CN220456935U - Compact direct current feeder cabinet - Google Patents

Abstract

The utility model belongs to the technical field of feeder cabinets and discloses a compact direct current feeder cabinet, which comprises a shell, wherein a mounting main board is arranged in the shell, grooves are symmetrically formed in the front surface and the rear surface of the mounting main board at equal intervals, electronic elements are arranged in the grooves, wires are connected to the electronic elements, a top rotating shaft is arranged at the top of the mounting main board, the top rotating shaft, a handle and the like are arranged.

Description

Compact direct current feeder cabinet

Technical Field

The utility model belongs to the technical field of feeder cabinets, and particularly relates to a compact direct current feeder cabinet.

Background

The feeder cabinet is distribution equipment in the circuit, and buses of strong current or weak current can be connected into the feeder cabinet, so that the feeder cabinet can be further distributed to other terminals, and the power consumption requirements of the terminals can be effectively guaranteed through the circuit protection and monitoring effects of the feeder cabinet.

Most of the existing feeder cabinets have more electronic components, the installation space provided for the feeder cabinets is not changed, so that only a small amount of electronic components can be installed in the feeder cabinets, the distribution monitoring and protection range is small, the use requirements of a large number of terminal equipment cannot be met, and in order to improve and expand the installation requirements of the electronic components in the feeder cabinets, the compact direct-current feeder cabinets are designed.

Disclosure of Invention

The utility model aims to provide a compact direct current feeder cabinet so as to solve the problem that an electronic component in the feeder cabinet proposed in the background art cannot meet the use requirements of a large number of terminal equipment.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a compact direct current feeder cabinet, includes the shell, the internally mounted of shell has the installation mainboard, the equal interval symmetry is seted up flutedly on the front and back two sides of installation mainboard, the inside of recess all is provided with electronic component, all be connected with the wire on the electronic component, the top pivot is installed at the top of installation mainboard, the rotary slot has been seted up for the position of top pivot to the shell, the inside that all imbeds the rotary slot in the top pivot and rotate at the inside of rotary slot, the handle is all installed to the front and back terminal surface symmetry of installation mainboard, the through-hole has been seted up to the inside of top pivot, the wire all runs through the installation mainboard and imbeds the outside that extends to the shell to the through-hole inside.

Preferably, the spout has all been seted up to terminal surface symmetry about the preceding terminal surface of shell, the inside of spout all slides has the slide, the slide all runs through the shell and can move to the outside of shell, two the relative one end of slide sets up respectively and has seted up connecting plate and spread groove, the connecting plate all can imbeds to the inside of spread groove, the push pedal is all installed to the preceding terminal surface of slide and the position that is close to connecting plate and spread groove, the standing groove has all been seted up to the position symmetry of shell for the push pedal, the push pedal all can imbeds inside the standing groove, all install the glass board on the slide.

Preferably, the fixed plate is all symmetrically installed at lower part both ends of installation mainboard, the fixed block is all symmetrically installed to the bottom that just is located the fixed plate on the shell inner wall, the fixed orifices has been seted up on the fixed plate, the inside of fixed orifices all is provided with the bolt, the bolt all imbeds to the fixed orifices inside and runs through the inside of fixed plate, extends to the inside of fixed block, the fixed slot has been seted up for the equal interval symmetry in position of fixed plate to the inner wall of shell, the fixed plate all imbeds to the inside of fixed slot.

Preferably, the radiating grooves are formed in two sides of the bottom of the shell and the bottom of the sliding plate, the radiating grooves are inclined outwards, sealing plates are mounted at two ends, away from each other, of the sliding plate, and the sealing plates can be embedded into the shell.

Preferably, the bottom rotating shaft is installed at the bottom of the installation main board, the second groove is formed in the position, corresponding to the bottom rotating shaft, of the shell, the bottom rotating shaft is embedded into the second groove and rotates in the second groove, and the base is installed at the bottom of the shell.

