CN221467206U - Heat abstractor for energy storage power station computer lab integrated management - Google Patents

Abstract

The utility model discloses a heat dissipating device for integrated management of an energy storage power station machine room, which comprises a machine room, wherein an air duct extending into the machine room is fixedly arranged on the outer wall of the machine room, an auxiliary component is arranged on the outer wall of the machine room and connected with the side wall of one end of the air duct, which is positioned in the machine room, a disassembly component is arranged on the inner wall of one end of the auxiliary component, and the driving motor, a first gear, a second gear, a bearing, a shell, a moisture absorption plate and a filter screen are arranged on the inner wall of one end of the auxiliary component, so that the transmitted cold air is absorbed by the moisture absorption plate and dispersed by the aid of the auxiliary component.

Description

Heat abstractor for energy storage power station computer lab integrated management

Technical Field

The utility model relates to the technical field of electric power, in particular to a heat dissipation device for integrated management of an energy storage power station machine room.

Background

In the power industry, a power station room is built for allocating power, a large number of electronic devices are needed to be used in the power station room, the electronic devices can generate heat during working, and the more the electronic devices generate higher the heat.

The application number 201911015293.X discloses a heat dissipating device for integrated management of an energy storage power station machine room, and the problem in the background technology is that; most of the existing power station rooms rely on cooling fans to cool, because the temperature in the power station rooms is higher, wind power coming out of the cooling fans also becomes hot air, so that the cooling effect of the power station rooms is not ideal, especially in hot seasons, the sun is in southwest direction for a long time under the influence of natural phenomena, the condition of sunning can occur, and at the moment, when the temperature in the day is highest, the temperature in the power station rooms is quickly increased for a long time, the electronic parts in the power station rooms are damaged due to the too high temperature, the electronic parts are damaged, inconvenience is brought to use, the use requirements of users can not be met, but the following problems exist,

The cooling device has the advantages that through the cooperation of the fan, the clamping block, the clamping column and the ice box, a user can cool the inside of the machine room through ice cubes, the heat dissipation efficiency in the machine room is accelerated, the practicability of the device is improved, the use requirement of the user is met, the cooling gas generated by using the cooling device or the existing refrigerating device contains moisture, water and the like, the cooling device is used for a long time, the moisture and the water assist the surface of the power equipment in the machine room, short circuit and other faults are easy to cause, and certain defects exist in the use effect, so that the cooling device for the integrated management of the machine room of the energy storage power station is provided for solving the problems.

Disclosure of utility model

The utility model provides a heat abstractor for integrated management of an energy storage power station machine room, which comprises a machine room, wherein an air duct extending into the machine room is fixedly arranged on the outer wall of the machine room, an auxiliary assembly is arranged on the outer wall of the machine room, the auxiliary assembly is connected with the side wall of one end of the air duct, which is positioned in the machine room, and a disassembly assembly is arranged on the inner wall of one end of the auxiliary assembly, which is positioned in the machine room;

the device comprises a driving motor, a first gear, a second gear, a bearing, a shell, a moisture absorption plate and a filter screen, wherein an output shaft of the driving motor is connected with the second gear in a transmission manner, an inner ring inner wall of the bearing is fixedly sleeved on a side wall of one end of an air duct, which is positioned in a machine room, an outer ring outer wall of the bearing is fixedly connected with an inner wall of the second gear, a front surface of the shell is fixedly sleeved on an outer ring outer wall of the bearing, the shell is positioned on the back surface of the second gear, and the moisture absorption plate and the filter screen are both in sliding connection with an inner side wall of the shell.

Preferably, the output shaft of the driving motor is fixedly provided with a rotating shaft extending into the machine room, one end side wall of the rotating shaft in the machine room is fixedly connected with the inner wall of the first gear, the outer wall teeth of the first gear are meshed with the outer wall teeth of the second gear, and the side wall of the rotating shaft is rotationally connected with the outer wall of the machine room.

Preferably, the outer wall of the machine room is fixedly provided with a mounting seat for mounting a driving motor, and the driving motor is connected with the controller through a wire.

Preferably, the moisture absorption plates are arranged in an annular array, one sides of the moisture absorption plates close to each other are fixedly connected, and the filter screen is positioned on one side of the moisture absorption plates far away from the air duct.

Preferably, the back of the shell is in an opening design, and the front of the shell is provided with a through hole for fixing the sleeved bearing.

Preferably, the disassembly component comprises a sliding groove, sliding blocks and screw holes, wherein the sliding groove is formed in the inner side wall of the shell in an annular array mode, the sliding blocks are placed in the sliding groove in an annular array mode, one sides, away from the sliding grooves, of the sliding blocks are fixedly connected with the moisture absorption plates respectively, the screw holes are formed in two, the two screw holes are formed in the back faces of the two sliding blocks respectively, and bolts are connected with the inner walls of the two screw holes in a threaded mode.

