CN117747360A - Low-voltage high-current conducting bar installation equipment for electric furnace transformer - Google Patents

Abstract

The invention relates to the technical field of high-voltage switch assembly, and discloses low-voltage high-current conducting bar mounting equipment of an electric furnace transformer, which comprises a mounting frame, wherein a first linear adjusting mechanism and a second linear adjusting mechanism are mounted on the mounting frame and vertically distributed, a workpiece arrangement frame is mounted at the output end of the first linear adjusting mechanism, a plurality of conducting bars are arranged on the workpiece arrangement frame, a mounting plate is mounted at the output end of the second linear adjusting mechanism, a tightening mechanism is mounted on the mounting plate and is used for installing and matching bolts with screw holes, a winding mechanism is further mounted on the mounting plate and is used for winding adhesive tapes on the conducting bars to form an insulating part; according to the invention, through the automatic actions of the tightening mechanism and the winding mechanism, the automatic installation of the conducting bars on the circuit breaker of the electric furnace transformer and the automatic winding of the insulating adhesive tape are realized, and the intelligent construction and the installation efficiency are improved.

Description

Low-voltage high-current conducting bar installation equipment for electric furnace transformer

Technical Field

The invention relates to the field of high-voltage switch assembly, in particular to low-voltage high-current conducting bar installation equipment for an electric furnace transformer.

Background

The electric furnace transformer is a special transformer for supplying power to an electric arc furnace for steel smelting. The device has the characteristics of large capacity, complex structure and higher technical requirement.

The circuit breaker of the transformer is usually provided with a conductive bar, so that larger power is distributed to each element of the dispersion system, and wires and cables are increasingly replaced in the engineering project of the low-voltage and high-current electric power transmission main line of the transformer.

The installation mode of the copper conductor bar on the circuit breaker of the existing transformer mainly relies on manual installation, the installation steps are as follows, firstly, one end of the conductor bar is inserted into corresponding insertion holes on two sides of the circuit breaker, through holes on the conductor bar are aligned with screw holes of the circuit breaker, then bolts penetrate into the screw holes from the through holes on the conductor bar, then a tool is used for screwing the bolts into the screw holes, the conductor bar is pressed, and the conductor bar is arranged and fixed on the circuit breaker in a horizontal and vertical posture; the current circuit breaker is generally provided with a plurality of conductive bars on two sides, so that when the current circuit breaker is electrified, the conductive bars are too closely spaced to generate electromagnetic interference, so that the normal use of the transformer circuit breaker is affected; however, the existing manual installation mode of the conductive bars is low in efficiency and cannot realize automatic installation.

Disclosure of Invention

The invention provides low-voltage high-current conducting bar installation equipment for an electric furnace transformer, which solves the technical problems that the conducting bar cannot be automatically installed and the insulating tape cannot be wound and wrapped in the related art.

The invention provides low-voltage high-current conducting bar installation equipment of an electric furnace transformer, which comprises a mounting frame, wherein a first linear adjusting mechanism and a second linear adjusting mechanism are installed on the mounting frame, the first linear adjusting mechanism and the second linear adjusting mechanism are vertically distributed, the output directions of the first linear adjusting mechanism and the second linear adjusting mechanism are arranged in parallel, a workpiece arrangement frame is installed at the output end of the first linear adjusting mechanism, a plurality of conducting bars are arranged on the workpiece arrangement frame, an installation plate is installed at the output end of the second linear adjusting mechanism, a tightening mechanism is installed on the installation plate and is used for installing and matching bolts with screw holes, a winding mechanism is also installed on the installation plate and is used for winding adhesive tapes on the conducting bars to form an insulating part;

the tightening mechanism comprises a connecting block, the connecting block is arranged on the mounting plate, a sleeve is arranged on the connecting block, a vertical clamping groove is formed in the sleeve and is matched with the bolt, a telescopic prism is arranged in the clamping groove, the end part of the prism is matched with the clamping groove at the top of the bolt, the prism movably penetrates through the top of an inner cavity of the sleeve, a first motor is arranged on the connecting block, and the output end of the first motor is in transmission connection with the prism;

the winding mechanism comprises a ring frame, the ring frame is of a C-shaped structure, a C-shaped toothed ring is embedded in the ring frame in a sliding manner, an insulating tape is arranged on the C-shaped toothed ring, the C-shaped toothed ring and the conductive bar are coaxially arranged, a gear III is rotatably arranged in the ring frame and meshed with the insulating tape, and the gear III is used for driving the insulating tape to rotate around the central axis of the conductive bar.