Preferably, the first rotating plate and the second rotating plate are respectively arranged on the outer sides of the top rotating shaft and the bottom rotating shaft, the first groove and the second groove are respectively formed in the positions of the shell, corresponding to the first rotating plate and the second rotating plate, of the shell, and the first rotating plate and the second rotating plate are respectively rotated in the first groove and the second groove.

Compared with the prior art, the utility model has the beneficial effects that:

(1) The utility model is provided with the installation main board, the top rotating shaft, the handle and the like, when in installation, electronic components can be respectively installed on the front end face and the rear end face of the installation main board, when in use, acting force can be applied by the handle, the installation main board is driven to rotate in the shell through the top rotating shaft, and then the electronic components positioned on the rear end face of the installation main board are exposed, so that the utility model is convenient to use, the internal capacity of the feeder cabinet is doubled, and the problem that the electronic components in the feeder cabinet can not meet the use requirements of a large number of terminal equipment is solved.

(2) The utility model is provided with the sliding plate, the sliding groove and the pushing plate, when the feeder cabinet is overhauled, the pushing plate can be used as a force application point, acting force is applied to drive the sliding plate to slide in the sliding groove, so that the inside of the shell is exposed, the operation space of maintainers is increased compared with a rotating shaft type, and the working efficiency of the maintainers is improved.

Drawings

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

FIG. 2 is a cross-sectional view of the present utility model;

FIG. 3 is an external view of the present utility model;

fig. 4 is an enlarged view at a in fig. 1;

in the figure: 1. a housing; 2. installing a main board; 3. a first groove; 4. a top spindle; 5. a wire; 6. a through hole; 7. a rotary groove; 8. a first rotating plate; 9. a heat sink; 10. a base; 11. a second groove; 12. a bottom rotating shaft; 13. a second rotating plate; 14. a handle; 15. a fixing groove; 16. a fixing plate; 17. a plug pin; 18. a sealing plate; 19. a glass plate; 20. a connecting plate; 21. a slide plate; 22. a chute; 23. a fixing hole; 24. and a fixed block.

Detailed Description

The following description of the embodiments of the present utility model 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 utility model, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

Referring to fig. 1-2 and fig. 4, the present utility model provides the following technical solutions: the utility model provides a compact direct current feeder cabinet, shell 1 is including the internally mounted of shell 1 has installation mainboard 2, equal interval symmetry sets up flutedly on the front and back of installation mainboard 2, the inside of recess all is provided with electronic component, all be connected with wire 5 on the electronic component, top pivot 4 is installed at the top of installation mainboard 2, the rotation groove 7 has been seted up for the position of top pivot 4 to shell 1, the inside that top pivot 4 all imbeds to rotation groove 7 and at rotation groove 7's inside is rotatory, the equal symmetry of front and back terminal surface of installation mainboard 2 installs handle 14, penetration hole 6 has been seted up to the inside of top pivot 4, wire 5 all runs through installation mainboard 2 and imbeds to the outside of penetration hole 6 inside extension to shell 1, bottom pivot 12 is installed to the bottom of installation mainboard 2, second recess 11 has been seted up for the position of bottom pivot 12, bottom pivot 12 all imbeds to the inside of second recess 11 and rotate in the inside of second recess 11, base 10 is installed to the bottom pivot 4 and bottom pivot 12 outside of shell 1, first rotor plate 8 and second rotor plate 13 are installed respectively in the first rotor plate 8 and second rotor plate 11 respectively, first rotor plate 3 and second rotor plate 11 and second rotor plate 3 are all seted up for first rotor plate 8 and second rotor plate 11.

