CN112821317B - Intensive bus duct and processing mode thereof - Google Patents

Abstract

The invention relates to the technical field of bus ducts, and discloses a compact bus duct which comprises two first plate bodies, second plate bodies and third plate bodies which are symmetrically distributed in front-back mode, wherein connecting plates are uniformly formed at the left parts of opposite sides of the two first plate bodies, protruding blocks are uniformly formed at the opposite sides of the two connecting plates, grooves are uniformly formed at the right parts of opposite sides of the two first plate bodies, and the grooves correspond to the protruding blocks; when the intelligent fire extinguishing device is used, the interior of the bus duct can be monitored in real time through the temperature sensor and the smoke sensor, after the condition that the interior of the bus duct is on fire is monitored, signals can be fed back to the singlechip, the singlechip can start the electromagnetic valve at the moment, fire extinguishing liquid in the second plate body is sprayed out through a plurality of spray holes on the guide pipe, so that fire in the bus duct can be extinguished timely, and the situation that the fire cannot be timely extinguished to cause the increase of fire is avoided, so that serious safety accidents and serious economic loss are caused is avoided.

Description

Intensive bus duct and processing mode thereof

Technical Field

The invention relates to the technical field of bus ducts, in particular to an intensive bus duct and a processing mode thereof.

Background

The bus duct is a closed metal device composed of copper and aluminum bus columns and is used for distributing larger power for each element of the dispersion system. The novel conductor is formed by taking copper or aluminum as a conductor, supporting the conductor by non-olefinic insulation and then installing the conductor in a metal groove, and now forms an indispensable wiring mode on electric equipment and power systems of high-rise buildings, factories and the like.

Disclosure of Invention

(one) solving the technical problems

Aiming at the defects of the prior art, the invention provides a compact bus duct and a processing mode thereof, and solves the problems in the background art.

(II) technical scheme

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a compact bus duct, includes two front and back symmetric distribution's first plate body, second plate body and third plate body, two the homogeneous shaping in opposite side left part of first plate body has the connecting plate, two the homogeneous shaping in opposite side of connecting plate has the lug, two the homogeneous shaping in opposite side right part of first plate body has the recess, the recess corresponds with the lug, two between the first plate body symmetry be fixed with insulating support, two equidistant copper bar that is equipped with between the insulating support plate, two are run through respectively to the both ends of copper bar insulating support, just the right-hand member of copper bar is fixed with the insulating cover, the insulating cover is right side open-ended cavity cuboid structure, just the inside upper surface and the inside lower surface of insulating cover all inlay and are fixed with the electro-magnet, the inside symmetry of insulating cover is equipped with the conducting block, the two conductive blocks are symmetrically fixed with conductive springs on opposite sides, one sides of the conductive springs, which are far away from the conductive blocks, are fixedly connected with the inner upper surface and the inner lower surface of the insulating sleeve respectively, the inner upper surface and the inner lower surface of the insulating sleeve are both fixed with moisture absorption pads, the rear surfaces of the two first plate bodies are provided with third plate bodies, connecting sleeves are fixed at four corners of the front surface of each third plate body, the four connecting sleeves are hollow cylindrical structures with front surface openings, the four connecting sleeves penetrate through the two first plate bodies respectively, through holes penetrating through the connecting sleeves are formed in the third plate bodies, the inner symmetrical integrated forming of the third plate bodies is provided with a partition plate, a main plate is fixed between the two partition plates, the front surface of the main plate is fixedly provided with a singlechip, and the front surface of mainboard is located the right side of singlechip is fixed with positioning module, the front surface of mainboard is located positioning module's below is fixed with wireless transmission module, the inside of third plate body is located two the opposite sides of baffle all is fixed with the battery, the front surface from the top down of third plate body is fixed with temperature sensor and smoke transducer respectively, two the front surface of first plate body is equipped with the second plate body, the second plate body is hollow structure, just the inside rear surface center department of second plate body is fixed with the solenoid valve, the output of solenoid valve is located the rear of second plate body is fixed with the pipe, a plurality of orifices have been seted up from left to right to the lateral wall equidistance of pipe, four corners of the rear surface of second plate body all are fixed with the inserted bar, and four the inserted bar is respectively pegged graft in four the inside of adapter sleeve, and four inside of inserted bar all are equipped with the pulling block, the inside rear surface center of the second plate body is fixed with the elastic connection of two skirt pull blocks, two the inside the front surface of skirt body is equipped with the elastic connection, the surface of skirt body is kept away from the front surface of two elastic connection, the front surface of skirt body is fixed with the elastic connection.