In a preferred embodiment, the insulating tape is formed by connecting a blank part, an adhesive part and a tearing part in an end-to-end manner continuously, the insulating tape comprises a rotary cylinder rotatably mounted on a C-shaped toothed ring, the film is attached to the periphery of the rotary cylinder, and a regulating roller is further mounted on the annular ring frame and used for tearing the film wound on the conductive bar.

In a preferred embodiment, a third linear adjusting mechanism is installed on the mounting plate, the output end of the third linear adjusting mechanism is connected with the ring frame, the third linear adjusting mechanism comprises two first guide rails, the bottoms of the first guide rails are fixedly installed on the same, second guide rails are slidably installed on the bottoms of the two first guide rails, a sliding frame is slidably installed on the bottoms of the second guide rails, the first guide rails are vertically arranged with the second guide rails, a vertical movable plate is rotatably installed on the sliding frame, and the movable plate is fixedly connected with the ring frame.

In a preferred embodiment, a first gear tooth is formed on one side of the first guide rail, a second motor is fixedly mounted on the second guide rail, the output end of the second motor is connected with a first gear, the first gear is in meshed connection with the first gear tooth, a second gear tooth is formed on the second guide rail, a third motor is fixedly mounted on the sliding frame, the output end of the third motor is connected with a second gear, and the second gear is in meshed connection with the second gear tooth.

In a preferred embodiment, two fold-preventing mechanisms are mounted on the ring frame and used for limiting and guiding the conductive bars, each fold-preventing mechanism comprises a box body fixedly connected with the ring frame, two vertically-distributed limiting blocks are mounted in the box body, a guide roller is rotatably mounted between the two limiting blocks, and the guide roller is in rolling contact with the side edges of the conductive bars.

In a preferred embodiment, a movable rod is connected between the limiting block and the box body, the movable rod movably penetrates through the box body, a spring is sleeved outside the movable rod, and two ends of the spring are respectively connected with the limiting block and the box body.

In a preferred embodiment, a second height adjusting member is mounted on the mounting frame, an output end of the second height adjusting member is connected with the first linear adjusting mechanism, and the second height adjusting member is used for driving the first linear adjusting mechanism to lift.

In a preferred embodiment, a first height adjusting member is further mounted on the mounting frame, an output end of the first height adjusting member is connected to the second linear adjusting mechanism, and the first height adjusting member is used for driving the first linear adjusting mechanism to lift.

In a preferred embodiment, the output end of the first linear adjustment mechanism is connected with a connecting frame, and the end of the connecting frame far away from the first linear adjustment mechanism is detachably connected with the workpiece arrangement frame.

In a preferred embodiment, the device further comprises a mobile vehicle, the mounting frame is detachably mounted on the mobile vehicle, and the mobile vehicle is used for driving the mounting frame to find a position for mounting the conducting bars.

The invention has the beneficial effects that: according to the invention, through the automatic actions of the tightening mechanism and the winding mechanism, the automatic installation of the conducting bars on the circuit breaker of the electric furnace transformer and the automatic winding of the insulating adhesive tape are realized, and the intelligent construction and the installation efficiency are improved.

Drawings

Fig. 1 is a schematic view of the structure of the apparatus of the present invention when installed.

Fig. 2 is a schematic front view of the overall structure of the present invention.

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

Fig. 4 is a schematic side view of the mount of the present invention.

Fig. 5 is a schematic side view of a third linear adjustment mechanism of the present invention.

Fig. 6 is a schematic perspective view of a third linear adjustment mechanism according to the present invention.

