CN219696580U - Energy storage cabinet capable of achieving independent heat dissipation - Google Patents

Abstract

The utility model relates to the technical field of electric power energy storage cabinets, in particular to an independent heat dissipation type energy storage cabinet which comprises a cabinet body. Through all having set up the air inlet chamber at the equipment box both ends of energy storage room top, when the interior fan that admits air of this chamber bottom panel that admits air operates, can inhale the back with outside air from the shutter and import in the energy storage room, simultaneously, the inside fan that gives vent to anger of base is synchronous opens, take out the inside hot air of energy storage room, form the air replacement, realize the heat transfer to the inside air of energy storage room, during the course, when the air passes through the air inlet window, by dehumidification sponge moisture absorption, make the inside air drying of entering energy storage room, avoid corroding the circuit that the energy storage battery exposes, cause the trouble, through set up the routing rack on the inside bottom plate of energy storage room for the laying of rack has increased the area that the energy storage battery contacted air, when the fan that admits air with give vent to anger synchronous operation, make the inside formation of energy storage room follow down air convection, cool down the energy storage battery, cooling efficiency is improved.

Description

Energy storage cabinet capable of achieving independent heat dissipation

Technical Field

The utility model relates to the technical field of electric power energy storage cabinets, in particular to an independent heat dissipation type energy storage cabinet.

Background

The energy storage power station is a power station which is set up for adjusting the peak-valley electricity consumption problem, the energy storage power station stores the electric quantity which is wasted in the period of low peak electricity consumption, and releases the electric quantity into the power grid again when the peak electricity consumption is high so as to achieve the purpose of solving the energy problem, and the energy storage power station generally comprises a water pumping energy storage power station and an oversized battery pack, wherein the oversized battery pack is generally arranged in an energy storage cabinet;

in the use of the battery energy storage cabinet, the battery can generate heat, the heat of heat dissipation of a plurality of oversized battery packs is higher, the use of the battery can be influenced, the existing battery energy storage cabinet mainly adopts an air cooling mode to dissipate heat of the battery packs, however, due to the fact that the volume of the energy storage cabinet is large, the arrangement of the battery packs is compact, air cooling of a conventional structure cannot penetrate through each heat dissipation surface of the battery packs, the heat dissipation efficiency of the battery packs is low, electric energy cannot be independently supplied, and therefore the independent heat dissipation type energy storage cabinet is provided for the problems.

Disclosure of Invention

The utility model aims to provide an independent heat-dissipation type energy storage cabinet so as to solve the problems in the background art.

In order to achieve the above purpose, the present utility model provides the following technical solutions:

an independently heat-dissipating energy storage cabinet, comprising:

the device comprises a cabinet body, wherein an equipment box and an energy storage chamber are sequentially arranged in the cabinet body from top to bottom, and a base is fixedly arranged at the bottom of the cabinet body;

the heat dissipation mechanism comprises an air inlet structure arranged at the top of the cabinet body and an air outlet structure arranged in the base, wherein the air inlet structure comprises an air inlet cavity arranged at the left end and the right end of the equipment box, an air inlet window is arranged on a cabinet body side plate at the outer side of the air inlet cavity, a shutter is arranged on the air inlet window, a dehumidifying sponge attached to the shutter is arranged at the outer side of the air inlet cavity, an air guide pipe is arranged on a bottom plate at the inner end of the air inlet cavity, an air inlet fan is arranged inside the air guide pipe, the air outlet structure comprises an air outlet panel arranged at the left side and the right side of the base, a fan mounting frame is arranged in the base at the inner side of the air outlet panel, an air outlet fan is arranged on the fan mounting frame, and an air vent is arranged between the middle part of a top plate of the base and the energy storage chamber.

As a preferable scheme, hollow partition plates are arranged above the bottom plate of the energy storage chamber at intervals, the hollow partition plates are fixed with the bottom plate of the energy storage chamber through sleepers, and the hollow partition plates are specifically of a perforated plate-type steel structure formed by splicing steel bars.

