CN218733431U - Energy storage device for wind power plant - Google Patents

Abstract

The utility model discloses an energy memory is used in wind power plant, including computer lab and energy storage module, the inside at the computer lab is installed to the energy storage module, the air intake has been seted up to the upper end of computer lab right side wall. The above structure is adopted in the utility model, can carry out wind-powered electricity generation's energy storage work through the energy storage module, and in the use of electricity storage module, can pass through the air outlet with the inside hot-air of computer lab through the exhaust fan and discharge, and external fresh air then gets into through the air intake, thereby reduce the temperature in the computer lab, and cool down to electricity storage module through heat exchange assemblies and radiator unit simultaneously, thereby avoid electricity storage module high temperature and influence life, and the position through adjustment mechanism adjustment support, and through the position of the firm support of slip subassembly, can load the electricity storage module of equidimension not in the support, and through articulating the subassembly with electricity storage module firm in the support, make electricity storage module in the maintenance, it is all more convenient when changing, and the heat dissipation energy consumption is low.

Description

Energy storage device for wind power plant

Technical Field

The utility model belongs to the energy memory field, in particular to energy memory is used to wind power plant.

Background

The wind generating set comprises a wind wheel and a generator; the wind wheel comprises blades, a hub, a reinforcing member and the like; the wind power generation power supply comprises a wind generating set, a tower frame for supporting the generating set, a storage battery charging controller, an inverter, an unloader, a grid-connected controller, a storage battery pack and the like.

In the prior art, the storage means of electric energy is single, can only adopt battery or condenser energy storage basically, and current wind-powered electricity generation energy memory also intelligence adopts battery or condenser energy storage, and when constantly charging and discharging energy memory, energy memory produces a large amount of heats, and because energy memory generally sets up in the computer lab, the air permeability is poor, need powerful fan or fan to fan out heat, especially large capacity wind-powered electricity generation energy memory, it is big to lead to the heat dissipation degree of difficulty, thereby influence wind-powered electricity generation energy memory's life.

SUMMERY OF THE UTILITY MODEL

To the problem mentioned in the background art, the utility model aims at providing an energy storage device is used in wind power plant to solve the wind power plant energy storage device among the prior art and can produce a large amount of heats in the use, and the radiating effect of the energy storage device computer lab among the prior art is poor, the heat dissipation degree of difficulty is big, the heat dissipation is with high costs, thereby influences wind power energy storage device life's problem.

The above technical purpose of the present invention can be achieved by the following technical solutions:

an energy storage device for a wind power plant comprises a machine room and an energy storage module, wherein the energy storage module is installed inside the machine room, the upper end of the right side wall of the machine room is provided with an air inlet, a filter screen is installed inside the air inlet, the upper end of the left side wall of the machine room is provided with an air outlet, and an exhaust fan is installed inside the air outlet;

the energy storage module includes the support body, the outer wall of support body is provided with heat exchange assemblies, the back of support body is provided with radiator unit, the inside lower extreme of support body is provided with adjustment mechanism, the inside lower extreme of support body has the support through adjustment mechanism sliding connection, the lower extreme outside of support is provided with the slip subassembly, the inside of support body is pegged graft and is had the electricity storage module, the front of support body is provided with articulates the subassembly, articulate the positive laminating of subassembly and electricity storage module.

Further, as preferred technical scheme, heat exchange assemblies includes inlet tube, heat exchange tube and outlet pipe, the inlet tube laminating is in one side of support body, the lateral wall at the outlet pipe is connected to the heat exchange tube, the inside of support body is stretched into to the one end of heat exchange tube, the lower extreme and the laminating of electricity storage module of heat exchange tube, the outlet pipe laminating is at the opposite side of support body, the one end and the play water piping connection of heat exchange tube, the computer lab is all run through to the one end of inlet tube and outlet pipe.

Further, as a preferred technical solution, the heat dissipation assembly includes an opening and a heat dissipation fan, the opening is provided on the back of the frame body, and the heat dissipation fan is installed inside the opening.

Further, as a preferred technical scheme, the adjusting mechanism includes a moving groove, a moving block and a screw rod, the moving groove is formed in the lower end of the inside of the frame body, the moving block is mounted at the lower end of the support, the moving block is slidably connected to the inside of the moving groove, the screw rod is rotatably connected to the side wall of the frame body, one end of the screw rod extends into the moving groove, one end of the screw rod penetrates through the moving block, the outer wall of the screw rod is in threaded connection with the moving block, threads on two sides of the outer wall of the screw rod are opposite, and positioning assemblies are arranged at two ends of the outer wall of the screw rod.