Fig. 7 is an enlarged schematic view of the structure of fig. 2 a of the present invention.

Fig. 8 is a schematic structural view of the winding mechanism of the present invention.

Fig. 9 is a schematic cross-sectional view of the winding mechanism of the present invention.

Fig. 10 is an enlarged schematic view of the structure at B in fig. 8 according to the present invention.

Fig. 11 is a schematic structural view of the insulating tape of the present invention.

Fig. 12 is a schematic view of the structure of the conductor bars installed in the present invention.

Fig. 13 is a schematic view of the structure of the installed circuit breaker of the present invention.

In the figure: 1. a mounting frame; 11. a first linear adjustment mechanism; 12. a second linear adjustment mechanism; 13. a connecting frame; 14. a first height adjuster; 15. a second height adjuster; 2. a workpiece arrangement rack; 3. a mounting plate; 4. a tightening mechanism; 41. a connecting block; 42. a first motor; 43. a sleeve; 431. a clamping groove; 44. a prism; 5. a third linear adjustment mechanism; 51. a first guide rail; 511. gear teeth I; 52. a second guide rail; 521. a second motor; 522. a first gear; 523. gear teeth II; 53. a carriage; 531. a third motor; 532. a second gear; 533. a movable plate; 6. a winding mechanism; 61. a ring frame; 611. a third gear; 62. c-shaped toothed ring; 63. an insulating tape; 631. a rotary drum; 632. an adhesive part; 633. a blank section; 634. a tear portion; 64. an adjusting roller; 65. a wrinkle prevention mechanism; 651. a case body; 652. a limiting block; 653. a guide roller; 654. a movable rod; 655. a spring; 100. a circuit breaker; 110. an opening; 120. a screw hole; 200. a conductive bar; 210. a bolt; 220. an insulating part; 300. and (5) moving the vehicle.

Detailed Description

The subject matter described herein will now be discussed with reference to example embodiments. It is to be understood that these embodiments are merely discussed so that those skilled in the art may better understand and implement the subject matter described herein and that changes may be made in the function and arrangement of the elements discussed without departing from the scope of the disclosure herein. Various examples may omit, replace, or add various procedures or components as desired. In addition, features described with respect to some examples may be combined in other examples as well.

The conductive bar 200 of the present invention is mounted on the circuit breaker 100, the mounted circuit breaker 100 is shown with reference to fig. 13, wherein the conductive bar 200 can be in a straight-line type or an L-shaped bent-line type, in this embodiment, a conventional straight-line type conductive bar 200 (shown with reference to fig. 12) is adopted, both ends of the straight-line type conductive bar 200 are provided with through holes, bolts 210 are penetrated into the through holes, the conductive bar 200 is exposed outside the circuit breaker 100, the insulating part 220 is provided with insulating tape 6 wound at the insulating part 220, and electromagnetic influence between adjacent conductive bars 200 is avoided in use; as shown in fig. 13, in the circuit breaker 100 provided by the invention, openings 110 are formed on both sides of the circuit breaker 100, screw holes 120 are formed at the bottom of the openings 110, and the screw holes 120 are matched with bolts 210 on a conductive bar 200.

As shown in fig. 1-13, the installation device for the low-voltage high-current conducting bar of the electric furnace transformer comprises a mounting frame 1, wherein a first linear adjusting mechanism 11 and a second linear adjusting mechanism 12 are installed on the mounting frame 1, the first linear adjusting mechanism 11 and the second linear adjusting mechanism 12 are vertically distributed, the output directions of the first linear adjusting mechanism 11 and the second linear adjusting mechanism 12 are arranged in parallel, a workpiece arrangement frame 2 is installed at the output end of the first linear adjusting mechanism 11, a plurality of conducting bars 200 are arranged on the workpiece arrangement frame 2, a mounting plate 3 is installed at the output end of the second linear adjusting mechanism 12, a tightening mechanism 4 is installed on the mounting plate 3, the tightening mechanism 4 is used for installing and matching a bolt 210 with a screw hole 120, a winding mechanism 6 is also installed on the mounting plate 3, and the winding mechanism 6 is used for winding an adhesive tape on the conducting bar 200 to form an insulating part 220;

