CN117239299A - Energy storage power station temperature control device - Google Patents

Abstract

The invention discloses a temperature control device of an energy storage power station, which comprises a box body, battery frames, a battery management system, an energy storage converter and a temperature control system, wherein the battery frames, the battery management system, the energy storage converter and the temperature control system are arranged in the box body, the battery frames are arranged side by side along the length direction of the box body, at least three rows of battery frames are arranged, a plurality of rows of battery frames are arranged at intervals, gaps are reserved between the side walls of the box body and the adjacent battery frames, the fixed-point cooling system is arranged in the box body, and the fixed-point cooling system is used for cooling a battery pack with abnormal temperature. The invention solves the problem that the temperature of an individual battery or a battery pack of the energy storage power station in the prior art is abnormal and can not be cooled locally in time.

Description

Energy storage power station temperature control device

Technical Field

The invention belongs to the field of energy storage power station temperature control, and particularly relates to a temperature control device of an energy storage power station.

Background

The energy storage power station is used for storing electric energy, and can adjust peak-valley electricity consumption, realize black start, stable output and other functions. Common ways of heat dissipation of container energy storage systems of energy storage power stations are natural heat dissipation, forced air cooling, liquid cooling and phase change direct cooling.

The natural heat dissipation efficiency is low, the space in the container is narrow, the air circulation is inconvenient, and the temperature control requirement is difficult to achieve; the liquid cooling and phase change direct cooling technology has higher requirements and cost, and is not suitable for being used in a container type battery energy storage system; the forced air cooling heat dissipation mode adopts an industrial air conditioner and a fan for refrigeration, can meet the heat dissipation requirement of an energy storage system, has the cost within an acceptable range, and is the most suitable heat dissipation mode of the prior container type battery energy storage system. The whole temperature in the container can be well adjusted by forced air cooling and heat dissipation, but when the energy storage battery is charged and discharged, the local heating condition can occur, and the forced air cooling can not timely and rapidly cool the local part, so that the condition of untimely cooling exists, and the risk of causing the whole thermal failure of a single battery or a battery pack exists. And because the space of the container is certain, the battery frames fixedly erected in the unit volume are certain, and enough operation gaps are reserved so as to replace and maintain the faulty battery or the battery pack in time, the number of the battery frames in the unit volume is fixed, the space of the container can not be utilized to the maximum extent, and the energy storage capacity is limited.

Disclosure of Invention

The invention aims at: the temperature control device for the energy storage power station is provided for solving the problem that the temperature of an individual battery or a battery pack of the energy storage power station in the prior art is abnormal and cannot be cooled locally in time.

In order to achieve the above purpose, the present invention adopts the following technical scheme: the utility model provides an energy storage power station temperature control device, is in including box, setting battery frame, battery management system, energy storage converter, temperature control system in the box, still includes fixed point cooling system, the battery frame is followed box length direction sets up side by side, the battery frame is provided with three rows at least, and adjacent two rows have the clearance between the battery frame, the lateral wall of box rather than adjacent have the clearance between the battery frame, fixed point cooling system sets up in the box, fixed point cooling system is used for cooling to the unusual battery package of temperature, be provided with the install bin in the box, the vertical setting of install bin, the install bin is located one side of battery frame length direction, set up the location track on the install bin, the location track with the battery frame corresponds, fixed point cooling system includes temperature sensor, controller, guide rail, guide duct, air outlet, temperature sensor sets up on the battery package on the battery frame, temperature sensor with the controller is connected, the guide rail is perpendicular with the install bin, the guide rail is followed to move the guide rail length, the other end and air conditioner air outlet intercommunication.