Further, as preferred technical scheme, locating component includes locating piece and constant head tank, the locating piece is installed at the both ends of screw rod outer wall, the constant head tank is seted up at the both ends of shifting chute, the locating piece rotates the inside of connecting at the constant head tank.

Further, as preferred technical scheme, the slip subassembly includes slider and spout, the slider is installed in the lower extreme outside of support, the spout is seted up in the inside lower extreme outside of support body, slider sliding connection is in the inside of spout, the outer wall of slider is provided with spacing subassembly.

Further, as preferred technical scheme, spacing subassembly includes stopper and spacing groove, the outer wall at the slider is installed to the stopper, the inner wall at the spout is seted up to the spacing groove, stopper sliding connection is in the inside of spacing groove.

Further, as preferred technical scheme, articulate the subassembly and include couple and peg, the couple is installed in the front of support, the peg articulates in the inside of couple, the back and the laminating of electricity storage module of peg.

To sum up, the utility model discloses mainly have following beneficial effect:

firstly, energy storage work of wind power can be carried out through an energy storage module, in the using process of the electricity storage module, hot air in a machine room can be discharged through an air outlet through an exhaust fan, external fresh air enters through an air inlet, the temperature in the machine room is reduced, meanwhile, the electricity storage module is cooled through a heat exchange assembly and a heat dissipation assembly, the problem that the service life of the electricity storage module is influenced due to overhigh temperature is avoided, the position of a support is adjusted through an adjusting mechanism, the position of the support is stabilized through a sliding assembly, the electricity storage modules with different sizes can be loaded in the support, the electricity storage module is stabilized in the support through a hanging assembly, the maintenance and replacement of the electricity storage module are more convenient, and the heat dissipation energy consumption is low;

second, send into the heat exchange tube through the inlet tube the refrigerant in, and lower extreme and the laminating of accumulate module through the heat exchange tube, make the heat exchange tube pass through the refrigerant and absorb the heat of accumulate module, discharge hot water through the outlet pipe afterwards, can play the heat that absorbs accumulate module through heat exchange assembly, thereby reach the effect for accumulate module cooling, through seting up the opening at the back of support body, and install radiator fan in the open-ended inside, can discharge the inside heat of support body through radiator fan, thereby reduce the inside heat of support body, and then reach for the radiating effect of accumulate module.

Drawings

Fig. 1 is a schematic structural diagram of the present invention;

fig. 2 is a cross-sectional view of the present invention;

FIG. 3 is a schematic view of the frame structure of the present invention;

fig. 4 is an enlarged view of a portion a of fig. 3 according to the present invention.

Reference numerals: 1. the computer lab, 11, the air intake, 111, the filter screen, 12, the air outlet, 121, the exhaust fan, 2, the energy storage module, 3, the support body, 31, heat exchange component, 311, the inlet tube, 312, the heat exchange tube, 313, the outlet pipe, 32, radiator unit, 321, the opening, 322, radiator fan, 4, adjustment mechanism, 41, shifting chute, 42, the movable block, 43, the screw rod, 44, locating component, 441, the locating piece, 442, the constant head tank, 5, the support, 51, sliding component, 511, the slider, 512, the spout, 52, spacing component, 521, the stopper, 522, the spacing groove, 53, articulate the subassembly, 531, the couple, 532, the peg, 6, the electricity storage module.

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.

Example 1

Referring to fig. 1 to 4, the energy storage device for a wind power plant according to this embodiment includes a machine room 1 and an energy storage module 2, the energy storage module 2 is installed inside the machine room 1, an air inlet 11 is formed in an upper end of a right side wall of the machine room 1, a filter screen 111 is installed inside the air inlet 11, an air outlet 12 is formed in an upper end of a left side wall of the machine room 1, and an exhaust fan 121 is installed inside the air outlet 12;

the energy storage module 2 comprises a frame body 3, a heat exchange assembly 31 is arranged on the outer wall of the frame body 3, a heat dissipation assembly 32 is arranged on the back of the frame body 3, an adjusting mechanism 4 is arranged at the lower end inside the frame body 3, the lower end inside the frame body 3 is connected with a support 5 in a sliding mode through the adjusting mechanism 4, a sliding assembly 51 is arranged on the outer side of the lower end of the support 5, an electricity storage module 6 is inserted into the frame body 3 in a plugging mode, a hanging assembly 53 is arranged on the front face of the frame body 3, and the hanging assembly 53 is attached to the front face of the electricity storage module 6;

