CN218261860U - Emergency power supply distribution device - Google Patents

Abstract

The application discloses emergency power supply distribution device belongs to the emergency equipment field. This emergency power distribution device includes: the device comprises a base, a lifting assembly, an operating platform and a power distribution assembly; the base and the operation platform are spaced, one side of the base, which is far away from the operation platform, is provided with a roller group, and the roller group is connected with the base; the lifting assembly is positioned between the base and the operating platform and used for driving the base and the operating platform to move mutually; the power distribution assembly is located on one side of the operating platform, which faces away from the lifting assembly. This application can improve the efficiency of construction, reduces the human cost.

Description

Emergency power supply distribution device

Technical Field

The application belongs to the field of emergency equipment, and particularly relates to an emergency power supply distribution device.

Background

The Power Distribution Unit (PDU) has a wide application in a data center, and can distribute Power to electric devices plugged thereon, so as to implement Distribution of Power.

In the process of operating the power distribution unit, if the power distribution unit fails, the failed power distribution unit needs to be replaced. In the related art, many people need to be called for to cooperate in construction to replace the power distribution unit, and the standby power distribution unit, the step ladder and the like are respectively carried, so that the construction efficiency is low, and the labor cost is high.

SUMMERY OF THE UTILITY MODEL

The embodiment of the application provides an emergency power supply distribution device, can improve the efficiency of construction, reduces the human cost. The technical scheme is as follows:

the embodiment of the application provides an emergency power distribution device, includes: the device comprises a base, a lifting assembly, an operating platform and a power distribution assembly;

the base and the operating platform are spaced, one side of the base, which is far away from the operating platform, is provided with a roller group, and the roller group is connected with the base;

the lifting assembly is positioned between the base and the operating platform and is used for driving the base and the operating platform to move mutually;

the power distribution assembly is located on a side of the operating platform facing away from the lifting assembly.

In one implementation of the present application, the lifting assembly includes a telescoping cylinder and an interdigitated telescoping boom;

two ends of the telescopic cylinder are respectively connected with the base and the operating platform;

the two ends of the cross-shearing type telescopic frame are respectively connected with the base and the operating platform, and the telescopic direction of the cross-shearing type telescopic frame is the same as that of the telescopic cylinder.

In one implementation of the present application, the base includes a case, a pressure measurement component, and a power component;

the pressure measurement assembly is positioned in the box body and is electrically connected with the power distribution assembly;

the power assembly is located in the box body and spaced from the pressure measuring assembly, and the power assembly is in transmission connection with the lifting assembly.

In one implementation of the present application, the base further comprises a partition;

the partition board is positioned in the box body so that the inner space of the box body is divided into a first space and a second space;

the pressure measurement assembly is located in the first space, and the power assembly is located in the second space.

In one implementation of the present application, the base further comprises an emergency power connector;

the emergency power supply connector is connected with the box body, and the emergency power supply connector is electrically connected with the power distribution assembly.

In one implementation of the present application, the power distribution assembly includes a frame body and a plurality of power distribution units;

the power distribution units are arranged on the rack at intervals and at least comprise power distribution units with interfaces of C13 specifications and power distribution units with interfaces of C19 specifications.

In one implementation of the present application, the power distribution assembly further comprises a test stand;

the test bench is located at the top of the frame body and electrically connected with the power distribution units to test the on-off of the power distribution units.

In one implementation of the present application, the operation platform includes a bearing platform and a guardrail;

one side of the bearing table is connected with the lifting assembly;

the guardrail with the power distribution subassembly all is located the opposite side of plummer, just the guardrail with the power distribution subassembly is arranged side by side, the guardrail with the power distribution subassembly links to each other.

In one implementation of the present application, the operating platform further comprises a step ladder;

one end of the step ladder is connected with the bearing table and located at the notch of the guardrail, and the other end of the step ladder extends towards the base.

In one implementation of the present application, the roller train includes a plurality of casters;

a plurality of the universal caster is arranged at intervals, and the universal caster is provided with a brake.

