CN214506130U - Intelligent temperature control type power distribution cabinet - Google Patents

Abstract

The utility model relates to a switch board technical field especially relates to an intelligence control by temperature change formula switch board, including switch board, cooling cabinet, insulated column and keeper, cooling cabinet fixed connection is in the switch board bottom, insulated column fixed connection in cooling cabinet bottom, keeper fixed connection is in the switch board openly, switch board top fixedly connected with closing cap, the inside cooling mechanism that is provided with of cooling cabinet. This intelligence control by temperature change formula switch board, electronic component through the switch board inside supplies power to cooling water pump, start cooling water pump back, cooling water pump takes cooling water out, and send into inside the heat-absorbing pipeline through the water supply pipeline, because the absorber plate is formed by the brass preparation, can absorb the inside heat of switch board, thereby make the inside temperature drop of switch board, get into the inside back of heat-absorbing pipeline at the cooling water, can absorb the inside heat of absorber plate, make the temperature drop of absorber plate, thereby continuously absorb the inside heat of switch board, make the inside temperature of switch board keep at a lower numerical value.

Description

Intelligent temperature control type power distribution cabinet

Technical Field

The utility model relates to a switch board technical field specifically is an intelligence control by temperature change formula switch board.

Background

The distribution cabinet (case) is a final-stage device of a distribution system and is a general name of a motor control center.

When the switch board was used, inside electronic component can distribute out more hot-air, and electronic component is in the higher temperature for a long time and carries out the during operation, can make electronic component's ageing speed accelerate, therefore most switch boards can be at internally mounted cooling device for cool down to switch board inside.

And the switch board heat sink on the present market is laid at the bottom or the top of switch board basically, directly carries out the trompil even at the back of switch board, and the switch board heat sink radiating effect on the present market is not good, can't be rapid in the summer of sweltering heat transfer the inside high temperature of switch board.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an intelligence control by temperature change formula switch board to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides an intelligence control by temperature change formula switch board, includes switch board, cooling cabinet, insulated column and keeper, cooling cabinet fixed connection is in the switch board bottom, insulated column fixed connection is in the cooling cabinet bottom, keeper fixed connection is in the switch board openly, switch board top fixedly connected with closing cap, the inside cooling body that is provided with of cooling cabinet.

The cooling mechanism includes cooling water pump, coolant tank, drinking-water pipeline, water feeding pipeline, absorber plate, heat absorption pipeline and return water pipeline, coolant pump fixed connection is in cooling cabinet inner wall bottom left side, coolant tank fixed connection is in cooling cabinet inner wall bottom, drinking-water pipeline fixed connection is on the coolant pump right side, water feeding pipeline fixed connection is in the cooling water pump left side, absorber plate fixed connection is in the inside back of switch board, the heat absorption pipeline is seted up inside the absorber plate, return water pipeline is seted up on the inside right side of switch board.

Preferably, the isolation columns are distributed at four corners of the bottom of the cooling cabinet to isolate the bottom of the cooling cabinet from the ground, the power distribution cabinet is provided with a door plate in the front, the door plate is fixedly connected with the door bolt, the door plate is hinged to the power distribution cabinet through the door bolt, the door plate can be pulled open, technicians can conveniently overhaul electronic elements inside the power distribution cabinet, and the top of the power distribution cabinet is provided with a notch.

Preferably, the inside ice-cube that fills of coolant tank can refrigerate the inside normal atmospheric temperature water of coolant tank, coolant tank openly left side top has seted up the filling opening, makes things convenient for operating personnel to the inside ice-cube that fills of coolant tank, the inside tampon piece that is provided with of filling opening avoids the inside air conditioning of coolant tank to leak, coolant tank inner wall bottom is the inclined plane, can make the inside cooling water of coolant tank pile up to one side.

Preferably, the pipeline that draws water runs through coolant tank to extend to the inside bottom of coolant tank, when cooling water pump started, the pipeline that draws water can be taken the cooling water out from coolant tank inside, the absorber plate is formed by the brass preparation, and brass has good heat conductivility.

Preferably, the left end and the water supply pipeline of heat absorption pipeline communicate, take the back at cooling water pump with the cooling water out, send the cooling water into the heat absorption pipeline through water supply pipeline in, return water pipeline runs through the inside and cooling cabinet outer wall of switch board to inside extending to coolant tank, in sending into the heat absorption pipeline through water supply pipeline, the right-hand member and the return water pipeline intercommunication of heat absorption pipeline absorb thermal cooling water that finishes, get into coolant tank through return water pipeline inside, the inside circulation of air mechanism that is provided with of switch board, remaining hot-air gives off to the switch board outside through circulation of air mechanism.