As a preferred scheme, cabinet body top is provided with the roof, is provided with the front end on the roof and rotates the rotation mounting bracket of being connected through hinge and roof, rotates mounting bracket top panel laminating and is provided with solar cell panel, and roof rear end middle part is provided with the mounting groove of undercut, is provided with the electric putter of telescopic link connection rotation mounting bracket on the bottom plate of mounting groove, and the positive and negative pole electric energy of electric putter motor inserts the end and passes through the positive and negative pole electric energy output of the electric putter controller that sets up in the wire connection mounting groove.

As a preferred scheme, the middle part of the equipment box is provided with a control room, a storage battery and a relay are sequentially arranged on a bottom plate inside the control room from left to right, the electric energy output end of the relay is respectively connected with the electric energy access ends of the air outlet fan and the air inlet fan through wires, the top panel of the control room is sequentially provided with a PLC (programmable logic controller) and a solar controller from left to right, the electric energy access end of the solar controller is connected with the electric energy output end of a solar cell panel through wires, a charging circuit of the solar controller is connected with the electric energy access end of the storage battery, the electric energy output end of the storage battery is respectively connected with the relay and the electric push rod controller through circuits, and an inverter is arranged on a circuit of the storage battery connected with the relay.

As a preferred scheme, the storage chamber is internally provided with a rack placed on the hollow partition board, a plurality of hollow racks which are transversely arranged are downwards arranged on the rack from top to bottom, and the storage battery is placed on the hollow racks.

As a preferable scheme, a solar tracking sensor is fixedly arranged on the rotary mounting frame, and a detection signal output end of the solar tracking sensor is connected with a detection signal access end of the PLC through an electric signal.

As a preferable scheme, an infrared temperature sensor is arranged on the inner wall of the energy storage chamber, a detection probe of the infrared temperature sensor is opposite to the energy storage battery, and a detection signal output end of the infrared temperature sensor is connected with a detection signal access end of the PLC through an electric signal.

As a preferable scheme, the front side panel of the cabinet body is provided with a cabinet door, and the edge of the cabinet door is provided with a sealing strip attached to the front side panel of the cabinet body.

According to the technical scheme provided by the utility model, the independent heat dissipation type energy storage cabinet provided by the utility model has the beneficial effects that:

1. through arranging the air inlet cavities at the two ends of the equipment box above the energy storage chamber, when the inner air inlet fan of the panel at the bottom of the air inlet cavity operates, external air can be sucked from the shutter and then is led into the energy storage chamber, meanwhile, the air outlet fan in the base is synchronously started to pump out hot air in the energy storage chamber, so that air replacement is formed, the heat exchange of the air in the energy storage chamber is realized, and during the period, when the air passes through the air inlet window, the air is absorbed by the dehumidification sponge, so that the air entering the energy storage chamber is dried, and the corrosion of a circuit exposed by an energy storage battery and faults are avoided;

2. through set up the fretwork rack on the inside bottom plate of energy storage room for the lay of rack, wherein, from last down the interval on the rack has set up the fretwork rack that is used for placing energy storage battery, has increased the area of energy storage battery contact air, when air inlet fan and the fan of giving vent to anger synchronous operation, makes the inside formation of energy storage room follow last decurrent air convection current, cools down energy storage battery, improves cooling efficiency.

Drawings

FIG. 1 is a schematic diagram of an energy storage cabinet capable of independently radiating;

fig. 2 is a schematic cross-sectional structure of an energy storage cabinet capable of independent heat dissipation according to the present utility model.

In the figure: 1. a cabinet body; 11. an equipment box; 12. an energy storage chamber; 13. hollow partition boards; 14. a sleeper; 15. a cabinet door; 16. a vent; 2. a base; 21. an air outlet panel; 22. a fan mounting rack; 23. an air outlet fan; 3. an air inlet window; 31. a shutter; 32. an air inlet cavity; 33. a dehumidifying sponge; 34. an air guide pipe; 35. an air intake fan; 36. a control room; 4. a top plate; 41. rotating the mounting frame; 42. a solar cell panel; 43. a sun-tracking sensor; 44. a mounting groove; 45. an electric push rod; 46. an electric push rod controller; 5. a storage battery; 51. a solar controller; 52. a relay; 53. a PLC controller; 54. an infrared temperature sensor; 6. a placing rack; 61. the placing frame is hollowed out; 62. an energy storage battery.

