CN113437715B

CN113437715B - Intelligent bus duct based on energy Internet of things

Info

Publication number: CN113437715B
Application number: CN202110773952.7A
Authority: CN
Inventors: 孙利; ***
Original assignee: Zhenjiang Changzheng Power Equipment Co ltd
Current assignee: Zhenjiang Changzheng Power Equipment Co ltd
Priority date: 2021-07-08
Filing date: 2021-07-08
Publication date: 2022-05-13
Anticipated expiration: 2041-07-08
Also published as: CN113437715A

Abstract

The invention discloses an intelligent bus duct based on an energy Internet of things, which comprises a bus duct body and a bus bar, wherein a sensor is arranged in the bus duct body; the heat dissipation main part is installed to the internal lateral wall of bus duct, and the heat dissipation main part cooperates with link gear, through link gear and the cooperation of fan motor for the heat dissipation of fan motor provides power. According to the invention, the air increasing motor is started, the air increasing rotating shaft rotates, the driving bevel gear rotates to drive the driven bevel gear to rotate, and the driven rotating shaft rotates to drive the air increasing fan to rotate; meanwhile, the driven wheel is driven to rotate through the linkage main wheel, so that the rotation of the auxiliary rotating shaft is realized, and the rotating block is connected and matched with the knocking block, so that the vertical column pushes the transverse rod to move, and then the connecting rod drives the butt joint block to move.

Description

Intelligent bus duct based on energy Internet of things

Technical Field

The invention relates to the technical field of bus ducts, in particular to an intelligent bus duct based on an energy Internet of things.

Background

The bus duct is a closed metal device formed from copper and aluminium bus posts, and is used for distributing large power for every element of dispersion system. Wire and cable have been increasingly replaced in indoor low voltage power transmission mains engineering projects; with the emergence of modern engineering facilities and equipment, the power consumption of various industries is increased rapidly, particularly, the appearance of numerous high-rise buildings and large-scale factory workshops, the traditional cable serving as a power transmission lead cannot meet the requirement in a large-current transmission system, and the parallel connection of multiple cables brings inconvenience to on-site installation, construction and connection; compared with the traditional cable, the high-voltage bus duct fully shows the advantages of the high-voltage bus duct during heavy current transmission, simultaneously greatly reduces the contact resistance and temperature rise at the connecting positions of two end parts of the bus duct and the splicing positions of the branch ports due to the adoption of a new technology and a new process, and uses high-quality insulating materials in the bus duct, thereby improving the safety and reliability of the bus duct and improving the whole system.

The existing bus duct has poor heat dissipation effect, when the working temperature in the bus duct rises, the inside of the bus duct does not have the heat dissipation function, and the service life of the bus duct is influenced.

Disclosure of Invention

The invention aims to provide an intelligent bus duct based on an energy Internet of things, and aims to solve the problems in the background technology.

In order to achieve the purpose, the invention provides the following technical scheme:

an intelligent bus duct based on an energy Internet of things comprises a bus duct body and a bus bar, wherein a sensor is arranged in the bus duct body; the heat dissipation main part is arranged on the inner side wall of the bus duct body, is matched with the linkage mechanism and is matched with the air booster through the linkage mechanism and used for providing power for heat dissipation of the air booster;

the heat dissipation main part comprises a heat dissipation box body, the heat dissipation box body is arranged in a penetrating manner with a bus duct body, a rotating shaft is installed in the heat dissipation box body and connected with a rotating disc, the rotating disc is matched with a winding wheel through a pull rope and used for matching and connecting a pulling piece, a connecting rod is hinged to the rotating disc and connected with a connecting block, a through rod is arranged at the upper part of the connecting block, the through rod penetrates through the heat dissipation box body to be demounted and installed with a heat dissipation fan, and the heat dissipation fan is mounted and demounted with the through rod through a demounting piece on the through rod;

the air increasing device comprises an air increasing box, an air increasing motor is installed on the inner top wall of the air increasing box, an output shaft of the air increasing motor is connected with an air increasing rotating shaft, a driving bevel gear is arranged on the air increasing rotating shaft, the driving bevel gear is meshed with a driven bevel gear, the driven bevel gear is connected with a driven rotating shaft, the driven rotating shaft is connected with an air increasing fan, and the air increasing device is connected with a heat dissipation main part in a matched mode through a linkage mechanism.

Preferably, the connecting block is arranged in a limiting sliding mode through the stabilizing column and the stabilizing groove in the stabilizing plate.

