CN220673128U - Intelligent power distribution cabinet with high safety performance - Google Patents

Abstract

The utility model provides an intelligent power distribution cabinet with high safety performance, and relates to the technical field of power distribution cabinets. The intelligent power distribution cabinet with high safety performance comprises a power distribution box body, wherein built-in grooves are formed in the left side and the right side of the power distribution box body, movable ports communicated with the built-in grooves are symmetrically formed in the bottom surface of the power distribution box body, and a stabilizing mechanism is movably arranged in the movable ports; the power distribution box is characterized in that a working cavity is formed in the rear side of the power distribution box body, a linkage mechanism is accommodated in the working cavity, a lifting mechanism is arranged at the junction of the linkage mechanism and the stabilizing mechanism, and a rotating mechanism is arranged at the driving end of the linkage mechanism. The intelligent power distribution cabinet with high safety performance has the advantages that the intelligent power distribution cabinet can support and strengthen the power distribution box body, so that the power distribution box body is prevented from collapsing due to external force collision, and the stability and safety of the power distribution box body are further effectively improved.

Description

Intelligent power distribution cabinet with high safety performance

Technical Field

The utility model relates to the technical field of power distribution cabinets, in particular to an intelligent power distribution cabinet with high safety performance.

Background

The intelligent power distribution cabinet is a power distribution cabinet aiming at the tail end of the energy source of the data center machine room, comprehensively collects all energy source data, provides high-precision measurement data for a terminal energy source monitoring system, reflects the power quality data in real time through a display unit, and uploads the power quality data to a background environment control system through digital communication so as to achieve effective management of real-time monitoring and operation quality of the whole power distribution system, help users optimize a network data center, strengthen energy consumption management and improve the operation efficiency of a server rack.

But current switch board is when using, adopts directly to put on ground generally, when the switch board received external force collision, can lead to the electric cabinet body to appear empting, causes the inside component of electric cabinet body to appear rocking to easily cause the inside component of switch board to appear breaking circuit, influence the normal use of switch board, increase user's economic loss.

Therefore, it is necessary to provide a new intelligent power distribution cabinet with high safety performance to solve the above technical problems.

Disclosure of Invention

In order to solve the technical problems, the utility model provides the intelligent power distribution cabinet with high safety performance.

The intelligent power distribution cabinet with high safety performance comprises a power distribution box body, wherein built-in grooves are formed in the left side and the right side of the power distribution box body, movable ports communicated with the built-in grooves are symmetrically formed in the bottom surface of the power distribution box body, and a stabilizing mechanism is movably arranged in the movable ports; the power distribution box is characterized in that a working cavity is formed in the rear side of the power distribution box body, a linkage mechanism is accommodated in the working cavity, a lifting mechanism is arranged at the junction of the linkage mechanism and the stabilizing mechanism, and a rotating mechanism is arranged at the driving end of the linkage mechanism.

Preferably, the rotating mechanism comprises a motor arranged on the outer wall of one side of the distribution box body, a rotating shaft is fixed at the driving end of the motor, and one end of the rotating shaft, far away from the motor, rotates and extends to the inside of the working cavity and is connected with an inner wall bearing of one side of the working cavity at the tail end.

Preferably, the linkage mechanism comprises first bevel gears symmetrically sleeved on the outer surface of the rotating shaft, and one sides of the two first bevel gears are respectively connected with a second bevel gear in a meshed mode.

Preferably, the lifting mechanism comprises a rotating shaft fixedly penetrating through the inner surface of the second bevel gear, and one end, far away from the second bevel gear, of the rotating shaft extends to the inside of the built-in groove and is connected with the front side inner wall bearing of the built-in groove at the tail end.

Preferably, the outer surface of the rotating shaft is fixedly sleeved with a gear, and the gear is positioned in the built-in groove.

Preferably, racks are connected to the left side and the right side of the gear in a meshed mode.

Preferably, the stabilizing mechanism comprises a movable frame movably arranged in the built-in groove, and the two racks are respectively and symmetrically fixed on the inner walls of the left side and the right side of the movable frame.

Preferably, a support is fixed on the bottom surface of the movable frame, and a base is fixed at the tail end of the support.