The beneficial effects that technical scheme that this application embodiment brought include at least:

because the bottom of base has the roller train, so a constructor just can promote emergency power supply distributor to the job site. After promoting emergency power distribution device to the job site, can drive operation platform through lifting unit and remove for the base, also realize operation platform's rising and decline to can be located constructor lifting to the trouble power distribution unit department that needs to be changed on the operation platform, with the cable from trouble power distribution unit change insert to emergency power distribution device's power distribution assembly, and then accomplish emergency construction.

That is to say, through the emergency power distribution device that this application embodiment provided, only need a constructor can accomplish emergent construction, the effectual efficiency of construction that has improved has reduced the human cost.

Drawings

In order to more clearly illustrate the technical solutions in the embodiments of the present application, the drawings required to be used in the description of the embodiments are briefly introduced below, and it is obvious that the drawings in the description below are only some embodiments of the present application, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an emergency power distribution apparatus provided in an embodiment of the present application;

FIG. 2 is a schematic circuit diagram of an emergency power connector portion according to an embodiment of the present disclosure;

fig. 3 is a schematic circuit diagram corresponding to an operating power connector portion according to an embodiment of the present application.

The symbols in the drawings represent the following meanings:

10. a base;

110. a box body; 111. an ascending indicator light; 112. a descent indication lamp; 113. a raise button; 114. a down button; 115. a stop button; 116. a work indicator light; 117. a working switch; 120. a pressure measurement component; 130. a power assembly; 140. a partition plate; 150. an emergency power supply connector; 160. a working power supply connector;

20. a lifting assembly;

210. a telescopic cylinder; 220. a scissor type telescopic frame;

30. an operating platform;

310. a bearing table; 320. a guardrail; 330. a step ladder is stepped;

40. a power distribution assembly;

410. a frame body; 420. a power distribution unit; 430. a test bench; 440. a socket;

50. a roller group;

510. a universal caster; 520. and (7) braking.

Detailed Description

To make the objects, technical solutions and advantages of the present application more clear, embodiments of the present application will be described in further detail below with reference to the accompanying drawings.

The Power Distribution Unit (PDU) has a wide application in a data center, and can distribute Power to electric devices plugged thereon, so as to implement Distribution of Power.

During operation of the power distribution unit, a power module of rack equipment in the data center fails, which may cause the power distribution unit to trip. The power distribution unit is used for a long time, and the inside of the power distribution unit is easy to generate abrasion faults. If the power distribution unit fails, the failed power distribution unit needs to be replaced.

In the related art, many people need to be called for to cooperate in construction to replace the power distribution unit, and the standby power distribution unit, the step ladder and the like are respectively carried, so that the construction efficiency is low, and the labor cost is high.

In order to solve the above technical problem, an emergency power distribution device is provided in an embodiment of the present application, where fig. 1 is a schematic structural diagram of the emergency power distribution device, and referring to fig. 1, in the embodiment, the emergency power distribution device includes a base 10, a lifting assembly 20, an operation platform 30, and a power distribution assembly 40.

The base 10 and the operation platform 30 are spaced apart, a side of the base 10 facing away from the operation platform 30 is provided with a roller set 50, the roller set 50 is connected to the base 10, the lifting assembly 20 is located between the base 10 and the operation platform 30 and used for driving the base 10 and the operation platform 30 to move relative to each other, and the power distribution assembly 40 is located on a side of the operation platform 30 facing away from the lifting assembly 20.

Since the base 10 has the roller set 50 at the bottom thereof, one operator can push the emergency power distribution apparatus to a construction site. After the emergency power distribution device is pushed to a construction site, the lifting assembly 20 can drive the operation platform 30 to move relative to the base 10, that is, the operation platform 30 can ascend and descend, so that a constructor on the operation platform 30 can be lifted to the fault power distribution unit 420 to be replaced, cables are plugged from the fault power distribution unit 420 to the power distribution assembly 40 of the emergency power distribution device, and emergency construction is completed.