Preferably, the pull piece includes the pull box, and it is equipped with the pull slider to slide in the pull box, and the pull slider is connected with the pull post, and is used for passing the pull box and installs the butt joint piece, and the pull slider is connected the setting with the stay cord, and the cover is equipped with the pull spring on the pull post, and pull spring one end is connected with the pull box inside wall, and the other end is connected with the pull slider.

Preferably, the dismounting member comprises a dismounting motor, a dismounting rotating shaft is connected to an output shaft of the dismounting motor, a first screw area and a second screw area are arranged on the dismounting rotating shaft, a screw block is connected to the first screw area and the second screw area in a threaded manner, the screw block is connected with a through position column, the through position column is connected with a limiting clamping frame, the limiting clamping frame is connected with a limiting clamping block, a positioning clamping block is arranged on the penetrating rod, a vertical block is arranged on the lower portion of the cooling fan, and a vertical groove is formed in the vertical block.

Preferably, the positioning fixture block is clamped with the mounting groove on the heat dissipation fan.

Preferably, the limiting clamping block is clamped with the vertical groove.

Preferably, the linkage mechanism comprises a linkage main wheel, the linkage main wheel is connected with the wind increasing rotating shaft, the linkage main wheel is connected with a driven wheel through a belt, the driven wheel is connected with the auxiliary rotating shaft, the top end of the auxiliary rotating shaft is connected with the rotating block, and the rotating block is connected with the beating block.

Preferably, the knocking block is matched with the vertical column, the vertical column is connected with the cross rod, and the cross rod is connected with the butt joint block through the vertical connecting rod.

Preferably, the vertical column and the transverse sliding groove of the outer bottom wall of the heat dissipation box body are arranged in a sliding limiting mode.

Preferably, the sensor transmits information to the central controller, and the central controller transmits information to the heat dissipation motor.

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

starting the wind increasing motor, enabling the wind increasing rotating shaft to rotate, enabling the driving bevel gear to rotate, driving the driven bevel gear to rotate, enabling the driven rotating shaft to rotate, and driving the wind increasing fan to rotate; meanwhile, the driven wheel is driven to rotate through the linkage main wheel, so that the rotation of the auxiliary rotating shaft is realized, and the rotating block is connected and matched with the knocking block, so that the vertical column pushes the transverse rod to move, and then the connecting rod drives the butt joint block to move; the butt joint block moves to drive the drawing column to move, so that the drawing slide block can draw the drawing rope to move, meanwhile, the connecting block is driven to move by the connecting rod through the rotation of the rotating disc, the penetrating rod penetrates through the heat dissipation box body to drive the heat dissipation fan to move, the heat dissipation fan moves up and down, and therefore the heat dissipation effect is improved; through the mounting groove joint on positioning fixture block and the radiator fan, dismantle the motor and start, drive and dismantle the pivot and rotate, and then realize that first spiral shell district, second spiral shell district rotate, through leading to a position post and spacing card frame cooperation simultaneously, and then spacing fixture block and perpendicular groove joint make things convenient for radiator fan's dismantlement and installation, improve the availability factor.

Drawings

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

FIG. 2 is a schematic structural diagram of a heat dissipation main part according to the present invention;

FIG. 3 is a schematic view of the structure of the air mover of the present invention;

figure 4 is a schematic view of the alarm configuration of the drawer of the present invention;

FIG. 5 is a schematic view of the construction of the stripper of the present invention;

FIG. 6 is an enlarged view of the structure at A in FIG. 2 according to the present invention;

fig. 7 is a schematic diagram of the system of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-7, the invention provides an intelligent bus duct based on an energy internet of things, which comprises a bus duct body 1 and a bus bar 2, wherein a sensor 3 is installed in the bus duct body 1; a heat dissipation main part 4 is installed on the inner side wall of the bus duct body 1, the heat dissipation main part 4 is matched with a linkage mechanism 5, and is matched with an air increasing actuator 6 through the linkage mechanism 5 and used for providing power for heat dissipation of the air increasing actuator 6;

the heat dissipation main part 4 comprises a heat dissipation box body 41, the heat dissipation box body 41 and the busbar slot body 1 are arranged in a penetrating mode, a rotating shaft 42 is installed in the heat dissipation box body 41, the rotating shaft 42 is connected with a rotating disc 43, the rotating disc 43 is matched with a winding wheel through a pull rope 44 and used for matching and connecting a pulling piece 45, a connecting rod 46 is hinged to the rotating disc 43, the connecting rod 46 is connected with a connecting block 47, a through rod 48 is arranged at the upper portion of the connecting block 47, a heat dissipation fan 410 is detachably installed after the through rod 48 penetrates through the heat dissipation box body 41, and the heat dissipation fan 410 is detachably installed with the through rod 48 through a dismounting piece 49 on the through rod 48;

the air increasing device 6 comprises an air increasing box 61, an air increasing motor 62 is installed on the inner top wall of the air increasing box 61, an air increasing rotating shaft 63 is connected to an output shaft of the air increasing motor 62, a driving bevel gear 64 is arranged on the air increasing rotating shaft 63, a driven bevel gear 65 is meshed with the driving bevel gear 64, the driven bevel gear 65 is connected with a driven rotating shaft 66, the driven rotating shaft 66 is connected with an air increasing fan 67, and the air increasing device 6 is connected with the heat dissipation main part 4 in a matched mode through a linkage mechanism 5.