Compared with the prior art, the technical scheme provided by the utility model has the following beneficial technical effects:

1. The device makes the moisture absorption board carry out the moisture absorption to the air conditioning of transmission through auxiliary assembly and spreads the air conditioning and scatter, avoids moisture and moisture in the air conditioning to get into in the computer lab, and makes the air conditioning spread and scatter and be favorable to improving the radiating effect to filter impurity such as dust in the air conditioning through the filter screen, avoid dust and impurity etc. to get into in the computer lab along with the air conditioning, the practicality is stronger.

2. The device is convenient for dismantle hygroscopic board and filter screen through dismantling the subassembly, is convenient for change and clearance etc. and convenient long-term use, and does not influence the casing and drive hygroscopic board rotation, the in-service use of being convenient for.

Drawings

Fig. 1 is a schematic diagram of an overall front view structure of a heat dissipating device for integrated management of an energy storage power station room.

Fig. 2 is a schematic diagram of a cross-sectional structure of a heat dissipating device for integrated management of a machine room of an energy storage power station according to the present utility model.

Fig. 3 is a schematic front view of an auxiliary assembly of a heat dissipating device for integrated management of an energy storage power station room according to the present utility model.

Fig. 4 is a schematic diagram of an explosion structure of an auxiliary assembly back view and a disassembly assembly of the heat dissipating device for integrated management of an energy storage power station room.

Reference numerals; 1. a machine room; 2. an air duct; 3. an auxiliary component; 301. a driving motor; 302. a housing; 303. a second gear; 304. a bearing; 305. a first gear; 306. a moisture absorption plate; 307. a filter screen; 4. disassembling the assembly; 401. a screw hole; 402. a slide block; 403. and a sliding groove.

Detailed Description

The objects, technical solutions and advantages of the present utility model will become more apparent by the following detailed description of the present utility model with reference to the accompanying drawings. It should be understood that the description is only illustrative and is not intended to limit the scope of the utility model. In addition, in the following description, descriptions of well-known structures and techniques are omitted so as not to unnecessarily obscure the present utility model.

As shown in fig. 1 and 2, the heat dissipating device for integrated management of a machine room 1 of an energy storage power station provided by the utility model comprises a machine room 1, wherein an air duct 2 extending into the machine room 1 is fixedly arranged on the outer wall of the machine room 1, an auxiliary assembly 3 is arranged on the outer wall of the machine room 1, the auxiliary assembly 3 is connected with the side wall of one end of the air duct 2, which is positioned in the machine room 1, and a disassembly assembly 4 is arranged on the inner wall of one end of the auxiliary assembly 3, which is positioned in the machine room 1.

In the concrete implementation, the air duct 2 is located at one end outside the machine room 1 and is connected with external refrigeration equipment, so that cold air generated by the refrigeration equipment is blown into the machine room 1 along the air duct 2, thereby radiating in the machine room 1, the driving motor 301 is started through the controller in the process of transmitting the cold air into the machine room 1 through the air duct 2, the output shaft of the driving motor 301 drives the second gear 303 to rotate, thereby driving the shell 302 to rotate, and the shell 302 drives the moisture absorption plate 306 to rotate while rotating, so that the moisture absorption plate 306 absorbs moisture of the transmitted cold air and simultaneously spreads the cold air, moisture and humidity in the cold air are prevented from entering the machine room 1, the heat radiating effect is improved, and after a period of use, the moisture absorption plate 306 and the filter screen 307 are conveniently detached through the disassembly component 4, replacement and cleaning are convenient, and the like.

As shown in fig. 2, 3 and 4, the driving motor 301, the first gear 305, the second gear 303, the bearing 304, the housing 302, the moisture absorption plate 306 and the filter screen 307 are in transmission connection, the output shaft of the driving motor 301 is fixedly provided with a rotating shaft extending into the machine room 1, one end side wall of the rotating shaft in the machine room 1 is fixedly connected with the inner wall of the first gear 305, the outer wall teeth of the first gear 305 are meshed with the outer wall teeth of the second gear 303, the side wall of the rotating shaft is rotationally connected with the outer wall of the machine room 1, the inner wall of the inner ring of the bearing 304 is fixedly sleeved on one end side wall of the air duct 2 in the machine room 1, the outer ring outer wall of the bearing 304 is fixedly connected with the inner wall of the second gear 303, the front surface of the housing 302 is fixedly sleeved on the outer ring outer wall of the bearing 304, the housing 302 is positioned on the back of the second gear 303, and the moisture absorption plate 306 and the filter screen 307 are both in sliding connection with the inner wall of the housing 302.

In a specific implementation, the driving motor 301 is started by the controller, the output shaft of the driving motor 301 drives the rotating shaft to rotate, the rotating shaft drives the first gear 305 to rotate, the first gear 305 drives the second gear 303 to rotate, the second gear 303 drives the outer ring outer wall of the bearing 304 to rotate, the outer ring outer wall of the bearing 304 drives the shell 302 to rotate, and the shell 302 drives the moisture absorption plate 306 to rotate while rotating.

Further, the outer wall of the machine room 1 is fixedly provided with a mounting seat for mounting the driving motor 301, and the driving motor 301 is connected with the controller through a wire, so that the driving motor 301 is convenient to mount.