Compared with the related art, the intelligent power distribution cabinet with high safety performance has the following beneficial effects:

the utility model provides an intelligent power distribution cabinet with high safety performance, which can drive a linkage mechanism to rotate on the front side and the back side in a working cavity through the arranged rotating mechanism, so that a lifting mechanism drives a stabilizing mechanism to move in the vertical direction in an internal groove through the linkage mechanism until the stabilizing mechanism moves to be attached to the bottom surface, and then the power distribution cabinet body can be supported and reinforced, so that the power distribution cabinet body is prevented from collapsing due to collision of external force, and the stability and safety of the power distribution cabinet body are further effectively improved.

Drawings

FIG. 1 is a schematic diagram of a preferred embodiment of an intelligent power distribution cabinet with high safety performance according to the present utility model;

fig. 2 is a schematic front sectional view of the block terminal body shown in fig. 1;

FIG. 3 is a schematic top cross-sectional view of the block terminal body shown in FIG. 1;

FIG. 4 is a schematic diagram showing a specific structure of the rotating mechanism, the linkage mechanism and the lifting mechanism shown in FIG. 3;

fig. 5 is a schematic structural diagram of the stabilizing mechanism shown in fig. 2.

Reference numerals in the drawings: 1. a distribution box body; 2. a stabilizing mechanism; 21. a movable frame; 22. a support post; 23. a base; 3. a rotating mechanism; 31. a motor; 32. a rotating shaft; 4. a built-in groove; 5. a working chamber; 6. a linkage mechanism; 61. a first bevel gear; 62. a second bevel gear; 7. a lifting mechanism; 71. a rotating shaft; 72. a gear; 73. a rack; 8. and a movable opening.

Detailed Description

The utility model will be further described with reference to the drawings and embodiments.

Referring to fig. 1 to 5 in combination, an intelligent power distribution cabinet with high safety performance comprises a power distribution box body 1, wherein built-in grooves 4 are formed in the left side and the right side of the power distribution box body 1, movable ports 8 communicated with the built-in grooves 4 are symmetrically formed in the bottom surface of the power distribution box body 1, and a stabilizing mechanism 2 is movably arranged in the movable ports 8; the rear side of the distribution box body 1 is internally provided with a working cavity 5, a linkage mechanism 6 is accommodated in the working cavity 5, a lifting mechanism 7 is arranged at the junction of the linkage mechanism 6 and the stabilizing mechanism 2, and a driving end of the linkage mechanism 6 is provided with a rotating mechanism 3.

When in use, when the distribution box body 1 needs to be fixedly supported, the motor 31 is started firstly, the rotating shaft 32 can rotate clockwise, the two first bevel gears 61 symmetrically sleeved on the outer wall of the rotating shaft 32 can rotate relatively in the rotating direction, the second bevel gears 62 respectively meshed with one sides of the two first bevel gears 61 can rotate along with the rotating shaft, at the moment, the two rotating shafts 71 respectively installed in the inner walls of the two second bevel gears 62 can rotate relatively in the rotating direction, the two gears 72 can synchronously rotate, the two movable frames 21 can vertically move downwards through the movable ports 8 in the built-in grooves 4 through the racks 73 symmetrically distributed, the two bases 23 respectively installed at the bottoms of the two support posts 22 can be moved to be attached to the bottom surface, the distribution box body 1 can be supported and reinforced, and the collapse of the distribution box body 1 caused by the collision of external force is avoided, so that the stability and safety of the distribution box body 1 are effectively improved.

In the implementation process, as shown in fig. 1 and 4, the rotating mechanism 3 includes a motor 31 installed on an outer wall of one side of the distribution box body 1, a rotating shaft 32 is fixed at a driving end of the motor 31, and one end of the rotating shaft 32 away from the motor 31 rotates and extends into the working chamber 5 and is connected with an inner wall bearing of one side of the working chamber 5 at a tail end.

In use, by connecting the rotary shaft 32 with the drive end of the motor 31, the rotary shaft 32 can rotate in the forward and reverse directions inside the working chamber 5 when the motor 31 is in operation.

Referring to fig. 3 and 4, the linkage mechanism 6 includes first bevel gears 61 symmetrically sleeved on the outer surface of the rotating shaft 32, and one side of each of the two first bevel gears 61 is engaged with and connected with a second bevel gear 62.

When in use, the two first bevel gears 61 are symmetrically sleeved on the outer wall of the rotating shaft 32, and when the rotating shaft 32 rotates, the two first bevel gears 61 synchronously rotate in opposite rotation directions, so that the two second bevel gears 62 respectively meshed with one side of the two first bevel gears 61 also rotate together.