Preferably, the cross sections of the convex blocks and the concave grooves are arc-shaped structures.

Preferably, opposite sides of the two conductive blocks are both spherical structures.

Preferably, the inner front surface and the inner rear surface of the insulating sleeve are provided with clamping grooves, and the clamping grooves are matched with the copper bars.

Preferably, the outer side wall of the inserted link is fixed with a rubber sleeve, and the rubber sleeve is made of rubber with good elasticity.

Preferably, the outer side wall of the guide pipe is symmetrically fixed with connecting rods about the spray holes, and one ends of the two connecting rods, which are far away from the guide pipe, are both fixed with a disc body.

Preferably, the inner rear surface of the second plate body is of a funnel-shaped structure.

Preferably, the front surface of the connecting sleeve is flush with the front surface of the first plate body.

Preferably, the processing mode of the intensive bus duct comprises the following steps of:

s1, integrally forming a first plate body and parts on the first plate body through a die or a stamping device, preparing two first plate bodies through the die or the stamping device, and forming reserved holes on the two first plate bodies through a drilling device;

s2, fixing two insulating supports between the two first plate bodies, enabling a plurality of copper bars to sequentially penetrate through the two insulating supports, and then coating insulating glue between the copper bars and the insulating supports to enable the copper bars and the insulating supports to be fixed;

s3, pouring an insulating sleeve by using a material with good insulating property through a die, opening a clamping groove on the inner wall of the junction sleeve, embedding a fixed electromagnet on the inner wall of the insulating sleeve, fixing a conductive spring on the inner wall of the insulating sleeve, fixing a conductive block at one end of the conductive spring, fixing the insulating sleeve at one end of a copper bar, and fixing a moisture absorption sheet in the insulating sleeve;

s4, preparing a cuboid box body with two partition boards and an opening inside by using punching equipment or a die, sequentially installing a storage battery and a main board with a singlechip, a positioning module and a wireless transmission module at corresponding positions of the box body, arranging wires, sealing the box body by using a plate to form a third plate body, fixing four cylindrical rods on the sealed plate, drilling holes on the four cylindrical rods by using drilling equipment to form a connecting sleeve and a through hole, wherein the through hole extends to the rear surface of the third plate body, and enabling the connecting sleeve to penetrate through a reserved hole on the first plate body;

s5, preparing an open cuboid box body by using punching equipment or a die, installing an electromagnetic valve at the middle position of a plate with high middle part at the inner side, fixing a guide pipe at the output end of the electromagnetic valve, arranging a plurality of spray holes on the outer wall of the guide pipe, fixing connecting rods at two sides of the spray holes, fixing a disc body on the connecting rods, fixing four inserted bars on the plate body, fixing a rubber sleeve on the outer wall of the inserted bars, installing a lifting block with a spring and a pull rope in the inserted bars, fixing one end of the spring and the inserted bars together, fixing an elastic plate which rotates mutually at one end of the pull rope, and sealing the box body by using the plate to form a second plate body;

s6, attaching the second plate body to the two first plate bodies, pulling the lifting block to enable the pull rope to drive the two elastic plates to be closed, enabling the inserting rod on the second plate body to be inserted into the connecting sleeve and penetrate through the through hole, then opening the lifting block, and under the action of the spring, enabling the two elastic plates to spring and attach to the rear surface of the third plate body, so that the first plate body, the second plate body and the third plate body can be mutually fixed, and finally the whole bus duct is formed.

