CN109599761B

CN109599761B - Electric power intelligent power distribution cabinet

Info

Publication number: CN109599761B
Application number: CN201910050906.7A
Authority: CN
Inventors: 姜平乐; 娄彪
Original assignee: Jiangxi Fengyuan Electric Co ltd
Current assignee: Jiangxi Fengyuan Electric Co.,Ltd.
Priority date: 2019-01-20
Filing date: 2019-01-20
Publication date: 2020-05-08
Anticipated expiration: 2039-01-20
Also published as: CN109599761A

Abstract

The invention discloses an intelligent power distribution cabinet, which comprises a main cabinet body consisting of a plurality of control cabinets, wherein a mounting groove with a forward opening is arranged in each control cabinet, an element installation body is arranged in each mounting groove, a first slot and a second slot are arranged in the rear side end wall of each mounting groove, the second slot is arranged on the lower side of the first slot, a first through groove is communicated and arranged between the first slot and the second slot, an automatic control mechanism is arranged in each first through groove, a first connecting rod fixedly matched and connected with the rear side end wall of each mounting groove is arranged on the upper side of each first slot, a first inclined surface block is fixedly arranged at the tail end of the front side of each first connecting rod, a movable cavity is arranged in each element installation body, and a second through groove communicated and arranged with the outside is arranged on the rear side wall of each movable; the invention has convenient operation and high safety, and greatly improves the working efficiency of disassembly, assembly and maintenance.

Description

Electric power intelligent power distribution cabinet

Technical Field

The invention relates to the technical field of electric power, in particular to an intelligent power distribution cabinet for electric power.

Background

Power distribution cabinets are often used in power distribution and are mainly used for mounting electronic components to achieve integrated control. The switch board main role is to carry out distribution and control and overload appears in the circuit to the consumer, when short circuit and electric leakage, provide power-off protection, drawer type switch board's manual control's mechanical lock at present, consequently, the maintenance speed has been reduced, complex operation, the practicality, the security is not high, in addition, for the security of safe in utilization and guarantee device maintenance, need be its outage when these cabinet body covers are in the open mode, traditional switch board contact easily exposes and is close for the operator easily and be unfavorable for the person and equipment safety, therefore, the urgent need is one kind and is controlled the convenience, safe electric power intelligent power distribution cabinet.

Disclosure of Invention

The invention aims to provide an intelligent power distribution cabinet for electric power, which is used for overcoming the defects in the prior art.

The invention relates to an electric power intelligent power distribution cabinet, which comprises a main cabinet body consisting of a plurality of control cabinets, wherein a mounting groove with a forward opening is arranged in each control cabinet, an element installation body is arranged in each mounting groove, a first slot and a second slot are arranged in the rear side end wall of each mounting groove, the second slot is arranged on the lower side of the first slot, a first through groove is communicated and arranged between the first slot and the second slot, an automatic control mechanism is arranged in each first through groove, a first connecting rod fixedly matched and connected with the rear side end wall of each mounting groove is arranged on the upper side of each first slot, a first inclined surface block is fixedly arranged at the front side tail end of each first connecting rod, a movable cavity is arranged in each element installation body, a second through groove communicated and arranged with the outside is arranged on the rear side end wall of each movable cavity, and a first insertion block arranged opposite to the first slot is fixedly arranged on the rear side end surface of, the rear side wall of the movable cavity is internally provided with a second insert block which is connected with the rear side wall of the movable cavity in a sliding fit manner and is arranged in a front-back extending manner, the rear side end of the second insert block is arranged opposite to the second slot, the rear side section of the second insert block extends out of the rear side end face of the element installation body, the bottom end face of the first insert block is internally provided with a conductive groove with a downward opening, the top end face of the second insert block is internally provided with a rack part, the front side wall of the movable cavity is internally provided with a first sliding groove in a communicated manner, the first sliding groove is connected with a first sliding block in a sliding fit manner, the first sliding block is internally connected with a first guide sliding rod in a sliding fit manner, the upper and lower extending ends of the first guide sliding rod are respectively connected with the upper and lower end walls of the first sliding groove in a fixed fit manner, and the lower side of the first sliding, the bottom of the movable cavity is connected with a push sliding plate in a sliding fit manner, the front extending tail end of the second insertion block extends into the movable cavity and is fixedly connected with the end face of the rear side of the push sliding plate in a matching manner, a third through groove is arranged in the push sliding plate, the bottom of the third through groove is connected with a second guide sliding rod which extends forwards and backwards in a sliding fit manner, the front end surface and the rear end surface of the second guide slide rod are respectively fixedly matched and connected with the front end wall and the rear end wall of the movable cavity, a second spring arranged around the outer side of the second guide sliding rod is arranged at the front side of the push sliding plate, an inclined sliding surface is arranged at the top of the third through groove, an inclined pushing block which extends into the third through groove and is connected with the inclined sliding surface in a pressing and sliding fit manner is fixedly arranged on the end face of the rear side of the first sliding block, the upper side of the inclined pushing block is provided with a second connecting rod fixedly matched and connected with the first sliding block, and the tail end of the rear side of the second connecting rod is fixedly provided with a second inclined surface block.