can carry out wind-powered electricity generation's energy storage work through energy storage module 2, and in electricity storage module 6's the use, can pass through air outlet 12 with the inside hot-air of computer lab 1 through exhaust fan 121 and discharge, and external fresh air then gets into through air intake 11, thereby reduce the temperature in computer lab 1, and cool down electricity storage module 6 through heat exchange assemblies 31 and radiator unit 32 simultaneously, thereby avoid electricity storage module 6 high temperature and influence life, and the position through adjustment mechanism 4 adjustment support 5, and stabilize the position of support 5 through sliding component 51, can load the electricity storage module 6 of equidimension not in support 5, and stabilize electricity storage module 6 in support 5 through articulating subassembly 53, make electricity storage module 6 maintain, it is all more convenient when changing.

Example 2

Referring to fig. 2, on the basis of embodiment 1, in order to achieve the purpose of absorbing heat of the electricity storage module 6, the heat exchange assembly 31 is innovatively designed in this embodiment, specifically, the heat exchange assembly 31 includes a water inlet pipe 311, a heat exchange pipe 312 and a water outlet pipe 313, the water inlet pipe 311 is attached to one side of the frame body 3, the heat exchange pipe 312 is connected to a side wall of the water outlet pipe 313, one end of the heat exchange pipe 312 extends into the frame body 3, the lower end of the heat exchange pipe 312 is attached to the electricity storage module 6, the water outlet pipe 313 is attached to the other side of the frame body 3, one end of the heat exchange pipe 312 is connected to the water outlet pipe 313, and one ends of the water inlet pipe 311 and the water outlet pipe 313 penetrate through the machine room 1; send into the refrigerant through inlet tube 311 in the heat exchange tube 312 to lower extreme and the laminating of electricity storage module 6 through heat exchange tube 312 make heat exchange tube 312 absorb the heat of electricity storage module 6 through the refrigerant, discharge hot water through outlet pipe 313 afterwards, can play the heat of absorbing electricity storage module 6 through heat exchange assembly 31, thereby reach the effect for the cooling of electricity storage module 6.

Referring to fig. 2, in order to achieve the purpose of dissipating heat from the electricity storage module 6, the heat dissipation assembly 32 of the present embodiment includes an opening 321 and a heat dissipation fan 322, the opening 321 is disposed on the back of the frame body 3, and the heat dissipation fan 322 is installed inside the opening 321; opening 321 is seted up through the back at support body 3 to install radiator fan 322 in opening 321's inside, can discharge the inside heat of support body 3 through radiator fan 322, thereby reduce the inside heat of support body 3, and then reach for the radiating effect of electricity storage module 6.

Example 3

Referring to fig. 3, on the basis of embodiment 2, in order to achieve the purpose of adjusting the position of the bracket 5, in this embodiment, an innovative design is performed on the adjusting mechanism 4, specifically, the adjusting mechanism 4 includes a moving groove 41, a moving block 42 and a screw 43, the moving groove 41 is opened at the lower end inside the frame body 3, the moving block 42 is installed at the lower end of the bracket 5, the moving block 42 is slidably connected inside the moving groove 41, the screw 43 is rotatably connected to the side wall of the frame body 3, one end of the screw 43 extends into the moving groove 41, one end of the screw 43 penetrates through the moving block 42, the outer wall of the screw 43 is in threaded connection with the moving block 42, the threads on both sides of the outer wall of the screw 43 are opposite, and both ends of the outer wall of the screw 43 are provided with positioning assemblies 44; when the position of support 5 needs to be adjusted, screw 43 is rotated, and the position of screw 43 is stabilized through locating component 44, namely, screw 43 drives moving block 42 to slide in moving groove 41, so that moving block 42 drives support 5 to move simultaneously, and the threads on two sides of the outer wall of screw 43 are opposite, so that two supports 5 move in opposite directions, and the effect of adjusting the position of support 5 is achieved, so that support 5 is suitable for electricity storage modules 6 with different sizes.

Referring to fig. 4, in order to stabilize the position of the screw 43, the positioning assembly 44 of the present embodiment includes a positioning block 441 and a positioning slot 442, the positioning block 441 is installed at two ends of the outer wall of the screw 43, the positioning slot 442 is opened at two ends of the moving slot 41, and the positioning block 441 is rotatably connected inside the positioning slot 442; the positioning block 441 is rotatably connected to the inside of the positioning groove 442, so that the positioning assembly 44 can stabilize the position of the screw rod 43, and the position of the moving block 42 is prevented from being influenced by the transverse movement of the screw rod 43.