(III) beneficial effects

The invention provides an intensive bus duct and a processing mode thereof, which have the following beneficial effects:

(1) When the intelligent fire extinguishing device is used, the interior of the bus duct can be monitored in real time through the temperature sensor and the smoke sensor, and when the condition that fire occurs in the interior of the bus duct is monitored, signals are fed back to the singlechip, and the singlechip starts the electromagnetic valve at the moment, so that fire extinguishing liquid in the second plate body is sprayed out through the plurality of spray holes on the guide pipe, and the fire in the bus duct can be extinguished in time, so that the condition that the fire cannot be extinguished in time to increase, and serious safety accidents and serious economic losses are caused is avoided.

(2) When the temperature sensor and the smoke sensor monitor the internal fire of the bus duct and feed signals back to the singlechip, the singlechip controls the electromagnetic valve to start and simultaneously electrifies the electromagnet, and the electromagnet attracts the conductive block, so that the conductive block is separated from the copper bar, the copper bar is further powered off, the copper bar is prevented from being always in a powered-on state, and the fire is easy to aggravate.

(3) In the using process, when the bus grooves are connected and fixed, the two connecting plates on one bus groove are inserted into the two bus grooves more conveniently and rapidly, and the convex blocks on the connecting plates can be clamped into the grooves on the first plate body, so that the two bus grooves can be spliced and installed completely, and the later disassembly and maintenance work is convenient.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention;

FIG. 2 is a schematic view of the internal structure of the present invention;

FIG. 3 is a schematic view showing the internal structure of a second plate according to the present invention;

FIG. 4 is a schematic view showing the internal structure of a third plate according to the present invention;

FIG. 5 is a schematic view of the inner part of the connecting sleeve according to the present invention;

fig. 6 is an enlarged schematic view of the structure of fig. 3 a in the present invention.

In the figure: 1. a connecting plate; 2. a copper bar; 3. a bump; 4. a second plate body; 5. connecting sleeves; 6. a first plate body; 7. a temperature sensor; 8. an insulating support; 9. a groove; 10. a through hole; 11. an insulating sleeve; 12. a smoke sensor; 13. a third plate body; 14. a rod; 15. a conduit; 16. a spray hole; 17. an electromagnetic valve; 18. a connecting rod; 19. a tray body; 20. a rubber sleeve; 21. a storage battery; 22. a partition plate; 23. a single chip microcomputer; 24. a main board; 25. a positioning module; 26. a wireless transmission module; 27. a clamping groove; 28. a conductive spring; 29. an electromagnet; 30. a conductive block; 31. an absorbent sheet; 32. lifting the block; 33. a pull rope; 34. an elastic plate; 35. a spring; 36. and a trailing edge skirt.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