In a further technical scheme, the automatic control mechanism comprises a sliding block which is connected and arranged in the first through groove in a sliding fit manner, a second sliding groove which is communicated and arranged in the rear side wall of the first through groove, and a second sliding block which is connected and arranged in the second sliding groove in a sliding fit manner and is fixedly matched and connected with the sliding block, the second sliding block is internally and screw-connected with a regulating screw rod which extends up and down, the top end of the regulating screw rod is in power fit connection with a regulating motor which is fixedly embedded in the top wall of the second sliding groove, the top end of the sliding block is fixedly provided with a power supply block connected with commercial power, the bottom end surface of the sliding block is internally provided with a driving groove with a downward opening, a driven gear is connected in the driving groove in a rotating matching way, the upper side of the driven gear is connected with a driving gear in a meshing way, and the right end of the driving gear is in power fit connection with an output shaft of a driving motor fixedly embedded in the right side wall of the driving groove.

According to the technical scheme, a switch door body in hinged fit connection with the control cabinet is arranged on the front side of the control cabinet, and a display area is arranged on the switch door body.

In a further technical scheme, the second through groove is opposite to the first inclined plane block.

In a further technical scheme, the first spring and the second spring are both top pressure springs.

According to a further technical scheme, the maximum circumscribed circle at the bottom of the driven gear extends out of the end face of the bottom of the sliding block.

The invention has the beneficial effects that:

1. according to the invention, the first inclined plane block extends into the second through groove and is connected with the second inclined plane block in a jacking fit manner, so that the second inclined plane block drives the first slide block at the tail end of the front side of the second connecting rod to downwards slide by overcoming the jacking force of the first spring until the first inclined plane block moves to the position of the front side of the second inclined plane block, at the moment, the first slide block drives the first slide block and the first inclined plane block at the tail end of the rear side of the second connecting rod to recover to the initial position under the jacking force of the first spring, and further, the locking connection work of the second inclined plane block and the first inclined plane block is realized, and the operation convenience of an operator is greatly improved;

2. the regulating motor controls the regulating screw to rotate forwards and backwards, and the regulating screw drives the second sliding block to slide in the second sliding groove in the up-and-down direction, so that the power supply connection and the power failure of the power supply block and the conductive groove are controlled, and the safety of an operator is greatly improved;

3. according to the invention, the driving gear and the driven gear are driven by the driving motor to rotate in sequence, so that the driven gear drives the second insert block and the push sliding plate at the bottom of the rack part to slide towards the front side direction in the movable cavity against the jacking force of the second spring, and further, the inclined sliding surface at the top of the third through groove is in jacking sliding fit with the inclined push block, so that the inclined push block drives the first slide block to slide downwards against the jacking force of the first spring, and further, the first slide block drives the second inclined surface block of the second connecting rod to slide downwards until the second inclined surface block is far away from the second through groove to the maximum extent, and at the moment, the element mounting body is pulled towards the front side, so that the rapid dismounting work can be realized, and the working efficiency during maintenance is greatly improved.

Drawings

FIG. 1 is a front view of an intelligent power distribution cabinet according to the present invention;

FIG. 2 is a top view of an intelligent power distribution cabinet according to the present invention;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 1 in accordance with the present invention;

FIG. 4 is an enlarged partial schematic view of B of FIG. 3 in accordance with the present invention;

FIG. 5 is a front view of the automatic control mechanism of the present invention;

FIG. 6 is a schematic perspective view of the first slider of the present invention in cooperation with the inclined pushing block and the second link, respectively;

fig. 7 is a schematic structural view of the second incline block and the first incline block in locking connection according to the present invention.