Referring to fig. 3, for the purpose of stabilizing the position of the bracket 5, the sliding assembly 51 of the present embodiment includes a sliding block 511 and a sliding groove 512, the sliding block 511 is installed at the outer side of the lower end of the bracket 5, the sliding groove 512 is opened at the outer side of the lower end inside the frame body 3, the sliding block 511 is slidably connected inside the sliding groove 512, and a limiting assembly 52 is disposed on the outer wall of the sliding block 511; the sliding block 511 is connected inside the sliding groove 512 in a sliding mode, the position of the sliding block 511 is stabilized through the limiting component 52, namely the position of the support 5 can be stabilized through the sliding component 51, and the situation that the position of the support 5 deviates and the like to influence the stability of the power storage module 6 is avoided.

Referring to fig. 3, in order to fix the position of the sliding block 511, the limiting component 52 of the embodiment includes a limiting block 521 and a limiting groove 522, the limiting block 521 is installed on the outer wall of the sliding block 511, the limiting groove 522 is opened on the inner wall of the sliding groove 512, and the limiting block 521 is slidably connected inside the limiting groove 522; the limiting block 521 is slidably connected inside the limiting groove 522, so that the limiting component 52 can stabilize the position of the sliding block 511 inside the sliding groove 512, and the sliding block 511 is prevented from being separated from the sliding groove 512 to influence the position of the bracket 5.

Referring to fig. 3, in order to avoid the electricity storage module 6 from falling off, the hanging assembly 53 of the present embodiment includes a hook 531 and a hanging rod 532, the hook 531 is installed on the front surface of the bracket 5, the hanging rod 532 is hung inside the hook 531, and the back surface of the hanging rod 532 is attached to the electricity storage module 6; after the electricity storage module 6 is inserted into the inside of the bracket 5, the hanging rod 532 is hung in the hook 531, so that the back of the hanging rod 532 is attached to the electricity storage module 6, the hanging rod 532 can stabilize the position of the electricity storage module 6 in the inside of the bracket 5, and the electricity storage module 6 can be prevented from falling off through the hanging component 53.

The use principle and the advantages are as follows: when the electricity storage module 6 needs to be installed, the position of the bracket 5 is adjusted according to the size of the electricity storage module 6, the screw 43 is rotated and is rotatably connected inside the positioning groove 442 through the positioning block 441, so that the positioning assembly 44 can stabilize the position of the screw 43, and the screw 43 is prevented from moving transversely, that is, the screw 43 can drive the moving block 42 to slide inside the moving groove 41, so that the moving block 42 can drive the bracket 5 to move transversely, and the two brackets 5 can move oppositely through the opposite threads on the two sides of the outer wall of the screw 43, and are slidably connected inside the limiting groove 522 through the limiting block 521, so that the limiting assembly 52 can stabilize the position of the sliding block 511 inside the sliding groove 512, that is, the position of the bracket 5 can be stabilized through the sliding assembly 51, the position of the bracket 5 is prevented from being deviated, so that the adjusting mechanism 4 achieves the effect of adjusting the position of the bracket 5, and then the electricity storage module 6 is inserted into the bracket 5, then the hanging rod 532 is hung inside the hook 531, that is, the electricity storage module 6 can be firmly fixed inside the bracket 5 through the hanging component 53, thereby completing the installation work of the electricity storage module 6, and further enabling the energy storage module 2 to perform the energy storage work of wind power, and during the use process of the energy storage module 2, hot air inside the machine room 1 can be discharged through the air outlet 12 by the exhaust fan 121, and external fresh air enters through the air inlet 11, and external impurities such as dust and the like can be prevented from entering through the filter screen 111, thereby reducing the temperature in the machine room 1, and meanwhile, the refrigerant is sent into the heat exchange tube 312 through the water inlet tube 311, and is attached to the electricity storage module 6 through the lower end of the heat exchange tube 312, so that the heat exchange tube 312 absorbs the heat of the electricity storage module 6 through the refrigerant, and then, the hot water is discharged through the water outlet tube 313, that the heat of the electricity storage module 6 can be absorbed through the heat exchange component 31, thereby reach the effect for the cooling of electricity storage module 6, through seting up opening 321 at the back of support body 3, and install radiator fan 322 in opening 321's inside, can discharge the heat of 3 inside of support body through radiator fan 322, thereby reduce the heat of 3 inside of support body, and then reach through radiator unit 32 and be the radiating effect of electricity storage module 6, not only make the radiating effect better through multiple heat dissipation, and the energy consumption of miniwatt fan is less than high-power fan far away, thereby the heat dissipation energy consumption that reduces, and maintaining electricity storage module 6, it is also more convenient when changing.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that various 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 (8)