As shown in fig. 1-6, the present invention provides a technical solution: the utility model provides a compact bus duct, including two first plate body 6 of front and back symmetric distribution, second plate body 4 and third plate body 13, the left portion homogeneous shaping of opposite side of two first plate body 6 has connecting plate 1, the homogeneous shaping of opposite side of two connecting plates 1 has lug 3, the right portion homogeneous shaping of opposite side of two first plate body 6 has recess 9, recess 9 corresponds with lug 3, symmetrically be fixed with insulating support 8 between two first plate body 6, equidistant copper bar 2 that is equipped with between two insulating support plates 8, two both ends of copper bar 2 run through two insulating support 8 respectively, and the right-hand member of copper bar 2 is fixed with insulating cover 11, insulating cover 11 is right side open-ended cavity cuboid structure, and the inside upper surface and the inside lower surface of insulating cover 11 all set firmly and are fixed with electro-magnet 29, the inside symmetry of insulating cover 11 is equipped with electrically conductive piece 30, the conductive springs 28 are symmetrically fixed on the opposite sides of the two conductive blocks 30, one sides of the plurality of conductive springs 28 far away from the conductive blocks 30 are fixedly connected with the inner upper surface and the inner lower surface of the insulating sleeve 11 respectively, the inner upper surface and the inner lower surface of the insulating sleeve 11 are both fixed with the moisture absorption pad 31, the rear surfaces of the two first plate bodies 6 are provided with the third plate bodies 13, the four corners of the front surface of the third plate bodies 13 are both fixed with the connecting sleeves 5, the four connecting sleeves 5 are hollow cylindrical structures with the front surface opened, the four connecting sleeves 5 respectively penetrate through the two first plate bodies 6, the through holes 10 are formed in the connecting sleeves 5, the third plate bodies 13 are hollow structures, the inner symmetrical integrated forming of the third plate bodies 13 is provided with the partition plates 23, the inner part of the third plate bodies 13 is positioned between the two partition plates 23 and is fixed with the main plate 24, the front surface of the main plate 24 is fixed with the singlechip 23, the front surface of the main board 24 is positioned on the right side of the singlechip 23 and is fixedly provided with a positioning module 25, the front surface of the main board 24 is positioned below the positioning module 25 and is fixedly provided with a wireless transmission module 26, the inside of the third board 13 is positioned on the opposite sides of the two partition boards 22 and is fixedly provided with a storage battery 21, the front surface of the third board 13 is respectively and fixedly provided with a temperature sensor 7 and a smoke sensor 12 from top to bottom, the front surface of the two first boards 6 is provided with a second board 4, the second board 4 is of a hollow structure, the center of the inner rear surface of the second board 4 is fixedly provided with an electromagnetic valve 17, the output end of the electromagnetic valve 17 is positioned behind the second board 4 and is fixedly provided with a guide pipe 15, the outer side wall of the guide pipe 15 is provided with a plurality of spray holes 16 from left to right and equidistant, four corners of the rear surface of the second board 4 are fixedly provided with inserted bars 14, the four inserted bars 14 are of a hollow cylindrical structure with openings at the bottom, the four inserting rods 14 are respectively inserted into the four connecting sleeves 5, the lifting blocks 32 are arranged in the four inserting rods 14, the rear edge skirt 36 is integrally formed on the rear surface of the lifting blocks 32, springs 35 are symmetrically fixed on the front surface of the rear edge skirt 36, the front ends of the springs 35 are fixedly connected with the inner front surface of the inserting rods 14, pull ropes 33 are fixed at the center of the rear surface of the lifting blocks 32, elastic plates 34 are symmetrically arranged on the rear surface of the inserting rods 14, the two elastic plates 34 are rotationally connected, one end of each pull rope 33 far away from the lifting blocks 32 is fixedly connected with the middle parts of the two elastic plates 34, when in use, bus grooves on each position are numbered in advance, the numbers are stored in the single chip microcomputer 23 in the third plate body 13 corresponding to the bus groove, when in installation and splicing of the bus grooves, the two connecting plates 1 on one bus groove are inserted into the two bus grooves, the lug 3 on the connecting plate 1 can be clamped into the groove 9 on the first plate body 6, one end of a plurality of copper bars 2 in one bus duct can be inserted into the insulating sleeve 11 on the other end of the plurality of copper bars 2 in the other bus duct, the conductive block in the insulating sleeve 11 can be attached to the copper bars 2, thereby the copper bars 2 in the two bus ducts can be electrically connected, the plurality of bus ducts can be conveniently and rapidly assembled and installed in the using process, after the condition that the temperature sensor 7 and the smoke sensor 12 in one bus duct detect fire in the bus duct, signals are fed back to the singlechip 23, the electromagnetic valve 17 is started at the moment, the fire extinguishing liquid in the second plate body 4 is sprayed out through the plurality of spray holes 16 on the guide pipe 15, the singlechip 23 can enable the electromagnet 29 to be electrified, the conductive block 30 to be separated from the copper bars 2, the temperature sensor 7 and the smoke sensor 12 in the first bus duct can detect fire in the bus duct, the second bus duct can be accurately controlled by the singlechip, the position of the second plate body is accurately controlled by the aid of the wireless control device, the maintenance plate is accurately positioned on the bus duct 25, and the second plate body is conveniently and the maintenance plate is conveniently separated from the bus duct 13, and the maintenance plate is accurately located by the position of the bus duct is conveniently and can be conveniently and automatically maintained by the maintenance plate 13, and can be conveniently and automatically kept up.