Detailed Description

The present invention is described in detail below with reference to fig. 1 to 7.

Referring to fig. 1-7, an intelligent power distribution cabinet according to an embodiment of the present invention includes a main cabinet 7 composed of a plurality of control cabinets 6, a mounting groove 63 with a forward opening is disposed in each control cabinet 6, a component mounting body 8 is disposed in each mounting groove 63, a first slot 64 and a second slot 65 are disposed in a rear side wall of each mounting groove 63, a first through groove 66 is disposed between each first slot 64 and each second slot 65, an automatic control mechanism is disposed in each first through groove 66, a first connecting rod 631 fixedly coupled to the rear side wall of each mounting groove 63 is disposed on an upper side of each first slot 64, a first inclined block 632 is fixedly disposed at a front end of each first connecting rod 631, a movable cavity 81 is disposed in each component mounting body 8, and a second through groove 83 communicated with the outside is disposed on a rear side wall of each movable cavity 81, a first inserting block 84 arranged opposite to the first inserting groove 64 is fixedly arranged on the rear side end face of the element mounting body 8, a second inserting block 85 extending forwards and backwards is further connected in the rear side wall of the movable cavity 81 in a sliding fit manner, the rear side end of the second inserting block 85 is arranged opposite to the second inserting groove 65, the rear side section of the second inserting block 85 extends out of the rear side end face of the element mounting body 8, a conductive groove 841 with a downward opening is arranged in the bottom end face of the first inserting block 84, a rack portion 851 is arranged in the top end face of the second inserting block 85, a first sliding groove 82 is communicated in the front side wall of the movable cavity 81, a first sliding block 821 is connected in a sliding fit manner in the first sliding groove 82, a first guide sliding rod 822 extending upwards and downwards is connected in the first sliding block 821 in a sliding fit manner, and the extending ends of the upper and the lower sides of the first guide sliding rod 822 are respectively fixedly connected with the upper and lower end walls of the first sliding groove 82 in a matching manner, a first spring 823 arranged around the outside of the first guide slide rod 822 is arranged on the lower side of the first slide block 821, a push-slide plate 86 is connected to the bottom of the movable cavity 81 in a sliding fit manner, the front extending end of the second insertion block 85 extends into the movable cavity 81 and is fixedly matched and connected with the rear end face of the push-slide plate 86, a third through groove 863 is arranged in the push-slide plate 86, a second guide slide rod 861 extending back and forth is connected to the bottom of the third through groove 863 in a sliding fit manner, the front end face and the rear end face of the second guide slide rod 861 are respectively fixedly matched and connected with the front end wall and the rear end wall of the movable cavity 81, a second spring 862 arranged around the outside of the second guide slide rod 861 is arranged on the front side of the push-slide plate 86, an inclined push block 824 extending into the third through groove 863 and connected with the inclined slide surface 864 in a pressing and sliding fit manner is fixedly arranged on the rear end face of the first slide block 821, a second connecting rod 825 fixedly matched and connected with the first sliding block 821 is arranged on the upper side of the inclined pushing block 824, and a second inclined block 826 is fixedly arranged at the tail end of the rear side of the second connecting rod 825.

Beneficially or exemplarily, the automatic control mechanism comprises a sliding block 661 disposed in the first through slot 66 in a sliding fit connection manner, a second sliding slot 67 disposed in a rear side wall of the first through slot 66 in a communicating manner, and a second sliding block 671 disposed in the second sliding slot 67 in a sliding fit connection manner and fixedly connected with the sliding block 661 in a fit manner, the second sliding block 671 is connected with an adjusting screw 673 extending up and down in a thread fit manner, a top end of the adjusting screw 673 is connected with an adjusting motor 672 fixedly embedded in a top wall of the second sliding slot 67 in a power fit manner, a top end of the sliding block 661 is fixedly provided with a power supply block 662 connected with a mains supply, a driving slot 663 with a downward opening is disposed in a bottom end surface of the sliding block 661, a driven gear 6631 is connected in a rotating fit manner in the driving slot 663, and a driving gear 6632 is connected to an upper side of the driven gear, the right end of the driving gear 6632 is in power fit connection with an output shaft of a driving motor 6633 fixedly embedded in the right side wall of the driving groove 663, so that automatic control power supply work is realized, the control safety of workers is greatly improved, and meanwhile, the working efficiency is improved.