Starting the wind increasing motor 62, enabling the wind increasing rotating shaft 63 to rotate, enabling the driving bevel gear 64 to rotate, driving the driven bevel gear 65 to rotate, enabling the driven rotating shaft 66 to rotate, and driving the wind increasing fan 67 to rotate;

the connecting block 47 of this embodiment is slidably disposed in a limited manner through the stabilizing column 411 and the stabilizing slot 413 of the stabilizing plate 412.

The drawing piece 45 of this embodiment includes the pull box 451, and it is equipped with the pull slider 452 to slide in the pull box 451, and the pull slider 452 is connected with the pull post 453, and is used for passing the pull box 451 and installs butt joint piece 454, and the pull slider 452 is connected with the stay cord 44 and sets up, and the cover is equipped with the pull spring 455 on the pull post 453, and pull spring 455 one end is connected with the pull box 451 inside wall, and the other end is connected with the pull slider 452.

The butt-joint block 454 moves to drive the drawing column 453 to move, so that the drawing slide block 452 pulls the drawing rope 44 to move, meanwhile, the link rod 46 drives the connecting block 47 to move through the rotation of the rotating disc 43, and further the penetrating rod 48 penetrates through the heat dissipation box body 41 to drive the heat dissipation fan 410 to move, so that the heat dissipation fan 410 moves up and down, and the heat dissipation effect is improved;

the dismounting member 49 of this embodiment includes a dismounting motor 491, an output shaft of the dismounting motor 491 is connected with a dismounting rotary shaft 492, the dismounting rotary shaft 492 is provided with a first screw area 493 and a second screw area 494, the first screw area 493 and the second screw area 494 are connected with a screw block 495 in a screw manner, the screw block 495 is connected with a through position column 496, the through position column 496 is connected with a limiting clamp frame 497, the limiting clamp frame 497 is connected with a limiting clamp block 498, the penetrating rod 48 is provided with a positioning clamp block 499, a vertical block 4911 is arranged at the lower part of the heat dissipation fan 410, and a vertical slot 4912 is arranged on the vertical block 4911.

The positioning fixture blocks 499 of this embodiment are engaged with the mounting slots 4910 of the heat dissipation fan 410.

The limit latch 498 of this embodiment is engaged with the vertical slot 4912.

Through the mounting groove 4910 joint on location fixture block 499 and radiator fan 410, dismantle the motor 491 and start, drive and dismantle pivot 492 and rotate, and then realize that first spiral shell district 493, second spiral shell district 494 rotate, simultaneously through leading to the cooperation of position post 496 and spacing card frame 497, and then spacing fixture block 498 and perpendicular groove 4912 joint make things convenient for radiator fan 410's dismantlement and installation, improve the availability factor.

The linkage mechanism 5 of the embodiment comprises a linkage main wheel 51, the linkage main wheel 51 is connected with a wind increasing rotating shaft 63, the linkage main wheel 51 is connected with a driven wheel 53 through a belt 52, the driven wheel 53 is connected with an auxiliary rotating shaft 54, the top end of the auxiliary rotating shaft 54 is connected with a rotating block 55, and the rotating block 55 is connected with a beating block 56.

In the present embodiment, the tapping block 56 is disposed in cooperation with the upright post 57, the upright post 57 is connected to the cross bar 58, and the cross bar 58 is connected to the docking block 454 through the upright link 59.

The vertical column 57 of the present embodiment is slidably and limitedly disposed with the lateral sliding groove 510 of the outer bottom wall of the heat dissipation box 41.

Meanwhile, the driven wheel 53 is driven to rotate through linkage of the main wheel 51, so that the auxiliary rotating shaft 54 is further driven to rotate, the rotating block 55 is connected and matched with the beating block 56, the vertical column 57 pushes the transverse rod 58 to move, and then the connecting rod 59 drives the butt-joint block 454 to move;

the sensor 3 of this embodiment gives information transmission to well accuse ware, and well accuse ware gives information transmission to the heat dissipation motor.

