, the fastener 4.1 is screwed, and the wire clamping frame 4.5 limits the wire pressing block 4.4, so that the wire pressing block 4.4 cannot rotate and only can slide up and down, and the wire and the current strip 3 can be pressed or loosened.

Furthermore, along the sliding direction, locking structures which are convenient for positioning the sliding module are further arranged at the two ends of the sliding module and the two ends of the shell.

As an embodiment, the left and right sides of the slider 5 are provided with the buckles 52, the left and right sides of the housing are provided with the clamping grooves 12, and the buckles 52 and the clamping grooves 12 form a locking structure. So that the slide block 5 can be locked by the lock catch when sliding to two ends along the shell 1. Pushing the slider 5 to separate the buckle 52 from the clamping groove 12, the slider 5 can slide relative to the shell; pushing the slider 5 engages the catch 52 with the catch slot 12 and the slider 5 is locked.

Further, a positioning portion 30 for positioning the extending length of the wire is further provided in the housing. When the wire stretches into the lower part of the wire pressing block 4.4, the positioning part 30 positions the stretching-in length of the wire, so that the crimping length of the wire can be ensured.

Further, when the sliding module slides to the working position, the sliding module is located at the upper end of the pressing position, and a gap is further formed between the sliding module and the positioning portion 30. I.e. the sliding module is at the end far away from the cold pressing head 8, i.e. in the working position, the gap between the sliding module and the cold pressing head 8 is larger than the gap between the positioning part 30 and the cold pressing head 8, so that the gap is also provided between the sliding module and the positioning part 30. A gap is provided between the sliding module and the positioning portion 30 so that contact between the wire and the positioning portion 30 is observed from the upper portion, so that the wiring is visualized.

Further, the sliding module is a sliding block 5, and a sliding structure of a guide rail and a sliding groove is arranged between the sliding block 5 and the shell and can slide relatively. As an implementation mode, sliding grooves 1.1 are formed in the inner walls of two sides of the notch of the shell; slide rails 51 are arranged on two sides of the sliding block 5, and the slide rails 51 and the sliding grooves 1.1 are matched to form a sliding structure between the sliding block 5 and the notch.

As another implementation mode, sliding rails are arranged on the inner walls of the two sides of the notch of the shell, and sliding grooves are arranged on the two sides of the sliding block 5; the sliding rail and the sliding groove are matched to form a sliding structure between the sliding block 5 and the notch.

As one embodiment, the housing includes a first housing 1, a second housing 2; a plurality of mounting posts 1.2 are arranged on the first shell 1; the second shell 2 is provided with a plurality of mounting holes 2.1; the mounting post 1.2 is inserted into the mounting hole 2.1 to connect the first housing 1 with the second housing 2.

Further, the first shell 1 and the second shell 2 are further provided with a plurality of buckles 1.3 or clamping grooves 1.4, and the buckles 1.3 or the clamping grooves 1.4 of the two shells are matched to connect the two shells, so that the anti-torque capacity is good.

Preferably, the fastener 4.1 adopts an inner hexagonal screw, so that the inner hexagonal screw is convenient to lock by adopting an inner hexagonal wrench.

As one implementation mode, the other end of the current bar 3 is fixedly connected with a stud 9; the cold ram 8 is connected to the current bar 3 by a nut 7.

When the direct terminal of the large-diameter wire is used, the sliding block 5 is firstly slid to the other end of the notch of the shell 1, namely, the sliding position, the wire is placed on one end of the current strip 3 from the upper end of the wire clamping frame 4.5, and the end part of the wire is positioned through the positioning part 30; when the sliding block 5 is slid to one end of the notch of the shell 1, namely a working position, the wire pressing block 4.4 is opposite to the wire 4, and then the fastener 4.1 is screwed, so that the wire pressing block 4.4 descends to press the wire and the current strip 3. When in compression, the reaction force of the wire pair pressing wire block 4.4 acts on the supporting block 4.3, the supporting block 4.3 transmits the acting force to the wire clamping frame 4.5, and the wire clamping frame 4.5 bears the huge load force exerted on the fastener 4.1.

When the large-wire-diameter direct wire terminal is assembled, the fastening piece 4.1, the reverse elastic piece 4.2, the supporting block 4.3 and the wire pressing block 4.4 are assembled, the fastening piece 4.1 and the wire pressing block 4.4 are movably riveted, the fastening piece 4.1 and the wire pressing block 4.4 can be integrated after being riveted, the fastening piece 4.1 is in threaded connection with the supporting block 4.3, the effect of adjusting the height is achieved, the free adjustment of the wire pressing block 4.4 in the up-down direction can be achieved, and the purpose of adjusting the wiring range is achieved. And simultaneously, the compression reaction force is transmitted to the wire clamping frame 4.5 through the supporting block 4.3. After the wire clamping frame 4.5 is installed, the wire clamping frame is assembled into the assembly metal assembly 4, the stud 9 is riveted into the current strip 3, the metal assembly 4 and the sliding block 5 are placed into the first shell 1, the second shell 2 is pressed in, the terminal is integrally fixed on the installation panel 12 by using the installation screw 11, the cold pressing head 8 is installed at the moment, the cold pressing head 8 is locked by using the integrated nut 7, the sliding block 5 slides, the lead 10 is placed into the wire clamping frame 4.5 from the top or the side and is contacted with the current strip 3, the sliding block 5 is pulled back, the hexagonal wrench is used for screwing the adjusting fastener 4.1, and the lead 10 is locked by the descending of the wire pressing block 4.4.