Through the technical scheme: during installation, can install the recess inside on terminal surface around the installation mainboard 2 respectively with electronic components, during the use, accessible handle 14 applys effort, through the rotation of top pivot 4 and bottom pivot 12, drive the inside rotation of installation mainboard 2 at shell 1, and then make the electronic components that is located the terminal surface behind the installation mainboard 2 expose, conveniently adjust and use, make feeder cabinet's internal capacity increase one time, the problem of the inside electronic components of feeder cabinet can't satisfy the user demand of a large amount of terminal equipment has been solved, in addition, through the first rotor plate 8 of setting and second rotor plate 13, when the inside rotation of installation mainboard 2 at shell 1, first rotor plate 8 and second rotor plate 13 also synchronous are at first recess 3 and the inside rotation of second recess 11, and then restricted top pivot 4 and bottom pivot 12 and rocked the range, and then guarantee the steady rotation of installation mainboard 2, make wire 5 need not to install outside installation mainboard 2 through the through hole 6 of setting, guarantee the inside neatly of shell 1, will install 2 and shell 1 break away from ground through the base 10 of setting and bottom 12, reduce the surface and the shell 1 and the life-span of water vapor and the life of the installation mainboard 2 and the life-span of the water vapor.

Further, the fixed plate 16 is symmetrically installed at both ends of the lower portion of the installation main board 2, the fixed block 24 is symmetrically installed at the bottom of the fixed plate 16 and on the inner wall of the shell 1, the fixed hole 23 is formed in the fixed plate 16, the bolt 17 is arranged in the fixed hole 23 and penetrates through the fixed plate 16, the bolt 17 is embedded into the fixed hole 23 and extends to the fixed block 24, the fixed slot 15 is symmetrically formed in the inner wall of the shell 1 at equal intervals relative to the part of the fixed plate 16, and the fixed plate 16 is embedded into the fixed slot 15.

Specifically, before the main board 2 is rotatably installed, the fixing plate 16 and the fixing block 24 are released from the fixed connection by pulling out the pins 17 located in the fixing holes 23, so that the fixing of the housing 1 and the main board 2 is released, and the stability of the main board 2 during the normalization period is ensured by the set pins 17.

Referring to fig. 1-3, sliding grooves 22 are symmetrically formed in the upper and lower end surfaces of the front end surface of the housing 1, sliding plates 21 slide in the sliding grooves 22, the sliding plates 21 penetrate through the housing 1 and can move to the outside of the housing 1, connecting plates 20 and connecting grooves are respectively formed in opposite ends of the two sliding plates 21, the connecting plates 20 can be embedded into the connecting grooves, pushing plates are mounted on the front end surface of the sliding plates 21 and positions, close to the connecting plates 20 and the connecting grooves, of the housing 1, placing grooves are symmetrically formed in the positions, corresponding to the pushing plates, of the housing 1, the pushing plates can be embedded into the placing grooves, and glass plates 19 are mounted on the sliding plates 21.

Through the technical scheme: when the feeder cabinet is overhauled, the electronic components on the main board 2 of the inner installation of the shell 1 can be directly observed outside the shell 1 through the glass plate 19, after observation is completed, the push plate can be used as a force application point, acting force is applied to drive the sliding plate 21 to slide in the sliding groove 22, the inner part of the shell 1 is further exposed, the inner part of the shell 1 is opened, the operation space of maintainers is relatively increased compared with a rotating shaft, the working efficiency of the maintainers is improved, the electronic components on the front end face of the main board 2 can be directly rotationally installed without consideration, the maintenance efficiency of the maintainers is accelerated, the maintenance time is reduced, the push plate positioned in the placing groove is pushed to drive the two sliding plates 21 to be closed after maintenance is completed, and the connecting plate 20 on one sliding plate 21 is embedded into the connecting groove on the other sliding plate 21 to complete the closing.

Further, the heat dissipation grooves 9 are formed in two sides of the bottom of the shell 1 and in the bottom of the sliding plate 21, the heat dissipation grooves 9 are inclined outwards, the sealing plates 18 are mounted at one ends, away from each other, of the two sliding plates 21, and the sealing plates 18 can be embedded into the shell 1.