Further, the cross sections of the protruding blocks 3 and the grooves 9 are arc-shaped structures, so that the splicing installation and the disassembly among the plurality of bus grooves are facilitated.

Further, the opposite sides of the two conductive blocks 30 are both spherical structures, so that the copper bar 2 can be inserted into the insulating sheath 11.

Further, draw-in groove 27 has all been seted up to the inside front surface and the inside rear surface of insulating boot 11, and draw-in groove 27 and copper bar 2 looks adaptation, and after copper bar 2 inserted insulating boot 11 in, the top and the bottom of copper bar 2 can block into draw-in groove 27 to top surface and bottom surface can laminate together with the internal surface of draw-in groove 27, avoid taking place the condition of rocking between two sections bus duct.

Further, the outer side wall of the insert rod 14 is fixed with a rubber sleeve 20, the rubber sleeve 20 is made of rubber with good elasticity, when the insert rod 14 is inserted into the connecting sleeve 5, the rubber sleeve 20 can fill gaps between the insert rod 14 and the connecting sleeve 5, and meanwhile friction between the insert rod 14 and the connecting sleeve 5 can be increased.

Further, the outer side wall of the conduit 15 is symmetrically fixed with a connecting rod 18 about the spray hole 16, one end of each connecting rod 18 far away from the conduit 15 is fixed with a tray 19, and when the fire extinguishing liquid is sprayed out from the spray hole 16, the fire extinguishing liquid collides with the tray 19, so that the fire extinguishing liquid splashes, and the fire extinguishing range is wider.

Further, the inside rear surface of the second plate body 4 is of a funnel-shaped structure, so that the fire extinguishing liquid can flow out conveniently.

Further, the front surface of the connecting sleeve 5 is flush with the front surface of the first plate body 6, so that the situation that the second plate body 4 cannot be tightly connected with the two first plate bodies 6 is avoided.

Further, a processing mode of the intensive bus duct comprises the following steps:

s1, integrally forming a first plate body 6 and parts on the first plate body through a die or a stamping device, preparing two first plate bodies 6 through the die or the stamping device, and forming reserved holes on the two first plate bodies 6 through a drilling device;

s2, fixing two insulation supports 8 between the two first plate bodies 6, enabling a plurality of copper bars 2 to sequentially penetrate through the two insulation supports 8, and then coating insulation glue between the copper bars 2 and the insulation supports 8 to enable the copper bars 2 to be fixed with the insulation supports;

s3, pouring an insulating sleeve 11 through a die by utilizing a material with good insulating performance, opening a clamping groove 27 on the inner wall of the junction sleeve 11, embedding a fixed electromagnet 29 on the inner wall of the insulating sleeve 11, fixing a conductive spring 28 on the inner wall of the insulating sleeve 11, fixing a conductive block 30 at one end of the conductive spring 28, fixing the insulating sleeve 11 at one end of a copper bar 2, and fixing a moisture absorption sheet 31 in the insulating sleeve 11;