As a further description of the above technical solution: the mounting box is internally provided with a limit rail, a rail rack, a traveling gear, a limit mounting block and a first servo motor, the limit rail comprises an outer limit plate and an inner limit plate, the positioning rail is positioned between the outer limit plate and the inner limit plate, an arch-shaped track groove is formed between the outer limit plate and the inner limit plate and corresponds to the positioning rail, a support plate and a rail rack are arranged in the arch-shaped track groove, the support plate is arranged along the inner limit plate, the rail rack is arranged along the outer limit plate, the limit mounting block is arranged in the arch-shaped track groove of the limit rail in a sliding manner, the first servo motor is fixed on a limit mounting block, a through hole for the output shaft of the first servo motor to pass through is arranged on the limit mounting block, the traveling gear is coaxially arranged on the output shaft of the first servo motor, the traveling gear is meshed with the track rack, the side that spacing installation piece kept away from first servo motor is provided with the connecting rod, the connecting rod passes the location track, the connecting rod is kept away from the one end of spacing installation piece is provided with the connecting block, the guide rail is fixed to be set up on the connecting block.

As a further description of the above technical solution: the guide rail is in a shape like a Chinese character 'Hui', a positioning rack is arranged in the guide rail along the length direction of the guide rail, a movable seat is arranged on the guide rail, the movable seat is slidably sleeved on the guide rail, a second servo motor is arranged on the movable seat, a guide gear is fixed on an output shaft of the second servo motor, the guide gear is meshed with the positioning rack, and an air outlet is fixedly arranged on the movable seat.

As a further description of the above technical solution: the air guide pipe is a universal telescopic pipe, and the air outlet is of a bidirectional opening air outlet structure.

As a further description of the above technical solution: still be provided with mounting plate in the box, mounting plate tiling is in the bottom surface of box, the support frame of battery rack slides and sets up on the mounting plate, be provided with the removal subassembly in the box, the removal subassembly sets up the battery rack with between the mounting plate, the removal subassembly is used for the drive the removal of battery rack for adjust adjacent interval between the battery rack.

As a further description of the above technical solution: the movable assembly comprises a track rod, bevel gear sets, rotating shafts, ball screws, screw rod sliding blocks and driving rods, wherein the track rod is vertically arranged on the side wall of the mounting box in a rotating mode, the track rod corresponds to the vertical track of the positioning track, the rotating shafts are arranged on the mounting bottom plate in a rotating mode, the bevel gear sets are arranged between the rotating shafts and the track rod, the ball screws are coaxially fixed on the rotating shafts, the screw rod sliding blocks are adapted to the ball screws, the driving rods are arranged in two mode, the two driving rods are symmetrically arranged relative to the screw rod sliding blocks, one end of each driving rod is connected to the screw rod sliding blocks in a rotating mode, the other end of each driving rod is connected to the supporting frame of the battery rack in a rotating mode, and the rotating shafts of the driving rods are vertically arranged and rotate under the driving of the guide rails.

As a further description of the above technical solution: the track rod is provided with a track groove, the track groove sequentially comprises a first vertical track groove, a spiral track groove and a second vertical track groove from top to bottom, the lower end of the first vertical track groove is communicated with the upper end of the spiral track groove, the lower end of the spiral track groove is communicated with the upper end of the second vertical track groove, the guide rail is provided with a driving protrusion, and the driving protrusion corresponds to the track groove of the track rod.

In summary, the technical scheme has the beneficial effects that.

(1) Through the battery package of slip setting on mounting plate, on the one hand can increase the energy storage in the box, can ensure through adjusting the interval between the battery package in addition that the space is abundant when the fixed point cooling and can help the circulation of refrigeration air.

(2) In-process that temperature is suitable and each battery package normal operating in the box can make air outlet horizontal migration through the work of second servo motor, and air outlet air-out direction is vertical direction, can disturb the interior air conditioner air current of box, further promotes the interior even circulation of refrigeration air of box.