the screwing mechanism 4 comprises a connecting block 41, the connecting block 41 is arranged on the mounting plate 3, a sleeve 43 is arranged on the connecting block 41, a vertical clamping groove 431 is formed in the sleeve 43, the clamping groove 431 is matched with the bolt 210, a telescopic prism 44 is arranged in the clamping groove 431, the end part of the prism 44 is matched with the clamping groove at the top of the bolt 210, the prism 44 movably penetrates through the top of an inner cavity of the sleeve 43, a first motor 42 is arranged on the connecting block 41, and the output end of the first motor 42 is in transmission connection with the prism 44;

the winding mechanism 6 comprises a ring frame 61, the ring frame 61 is of a C-shaped structure, a C-shaped toothed ring 62 is embedded in the ring frame 61 in a sliding manner, an insulating adhesive tape 63 is arranged on the C-shaped toothed ring 62, the C-shaped toothed ring 62 and the conductive bar 200 are coaxially arranged, a gear three 611 is rotatably arranged in the ring frame 61, the gear three 611 is meshed with the insulating adhesive tape 63, and the gear three 611 is used for driving the insulating adhesive tape 63 to rotate around the central axis of the conductive bar 200.

It should be noted that, the first linear adjusting mechanism 11 and the second linear adjusting mechanism 12 are both air cylinder members, that is, the fixed ends of the air cylinder members are mounted on the mounting frame 1, while the output ends are respectively connected with the connecting frame 13 and the mounting plate 3, and both are used for linear adjustment distance in the horizontal direction; the workpiece arrangement frame 2 comprises a linear rod, a fixing piece or a clamp is mounted on the linear rod, the fixing piece or the clamp limits the conductive bars 200 on the linear rod, the other end of the conductive bars 200 is a to-be-mounted end, and is in a suspended state, the conductive bars 200 are arranged on the workpiece arrangement frame 2 in a manual or automatic mode, in the embodiment, the workpiece arrangement frame 2 and the connecting frame 13 are detachably connected, namely, each time the conductive bars 200 are mounted, the conductive bars 200 corresponding to the openings 110 of the circuit breaker 100 are arranged on the workpiece arrangement frame 2, so that all the conductive bars 200 on one side of the circuit breaker 100 are mounted in place at one time.

It should be further noted that the cross section of the slot 431 is preferably hexagonal, and is generally designed based on the shape of the bolt 210; the telescopic prism 44 is movably connected with the prism intermediate, and may also be telescopic with a telescopic rod, but it should be noted that the telescopic rod must be telescopic to limit the degree of freedom of rotation.

It should be noted that, the fourth motor is installed on the ring frame 61, and the output end of the fourth motor is in transmission connection with the third gear 611, so as to provide power support for the C-shaped toothed ring 62 to rotate.

In this embodiment, the implementation scenario specifically includes: firstly, installing the workpiece arrangement frame 2 on the output end of a first linear adjusting mechanism 11, then, based on an automatic program, searching the position of the conducting bars 200 to be installed on the circuit breaker 100, conveying the workpiece arrangement frame 2 to the corresponding position through the first linear adjusting mechanism 11, enabling each conducting bar 200 to be matched with the corresponding opening 110, then, moving downwards, and driving the bolts 210 to be aligned with the screw holes 120; the prism 44 moves downwards to be matched and aligned with a clamping groove at the top of the bolt 210, and the motor I42 drives the prism 44 to rotate, so that the bolt 210 is screwed into the screw hole 120, and automatic installation of the conducting bar 200 and the circuit breaker 100 is realized; while mounting, the motor four in the winding mechanism 6 drives the C-shaped toothed ring 62 to rotate, so that the insulating part of the insulating adhesive tape 6 on the conductive strip 200 is wound, and the functions of automatically mounting the conductive strip 200 and winding the insulating adhesive tape 6 on the conductive strip 200 are realized.