s4, preparing a cuboid box body with two partition plates 22 inside and an opening by using punching equipment or a die, sequentially installing a storage battery 21 and a main board 24 with a singlechip 23, a positioning module 25 and a wireless transmission module 26 at corresponding positions of the box body, arranging wires, sealing the box body by using a plate to form a third plate body 13, fixing four cylindrical rods on the sealed plate, drilling holes on the four cylindrical rods by using drilling equipment to form a connecting sleeve 5 and a through hole 10, wherein the through hole 10 extends to the rear surface of the third plate body 13, and enabling the connecting sleeve 5 to penetrate through a reserved hole on the first plate body 6;

s5, preparing an open cuboid box body by using punching equipment or a die, installing an electromagnetic valve 17 at the middle position of a plate with high periphery and low middle at the inner side, fixing a guide pipe 15 at the output end of the electromagnetic valve 17, forming a plurality of spray holes 16 on the outer wall of the guide pipe 15, fixing connecting rods 18 on two sides of the spray holes 16, fixing a disc 19 on the connecting rods 18, fixing four inserted bars 14 on the plate body, fixing a rubber sleeve 20 on the outer wall of the inserted bars 14, installing a lifting block 32 with a spring 35 and a pull rope 33 in the inserted bars, fixing one end of the spring 35 with the inserted bars 14, fixing an elastic plate 34 which rotates mutually at one end of the pull rope, and sealing the box body by using the plate to form a second plate body 4;

s6, attaching the second plate body 4 to the two first plate bodies 6, pulling the lifting blocks 32, enabling the pull ropes 34 to drive the two elastic plates 34 to be closed, enabling the inserting rods 14 on the second plate body 4 to be inserted into the connecting sleeves 5 and penetrate through the through holes 10, then bouncing off the lifting blocks 32 from the opening under the action of the springs 35, attaching the two elastic plates 34 to the rear surface of the third plate body 13, and accordingly fixing the first plate body 6, the second plate body 4 and the third plate body 13 to each other, and finally forming the whole bus duct.

To sum up, the workflow of the invention: when the bus duct is used, the bus duct on each position is numbered in advance, and the numbers are stored in the single chip microcomputer 23 in the corresponding bus duct third plate body 13, when the bus duct is assembled, the two connecting plates 1 on one bus duct are inserted into the two bus ducts, at the moment, the bump 3 on one bus duct 1 can be clamped into the groove 9 on the first plate body 6, at the moment, one end of the copper bars 2 in one bus duct can be inserted into the insulating sleeve 11 on the other end of the copper bars 2 in the other bus duct, at the moment, the conducting blocks in the insulating sleeve 11 can be attached to the copper bars 2, so that the copper bars 2 in the two bus ducts can be electrically connected, the plurality of bus ducts can be conveniently and quickly assembled in a use process, after the temperature sensor 7 and the smoke sensor 12 in one bus duct detect the condition of a fire hole in the bus duct, signals are fed back to the starter microcomputer 23, the single chip microcomputer 17 can enable one end of the copper bars 2 to be inserted into the insulating sleeve 11, at the moment, the conducting blocks in the insulating sleeve 11 can be attached to the copper bars 2 in the bus duct 2, the electromagnetic valve can be conveniently and quickly pulled out of the bus duct 30 through the electromagnetic valve 16, and the position of the electromagnetic valve 30 can be conveniently and quickly pulled out of the bus duct 30, and the position of the electromagnetic valve can be conveniently and accurately controlled, and the position of the bus duct can be conveniently and opened to the bus duct 30, and the bus duct can be conveniently and opened through the electromagnetic valve 30, and the position can be conveniently and opened to the position and the bus duct 30, and then the second plate body 4 and the third plate body 13 are directly pulled up and down, so that the second plate body 4 and the third plate body 13 are separated from the bus duct, and maintenance personnel can conveniently maintain the bus duct.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations can be made therein without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (9)