Preferably, the air circulation mechanism comprises an air inlet hole, an air circulation groove and a separation net, the air inlet hole is formed in the outer wall of the power distribution cabinet, the air circulation groove is formed in the center of the inside of the sealing cover, the separation net is fixedly connected to the top of the inside of the air circulation groove, and residual hot air is emitted to the outside of the power distribution cabinet through the air circulation mechanism, so that the air temperature inside the power distribution cabinet is kept at a lower value.

Preferably, the air inlet holes are uniformly distributed on the left side and the right side of the power distribution cabinet at equal intervals, more low-temperature air can enter the power distribution cabinet through the air inlet holes, the air flow through grooves are communicated with the notches, and residual high-temperature air in the power distribution cabinet is distributed to the outside of the power distribution cabinet through the air flow through grooves and the notches.

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

1. the intelligent temperature control type power distribution cabinet supplies power to the cooling water pump through an electronic element in the power distribution cabinet under the condition of hot weather, after the cooling water pump is started, the cooling water pump pumps out the cooling water in the cooling water tank through the water pumping pipeline and sends the cooling water into the heat absorption pipeline through the water sending pipeline, the heat absorption plate is made of brass, the brass has good heat conduction performance and can absorb the heat in the power distribution cabinet, so that the temperature in the power distribution cabinet is reduced, after the cooling water enters the heat absorption pipeline, the heat in the heat absorption plate can be absorbed, the temperature of the heat absorption plate is reduced, so that the heat in the power distribution cabinet is continuously absorbed, the temperature in the power distribution cabinet is kept at a lower value, the cooling water absorbing the heat in the heat absorption plate returns to the cooling water tank through the water returning pipeline, and ice blocks are filled in the cooling water tank, the temperature of the cooling water can be rapidly reduced, and meanwhile, the ice blocks are melted, so that water evaporated due to high temperature in the cooling water tank can be supplemented, and the water level in the cooling water tank is kept.

2. This intelligence control by temperature change formula switch board, at cooling mechanism during operation, the inside remaining high temperature of switch board makes the inside atmospheric pressure step-down of switch board to make the inside high temperature air of switch board pass through the outside that the air current leads to the groove and discharge out the switch board, and inside the low temperature air passes through the air access hole and gets into the switch board, reach the purpose that the air circulates fast, further reduction the inside temperature of switch board.

Drawings

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

FIG. 2 is a schematic view of the interior of the finishing structure of the present invention;

fig. 3 is a back sectional view of the structure of the power distribution cabinet of the present invention;

FIG. 4 is an enlarged schematic view of the cooling water tank structure of the present invention;

fig. 5 is a schematic view of the inside of the cooling water tank structure of the present invention.

In the figure: 1. a power distribution cabinet; 2. a cooling cabinet; 3. an isolation column; 4. a door bolt; 5. a door panel; 6. sealing the cover; 7. a cooling mechanism; 701. a cooling water pump; 702. a cooling water tank; 7021. a fill port; 7022. a filling block; 703. a water pumping pipeline; 704. a water supply pipeline; 705. a heat absorbing plate; 706. a heat absorption pipeline; 707. a water return pipe; 8. an air circulation mechanism; 801. an air inlet hole; 802. an air circulation groove; 803. and (4) isolating nets.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: an intelligent temperature control type power distribution cabinet comprises a power distribution cabinet 1, a cooling cabinet 2, isolation columns 3 and door bolts 4, wherein the top of the power distribution cabinet 1 is provided with a notch, the cooling cabinet 2 is fixedly connected to the bottom of the power distribution cabinet 1, the isolation columns 3 are fixedly connected to the bottom of the cooling cabinet 2, the isolation columns 3 are distributed at four corners of the bottom of the cooling cabinet 2 to separate the bottom of the cooling cabinet 2 from the ground, so that the corrosion caused by the long-time contact between the cooling cabinet 2 and the ground is avoided, the service life of the cooling cabinet 2 is prolonged, the door bolts 4 are fixedly connected to the front surface of the power distribution cabinet 1, the front surface of the power distribution cabinet 1 is provided with door plates 5, the door plates 5 are fixedly connected with the door bolts 4, the door plates 5 are hinged with the power distribution cabinet 1 through the door bolts 4, the door plates 5 can be pulled open, technicians can conveniently overhaul electronic elements in the power distribution cabinet 1, the top of the power distribution cabinet 1 is fixedly connected with a sealing cover 6, and the cooling mechanism 7 is arranged in the cooling cabinet 2, the inside air circulation mechanism 8 that is provided with of switch board 1.