That is to say, through the emergency power distribution device that this application embodiment provided, only need a constructor can accomplish emergent construction, the effectual efficiency of construction that has improved has reduced the human cost.

In this embodiment, the roller set 50 includes a plurality of casters 510, the casters 510 are spaced apart from each other, and the casters 510 have brakes 520.

The emergency power distribution device can move in multiple directions through the universal caster 510, and the movement convenience of the emergency power distribution device is guaranteed. During the movement, the brake 520 is in a release state, and the normal movement of the emergency power distribution device is not influenced. After the emergency power distribution device is moved in place, the brake 520 is adjusted to a locking state, so that unnecessary movement of the emergency power distribution device is avoided.

As can be seen from the foregoing, the emergency power distribution apparatus provided in the embodiments of the present application integrates a plurality of functional modules, such as the power distribution assembly 40, the lifting assembly 20, and the like, so as to facilitate the operation of one constructor. The following describes each functional module of the emergency power distribution apparatus.

In this embodiment, the lifting assembly 20 includes a telescoping cylinder 210 and a scissor jack 220. Two ends of the telescopic cylinder 210 are respectively connected with the base 10 and the operating platform 30, two ends of the cross-shear type telescopic frame 220 are respectively connected with the base 10 and the operating platform 30, and the telescopic direction of the cross-shear type telescopic frame 220 is the same as that of the telescopic cylinder 210.

In the above implementation, the telescopic cylinder 210 is used to provide power to drive the base 10 and the operation platform 30 at two ends of the telescopic cylinder to move relative to each other through self expansion and contraction. When the telescopic cylinder 210 is extended, the base 10 and the operation platform 30 move back to back, that is, the operation platform 30 is raised. When the telescopic cylinder 210 is shortened, the base 10 and the operation platform 30 move towards each other, that is, the operation platform 30 is lowered. The scissor type telescopic frame 220 is used for providing a supporting force, so that unnecessary shaking between the base 10 and the operating platform 30 is avoided, and the connection stability of the lifting assembly 20 between the base 10 and the operating platform 30 is effectively improved.

Illustratively, the telescopic cylinder 210 includes a cylinder body and a piston rod, one end of the piston rod is movably inserted into the cylinder body, the other end of the piston rod is connected to the operation platform 30, and the end of the cylinder body away from the piston rod is connected to the base 10.

In the present embodiment, the lifting assembly 20 includes a plurality of telescopic cylinders 210 and a plurality of scissor-type telescopic frames 220, which are respectively and uniformly distributed between the base 10 and the operation platform 30, so that the relative movement between the base 10 and the operation platform 30 can be more stable.

In the present embodiment, the base 10 includes a case 110, a pressure measuring unit 120, and a power unit 130. The pressure measuring component 120 is located in the box body 110 and electrically connected to the power distribution component 40, the power component 130 is located in the box body 110 and spaced apart from the pressure measuring component 120, and the power component 130 is in transmission connection with the lifting component 20.

In the above implementation, the box 110 is a frame 410 of the base 10, and can accommodate the pressure measuring assembly 120 and the power assembly 130, and provide stable support for the lifting assembly 20 on the top thereof. The pressure measuring assembly 120 and the power assembly 130 are respectively located in the box body 110, and are spaced from each other without affecting each other. The pressure measurement component 120 is electrically connected to the power distribution component 40, measures parameters of the power distribution component 40, such as voltage, current, power, temperature, and the like, and comprehensively determines whether the power distribution component 40 meets the requirements of the pressure test. The power assembly 130 is used for providing power to the lifting assembly 20, so that the lifting assembly 20 can drive the base 10 and the operation platform 30 to move mutually.