Description of the embodiments

The present utility model will be described in further detail with reference to the drawings and examples, in order to make the objects, technical solutions and advantages of the present utility model more apparent. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

It will be understood that when an element is referred to as being "mounted" or "disposed" on another element, it can be directly on the other element or be indirectly on the other element. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

In the description of the present utility model, it should be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate orientations or positional relationships based on the orientation or positional relationships shown in the drawings, merely to facilitate describing the present utility model and simplify the description, and do not indicate or imply that the devices or elements referred to must have a specific orientation, be configured and operated in a specific orientation, and therefore should not be construed as limiting the present utility model.

Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include one or more such feature. In the description of the present utility model, the meaning of "a plurality" is two or more, unless explicitly defined otherwise.

In order to better understand the above technical solutions, the following detailed description will be given with reference to the accompanying drawings and the specific embodiments.

As shown in fig. 1-2, an embodiment of the present utility model provides an energy storage cabinet capable of independent heat dissipation, including:

the energy storage cabinet comprises a cabinet body 1, wherein an equipment box 11 and an energy storage chamber 12 are sequentially arranged in the cabinet body 1 from top to bottom, a base 2 is fixedly arranged at the bottom of the cabinet body 1, a cabinet door 15 is arranged on a front side panel of the cabinet body 1, and a sealing strip attached to the front side panel of the cabinet body 1 is arranged at the edge of the cabinet door 15;

the heat dissipation mechanism comprises an air inlet structure arranged at the top of the cabinet body 1 and an air outlet structure arranged in the base 2, wherein the air inlet structure comprises an air inlet cavity 32 arranged at the left end and the right end of the equipment box 11, an air inlet window 3 is arranged on a side plate of the cabinet body 1 outside the air inlet cavity 32, a louver 31 is arranged on the air inlet window 3, a dehumidifying sponge 33 attached to the louver 31 is arranged outside the air inlet cavity 32, an air guide pipe 34 is arranged on a bottom plate at the inner end of the air inlet cavity 32, an air inlet fan 35 is arranged inside the air guide pipe 34, the air outlet structure comprises an air outlet panel 21 arranged at the left side and the right side of the base 2, a fan mounting frame 22 is arranged in the base 2 at the inner side of the air outlet panel 21, an air outlet fan 23 is arranged on the fan mounting frame 22, and an air vent 16 is arranged between the middle part of a top plate of the base 2 and the energy storage chamber 12.

Among the above-mentioned devices, the bottom plate top interval of energy storage room 12 is provided with fretwork baffle 13, and is fixed through sleeper 14 between fretwork baffle 13 and the bottom plate of energy storage room 12, and fretwork baffle 13 is specifically by the foraminiferous board type steel construction of billet splice-forming, and the inside rack 6 of placing on fretwork baffle 13 that is provided with of energy storage room 12 is provided with the fretwork rack 61 of several horizontal setting from last down on the rack 6, places energy storage battery 62 on the fretwork rack 61.

Among the above-mentioned devices, cabinet body 1 top is provided with roof 4, is provided with the rotation mounting bracket 41 that the front end passes through hinge and roof 4 rotation to be connected on the roof 4, rotates mounting bracket 41 top panel laminating and is provided with solar cell panel 42, and roof 4 rear end middle part is provided with the mounting groove 44 of indent, is provided with telescopic link connection on the bottom plate of mounting groove 44 and rotates the electric putter 45 of mounting bracket 41, and the positive and negative pole electric energy of electric putter 45 motor inserts the end and passes through the positive and negative pole electric energy output of electric putter controller 46 that sets up in the wire connection mounting groove 44.