The cooling mechanism 7 comprises a cooling water pump 701, a cooling water tank 702, a water pumping pipeline 703, a water feeding pipeline 704, a heat absorbing plate 705, a heat absorbing pipeline 706 and a water returning pipeline 707, the cooling water pump 701 is fixedly connected to the left side of the bottom of the inner wall of the cooling cabinet 2, the cooling water tank 702 is fixedly connected to the bottom of the inner wall of the cooling cabinet 2, ice cubes are filled in the cooling water tank 702, normal-temperature water in the cooling water tank 702 can be refrigerated, the melted ice cubes can fill up evaporated water in the cooling water tank 702, it is ensured that the water in the cooling water tank 702 is not too little, the working efficiency of the cooling mechanism 7 is ensured, a filling port 7021 is formed in the top of the left front side of the cooling water tank 702, an operator can conveniently fill ice cubes in the cooling water tank 702, a filling block 7022 is arranged in the filling port 7021, leakage of cold air in the cooling water tank 702 is avoided, the bottom of the inner wall of the cooling water tank 702 is an inclined plane, the cooling water in the cooling water tank 702 can be accumulated to one side, the cooling water pump 701 can more easily pump the cooling water, the water pumping pipeline 703 is fixedly connected to the right side of the cooling water pump 701, the water pumping pipeline 703 penetrates through the cooling water tank 702 and extends to the bottom inside the cooling water tank 702, when the cooling water pump 701 is started, the water pumping pipeline 703 can pump the cooling water out of the cooling water tank 702, the water feeding pipeline 704 is fixedly connected to the left side of the cooling water pump 701, the heat absorbing plate 705 is fixedly connected to the back inside the power distribution cabinet 1, the heat absorbing plate 705 is made of brass, the brass has good heat conducting performance and can absorb heat inside the power distribution cabinet 1, so that the temperature inside the power distribution cabinet 1 is reduced, the heat absorbing pipeline 706 is arranged inside the heat absorbing plate 705, the left end of the heat absorbing pipeline 706 is communicated with the water feeding pipeline 704, after the cooling water is pumped out by the cooling water pump 701, the cooling water feeding pipeline 706 is fed into the heat absorbing pipeline 706, the water return pipeline 707 is arranged on the right side inside the power distribution cabinet 1, the water return pipeline 707 penetrates through the inside of the power distribution cabinet 1 and the outer wall of the cooling cabinet 2 and extends into the cooling water tank 702, the water is sent into the heat absorption pipeline 706 through the water feeding pipeline 704 to absorb heat inside the heat absorption pipeline 706, the right end of the heat absorption pipeline 706 is communicated with the water return pipeline 707, cooling water which absorbs the heat enters the cooling water tank 702 through the water return pipeline 707, ice blocks inside the cooling water tank 702 rapidly cool the returned cooling water, so that the recycling effect is achieved, under the hot weather condition, the cooling water pump 701 is powered through electronic components inside the power distribution cabinet 1, after the cooling water pump 701 is started, the cooling water inside the cooling water tank 702 is pumped out through the water pumping pipeline and is sent into the heat absorption pipeline 706 through the water feeding pipeline 704, because the heat absorption plate 705 is made of brass, and the brass has good heat conductivility, can absorb the inside heat of switch board 1, thereby make the inside temperature of switch board 1 descend, after cooling water gets into heat-absorbing pipe 706 inside, can absorb the inside heat of absorber plate 705, make the temperature of absorber plate 705 descend, thereby continuously absorb the inside heat of switch board 1, make the inside temperature of switch board 1 keep at a lower numerical value, and absorb the inside thermal cooling water of absorber plate 705, get back to in cooling water tank 702 through return water pipe 707, and cooling water tank 702 is inside to be filled with the ice-cube, can make the temperature of cooling water descend rapidly, the ice-cube melts can supply the inside water that evaporates because of high temperature of cooling water tank 702 simultaneously, keep the inside water level of cooling water tank 702.

The air circulation mechanism 8 comprises an air inlet hole 801, an air circulation groove 802 and a separation net 803, the air inlet hole 801 is arranged on the outer wall of the power distribution cabinet 1, the air inlet hole 801 is evenly distributed on the left side and the right side of the power distribution cabinet 1 at equal intervals, more low-temperature air can enter the power distribution cabinet 1 through the air inlet hole 801, the air circulation groove 802 is arranged in the center of the inner part of the sealing cover 6, the air circulation groove 802 is communicated with the notch, residual high-temperature air in the power distribution cabinet 1 is emitted to the outer part of the power distribution cabinet 1 through the air circulation groove 802 and the notch, the separation net 803 is fixedly connected to the top of the inner part of the air circulation groove 802, when the cooling mechanism 7 works, the air pressure in the power distribution cabinet 1 is reduced due to the residual high temperature in the power distribution cabinet 1, so that the high-temperature air in the power distribution cabinet 1 is discharged out of the power distribution cabinet 1 through the air circulation groove 802, and the low-temperature air enters the power distribution cabinet 1 through the air inlet hole 801, the purpose of rapid air circulation is achieved, and the air temperature in the power distribution cabinet 1 is further reduced.