For example, if the telescopic cylinder 210 is a hydraulic cylinder, the power assembly 130 includes a motor and a hydraulic pump, the motor drives the hydraulic pump to work, the hydraulic pump is connected to the telescopic cylinder 210 through an oil pipe, and the hydraulic pump pumps hydraulic oil into the telescopic cylinder 210, so as to provide kinetic energy to the telescopic cylinder 210. If the telescopic cylinder 210 is an air cylinder, the power assembly 130 includes a motor and an air pump, the motor drives the air pump to work, the air pump is connected with the telescopic cylinder 210 through an air pipe, and the air pump pumps high-pressure air into the telescopic cylinder 210, so as to provide kinetic energy for the telescopic cylinder 210.

In this embodiment, the case 110 further has an up indicator 111, a down indicator 112, an up button 113, a down button 114, and a stop button 115. When the worker presses the up button 113, the up indicator lamp 111 is turned on, the lifting unit 20 drives the operation platform 30 to ascend, the worker presses the down button 114, the down indicator lamp 112 is turned on, and the lifting unit 20 drives the operation platform 30 to descend. During the process of ascending or descending the operation platform 30, the operator can press the stop button 115 at any time, so that the operation of the elevation assembly 20 is stopped.

Since the pressure measuring component 120 is related to an electric circuit and the power component 130 is related to a hydraulic oil circuit, in order to avoid mutual influence between the two components, in this embodiment, the base 10 further includes a partition plate 140, the partition plate 140 is located in the case 110, so that the internal space of the case 110 is divided into a first space and a second space, the pressure measuring component 120 is located in the first space, and the power component 130 is located in the second space.

That is, the pressure measuring assembly 120 and the power assembly 130 are separated by the partition 140, and the mutual influence between the two is effectively avoided.

In this embodiment, the base 10 further includes an emergency power connector 150, the emergency power connector 150 is connected to the box 110, and the emergency power connector 150 is connected to the power distribution assembly 40.

In the above implementation, the emergency power connector 150 is used to dock a power plug within a data center, thereby enabling the emergency power distribution device to obtain power and distribute the power to the power distribution assembly 40, thereby enabling the power distribution assembly 40 to provide sufficient backup power.

For example, a power plug in a data center can output 220V of mains power. Of course, the electric energy of other specifications can be output according to the requirement, and the application does not limit the electric energy.

In this embodiment, the base 10 further includes a working power connector 160, the working power connector 160 is connected to the housing 110, the working power connector 160 is electrically connected to the power assembly 130, and the working power connector 160 can also be connected to a power plug in the data center, so that the emergency power distribution device can obtain power and distribute the power to the power assembly 130, thereby providing power to the motor of the power assembly 130.

In this embodiment, the power distribution assembly 40 includes a frame 410 and a plurality of power distribution units 420, the plurality of power distribution units 420 are arranged on the frame 410 at intervals, and at least one of the plurality of power distribution units 420 includes a power distribution unit 420 having an interface of a C13 specification and a power distribution unit 420 having an interface of a C19 specification.

The frame 410 is used to provide a stable installation base for the power distribution units 420, so that each power distribution unit 420 can be stably installed on the frame 410. Since the power distribution units 420 are spaced apart from each other, the power distribution units 420 do not affect each other, thereby ensuring the reliability of the power distribution module 40.

In addition, since the plurality of power distribution units 420 at least include the power distribution unit 420 having the interface of the C13 specification and the power distribution unit 420 having the interface of the C19 specification, the applicability of the power distribution assembly 40 is effectively improved, the specification of the faulty power distribution unit does not need to be determined in advance, and the construction efficiency is further improved. Moreover, since the power distribution unit 420 is provided, the number of the fault power distribution units does not need to be determined, and the construction efficiency is further improved. Of course, the power distribution units 420 with interfaces of other specifications can be provided in the plurality of power distribution units 420, which is not limited in this application.

In this embodiment, the box body 110 has the work indicator 116 and the work switch 117, each power distribution unit 420 corresponds to one work indicator 116 and one work switch 117, on-off control of the power distribution unit 420 can be achieved through the work switch 117, and on-off states of the power distribution unit 420 can be indicated through the work indicator 116.