The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims

1. An intelligent bus duct based on an energy Internet of things is characterized by comprising a bus duct body (1) and a bus bar (2), wherein a sensor (3) is installed in the bus duct body (1); a heat dissipation main part (4) is installed on the inner side wall of the bus duct body (1), the heat dissipation main part (4) is matched with the linkage mechanism (5), and is matched with the air increasing actuator (6) through the linkage mechanism (5) and used for providing power for heat dissipation of the bus bar (2);

the heat dissipation main part (4) comprises a heat dissipation box body (41), the heat dissipation box body (41) and the busbar groove body (1) are arranged in a penetrating mode, a rotating shaft (42) is installed in the heat dissipation box body (41), the rotating shaft (42) is connected with a rotating disc (43), the rotating disc (43) is matched with a winding wheel through a pull rope (44) and is used for matching and connecting a pulling piece (45), a connecting rod (46) is hinged to the rotating disc (43), the connecting rod (46) is connected with a connecting block (47), a penetrating rod (48) is arranged on the upper portion of the connecting block (47), the penetrating rod (48) penetrates through the heat dissipation box body (41) to be demounted and installed with a heat dissipation fan (410), and the heat dissipation fan (410) is mounted and demounted and mounted with the penetrating rod (48) through a demounting piece (49) on the penetrating rod (48);

the wind increasing device (6) comprises a wind increasing box (61), a wind increasing motor (62) is installed on the inner top wall of the wind increasing box (61), an output shaft of the wind increasing motor (62) is connected with a wind increasing rotating shaft (63), a driving bevel gear (64) is arranged on the wind increasing rotating shaft (63), a driven bevel gear (65) is meshed with the driving bevel gear (64), the driven bevel gear (65) is connected with a driven rotating shaft (66), the driven rotating shaft (66) is connected with a wind increasing fan (67), and the wind increasing device (6) is matched and connected with a heat dissipation main part (4) through a linkage mechanism (5);

the connecting block (47) is in limited sliding arrangement with a stabilizing groove (413) on the stabilizing plate (412) through a stabilizing column (411); the drawing piece (45) comprises a drawing box (451), a drawing slider (452) is arranged in the drawing box (451) in a sliding mode, the drawing slider (452) is connected with a drawing column (453) and used for penetrating through the drawing box (451) to be provided with a butt joint block (454), the drawing slider (452) is connected with a drawing rope (44), a drawing spring (455) is sleeved on the drawing column (453), one end of the drawing spring (455) is connected with the inner side wall of the drawing box (451), and the other end of the drawing spring is connected with the drawing slider (452);

the linkage mechanism (5) comprises a linkage main wheel (51), the linkage main wheel (51) is connected with a wind increasing rotating shaft (63), the linkage main wheel (51) is connected with a driven wheel (53) through a belt (52), the driven wheel (53) is connected with an auxiliary rotating shaft (54), the top end of the auxiliary rotating shaft (54) is connected with a rotating block (55), and the rotating block (55) is connected with a beating block (56); the knocking block (56) is matched with the vertical column (57), the vertical column (57) is connected with the transverse rod (58), and the transverse rod (58) is connected with the butt joint block (454) through the vertical connecting rod (59).

2. The intelligent bus duct based on the energy Internet of things as claimed in claim 1, wherein the dismounting member (49) comprises a dismounting motor (491), an output shaft of the dismounting motor (491) is connected with a dismounting rotating shaft (492), the dismounting rotating shaft (492) is provided with a first screw area (493) and a second screw area (494), the first screw area (493) and the second screw area (494) are in threaded connection with a screw block (495), the screw block (495) is connected with a through position column (496), the through position column (496) is connected with a limiting clamping frame (497), the limiting clamping frame (497) is connected with a limiting clamping block (498), the through rod (48) is provided with a positioning clamping block (499), the lower portion of the cooling fan (410) is provided with a vertical block (4911), and the vertical block (4912) is arranged on the vertical block (4911).

3. The intelligent bus duct based on the internet of things of energy sources as claimed in claim 2, wherein the positioning fixture block (499) is clamped with the mounting groove (4910) of the cooling fan (410).

4. The intelligent bus duct based on the energy Internet of things as claimed in claim 3, wherein the limiting clamping block (498) is clamped with the vertical groove (4912).

5. The intelligent bus duct based on the energy Internet of things as claimed in claim 1, wherein the vertical column (57) and the transverse sliding groove (510) of the outer bottom wall of the heat dissipation box body (41) are arranged in a sliding limiting manner.

6. The intelligent bus duct based on the Internet of things of energy sources as claimed in claim 1, wherein the sensor (3) transmits information to a central controller, and the central controller transmits the information to a heat dissipation motor.