According to the invention, the line pressing module is driven to horizontally slide by the sliding block module, so that line feeding in a line feeding mode is realized, and meanwhile, the line pressing module is adjusted to move up and down, so that the installation of the guide of different line diameters can be satisfied. The crimp length of the wire can be realized through the positioning part, the crimp length is ensured, and the crimp length standardization is realized; meanwhile, the contact between the end part of the wire and the positioning part can be observed from top to bottom, and the visualization of wiring is realized. The locking structure is arranged between the sliding module and the shell, so that the sliding block has a sliding stopping function, the space in the length direction of the shell is maximally utilized, and the accuracy of the sliding position is ensured. The compaction of the line pressing module only needs an inner hexagonal wrench, and the tedious crimping mode is changed.

Claims

1. The direct terminal of the large-wire-diameter wire is characterized by comprising a shell, a sliding module, a wire pressing module and a wiring module; the sliding module, the wiring module and the line pressing module are all arranged in the shell;

the wiring module is used for accommodating wires entering the terminal;

the wire pressing module is connected with the sliding module, the wire pressing module can move up and down along the surface perpendicular to the plane where the sliding module is located, the wire pressing module is provided with an upper limit position and a lower limit position in the moving process, and when the wire pressing module is in the lower limit position, the wire pressing module is contacted with a wire entering the wiring module and used for fixing the wire connected into the wiring module so as to realize the electrifying of the terminal; when the wire pressing module is in the upper limit, the wire pressing module is separated from the wire entering the wiring module and is used for realizing the withdrawal of the wire entering the wiring module, and at the moment, the terminal is powered off;

the shell is also internally provided with a wire clamping frame (4.5) for supporting the wiring module and bearing the reverse acting force of the wire pressing module for pressing the wire; the shell is provided with a notch for accommodating the wire clamping frame (4.5), and the wire clamping frame (4.5) is fixed in the notch; the wiring module is arranged in the wire clamping frame (4.5);

and a positioning part (30) for positioning the extending length of the lead is also arranged in the shell.

2. The large wire diameter direct terminal of claim 1, wherein the wire pressing module comprises a fastener (4.1), a support block (4.3), a wire pressing block (4.4);

sliding grooves (4.51) are formed in two sides of the wire clamp frame (4.5); protrusions (4.31) are arranged on two sides of the supporting block (4.3) and are used for being matched with the sliding grooves (4.51) and transmitting clamping force; the fastener (4.1) is used for connecting the supporting block (4.3), the pressing line block (4.4) and the sliding module into a whole; and operating the fastener, wherein the pressing line block can move up and down along the surface perpendicular to the plane of the sliding module.

3. The direct terminal of a large-diameter wire according to claim 2, wherein the upper end of the supporting block (4.3) is further provided with a reverse spring piece (4.2); the fastener (4.1) passes through the reverse elastic sheet (4.2); the reverse elastic sheet (4.2) is provided with a plurality of guide bulges (4.21) and elastic bulges (4.22), and the guide bulges (4.21) are attached to the wire clamp frame (4.5); the elastic bulge (4.22) is tilted upwards and extends into the chute (4.51).

4. The large-diameter wire direct terminal according to claim 1, wherein the two ends of the sliding module are provided with a clamping hook part, the two ends of the shell are provided with a clamping buckle part, and the clamping hook part is matched with the clamping buckle part for realizing the fixation of the sliding module at the working position and the sliding position.

5. The large-diameter wire direct terminal according to claim 1, wherein a gap is provided between the sliding module and the positioning portion (30) when the sliding module is slid to the working position.

6. The large wire diameter direct terminal according to claim 1, characterized in that the wiring module comprises a current strip (3); the shell is internally provided with a supporting part (40) for supporting the current strip (3), one end of the current strip (3) is positioned in the wire clamping frame (4.5), and the other end of the current strip is used for being connected with a cold pressing head.

7. The direct terminal of the large-diameter wire according to claim 6, wherein the other end of the current strip (3) is fixedly connected with a stud (9); the cold pressure head is connected with the current bar (3) through a nut (7).

8. The large-wire-diameter wire direct terminal according to claim 1, wherein the housing comprises a first housing (1), a second housing (2); a plurality of mounting columns (1.2) are arranged on the first shell (1); a plurality of mounting holes (2.1) are formed in the second shell (2); the mounting column (1.2) is inserted into the mounting hole (2.1) to connect the first shell (1) with the second shell (2).