In the above device, the middle part of the equipment box 11 is provided with the control room 36, the bottom plate inside the control room 36 is provided with the storage battery 5 and the relay 52 from left to right in turn, the electric energy output end of the relay 52 is respectively connected with the electric energy access ends of the air outlet fan 23 and the air inlet fan 35 through wires, the top panel of the control room 36 is provided with the PLC controller 53 and the solar controller 51 from left to right in turn, the electric energy access end of the solar controller 51 is connected with the electric energy output end of the solar panel 42 through wires, the charging circuit of the solar controller 51 is connected with the electric energy access end of the storage battery 5, the electric energy output end of the storage battery 5 is respectively connected with the relay 52 and the electric putter controller 46 through circuits, and the circuit of the storage battery 5 connected with the relay 52 is provided with the inverter.

In the above device, the rotation mounting frame 41 is fixedly provided with the sun tracking sensor 43, and the detection signal output end of the sun tracking sensor 43 is connected with the detection signal access end of the PLC controller 53 through an electrical signal.

In the above device, an infrared temperature sensor 54 is disposed on the inner wall of the energy storage chamber 12, a detection probe of the infrared temperature sensor 54 faces the energy storage battery 62, and a detection signal output end of the infrared temperature sensor 54 is connected with a detection signal access end of the PLC controller 53 through an electrical signal.

Embodiments of the present utility model will be described in further detail below with reference to the attached drawings:

referring to fig. 1-2, the energy storage cabinet comprises a cabinet body 1, wherein an equipment box 11 and an energy storage chamber 12 are sequentially arranged in the cabinet body 1 from top to bottom, a base 2 is fixedly arranged at the bottom of the cabinet body 1, a cabinet door 15 is arranged on a front side panel of the cabinet body 1, and a sealing strip attached to the front side panel of the cabinet body 1 is arranged at the edge of the cabinet door 15;

further, please refer to fig. 1 and 2, still include the air inlet structure that cabinet body 1 top set up and the structure of giving vent to anger that sets up in base 2, the air inlet structure includes the air inlet chamber 32 that both ends set up about equipment box 11, be provided with air inlet window 3 on the cabinet body 1 curb plate in the air inlet chamber 32 outside, be provided with shutter 31 on air inlet window 3, be provided with the dehumidification sponge 33 with shutter 31 laminating in the air inlet chamber 32 outside, be provided with guide duct 34 on the bottom plate in air inlet chamber 32 inner, guide duct 34 inside is provided with air inlet fan 35, the structure of giving vent to anger includes the air outlet panel 21 that the base 2 left and right sides set up, be provided with fan mounting bracket 22 in the base 2 of air outlet panel 21 inboard, and be provided with air outlet fan 23 on the fan mounting bracket 22, be provided with the air inlet chamber 16 between the roof middle part of base 2 and the energy storage chamber 12, through the interior air inlet fan 35 during operation of the equipment box 11 both ends of this air inlet window 32 bottom panel, can inhale the back from shutter 31 and import energy storage chamber 12 with outside air, simultaneously, the fan 23 in the inside the base 2 is synchronous opens, with the inside of energy storage chamber 12, the inside is drawn out, the inside is realized, the inside the air storage panel is drawn out to the inside the energy storage chamber is cooled down, the inside is avoided the air storage chamber is cooled down by the air, the air storage is replaced by the air storage chamber 12, when the inside air is cooled down, the inside the air storage chamber is cooled down, and is cooled down, the inside the air storage is cooled down, and is cooled down.

