CN215003112U - Electric power energy device of high-efficient storage - Google Patents

Abstract

The utility model discloses an electric power energy device of high-efficient storage, including the equipment box, the equipment box internal fixation has the mount, installs on the mount and stores the magnetic disc, and in the cavity of seal box was located to the disk motor of storing the magnetic disc, install on the seal box and connect the mouth of pipe, connect the mouth of pipe including install in the seal box all around four sides lean on advancing of top position take over and install in the play takeover of seal box bottom intermediate position. The utility model provides an electric power energy device of high-efficient storage, the structure sets up ingenious and arranges rationally, utilize the seal box to surround the disk motor entirely, fill the heat-conducting medium again in the seal box, when motor work sent the heat, the heat is direct to conduct with the medium, compare with traditional air-cooled disk structure-fin-air heat dissipation flow, simplify more, and the heat transfer efficiency of air is minimum for holistic radiating effect obtains the restriction, compare with water-cooled disk structure-water-cooled tube heat dissipation flow, the flow also has the advantage of simplifying.

Description

Electric power energy device of high-efficient storage

Technical Field

The utility model relates to a storage facilities technical field specifically is an electric power energy device of high-efficient storage.

Background

Electric power is an energy source using electric energy as power. The discovery and use of electricity has raised a second industrial surge in the 70's of the 19 th century. The technology becomes one of three technological revolution which occur in the world since 18 th century of human history, and the technology changes the lives of people. The large-scale power system appearing in the 20 th century is one of the most important achievements in the history of human engineering science, and is a power generation and consumption system consisting of links of power generation, power transmission, power transformation, power distribution, power utilization and the like. It converts the primary energy of nature into electric power through mechanical energy devices, and then supplies the electric power to each user through power transmission, transformation and distribution.

At present, when electric power is transmitted and managed by enterprises, a large amount of data can be generated, the data are stored in a storage disk in a transferring mode, the storage speed of the storage disk is one of key factors except a manufacturing process, the running speed of the disk is limited by heat dissipation, the rotating speed is controlled to be 7000 revolutions at most, and therefore the storage efficiency of the disk is limited. Therefore, the inventor provides an electric power energy device with high-efficiency storage by combining various factors.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide an electric power energy device of high-efficient storage to solve the problem that proposes among the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme:

an electric power energy device with high-efficiency storage comprises an equipment box, wherein a fixing frame is fixed in the equipment box, a storage magnetic disk is arranged on the fixing frame, a magnetic disk motor for storing the magnetic disk is arranged in a cavity of a seal box, a pipe connecting port is arranged on the seal box, and the pipe connecting port comprises a pipe inlet connecting pipe arranged at the top position of the front side, the rear side, the left side and the right side of the seal box and a pipe outlet connecting pipe arranged at the middle position of the bottom of the seal box;

the heat dissipation stack comprises a fan radiator and a first-stage liquid storage tank which are connected, and a heat conducting medium is arranged in the first-stage liquid storage tank.

The magnetic disk motor is completely surrounded by the seal box, the heat conducting medium is filled in the seal box, when the motor works to emit heat, the heat is directly conducted with the medium, compared with the traditional air-cooled magnetic disk structure-radiating fin-air radiating flow, the heat radiating flow is more simplified, the heat transfer efficiency of air is lowest, the integral radiating effect is limited, compared with the water-cooled magnetic disk structure-water-cooling pipe radiating flow, the flow also has the advantage of simplification, meanwhile, the heat is not easy to form accumulation in the magnetic disk, the low-heat environment operation of the magnetic disk can be effectively ensured, the rotating speed of the magnetic disk motor can be improved, and the storage and reading-writing speed of the storage magnetic disk is improved.

As a further aspect of the present invention: the heat-conducting medium is liquid, so that the heat-conducting medium has circulating fluidity, and long-time heat conduction and heat dissipation requirements are met.

As a further aspect of the present invention: the liquid is liquid metal, the heat conductivity of the metal is better than that of water and various cooling liquids, and heat emitted by the disk motor can be quickly absorbed, so that efficient heat conduction and heat dissipation are carried out.