Beneficially or exemplarily, a switch door body 61 connected with the control cabinet 6 in a hinged fit manner is arranged on the front side of the control cabinet 6, and a display area 610 is arranged on the switch door body 61, so that monitoring by workers is facilitated.

Advantageously or exemplarily, the second through slot 83 is disposed opposite to the first sloping block 632.

Advantageously or exemplarily, the first spring 823 and the second spring 862 are both top pressure springs, so as to automatically control the quick return operation of the first slider 821 and the push-slide plate 86.

Advantageously or exemplarily, the maximum circumcircle of the bottom of the driven gear 6631 protrudes out of the end face of the bottom of the sliding block 661, thereby achieving a convenient power-fit connection with the rack portion 851.

When the power supply device is not used, the second slider 671 is located at the bottommost position in the second sliding groove 67, at the moment, the second slider 671 drives the sliding block 661 to be located at the bottom position in the first through groove 66, and meanwhile, the power supply block 662 at the top of the sliding block 661 is far away from the first slot 64, and the maximum circumcircle at the bottom of the driven gear 6631 extends into the second slot 65; at this time, the pushing-sliding plate 86 is pressed by the second spring 862 to be located at the rearmost position in the movable cavity 81, and the first slider 821 is pressed by the first spring 823 to be located at the topmost position in the first sliding slot 82, so that the rear section of the inclined pushing block 824 is in contact with the inclined sliding surface 864, and the second connecting rod 825 drives the second inclined block 826 to be located at the front opposite position of the second through-slot 83.

When the component mounting body 8 is required to be mounted and used, the component mounting body 8 is pushed into the mounting groove 63, at this time, the first inclined surface block 632 is positioned at the rear side of the second through groove 83 in a relative position, and at the same time, the first insertion groove 64 and the first insertion block 84, and the second insertion groove 65 and the second insertion block 85 are positioned in a relative state, until the component mounting body 8 is completely pushed into the mounting groove 63, at this time, the first insertion block 84 is completely inserted into the first insertion groove 64, and the second insertion block 85 is completely inserted into the second insertion groove 65, and the front side section of the rack portion 851 and the driven gear 6631 are in a meshing connection state, and at the same time, the conductive groove 841 at the bottom of the first insertion block 84 and the power supply block 662 are positioned in a relative position, during this process, the first inclined surface block 632 is inserted into the second through groove 83 and is connected with the second inclined surface block 826 in a pressing fit manner, and the second inclined surface block 826 drives the first slider 821 at the front side end of the second connecting rod 825 to slide downward against the pressing force of the first spring, until the first inclined block 632 moves to the front position of the second inclined block 826, at this time, the first slider 821 is pressed by the first spring 823 to drive the first slider 821 and the first inclined block 632 at the rear end of the second link 825 to return to the initial position, so as to achieve the locking connection operation of the second inclined block 826 and the first inclined block 632 as shown in fig. 7, then the adjusting motor 672 controls the rotation of the adjusting screw 673, and the adjusting screw 673 drives the second slider 671 to slide to the topmost position in the second sliding groove 67, at this time, the second slider 671 drives 661 slider to be located at the topmost position in the first through groove 66, and at the same time, the second slider 671 drives the power supply block 662 to completely extend into the conductive groove 841 to achieve the automatic control power supply operation;

when the disassembly is needed, the reverse rotation of the adjusting screw 673 is controlled by the adjusting motor 672, so that the adjusting screw 673 drives the second slider 671 to move to the initial position, and at the same time, the second slider 671 drives the slider 661 to move to the initial position, so that the power-off operation of the power supply block 662 and the conductive groove 841 is automatically controlled, then the driving motor 6633 drives the driving gear 6632 and the driven gear 6631 to rotate sequentially, so that the driven gear 6631 drives the second insert 85 and the push-slide plate 86 at the bottom of the rack portion 851 to slide towards the front side direction in the movable cavity 81 against the jacking force of the second spring 862, so that the inclined slide surface 864 at the top of the third groove 863 is in jacking and sliding fit with the inclined push block 824, so that the inclined push block 824 drives the first slider 821 to slide downwards against the jacking force of the first spring 823, and further the first slider 821 drives the second inclined block 826 to slide downwards, until the second inclined block 826 is away from the second through-groove 83 to the maximum extent, the component mounting body 8 is pulled to the front side, and then the quick disassembling operation can be realized.