Referring to fig. 1 and 2, a hollow partition 13 is arranged above a bottom plate of an energy storage chamber 12 at intervals, the hollow partition 13 is fixed with the bottom plate of the energy storage chamber 12 through a sleeper 14, the hollow partition 13 is specifically a perforated plate-type steel structure formed by splicing steel bars, a placing frame 6 placed on the hollow partition 13 is arranged inside the energy storage chamber 12, a plurality of hollow placing frames 61 which are transversely arranged are arranged on the placing frame 6 from top to bottom, an energy storage battery 62 is placed on the hollow placing frames 61, the hollow partition 13 is used for placing the placing frames 6 too high to facilitate air flowing, the sleeper 14 is used for supporting the hollow partition 13, the placing frames 6 are used for placing the energy storage battery 62, and the energy storage batteries 62 are separated through the hollow placing frames 61, so that the heat dissipation area of the energy storage battery 62 is increased, and the heat dissipation efficiency is improved.

In this embodiment, referring to fig. 1 and 2, a top plate 4 is provided at the top of the cabinet body 1, a rotation mounting frame 41 with a front end rotationally connected with the top plate 4 through a hinge is provided on the top plate 4, a solar panel 42 is attached to a top panel of the rotation mounting frame 41, a downward concave mounting groove 44 is provided in the middle of a rear end of the top plate 4, a bottom plate of the mounting groove 44 is provided with an electric push rod 45 with a telescopic rod connected with the rotation mounting frame 41, and an anode and cathode electric energy access end of a motor of the electric push rod 45 is connected with an anode and cathode electric energy output end of an electric push rod controller 46 provided in the mounting groove 44 through a wire;

further, the solar tracking sensor 43 is fixedly arranged on the rotating mounting frame 41, a detection signal output end of the solar tracking sensor 43 is connected with a detection signal access end of the PLC controller 53 through an electric signal, the solar tracking sensor 43 is used for detecting the angle of the sun and the rotating mounting frame 41 and transmitting information to the PLC controller 53, the PLC controller 53 controls the electric push rod 45 to stretch out and draw back, and the inclination angle of the rotating mounting frame 41 is adjusted, so that the electric energy conversion efficiency of the solar cell panel 42 is improved.

Referring to fig. 2, a control room 36 is provided in the middle of the equipment box 11, a storage battery 5 and a relay 52 are sequentially provided on a bottom plate inside the control room 36 from left to right, an electric energy output end of the relay 52 is respectively connected with an electric energy access end of an air outlet fan 23 and an electric energy access end of an air inlet fan 35 through wires, a PLC controller 53 and a solar controller 51 are sequentially provided on a top panel of the control room 36 from left to right, the electric energy access end of the solar controller 51 is connected with an electric energy output end of a solar panel 42 through wires, a charging circuit of the solar controller 51 is connected with an electric energy access end of a storage battery 5, the electric energy output end of the storage battery 5 is respectively connected with the relay 52 and an electric push rod controller 46 through circuits, and an inverter is provided on a circuit of the storage battery 5 connected with the relay 52.

In this embodiment, an infrared temperature sensor 54 is disposed on the inner wall of the energy storage chamber 12, a detection probe of the infrared temperature sensor 54 faces the energy storage battery 62, and a detection signal output end of the infrared temperature sensor 54 is connected with a detection signal access end of the PLC controller 53 through an electrical signal;

the infrared temperature sensor 54 is provided to detect the temperature of the surface of the energy storage battery 62 and transmit detection information to the PLC controller 53, and the PLC controller 53 synchronously controls the operation of the air inlet fan 35 and the air outlet fan 23, so that independent heat dissipation of the interior of the energy storage chamber 12 can be realized.

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

Claims (8)

1. An energy storage cabinet capable of independently radiating, which is characterized in that: comprising the following steps:

the energy storage device comprises a cabinet body (1), wherein an equipment box (11) and an energy storage chamber (12) are sequentially arranged in the cabinet body (1) from top to bottom, and a base (2) is fixedly arranged at the bottom of the cabinet body (1);

the heat dissipation mechanism, the heat dissipation mechanism includes the structure of giving vent to anger that sets up in the air inlet structure and the base (2) of cabinet body (1) top set up, the air inlet structure includes air inlet chamber (32) that both ends set up about equipment box (11), be provided with air inlet window (3) on cabinet body (1) curb plate in air inlet chamber (32) outside, be provided with shutter (31) on air inlet window (3), air inlet chamber (32) outside is provided with dehumidification sponge (33) with shutter (31) laminating, be provided with guide duct (34) on the bottom plate of air inlet chamber (32) inner, guide duct (34) inside is provided with air inlet fan (35), the structure of giving vent to anger includes air outlet panel (21) that base (2) left and right sides set up, be provided with fan mounting bracket (22) in base (2) of air outlet panel (21), and be provided with air outlet fan (23) on fan mounting bracket (22), be provided with between roof middle part and the energy storage chamber (12) of base (2).