In this embodiment, the power distribution assembly 40 further includes a testing table 430, the testing table 430 is located on the top of the frame 410, and the testing table 430 is electrically connected to the plurality of power distribution units 420 to test on/off of the plurality of power distribution units 420.

The test bench 430 is disposed on the top of the frame body 410, so that the operation of a constructor can be facilitated, and the on/off of each power distribution unit 420 can be tested through the test bench 430.

For example, power for test station 430 can be provided by a working power connection.

In this embodiment, the operation platform 30 comprises a carrying platform 310 and a guardrail 320, one side of the carrying platform 310 is connected to the lifting assembly 20, the guardrail 320 and the power distribution assembly 40 are located on the other side of the carrying platform 310, the guardrail 320 and the power distribution assembly 40 are arranged side by side, and the guardrail 320 is connected to the power distribution assembly 40.

One side of the carrier 310 is connected to the telescopic cylinder 210 and the scissor type telescopic frame 220, respectively, and the other side of the carrier 310 is connected to the guard rail 320 and the frame body 410, thereby providing a stable bearing for the guard rail 320 and the frame body 410. In addition, in the region where the guard rail 320 is disposed, the bearing platform 310 can also bear the weight of the constructor, thereby providing a construction space for the constructor. Further, under the protection of the guard rail 320, the construction safety of the constructor can be improved.

Illustratively, to facilitate operation by a worker at guardrail 320, test station 430 is located at the top of frame 410 near guardrail 320.

In this embodiment, the operation platform 30 further comprises a step ladder 330, one end of the step ladder 330 is connected to the bearing platform 310 and is located at the gap of the guardrail 320, and the other end of the step ladder 330 extends toward the base 10. Through the step ladder 330, the constructor can conveniently get on the bearing table 310, the constructor is prevented from falling down in the process, and the safety of the emergency power distribution device is improved.

It should be noted that if the operation platform does not have the step ladder 330, it may be inconvenient for the constructor to get on the operation platform 30 after the operation platform 30 is raised. In this case, the constructor gets on the operation platform 30 before the operation platform 30 is raised, and controls the lifting assembly 20 to lift or lower the operation platform 30 by means of the wireless remote control. Still alternatively, the aforementioned ascending indicator 111, descending indicator 112, ascending button 113, descending button 114, and stop button 115 may be disposed on the top of the frame 410, so that the constructor can control the ascending and descending of the operation platform 30 on the operation platform 30.

The circuit parts involved in the emergency power distribution apparatus are described below.

Fig. 2 is a schematic circuit diagram corresponding to the emergency power connector part, and in conjunction with fig. 2, in this embodiment, each power distribution unit 420 is electrically connected to the emergency power connector 150, so that power is supplied to each power distribution unit 420 through the emergency power connector 150.

FIG. 3 is a corresponding schematic circuit diagram of the portion of the working power connector, and in conjunction with FIG. 3, in this embodiment, the motor of the power assembly 130 is electrically connected to the test station 430, such that power is supplied to the motor of the power assembly 130 and the test station 430 through the working power connector.

In addition, still be connected with socket 440 on the working power source connector, this socket 440 is located the top of support body 410, is convenient for supply power for constructor's electric tool.

Unless defined otherwise, technical or scientific terms used herein shall have the ordinary meaning as understood by one of ordinary skill in the art to which this disclosure belongs. The terms "first," "second," "third," and the like, as used in the description and in the claims of the present disclosure, do not denote any order, quantity, or importance, but rather are used to distinguish one element from another. Also, the use of the terms a, an, etc. do not denote a limitation of quantity, but rather denote the presence of at least one. The word "comprise" or "comprises", and the like, means that the element or item listed before "comprises" or "comprising" covers the element or item listed after "comprising" or "comprises" and its equivalents, and does not exclude other elements or items. The terms "connected" or "coupled" and the like are not restricted to physical or mechanical connections, but may include electrical connections, whether direct or indirect. "upper", "lower", "left", "right", and the like are used merely to indicate relative positional relationships, and when the absolute position of the object being described is changed, the relative positional relationships may also be changed accordingly.