Further, the moisture absorbing plates 306 are arranged in an annular array, so that the air conditioner is convenient to use, one sides of the moisture absorbing plates 306 close to each other are fixedly connected, and the filter screen 307 is positioned on one side of the moisture absorbing plates 306 away from the air duct 2, so that dust and impurities in cool air can be filtered conveniently.

Furthermore, the back of the casing 302 is designed to be an opening shape, so that the cold air can enter the machine room 1 conveniently, and the front of the casing 302 is provided with a through hole for fixing the sleeved bearing 304.

As shown in fig. 4, the disassembling component 4 includes a sliding groove 403, a sliding block 402 and screw holes 401, the sliding groove 403 is formed in an annular array on the inner side wall of the housing 302, the sliding block 402 is placed in the sliding groove 403 in an annular array, one side, away from the sliding groove 403, of the sliding block 402 is fixedly connected with the moisture absorption plate 306 respectively, two screw holes 401 are formed in two screw holes 401, the two screw holes 401 are formed in the back surfaces of the two sliding blocks 402 respectively, and bolts are connected with the inner walls of the two screw holes 401 in a threaded manner.

In a specific implementation, the filter screen 307 and the moisture absorbing plate 306 are removed from the housing 302 by unscrewing the bolts by a tool such as a wrench and removing the bolts, and then disengaging the slider 402 from the slide groove 403.

It is to be understood that the above-described embodiments of the present utility model are merely illustrative of or explanation of the principles of the present utility model and are in no way limiting of the utility model. Accordingly, any modification, equivalent replacement, improvement, etc. made without departing from the spirit and scope of the present utility model should be included in the scope of the present utility model. Furthermore, the appended claims are intended to cover all such changes and modifications that fall within the scope and boundary of the appended claims, or equivalents of such scope and boundary.

Claims (6)

1. The utility model provides a heat abstractor for energy storage power station computer lab integrated management, includes computer lab (1), its characterized in that, the outer wall of computer lab (1) is fixed to be equipped with air duct (2) that extend to in computer lab (1), and the outer wall of computer lab (1) is provided with auxiliary assembly (3), and auxiliary assembly (3) are connected with one end lateral wall that air duct (2) are located in computer lab (1), and one end inner wall that auxiliary assembly (3) are located in computer lab (1) is provided with dismantles subassembly (4);

The auxiliary assembly (3) comprises a driving motor (301), a first gear (305), a second gear (303), a bearing (304), a shell (302), a moisture absorption plate (306) and a filter screen (307), wherein an output shaft of the driving motor (301) is in transmission connection with the second gear (303), an inner ring inner wall of the bearing (304) is fixedly sleeved on one end side wall of an air duct (2) located in a machine room (1), an outer ring outer wall of the bearing (304) is fixedly connected with an inner wall of the second gear (303), the front surface of the shell (302) is fixedly sleeved on an outer ring outer wall of the bearing (304), the shell (302) is located on the back surface of the second gear (303), and the moisture absorption plate (306) and the filter screen (307) are both in sliding connection with the inner side wall of the shell (302).

2. The heat dissipating device for integrated management of an energy storage power station room according to claim 1, wherein the output shaft of the driving motor (301) is fixedly provided with a rotating shaft extending into the room (1), one end side wall of the rotating shaft in the room (1) is fixedly connected with the inner wall of the first gear (305), the outer wall teeth of the first gear (305) are meshed with the outer wall teeth of the second gear (303), and the side wall of the rotating shaft is rotatably connected with the outer wall of the room (1).

3. The heat dissipating device for integrated management of an energy storage power station room according to claim 1, wherein an installation seat for installing a driving motor (301) is fixedly arranged on the outer wall of the room (1), and the driving motor (301) is connected with a controller through a wire.

4. The heat dissipating device for integrated management of an energy storage power station room according to claim 1, wherein the moisture absorbing plates (306) are arranged in an annular array, one sides of the moisture absorbing plates (306) close to each other are fixedly connected, and the filter screen (307) is located at one side of the moisture absorbing plates (306) far away from the air duct (2).

5. The heat dissipating device for integrated management of an energy storage power station room according to claim 1, wherein the back surface of the housing (302) is designed in an opening shape, and the front surface of the housing (302) is provided with a through hole for fixedly sleeving the bearing (304).

6. The heat dissipation device for integrated management of an energy storage power station machine room according to claim 1, wherein the disassembly component (4) comprises a sliding groove (403), sliding blocks (402) and screw holes (401), the sliding groove (403) is formed in an annular array and is formed in the inner side wall of the shell (302), the sliding blocks (402) are placed in the sliding groove (403) in an annular array, one sides, far away from the sliding groove (403), of the sliding blocks (402) are fixedly connected with the moisture absorption plate (306) respectively, the screw holes (401) are formed in two, the two screw holes (401) are formed in the back surfaces of the two sliding blocks (402) respectively, and bolts are connected to the inner walls of the two screw holes (401) in a threaded mode.