When the cooling water distribution cabinet is used, under the condition of hot weather, the cooling water pump 701 is powered by electronic components in the power distribution cabinet 1, after the cooling water pump 701 is started, the cooling water in the cooling water tank 702 is pumped out by the cooling water pump 701 through the water pumping pipeline 703 and is sent into the heat absorption pipeline 706 through the water sending pipeline 704, as the heat absorption plate 705 is made of brass and has good heat conduction performance, the heat in the power distribution cabinet 1 can be absorbed, so that the temperature in the power distribution cabinet 1 is reduced, after the cooling water enters the heat absorption pipeline 706, the heat in the heat absorption plate 705 can be absorbed, so that the temperature of the heat absorption plate 705 is reduced, so that the heat in the power distribution cabinet 1 is continuously absorbed, the temperature in the power distribution cabinet 1 is kept at a lower value, and the cooling water absorbing the heat in the heat absorption plate 705 returns to the cooling water tank 702 through the water returning pipeline 707, the cooling water tank 702 is filled with ice blocks, so that the temperature of the cooling water can be rapidly reduced, and the ice blocks are melted to supplement water evaporated due to high temperature in the cooling water tank 702 and maintain the water level in the cooling water tank 702.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides an intelligence control by temperature change formula switch board, includes switch board (1), cooling cabinet (2), insulated column (3) and keeper (4), its characterized in that: the cooling cabinet (2) is fixedly connected to the bottom of the power distribution cabinet (1), the isolation column (3) is fixedly connected to the bottom of the cooling cabinet (2), the door bolt (4) is fixedly connected to the front of the power distribution cabinet (1), the top of the power distribution cabinet (1) is fixedly connected with a sealing cover (6), and a cooling mechanism (7) is arranged inside the cooling cabinet (2);

cooling mechanism (7) include cooling water pump (701), cooling water tank (702), water pumping pipeline (703), send water pipeline (704), absorber plate (705), heat absorption pipeline (706) and return water pipeline (707), cooling water pump (701) fixed connection is in cooling cabinet (2) inner wall bottom left side, cooling water tank (702) fixed connection is in cooling cabinet (2) inner wall bottom, water pumping pipeline (703) fixed connection is in cooling water pump (701) right side, send water pipeline (704) fixed connection in cooling water pump (701) left side, absorber plate (705) fixed connection is in the inside back of switch board (1), heat absorption pipeline (706) are seted up inside absorber plate (705), return water pipeline (707) are seted up on the inside right side of switch board (1).

2. The intelligent temperature-controlled power distribution cabinet according to claim 1, characterized in that: the isolation columns (3) are distributed at four corners of the bottom of the cooling cabinet (2), the front face of the power distribution cabinet (1) is provided with a door plate (5), the door plate (5) is fixedly connected with a door bolt (4), the door plate (5) is hinged to the power distribution cabinet (1) through the door bolt (4), and the top of the power distribution cabinet (1) is provided with a notch.

3. The intelligent temperature-controlled power distribution cabinet according to claim 1, characterized in that: the ice cube is filled in the cooling water tank (702), a filling opening (7021) is formed in the top of the left side of the front of the cooling water tank (702), a filling block (7022) is arranged in the filling opening (7021), and the bottom of the inner wall of the cooling water tank (702) is an inclined surface.

4. The intelligent temperature-controlled power distribution cabinet according to claim 1, characterized in that: the water pumping pipeline (703) penetrates through the cooling water tank (702) and extends to the bottom of the inside of the cooling water tank (702), and the heat absorbing plate (705) is made of brass.

5. The intelligent temperature-controlled power distribution cabinet according to claim 1, characterized in that: the left end and the water feeding pipeline (704) intercommunication of heat absorption pipeline (706), the right-hand member and return water pipeline (707) intercommunication of heat absorption pipeline (706), return water pipeline (707) run through inside and cooling cabinet (2) outer wall of switch board (1) to inside extending to coolant tank (702), inside circulation of air mechanism (8) that is provided with of switch board (1).

6. The intelligent temperature-controlled power distribution cabinet according to claim 5, characterized in that: the air circulation mechanism (8) comprises an air inlet hole (801), an air circulation groove (802) and a separation net (803), the air inlet hole (801) is formed in the outer wall of the power distribution cabinet (1), the air circulation groove (802) is formed in the center of the inside of the sealing cover (6), and the separation net (803) is fixedly connected to the top of the inside of the air circulation groove (802).

7. The intelligent temperature-controlled power distribution cabinet according to claim 6, characterized in that: the air inlet holes (801) are uniformly distributed on the left side and the right side of the power distribution cabinet (1) at equal intervals, and the air circulation grooves (802) are communicated with the notches.

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