(3) Under the effect of moving the subassembly, when fixed point cooling system cools down specific battery package, the interval setting of adjacent battery frame to and the clearance between battery frame and the box lateral wall, make the battery frame remove and have sufficient activity space, the removal of guide rail makes the battery frame clearance of moving the subassembly drive change, realizes the self-adaptation in-process and adjusts, and battery frame clearance just can change when the drive protruding along spiral track groove removes, and the drive protruding is along the clearance of first vertical track or the battery frame of second vertical track when removing remains unchanged.

Drawings

Fig. 1 is a schematic perspective view of the present invention.

Fig. 2 is a schematic view of the internal structure of the case of the present invention.

FIG. 3 is a schematic diagram of the structure of the installation base plate, the installation box and the fixed-point cooling system.

Fig. 4 is a schematic view of the structure of the guide rail between the first row of battery frames and the second row of battery frames.

Fig. 5 is a schematic view of the structure of the guide rail between the second row of battery frames and the third row of battery frames.

FIG. 6 is a sectional view of the mounting box of the present invention with the setpoint cooling system in an initial state.

Fig. 7 is a schematic view of the internal structure of the mounting box of the present invention.

Fig. 8 is a front view showing an initial state of the inside of the mounting box of the present invention.

FIG. 9 is an interior elevation view of the mounting case of the present invention with the spot cooling system positioned where the first vertical rail communicates with the second vertical rail.

Legend description: 1. a case; 2. a battery holder; 3. a battery pack; 4. a mounting box; 5. positioning a track; 6. a first vertical rail; 7. a second vertical rail; 8. an arc-shaped track; 9. a limit rail; 10. an outer limiting plate; 11. an inner limiting plate; 12. arch-shaped track grooves; 13. a support plate; 14. a track rack; 15. a first servo motor; 16. a limit mounting block; 17. a traveling gear; 18. a connecting rod; 19. a connecting block; 20. a guide rail; 21. positioning a rack; 22. a movable seat; 23. a second servo motor; 24. a guide gear; 25. an air guide pipe; 26. an air outlet; 27. a mounting base plate; 28. a support frame; 29. a moving assembly; 30. a track bar; 31. a first vertical track slot; 32. a spiral track groove; 33. a second vertical track slot; 34. a rotating shaft; 35. a bevel gear set; 36. a ball screw; 37. a screw rod sliding block; 38. a driving rod; 39. the driving protrusion.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-9, the present invention provides a technical solution of a temperature control device of an energy storage power station.

The utility model provides an energy storage power station temperature control device, includes box 1 and battery frame 2 and battery management system, energy storage converter, temperature control system, the fixed point cooling system of setting in box 1, and battery frame 2 sets up side by side along box 1 length direction, and battery frame 2 is provided with three row at least, and in this embodiment, battery frame 2 is provided with three rows, has the clearance between the battery frame 2 of adjacent two rows, has the clearance between the lateral wall of box 1 and its adjacent battery frame 2.

The battery management system is used for intelligently managing and maintaining the batteries in the battery packs 3 on the battery frames 2, preventing the batteries from being overcharged and overdischarged, prolonging the service lives of the batteries and monitoring the states of the batteries. The energy storage converter is used for controlling the charging and discharging processes of the storage battery. The temperature control system is used for controlling the temperature of the whole inside the box body 1, so that the temperature inside the box body 1 is kept in the optimal temperature range for the operation of the battery pack 3. The fixed-point cooling system is arranged in the box body 1 and is used for cooling the battery pack 3 with abnormal temperature.