The invention has the beneficial effects that:

It will be apparent to those skilled in the art that various modifications may be made to the above embodiments without departing from the general spirit and concept of the invention. All falling within the scope of protection of the present invention. The protection scheme of the invention is subject to the appended claims.

Claims

1. An electric power intelligent power distribution cabinet comprises a main cabinet body consisting of a plurality of control cabinets, wherein a mounting groove with a forward opening is arranged in each control cabinet, an element installation body is arranged in each mounting groove, a first slot and a second slot are arranged in the rear side end wall of each mounting groove, the second slot is arranged on the lower side of the first slot, a first through groove is communicated and arranged between the first slot and the second slot, an automatic control mechanism is arranged in each first through groove, a first connecting rod is arranged on the upper side of each first slot and fixedly matched and connected with the rear side end wall of each mounting groove, a first inclined surface block is fixedly arranged at the front side tail end of each first connecting rod, a movable cavity is arranged in each element installation body, a second through groove communicated and arranged with the outside is arranged on the rear side end wall of each movable cavity, and a first inserting block opposite to the first slot is fixedly arranged on the rear side end surface of each element installation body, the rear side wall of the movable cavity is internally provided with a second insert block which is connected with the rear side wall of the movable cavity in a sliding fit manner and is arranged in a front-back extending manner, the rear side end of the second insert block is arranged opposite to the second slot, the rear side section of the second insert block extends out of the rear side end face of the element installation body, the bottom end face of the first insert block is internally provided with a conductive groove with a downward opening, the top end face of the second insert block is internally provided with a rack part, the front side wall of the movable cavity is internally provided with a first sliding groove in a communicated manner, the first sliding groove is connected with a first sliding block in a sliding fit manner, the first sliding block is internally connected with a first guide sliding rod in a sliding fit manner, the upper and lower extending ends of the first guide sliding rod are respectively connected with the upper and lower end walls of the first sliding groove in a fixed fit manner, and the lower side of the first sliding, the bottom of the movable cavity is connected with a push sliding plate in a sliding fit manner, the front side extending tail end of the second insertion block extends into the movable cavity and is fixedly matched and connected with the rear side end face of the push sliding plate, a third through groove is arranged in the push sliding plate, the bottom of the third through groove is connected with a second guide sliding rod which extends forwards and backwards in a sliding fit manner, the front end face and the rear end face of the second guide sliding rod are respectively fixedly matched and connected with the front end wall and the rear end wall of the movable cavity, a second spring which is arranged on the outer side of the second guide sliding rod in a surrounding manner is arranged on the front side of the push sliding plate, an inclined pushing block which extends into the third through groove and is connected with the inclined sliding block in a jacking and sliding fit manner is fixedly arranged on the upper side of the inclined pushing block, a second connecting rod which is fixedly matched and connected with the first sliding block is arranged on the upper side of the inclined pushing block, and a second inclined block is fixedly arranged on the rear, the automatic control mechanism comprises a sliding block which is connected and arranged in the first through groove in a sliding fit manner, a second sliding groove which is communicated and arranged in the rear side wall of the first through groove, and a second sliding block which is arranged in the second sliding groove in a sliding fit manner and is fixedly connected with the sliding block in a matching manner, the second sliding block is internally and screw-connected with a regulating screw rod which extends up and down, the top end of the regulating screw rod is in power fit connection with a regulating motor which is fixedly embedded in the top wall of the second sliding groove, the top end of the sliding block is fixedly provided with a power supply block connected with commercial power, the bottom end surface of the sliding block is internally provided with a driving groove with a downward opening, a driven gear is connected in the driving groove in a rotating matching way, the upper side of the driven gear is connected with a driving gear in a meshing way, and the right end of the driving gear is in power fit connection with an output shaft of a driving motor fixedly embedded in the right side wall of the driving groove.

2. An electric power intelligent power distribution cabinet according to claim 1, characterized in that: the front side of the control cabinet is provided with a switch door body which is connected with the control cabinet in a hinged fit mode, and the switch door body is provided with a display part.

3. An electric power intelligent power distribution cabinet according to claim 1, characterized in that: the second through groove is opposite to the first inclined plane block.

4. An electric power intelligent power distribution cabinet according to claim 1, characterized in that: the first spring and the second spring are both top pressure springs.

5. An electric power intelligent power distribution cabinet according to claim 1, characterized in that: the maximum circumcircle at the bottom of the driven gear extends out of the end face of the bottom of the sliding block.