2. An independently heat-dissipating energy storage cabinet according to claim 1, wherein: the energy storage device is characterized in that hollow partition plates (13) are arranged above the bottom plate of the energy storage chamber (12) at intervals, the hollow partition plates (13) are fixed with the bottom plate of the energy storage chamber (12) through sleepers (14), and the hollow partition plates (13) are of a perforated plate type steel structure formed by splicing steel bars.

3. An independently heat-dissipating energy storage cabinet according to claim 1, wherein: the utility model discloses a solar cell panel, including cabinet body (1), roof (1), mounting bracket (42), electric putter (45), positive and negative pole electric energy access end, electric putter (45) are connected in telescopic link connection rotation mounting bracket (41) are provided with on the roof (4), be provided with front end on roof (4) and rotate rotation mounting bracket (41) of being connected through hinge and roof (4), rotation mounting bracket (41) top panel laminating is provided with solar cell panel (42), roof (4) rear end middle part is provided with undercut mounting groove (44), be provided with electric putter controller (46) that the positive and negative pole electric energy access end of electric putter (45) motor passes through the positive and negative pole electric energy output of wire connection mounting groove (44) interior electric putter controller that sets up.

4. An independently heat-dissipating energy storage cabinet according to claim 1, wherein: the utility model discloses a solar energy power generation device, including equipment box (11), control room (36) are provided with at the middle part, battery (5) and relay (52) have been set gradually from a left side to the right side on the inside bottom plate of control room (36), the electric energy output of relay (52) is connected the electric energy access end of giving vent to anger fan (23) and air inlet fan (35) respectively through the wire, PLC controller (53) and solar controller (51) have been set gradually from a left side to the right side on the top panel of control room (36), the electric energy access end of solar controller (51) is connected the electric energy output of solar cell panel (42) through the wire, the electric energy access end of battery (5) is connected to the charging line of solar controller (51), the electric energy output of battery (5) is provided with the dc-to-ac converter through circuit connection relay (52) and electric putter controller (46) respectively, and the circuit that battery (5) is connected to relay (52).

5. An independently heat-dissipating energy storage cabinet according to claim 1, wherein: the energy storage chamber (12) is internally provided with a placement frame (6) placed on the hollowed-out partition plate (13), a plurality of hollowed-out placement frames (61) which are transversely arranged are arranged on the placement frame (6) from top to bottom, and energy storage batteries (62) are placed on the hollowed-out placement frames (61).

6. A self-contained heat dissipating energy storage cabinet in accordance with claim 3, wherein: the solar energy tracking device is characterized in that a solar energy tracking sensor (43) is fixedly arranged on the rotary mounting frame (41), and a detection signal output end of the solar energy tracking sensor (43) is connected with a detection signal access end of the PLC (53) through an electric signal.

7. An independently heat-dissipating energy storage cabinet according to claim 1, wherein: an infrared temperature sensor (54) is arranged on the inner wall of the energy storage chamber (12), a detection probe of the infrared temperature sensor (54) is opposite to the energy storage battery (62), and a detection signal output end of the infrared temperature sensor (54) is connected with a detection signal access end of the PLC (53) through an electric signal.

8. An independently heat-dissipating energy storage cabinet according to claim 1, wherein: the novel cabinet is characterized in that a cabinet door (15) is arranged on the front side panel of the cabinet body (1), and sealing strips attached to the front side panel of the cabinet body (1) are arranged at the edge of the cabinet door (15).