1. An energy storage device for a wind power plant, characterized in that: the energy storage module (2) is installed inside the machine room (1), an air inlet (11) is formed in the upper end of the right side wall of the machine room (1), a filter screen (111) is installed inside the air inlet (11), an air outlet (12) is formed in the upper end of the left side wall of the machine room (1), and an exhaust fan (121) is installed inside the air outlet (12);

energy storage module (2) are including support body (3), the outer wall of support body (3) is provided with heat exchange assemblies (31), the back of support body (3) is provided with radiator unit (32), the inside lower extreme of support body (3) is provided with adjustment mechanism (4), the inside lower extreme of support body (3) has support (5) through adjustment mechanism (4) sliding connection, the lower extreme outside of support (5) is provided with sliding assembly (51), the inside of support body (3) is pegged graft and is had storage battery module (6), the front of support body (3) is provided with articulates subassembly (53), articulate subassembly (53) and the positive laminating of storage battery module (6).

2. The energy storage device for a wind power plant according to claim 1, wherein: heat exchange assemblies (31) include inlet tube (311), heat exchange tube (312) and outlet pipe (313), the laminating of inlet tube (311) is in one side of support body (3), the lateral wall at outlet pipe (313) is connected in heat exchange tube (312), the inside of support body (3) is stretched into to the one end of heat exchange tube (312), the lower extreme and the laminating of electricity storage module (6) of heat exchange tube (312), the opposite side at support body (3) is laminated in outlet pipe (313), the one end and the outlet pipe (313) of heat exchange tube (312) are connected, computer lab (1) is all run through to the one end of inlet tube (311) and outlet pipe (313).

3. The energy storage device for a wind power plant according to claim 1, wherein: the heat dissipation assembly (32) comprises an opening (321) and a heat dissipation fan (322), the opening (321) is arranged on the back of the frame body (3), and the heat dissipation fan (322) is arranged inside the opening (321).

4. The energy storage device for a wind power plant according to claim 1, wherein: the adjusting mechanism (4) comprises a moving groove (41), a moving block (42) and a screw (43), the moving groove (41) is formed in the lower end of the inside of the frame body (3), the moving block (42) is installed at the lower end of the support (5), the moving block (42) is connected to the inside of the moving groove (41) in a sliding mode, the screw (43) is rotatably connected to the side wall of the frame body (3), one end of the screw (43) extends into the inside of the moving groove (41), one end of the screw (43) penetrates through the moving block (42), the outer wall of the screw (43) is in threaded connection with the moving block (42), threads on two sides of the outer wall of the screw (43) are opposite, and positioning assemblies (44) are arranged at two ends of the outer wall of the screw (43).

5. The energy storage device for a wind power plant according to claim 4, wherein: the positioning assembly (44) comprises a positioning block (441) and a positioning groove (442), the positioning block (441) is installed at two ends of the outer wall of the screw rod (43), the positioning groove (442) is arranged at two ends of the movable groove (41), and the positioning block (441) is rotatably connected inside the positioning groove (442).

6. The energy storage device for a wind power plant according to claim 1, wherein: sliding assembly (51) include slider (511) and spout (512), the lower extreme outside at support (5) is installed in slider (511), the lower extreme outside in support body (3) inside is seted up in spout (512), slider (511) sliding connection is in the inside of spout (512), the outer wall of slider (511) is provided with spacing subassembly (52).

7. The energy storage device for a wind power plant according to claim 6, wherein: the limiting assembly (52) comprises a limiting block (521) and a limiting groove (522), the limiting block (521) is installed on the outer wall of the sliding block (511), the limiting groove (522) is formed in the inner wall of the sliding groove (512), and the limiting block (521) is connected to the inside of the limiting groove (522) in a sliding mode.

8. The energy storage device for a wind power plant according to claim 1, wherein: articulate subassembly (53) including couple (531) and peg (532), the front at support (5) is installed in couple (531), peg (532) articulate in the inside of couple (531), the back and the laminating of accumulate module (6) of peg (532).

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