The insulating tape 63 is formed by connecting a continuous blank 633, an adhesive 632 and a tearing 634 end to end, the insulating tape 63 comprises a rotary drum 631, the rotary drum 631 is rotatably mounted on the C-shaped gear ring 62, the film is attached to the periphery of the rotary drum 631, the ring frame 61 is also mounted with a regulating roller 64, and the regulating roller 64 is used for tearing the film wound on the conductive strip 200.

It should be noted that, the length of the bonding portion 632 is adapted to the length of the adhesive tape to be wound on the conductive strip 200, the blank portion 633 is used for being naturally hung down when the adhesive tape is not wound, so that the mechanical energy can quickly find out the end portion of the film, and the tearing portion 634 is a plurality of continuous impressions and hollows, similar to the structure of the connecting end of the garbage bag; the adjusting roller 64 includes a telescopic rod and a roller body, and an output end of the telescopic rod is connected to the roller body, for pressing the blank 633 and the adhesive portion 632, which naturally hang down, on the surface of the conductive strip 200, so that the adhesive tape can form the insulating portion 220 on the conductive strip 200, and after winding is completed, a supporting force can be provided for the film, and the film can be torn off.

The mounting plate 3 is provided with a third linear adjusting mechanism 5, the output end of the third linear adjusting mechanism 5 is connected with the circular ring frame 61, the third linear adjusting mechanism 5 comprises two first guide rails 51, the first guide rails 51 are fixedly arranged at the bottoms of the first guide rails 31, the bottoms of the two first guide rails 51 are slidably provided with second guide rails 52, the bottoms of the second guide rails 52 are slidably provided with sliding frames 53, the first guide rails 51 and the second guide rails 52 are vertically arranged, the sliding frames 53 are rotatably provided with vertical movable plates 533, and the movable plates 533 are fixedly connected with the circular ring frame 61.

The third linear adjustment mechanism 5 may implement distance adjustment of the winding mechanism 6 in two directions on the horizontal plane.

One side of the first guide rail 51 is provided with a first gear tooth 511, the second guide rail 52 is fixedly provided with a second motor 521, the output end of the second motor 521 is connected with a first gear 522, the first gear 522 is in meshed connection with the first gear tooth 511, the second guide rail 52 is provided with a second gear tooth 523, the sliding frame 53 is fixedly provided with a third motor 531, the output end of the third motor 531 is connected with a second gear 532, and the second gear 532 is in meshed connection with the second gear tooth 523.

In one embodiment of the invention, two anti-wrinkling mechanisms 65 are arranged on the ring frame 61, the two anti-wrinkling mechanisms 65 limit and guide the conductive bar 200, the anti-wrinkling mechanisms 65 comprise a box body 651, the box body 651 is fixedly connected with the ring frame 61, two limiting blocks 652 which are vertically distributed are arranged in the box body 651, a guide roller 653 is rotatably arranged between the two limiting blocks 652, and the guide roller 653 is in rolling contact with the side edge of the conductive bar 200;

a movable rod 654 is connected between the limiting block 652 and the box body 651, the movable rod 654 movably penetrates through the box body 651, a spring 655 is sleeved outside the movable rod 654, and two ends of the spring 655 are respectively connected with the limiting block 652 and the box body 651.

During the process of screwing the bolt 210 into the screw hole 120 by the tightening mechanism 4, the conductive bar 200 is easily offset around the bolt 210 due to the influence of friction force, so that when the adhesive tape is wound, the distances between the surfaces and the insulating tape 6 are different, which causes the insulating part 220 to be wrinkled and affects the insulation protection performance; in the present embodiment, the above-described problems can be solved well by rotationally connecting the winding mechanism 6 with the output end of the third linear adjusting mechanism 5, and providing the wrinkle preventing mechanism 65; specifically, before the insulating adhesive tape 6 needs to be wound on the surface of the conductive bar 200, the conductive bar 200 is inserted between 2 guide rollers 653, so that the conductive bar 200 is clamped in a groove formed between the two limiting blocks 652 and the guide rollers 653, the conductive bar 200 is limited, the conductive bar 200 is prevented from being deviated, and the regular winding is ensured; even if the conductive strip 200 is still offset, under the limitation of the groove formed between the two limiting blocks 652 and the guide roller 653, the conductive strip 200 can drive the winding mechanism 6 to offset and rotate together due to the rotational connection of the winding mechanism 6 and the output end of the third linear adjusting mechanism 5, so that the rotating surface of the winding mechanism 6 is always perpendicular to the central line axis of the conductive strip 200, and further, the situation that the insulating tape 6 is wound on the conductive strip 200 to generate wrinkles is avoided.