As a further aspect of the present invention: the utility model discloses a magnetic disk motor, including a disk motor, a supporting column, a connecting rod, the seal box outside, improve the disk heat-sinking capability, the magnetic disk motor's rotational speed can obtain promoting, inevitably bring bigger vibration after the rotational speed promotes, owing to adopt the seal box to surround the setting completely to the magnetic disk motor, consequently compare with traditional fixed mode and must have the defect that stability is not enough, and it is fixed with the seal box with the magnetic disk motor through the support column, the seal box is fixed when the installation, wear the connecting rod in the support column again simultaneously, make the magnetic disk motor obtain simultaneously with two fixed points of seal box and magnetic disk structure, fixed stability has obtained effective promotion, the higher demand of stability after having satisfied the magnetic disk motor rotational speed and improving.

As a further aspect of the present invention: a heat dissipation window is formed in the bottom of the rear side of the equipment box, the fan radiator is opposite to the heat dissipation window, and the medium which flows back after the heat of the disk motor is absorbed is effectively dissipated to enable the medium to recover a lower temperature state so as to circularly absorb heat again;

as a further aspect of the present invention: the heat radiation stack further comprises a communicating pipe, a communicating pump and a second-stage liquid storage tank, the fan radiator is connected with the outlet connecting pipe through a return pipe, the communicating pipe is communicated with the first-stage liquid storage tank and the second-stage liquid storage tank, the communicating pump is installed on the communicating pipe, and a feeding pump installed in the second-stage liquid storage tank is connected with the inlet connecting pipe through a feeding pipe.

Compared with the prior art, the utility model discloses the beneficial effect of following several aspects has:

1. the utility model provides an electric power energy device of high-efficient storage, the structure sets up ingeniously and arranges rationally, the utility model discloses in utilize the seal box to carry out the complete encirclement to the disk motor, fill the heat-conducting medium in the seal box again, when motor work sends out the heat, the heat directly conducts with the medium, compare with traditional air-cooled disk structure-fin-air heat dissipation flow, it is more simplified, and the heat transfer efficiency of air is minimum, make the whole radiating effect obtain the restriction, compare with water-cooled disk structure-water-cooled tube heat dissipation flow, the flow also has the simplification advantage, the heat is difficult for forming the accumulation in the disk simultaneously, can effectively guarantee the low-heat environment operation of disk, thereby can improve the rotational speed of disk motor, in order to promote the storage and the reading and writing speed of storing the disk;

2. the utility model discloses further utilize liquid metal as heat-conducting medium, when satisfying that the circulation flow provides long-time heat conduction heat dissipation demand, the heat conductivility of metal is better than the heat conductivility of water and various coolant liquids, can absorb the heat that the disk motor distributed out fast to carry out efficient heat conduction and heat dissipation.

Drawings

Fig. 1 is a schematic structural diagram of an electric power energy device with high storage efficiency.

Fig. 2 is a schematic diagram of a disk motor in a high-efficiency storage power source device.

Fig. 3 is a schematic structural diagram of a sealed box in an electric power energy device with high storage efficiency.

In the figure: 1. an equipment box; 11. a fixed mount; 12. a heat dissipation window; 2. storing the magnetic disk; 21. a disk motor; 22. a sealing box; 23. a pipe connecting port; 231. a pipe is connected; 232. discharging the connecting pipe; 24. a cavity; 25. a support pillar; 26. a connecting rod; 3. a heat dissipation reactor; 31. a fan radiator; 32. a primary liquid storage tank; 33. a communicating pipe; 34. a pump in communication; 35. a secondary liquid storage tank; 36. a feeding pipe; 37. a return pipe.

Detailed Description

The technical solution of the present patent will be described in further detail with reference to the following embodiments.

Referring to fig. 1-3, an electric power energy device with high-efficiency storage includes an equipment box 1, a storage disk 2 and a heat dissipation stack 3;

a fixed frame 11 is fixed in the equipment box 1 through bolts, and a heat dissipation window 12 is arranged at the bottom of the rear side of the equipment box 1;