Specifically, at feeder cabinet use formula, outside air gets into inside shell 1 through heat dissipation groove 9, remove and carry out the heat dissipation processing for it with the electron element that is located on the installation mainboard 2, because heat dissipation groove 9 itself all incline to set up outward, outside water droplet can't get into inside shell 1 through the heat dissipation that inclines to set up, reduce the possibility that electronic components met water, in addition, reduce the possibility that water droplet gets into inside shell 1 through slide 21 department through the closing plate 18 that sets up, further reduce the possibility that water droplet gets into inside shell 1, make the inside relatively dry environment that is in for a long time of shell 1, in order to guarantee the normal operating of electronic components.

Although embodiments of the present utility model 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 utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. A compact direct current feeder cabinet is characterized in that: including shell (1), internally mounted of shell (1) has installed mainboard (2), equidistant symmetry sets up flutedly on the front and back both sides of installation mainboard (2), the inside of recess all is provided with electronic component, all be connected with wire (5) on the electronic component, top pivot (4) are installed at the top of installation mainboard (2), rotary groove (7) have been seted up at the position of shell (1) for top pivot (4), inside and the internal rotation at rotary groove (7) of top pivot (4) all imbeds to rotary groove (7), handle (14) are all symmetrically installed to the front and back terminal surface of installation mainboard (2), through-hole (6) have been seted up to the inside of top pivot (4), wire (5) all run through installation mainboard (2) and imbed the outside that extends to shell (1) inside through-hole (6).

2. A compact dc feeder cabinet as claimed in claim 1, wherein: the upper end face and the lower end face of the front end face of the shell (1) are symmetrically provided with sliding grooves (22), sliding plates (21) are respectively sliding in the sliding grooves (22), the sliding plates (21) penetrate through the shell (1) and can move to the outside of the shell (1), one ends of the two sliding plates (21) opposite to each other are respectively provided with a connecting plate (20) and a connecting groove, the connecting plate (20) can be embedded into the connecting groove, the push plate is arranged on the front end face of the sliding plate (21) and the position close to the connecting plate (20) and the connecting groove, the placing groove is symmetrically arranged on the position of the shell (1) corresponding to the push plate, the push plate can be embedded into the placing groove, and the glass plate (19) is arranged on the sliding plate (21).

3. A compact dc feeder cabinet as claimed in claim 2, wherein: the utility model discloses a fixing device for the fixed slot (15) of the electric motor comprises a fixing main board (2), a fixing block (24) is evenly symmetrically installed at the lower part both ends of installation main board (2), fixed block (24) is evenly symmetrically installed on the inner wall of shell (1) and is located the bottom of fixed plate (16), fixed hole (23) are all provided with bolt (17) on fixed plate (16), bolt (17) are all embedded into fixed hole (23) inside and run through the inside of fixed plate (16), extend to the inside of fixed block (24), fixed slot (15) have been seted up for the equal interval symmetry in position of fixed plate (16) to the inner wall of shell (1), the inside of fixed slot (15) is all embedded into to fixed plate (16).

4. A compact dc feeder cabinet according to claim 3, characterized in that: the heat dissipation grooves (9) are formed in two sides of the bottom of the shell (1) and the bottom of the sliding plate (21), the heat dissipation grooves (9) are inclined outwards, sealing plates (18) are mounted at one ends, away from each other, of the two sliding plates (21), and the sealing plates (18) can be embedded into the shell (1).

5. A compact dc feeder cabinet according to claim 4, wherein: the bottom rotating shaft (12) is arranged at the bottom of the installation main board (2), the second groove (11) is formed in the position of the shell (1) corresponding to the bottom rotating shaft (12), the bottom rotating shaft (12) is embedded into the second groove (11) and rotates in the second groove (11), and the base (10) is arranged at the bottom of the shell (1).

6. A compact dc feeder cabinet according to claim 5, wherein: the top rotating shaft (4) and the bottom rotating shaft (12) are respectively provided with a first rotating plate (8) and a second rotating plate (13), the first groove (3) and the second groove (11) are respectively formed in the positions of the shell (1) corresponding to the first rotating plate (8) and the second rotating plate (13), and the first rotating plate (8) and the second rotating plate (13) are respectively rotated in the first groove (3) and the second groove (11).