The mounting frame 1 is provided with a second height adjusting piece 15, the output end of the second height adjusting piece 15 is connected with the first linear adjusting mechanism 11, and the second height adjusting piece 15 is used for driving the first linear adjusting mechanism 11 to lift.

The mounting frame 1 is also provided with a first height adjusting piece 14, the output end of the first height adjusting piece 14 is connected with the second linear adjusting mechanism 12, and the first height adjusting piece 14 is used for driving the first linear adjusting mechanism 11 to lift.

The output end of the first linear adjusting mechanism 11 is connected with a connecting frame 13, and the end part of the connecting frame 13 far away from the first linear adjusting mechanism 11 is detachably connected with the workpiece arrangement frame 2.

It should be noted that, the connecting frame 13 is provided with a chute, and the workpiece arranging frame 2 is slidably connected with the connecting frame 13, so as to facilitate quick assembly and disassembly.

The busbar installation device further comprises a trolley 300, the installation frame 1 is detachably installed on the trolley 300, and the trolley 300 is used for driving the installation frame 1 to find a position for installing the busbar 200.

The embodiment has been described above with reference to the embodiment, but the embodiment is not limited to the above-described specific implementation, which is only illustrative and not restrictive, and many forms can be made by those of ordinary skill in the art, given the benefit of this disclosure, are within the scope of this embodiment.

Claims (10)

1. The utility model provides a high-current conducting bar erection equipment of electric furnace transformer low pressure, its characterized in that, including mounting bracket (1), install first straight line adjustment mechanism (11) and second straight line adjustment mechanism (12) on mounting bracket (1), first straight line adjustment mechanism (11) and second straight line adjustment mechanism (12) vertical distribution, just the output direction parallel arrangement of first straight line adjustment mechanism (11) and second straight line adjustment mechanism (12), work piece frame (2) are arranged in the output of first straight line adjustment mechanism (11), a plurality of conducting bars (200) are arranged on work piece frame (2) are arranged, mounting panel (3) are installed in the output of second straight line adjustment mechanism (12), install tightening mechanism (4) on mounting panel (3), tightening mechanism (4) are used for installing bolt (210) and screw (120) cooperation, still install winding mechanism (6) on mounting panel (3), winding mechanism (6) are used for twining on conducting bars (200) and form insulating part (220);

the tightening mechanism (4) comprises a connecting block (41), the connecting block (41) is arranged on the mounting plate (3), a sleeve (43) is arranged on the connecting block (41), a vertical clamping groove (431) is formed in the sleeve (43), the clamping groove (431) is matched with the bolt (210), a telescopic prism (44) is arranged in the clamping groove (431), the end part of the prism (44) is matched with the clamping groove at the top of the bolt (210), the prism (44) movably penetrates through the top of an inner cavity of the sleeve (43), a first motor (42) is arranged on the connecting block (41), and the output end of the first motor (42) is connected with the prism (44) in a transmission manner;

the winding mechanism (6) comprises a ring frame (61), the ring frame (61) is of a C-shaped structure, a C-shaped toothed ring (62) is embedded in the ring frame (61) in a sliding mode, an insulating adhesive tape (63) is installed on the C-shaped toothed ring (62), the C-shaped toothed ring (62) and the conductive bar (200) are coaxially arranged, a gear III (611) is installed in the ring frame (61) in a rotating mode, the gear III (611) is meshed with the insulating adhesive tape (63), and the gear III (611) is used for driving the insulating adhesive tape (63) to rotate around the central axis of the conductive bar (200).