the storage disk 2 is mounted on the fixed frame 11, the disk motor 21 of the storage disk 2 is arranged in the cavity 24 of the seal box 22, the seal box 22 is provided with the connecting pipe opening 23, the connecting pipe opening 23 comprises a connecting pipe inlet 231 mounted at the top positions of the front side, the rear side, the left side and the right side of the seal box 22 and a connecting pipe outlet 232 mounted at the middle position of the bottom of the seal box 22, the disk motor 21 is fixed in the seal box 22 through a support pillar 25, the support pillar 25 is arranged in a hollow structure, a connecting rod 26 penetrates through the hollow support pillar 25, and the connecting rod 26 penetrates to the outer side of the seal box 22;

the heat radiation stack 3 comprises a fan radiator 31, a first-level liquid storage tank 32, a communicating pipe 33, a communicating pump 34 and a second-level liquid storage tank 35, the fan radiator 31 is connected with an outlet connecting pipe 232 through a return pipe 37, the fan radiator 31 is simultaneously connected with the first-level liquid storage tank 32, the communicating pipe 33 is communicated with the first-level liquid storage tank 32 and the second-level liquid storage tank 35, the communicating pump 34 is installed on the communicating pipe 33, a feeding pump installed in the second-level liquid storage tank 35 is connected with an inlet connecting pipe 231 through a feeding pipe 36, and a liquid metal heat-conducting medium is installed in the first-level liquid storage tank 35.

The utility model discloses a theory of operation is: the heat emitted by the disk motor 21 during operation is directly absorbed by the liquid metal in contact with the disk motor 21, the liquid metal after heat absorption enters the fan radiator 31 through the return pipe 37, the absorbed heat is emitted by the fan radiator 31 under the blowing action of the fan, the liquid metal after preliminary heat dissipation enters the primary liquid storage tank 32 for storage, then is extracted into the secondary liquid storage tank 35 through the communicating pipe 33 by the communicating pump 34, and is fed into the cavity 24 of the sealed box 21 along the feeding pipe 36 in the secondary liquid storage tank 35 by the feeding pump, thereby completing the heat dissipation cycle. Meanwhile, heat is not easy to accumulate in the disk, and the low-heat environment operation of the disk can be effectively ensured.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art through specific situations.

Although the preferred embodiments of the present patent have been described in detail, the present patent is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present patent within the knowledge of those skilled in the art.

Claims (6)

1. An electric energy device with high-efficiency storage comprises an equipment box (1) and is characterized in that a fixing frame (11) is fixed in the equipment box (1), a storage magnetic disc (2) is installed on the fixing frame (11), a magnetic disc motor (21) of the storage magnetic disc (2) is arranged in a cavity (24) of a sealing box (22), a connecting pipe orifice (23) is installed on the sealing box (22), and the connecting pipe orifice (23) comprises a connecting pipe inlet (231) and a connecting pipe outlet (232) which are installed at the top positions of the front side, the rear side, the left side, the right side and the left side of the sealing box (22) and are arranged at the middle position of the bottom of the sealing box (22);

the reactor also comprises a heat radiation stack (3) connected with the seal box (22), the heat radiation stack (3) comprises a fan radiator (31) and a first-stage liquid storage box (32) which are connected, and a heat-conducting medium is filled in the first-stage liquid storage box (32).

2. A device as claimed in claim 1, wherein said heat transfer medium is a liquid.

3. A high efficiency stored electric power energy apparatus as claimed in claim 2, wherein said liquid is a liquid metal.

4. A device for storing electric energy efficiently as claimed in any one of claims 1 to 3, wherein said disk motor (21) is fixed in said sealed box (22) by a support column (25), said support column (25) is a hollow structure, a connecting rod (26) is threaded in said hollow support column (25), and said connecting rod (26) is threaded to the outside of said sealed box (22).

5. The efficient storage electric power energy device according to claim 4, wherein the bottom of the rear side of the equipment box (1) is provided with a heat dissipation window (12), and the fan radiator (31) is opposite to the heat dissipation window (12).

6. The efficient storage electric power energy device according to claim 4, wherein the heat dissipation stack (3) further comprises a communication pipe (33), a communication pump (34) and a secondary liquid storage tank (35), the fan radiator (31) is connected with the outlet connection pipe (232) through a return pipe (37), the communication pipe (33) is connected with the primary liquid storage tank (32) and the secondary liquid storage tank (35), the communication pump (34) is installed on the communication pipe (33), and the inlet pump installed in the secondary liquid storage tank (35) is connected with the inlet connection pipe (231) through an inlet pipe (36).

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