1. The utility model provides an intensive bus duct, includes two around symmetric distribution's first plate body (6), second plate body (4) and third plate body (13), its characterized in that: the left part of the opposite sides of the two first plate bodies (6) are uniformly formed with connecting plates (1), the right parts of the opposite sides of the two connecting plates (1) are uniformly formed with bumps (3), the right parts of the opposite sides of the two first plate bodies (6) are uniformly formed with grooves (9), the grooves (9) correspond to the bumps (3), insulating supports (8) are symmetrically fixed between the two first plate bodies (6), copper bars (2) are equidistantly arranged between the two insulating supports (8), two ends of each copper bar (2) respectively penetrate through the two insulating supports (8), the right ends of each copper bar (2) are fixedly provided with insulating sleeves (11), each insulating sleeve (11) is of a hollow cuboid structure with an opening on the right side, electromagnets (29) are embedded and fixed on the inner upper surface and the inner lower surface of each insulating sleeve (11), conductive blocks (30) are symmetrically arranged in the inner parts of the insulating sleeves (11), a plurality of conductive springs (28) are symmetrically fixed on the opposite sides of the two conductive blocks (30), the inner surfaces of the conductive blocks (28) are respectively connected with the inner surfaces of the inner surfaces (28) of the insulating sleeves (11), the inner surfaces of the insulating sleeves (11) are respectively fixed on the inner surfaces of the insulating sleeves (30), the back surfaces of the two first plate bodies (6) are provided with third plate bodies (13), connecting sleeves (5) are fixed at four corners of the front surface of each third plate body (13), four connecting sleeves (5) are hollow cylindrical structures with front surfaces open, the four connecting sleeves (5) penetrate through the two first plate bodies (6) respectively, through holes (10) penetrating through the connecting sleeves (5) are formed in the connecting sleeves (5), the third plate bodies (13) are of hollow structures, partition plates (23) are symmetrically and integrally formed in the third plate bodies (13), a main board (24) is fixed between the two partition plates (23) in the third plate bodies (13), a single chip microcomputer (23) is fixed on the front surface of each main board (24), a positioning module (25) is fixed on the right side of each single chip microcomputer (23), a wireless transmission module (26) is fixed on the front surface of each main board (24) below the positioning module (25), a wireless sensor (21) is fixed on the back surface of each third plate body (13), a temperature sensor (21) is fixed on the front surface of each third plate body (13), the front surfaces of the two first plate bodies (6) are provided with the second plate bodies (4), the second plate bodies (4) are of hollow structures, electromagnetic valves (17) are fixed at the centers of the inner rear surfaces of the second plate bodies (4), the output ends of the electromagnetic valves (17) are positioned behind the second plate bodies (4), guide pipes (15) are fixed at the rear sides of the guide pipes (15), a plurality of spray holes (16) are formed in the outer side walls of the guide pipes (15) at equal intervals from left to right, inserted rods (14) are fixed at four corners of the rear surfaces of the second plate bodies (4), the four inserted rods (14) are of hollow cylindrical structures with openings at the bottoms, the four inserted rods (14) are respectively inserted into the four connecting sleeves (5), lifting blocks (32) are arranged in the four inserted rods (14), rear surfaces of the lifting blocks (32) are integrally formed with rear edge skirts (36), springs (35) are symmetrically fixed on the front surfaces of the rear edge skirts (36), the front surfaces of the springs (35) are symmetrically connected with the front surfaces of the lifting blocks (14), the front surfaces of the lifting blocks (14) are symmetrically connected with the front surfaces of the lifting blocks (34), the elastic plates (34) are fixedly connected with the centers of the front surfaces of the lifting blocks (14), one end of the pull rope (33) far away from the lifting block (32) is fixedly connected with the middle parts of the two elastic plates (34).

2. An intensive bus duct as set forth in claim 1, wherein: the cross sections of the convex blocks (3) and the grooves (9) are arc-shaped structures.

3. An intensive bus duct as set forth in claim 1, wherein: the opposite sides of the two conductive blocks (30) are of spherical structures.

4. An intensive bus duct as set forth in claim 1, wherein: clamping grooves (27) are formed in the front surface and the rear surface of the inside of the insulating sleeve (11), and the clamping grooves (27) are matched with the copper bars (2).