2. The electric furnace transformer low-voltage high-current conducting bar mounting equipment according to claim 1, wherein the insulating tape (63) is formed by connecting a blank part (633), an adhesive part (632) and a tearing part (634) continuously end to end, the insulating tape (63) comprises a rotary drum (631), the rotary drum (631) is rotatably mounted on a C-shaped toothed ring (62), the film is attached to the periphery of the rotary drum (631), a regulating roller (64) is further mounted on the annular frame (61), and the regulating roller (64) is used for tearing the film wound on the conducting bar (200).

3. The electric furnace transformer low-voltage high-current conducting bar mounting device according to claim 2, wherein a third linear adjusting mechanism (5) is mounted on the mounting plate (3), an output end of the third linear adjusting mechanism (5) is connected with the circular ring frame (61), the third linear adjusting mechanism (5) comprises two first guide rails (51), the first guide rails (51) are fixedly mounted at the bottoms of the first guide rails (31), second guide rails (52) are slidably mounted at the bottoms of the two first guide rails (51), a sliding frame (53) is slidably mounted at the bottoms of the second guide rails (52), the first guide rails (51) are vertically arranged with the second guide rails (52), a vertical movable plate (533) is rotatably mounted on the sliding frame (53), and the movable plate (533) is fixedly connected with the circular ring frame (61).

4. The electric furnace transformer low-voltage high-current conducting bar installation device according to claim 3, wherein one side of the first guide rail (51) is provided with a first gear tooth (511), the second guide rail (52) is fixedly provided with a second motor (521), the output end of the second motor (521) is connected with a first gear (522), the first gear (522) is in meshed connection with the first gear tooth (511), the second guide rail (52) is provided with a second gear tooth (523), the sliding frame (53) is fixedly provided with a third motor (531), the output end of the third motor (531) is connected with a second gear (532), and the second gear (532) is in meshed connection with the second gear tooth (523).

5. The electric furnace transformer low-voltage high-current conducting bar installation device according to claim 4, wherein two anti-wrinkling mechanisms (65) are installed on the circular ring frame (61), the two anti-wrinkling mechanisms (65) limit and guide the conducting bar (200), the anti-wrinkling mechanisms (65) comprise a box body (651), the box body (651) is fixedly connected with the circular ring frame (61), two vertically distributed limiting blocks (652) are installed in the box body (651), guide rollers (653) are rotatably installed between the two limiting blocks (652), and the guide rollers (653) are in rolling contact with the side edges of the conducting bar (200).

6. The electric furnace transformer low-voltage high-current conducting bar installation device according to claim 5, wherein a movable rod (654) is connected between the limiting block (652) and the box body (651), the movable rod (654) is movably penetrated through the box body (651), a spring (655) is sleeved outside the movable rod (654), and two ends of the spring (655) are respectively connected with the limiting block (652) and the box body (651).

7. The electric furnace transformer low-voltage high-current conducting bar installation device according to claim 6, wherein a second height adjusting piece (15) is installed on the installation frame (1), the output end of the second height adjusting piece (15) is connected with the first linear adjusting mechanism (11), and the second height adjusting piece (15) is used for driving the first linear adjusting mechanism (11) to lift.

8. The electric furnace transformer low-voltage high-current conducting bar installation device according to claim 7, wherein a first height adjusting piece (14) is further installed on the installation frame (1), the output end of the first height adjusting piece (14) is connected with the second linear adjusting mechanism (12), and the first height adjusting piece (14) is used for driving the first linear adjusting mechanism (11) to lift.

9. The electric furnace transformer low-voltage high-current conducting bar installation device according to claim 8, wherein the output end of the first linear adjusting mechanism (11) is connected with a connecting frame (13), and the end of the connecting frame (13) far away from the first linear adjusting mechanism (11) is detachably connected with the workpiece arrangement frame (2).

10. The electric furnace transformer low-voltage high-current conductor bar mounting device according to claim 9, further comprising a moving vehicle (300), wherein the mounting frame (1) is detachably mounted on the moving vehicle (300), and the moving vehicle (300) is used for driving the mounting frame (1) to find a position for mounting the conductor bar (200).