Referring to fig. 1 and 4, the elevating mechanism 7 includes a rotation shaft 71 fixedly installed on the inner surface of the second bevel gear 62, and one end of the rotation shaft 71 away from the second bevel gear 62 extends into the interior of the built-in groove 4 and is bearing-connected at the end with the front inner wall of the built-in groove 4.

Referring to fig. 4, a gear 72 is fixedly coupled to the outer surface of the rotation shaft 71, and the gear 72 is positioned inside the built-in groove 4.

As shown in fig. 5, racks 73 are engaged with and connected to both the left and right sides of the gear 72.

In use, the rotary shaft 71 is mounted inside the second bevel gear 62, and when the second bevel gear 62 rotates, the rotary shaft 71 will rotate together, so that the racks 73 meshed with the left and right sides of the gear 72 will move vertically up and down, in preparation for adjusting the position of the stabilizing mechanism 2 later.

Referring to fig. 2 and 5, the stabilizing mechanism 2 includes a movable frame 21 movably disposed in the interior of the built-in slot 4, and two racks 73 are symmetrically fixed to the inner walls of the left and right sides of the movable frame 21, respectively.

Referring to fig. 3 and 5, a pillar 22 is fixed to the bottom surface of the movable frame 21, and a base 23 is fixed to the end of the pillar 22.

When the electric power distribution box is used, the movable frame 21 is meshed and connected with the gear 72 through the rack 73, and when the gear 72 rotates, the movable frame 21 is meshed with the gear 72 through the rack 73, so that the movable frame 21 can drive the support column 22 to move in the vertical direction in the built-in groove 4, the base 23 can move to be tightly attached to the bottom surface, and the electric power distribution box can support and fix the electric power distribution box body 1.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present utility model.

Claims (8)

1. The intelligent power distribution cabinet with high safety performance is characterized by comprising a power distribution box body (1), wherein built-in grooves (4) are formed in the left side and the right side of the power distribution box body (1), movable ports (8) communicated with the built-in grooves (4) are symmetrically formed in the bottom surface of the power distribution box body (1), and a stabilizing mechanism (2) is movably arranged in the movable ports (8); the power distribution box is characterized in that a working cavity (5) is formed in the rear side of the power distribution box body (1), a linkage mechanism (6) is contained in the working cavity (5), a lifting mechanism (7) is arranged at the junction of the linkage mechanism (6) and the stabilizing mechanism (2), and a rotating mechanism (3) is arranged at the driving end of the linkage mechanism (6).

2. The intelligent power distribution cabinet with high safety performance according to claim 1, wherein the rotating mechanism (3) comprises a motor (31) mounted on one side outer wall of the power distribution cabinet body (1), a rotating shaft (32) is fixed at the driving end of the motor (31), and one end, far away from the motor (31), of the rotating shaft (32) rotates, extends into the working cavity (5) and is connected with one side inner wall bearing of the working cavity (5) at the tail end.

3. The intelligent power distribution cabinet with high safety performance according to claim 1, wherein the linkage mechanism (6) comprises first bevel gears (61) symmetrically sleeved on the outer surface of the rotating shaft (32), and one sides of the two first bevel gears (61) are respectively connected with a second bevel gear (62) in a meshed mode.

4. The intelligent power distribution cabinet with high safety performance according to claim 1, wherein the lifting mechanism (7) comprises a rotating shaft (71) fixedly penetrating through the inner surface of the second bevel gear (62), and one end of the rotating shaft (71) away from the second bevel gear (62) extends to the inside of the built-in groove (4) and is connected with a front side inner wall bearing of the built-in groove (4) at the tail end.

5. The intelligent power distribution cabinet with high safety performance according to claim 4, wherein a gear (72) is fixedly sleeved on the outer surface of the rotating shaft (71), and the gear (72) is positioned in the built-in groove (4).

6. The intelligent power distribution cabinet with high safety performance according to claim 5, wherein racks (73) are connected to the left side and the right side of the gear (72) in a meshed mode.

7. The intelligent power distribution cabinet with high safety performance according to claim 6, wherein the stabilizing mechanism (2) comprises a movable frame (21) movably arranged in the built-in groove (4), and two racks (73) are symmetrically fixed on the inner walls of the left side and the right side of the movable frame (21) respectively.

8. The intelligent power distribution cabinet with high safety performance according to claim 7, wherein a pillar (22) is fixed on the bottom surface of the movable frame (21), and a base (23) is fixed at the tail end of the pillar (22).