The above description is only exemplary of the present application and should not be taken as limiting, as any modification, equivalent replacement, or improvement made within the spirit and principle of the present application should be included in the protection scope of the present application.

Claims (10)

1. An emergency power distribution apparatus, comprising: the device comprises a base (10), a lifting assembly (20), an operating platform (30) and a power distribution assembly (40);

the base (10) is spaced from the operating platform (30), a roller group (50) is arranged on one side, facing away from the operating platform (30), of the base (10), and the roller group (50) is connected with the base (10);

the lifting assembly (20) is positioned between the base (10) and the operating platform (30) and is used for driving the base (10) and the operating platform (30) to move mutually;

the power distribution assembly (40) is located on a side of the operating platform (30) facing away from the lifting assembly (20).

2. The emergency power distribution device of claim 1, wherein the lifting assembly (20) comprises a telescoping cylinder (210) and a cross-scissor jack (220);

two ends of the telescopic cylinder (210) are respectively connected with the base (10) and the operating platform (30);

two ends of the cross-shearing type telescopic frame (220) are respectively connected with the base (10) and the operating platform (30), and the stretching direction of the cross-shearing type telescopic frame (220) is the same as that of the telescopic cylinder (210).

3. Emergency power distribution device according to claim 1, wherein the base (10) comprises a box (110), a pressure measurement assembly (120) and a power assembly (130);

the pressure measurement component (120) is positioned in the box body (110) and is electrically connected with the power distribution component (40);

the power assembly (130) is located in the box body (110) and is spaced from the pressure measuring assembly (120), and the power assembly (130) is in transmission connection with the lifting assembly (20).

4. Emergency power distribution device according to claim 3, characterized in that the base (10) further comprises a partition (140);

the partition (140) is positioned in the case (110) to divide an inner space of the case (110) into a first space and a second space;

the pressure measuring assembly (120) is located in the first space, and the power assembly (130) is located in the second space.

5. Emergency power distribution device according to claim 3, wherein the base (10) further comprises an emergency power connection (150);

the emergency power supply connector (150) is connected with the box body (110), and the emergency power supply connector (150) is electrically connected with the power distribution assembly (40).

6. The emergency power distribution device of claim 1, wherein the power distribution assembly (40) comprises a frame (410) and a plurality of power distribution units (420);

the plurality of power distribution units (420) are arranged on the frame body (410) at intervals, and the plurality of power distribution units (420) at least comprise the power distribution unit (420) with a C13 specification interface and the power distribution unit (420) with a C19 specification interface.

7. Emergency power distribution device according to claim 6, wherein the power distribution assembly (40) further comprises a test station (430);

the test bench (430) is located at the top of the frame body (410), and the test bench (430) is electrically connected with the plurality of power distribution units (420) so as to test the connection and disconnection of the plurality of power distribution units (420).

8. Emergency power distribution unit according to claim 1, characterized in that the operating platform (30) comprises a load-bearing platform (310) and a railing (320);

one side of the bearing platform (310) is connected with the lifting assembly (20);

the guardrail (320) and the power distribution assembly (40) are located on the other side of the bearing platform (310), the guardrail (320) and the power distribution assembly (40) are arranged side by side, and the guardrail (320) is connected with the power distribution assembly (40).

9. The emergency power distribution device of claim 8, wherein the operating platform (30) further comprises a step ladder (330);

one end of the step ladder (330) is connected with the bearing platform (310) and is positioned at the gap of the guardrail (320), and the other end of the step ladder (330) extends towards the base (10).

10. The emergency power distribution device according to claim 1, wherein the roller set (50) comprises a plurality of casters (510);

the universal casters (510) are arranged at intervals, and the universal casters (510) are provided with brakes (520).

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