5. An intensive bus duct as set forth in claim 1, wherein: the outer side wall of the inserted link (14) is fixed with a rubber sleeve (20), and the rubber sleeve (20) is made of rubber with good elasticity.

6. An intensive bus duct as set forth in claim 1, wherein: connecting rods (18) are symmetrically fixed on the outer side wall of the guide pipe (15) relative to the spray holes (16), and a disc body (19) is fixed at one end, far away from the guide pipe (15), of each connecting rod (18).

7. An intensive bus duct as set forth in claim 1, wherein: the inner rear surface of the second plate body (4) is of a funnel-shaped structure.

8. An intensive bus duct as set forth in claim 1, wherein: the front surface of the connecting sleeve (5) is flush with the front surface of the first plate body (6).

9. The method of claim 1, comprising the steps of:

s1, integrally forming a first plate body (6) and parts on the first plate body through a die or a stamping device, preparing two first plate bodies (6) through the die or the stamping device, and forming reserved holes on the two first plate bodies (6) through a drilling device;

s2, fixing two insulating supports (8) between the two first plate bodies (6), sequentially penetrating the plurality of copper bars (2) through the two insulating supports (8), and then coating insulating glue between the copper bars (2) and the insulating supports (8) to fix the copper bars (2) and the insulating supports;

s3, pouring an insulating sleeve (11) through a die by utilizing a material with good insulating performance, opening a clamping groove (27) on the inner wall of the insulating sleeve (11), embedding a fixing electromagnet (29) on the inner wall of the insulating sleeve (11), fixing a conductive spring (28) on the inner wall of the insulating sleeve (11), fixing a conductive block (30) at one end of the conductive spring (28), fixing the insulating sleeve (11) at one end of a copper bar (2), and fixing a moisture absorption sheet (31) in the insulating sleeve (11);

s4, preparing a cuboid box body with two partition boards (22) inside and an opening by using punching equipment or a die, sequentially installing a storage battery (21) and a main board (24) with a singlechip (23), a positioning module (25) and a wireless transmission module (26) at corresponding positions of the box body, arranging wires, sealing the box body by using a plate to form a third plate body (13), fixing four cylindrical rods on the sealed plate, drilling holes on the four cylindrical rods by using drilling equipment to form a connecting sleeve (5) and a through hole (10), and extending the through hole (10) to the rear surface of the third plate body (13) to enable the connecting sleeve (5) to penetrate through a reserved hole on the first plate body (6);

s5, preparing an open cuboid box body by using punching equipment or a die, installing an electromagnetic valve (17) at the middle position of a plate with high middle part and low middle part on the inner side, fixing a guide pipe (15) at the output end of the electromagnetic valve (17), opening a plurality of spray holes (16) on the outer wall of the guide pipe (15), fixing connecting rods (18) on two sides of the spray holes (16), fixing a tray body (19) on the connecting rods (18), fixing four inserting rods (14) on the tray body, fixing rubber sleeves (20) on the outer wall of the inserting rods (14), installing lifting blocks (32) with springs (35) and pull ropes (33) in the inserting rods, fixing one ends of the springs (35) with the inserting rods (14), fixing elastic plates (34) rotating mutually at one ends of the pull ropes, and sealing the box body by using the plate to form a second plate body (4);

s6, attaching the second plate body (4) to the two first plate bodies (6), pulling the lifting blocks (32), enabling the pull ropes (34) to drive the two elastic plates (34) to be closed, enabling the inserting rods (14) on the second plate body (4) to be inserted into the connecting sleeves (5) and penetrate through the through holes (10), then enabling the two elastic plates (34) to spring out under the action of the springs (35) and attach to the rear surface of the third plate body (13), and accordingly fixing the first plate body (6), the second plate body (4) and the third plate body (13) to each other, and finally forming the whole bus duct.