The fixed-point cooling system comprises a temperature sensor, a controller, a first servo motor 15, a second servo motor 23, a positioning track 5, a guide rail 20, an air guide pipe 25 and an air outlet 26, wherein a mounting box 4 is arranged in a box body 1, the mounting box 4 is vertically arranged, the mounting box 4 is positioned on one side of the length direction of a battery frame 2, the mounting box 4 is parallel to the end wall of the box body 1, the positioning track 5 is arranged on the mounting box 4, and the positioning track 5 is opposite to the battery frame 2. In this embodiment, the three rows of battery frames 2 are sequentially a first row of battery frames, a second row of battery frames and a third row of battery frames, the positioning rail 5 is composed of a first vertical rail 6, a second vertical rail 7 and an arc rail 8, the first vertical rail 6, the arc rail 8 and the second vertical rail 7 form a smooth transition arch rail, and a gap formed between the first row of battery frames and the second row of battery frames corresponds to the first vertical rail 6. The gaps formed between the second row of cell holders and the third row of cell holders correspond to the second vertical rails 7.

The mounting box 4 is internally provided with a limiting rail 9, a rail rack 14, a traveling gear 17, a limiting mounting block 16 and a first servo motor 15, wherein the limiting rail 9 is arch-shaped, the limiting rail 9 comprises an outer limiting plate 10 and an inner limiting plate 11, a positioning rail 5 is positioned between the outer limiting plate 10 and the inner limiting plate 11, an arch-shaped track groove 12 is formed between the outer limiting plate 10 and the inner limiting plate 11 and corresponds to the positioning rail 5, a supporting plate 13 and the rail rack 14 are arranged in the arch-shaped track groove 12, the supporting plate 13 is arranged along the inner limiting plate 11, the rail rack 14 is arranged along the outer limiting plate 10, the limiting mounting block 16 is slidably arranged in the arch-shaped track groove 12 of the limiting rail 9, the first servo motor 15 is fixed on the limiting mounting block 16, the first servo motor 15 is connected with a controller, a through hole for the first servo motor output shaft to pass through is formed in the limiting mounting block 16, the traveling gear 17 is coaxially arranged on the output shaft of the first servo motor 15, and the traveling gear 17 is meshed with the rail rack 14.

The side that spacing installation piece 16 kept away from first servo motor 15 is provided with connecting rod 18, and connecting rod 18 passes positioning rail 5, and connecting rod 18 is provided with two, and two connecting rods 18 are symmetrical about the output shaft of first servo motor 15, and the one end that spacing installation piece 16 was kept away from to connecting rod 18 is provided with connecting block 19, and guide rail 20 is fixed to be set up on connecting block 19, and guide rail 20 perpendicular to box 1 side. The first side of the limit mounting block 16 is matched with the inner arc surface of the outer limit plate 10, and the second side of the limit mounting plate is tangent with the outer arc surface of the inner limit plate 11.

In the initial state, the limit mounting block 16 is positioned at the highest position of the limit rail 9. When the first servo motor 15 works, the traveling gear 17 rotates, the traveling gear 17 is meshed with the track rack 14, and as the first side surface of the limit installation block 16 is matched with the inner arc surface of the outer limit plate 10 and the second side surface of the limit installation block is tangential to the outer arc surface of the inner limit plate 11, the limit installation block 16 integrally moves along the arch-shaped track groove 12 to drive the connecting block 19 and the guide rail 20 to integrally move.

The guide rail 20 is the back font, be provided with the location rack 21 along its length direction in the guide rail 20, be provided with on the guide rail 20 and remove seat 22, it establishes on the guide rail 20 to remove seat 22 slip cap, the fixed setting of second servo motor 23 is on removing seat 22, second servo motor 23 is connected with the controller, be fixed with guide gear 24 on the output shaft of second servo motor 23, guide gear 24 meshes with location rack 21, the fixed setting of air outlet 26 is on removing seat 22, guide duct 25 one end and air outlet 26 intercommunication, the other end is connected with temperature control system's air conditioner wind gap, and be provided with the air extraction pump in the junction, drive guide gear 24 through second servo motor 23 and rotate, drive and remove seat 22 and air outlet 26 global motion, guide duct 25 is universal flexible pipe, air outlet 26 is two-way opening air-out structure.

Still be provided with mounting plate 27 in the box 1, mounting plate 27 tiling is in the bottom surface of box 1, and the support frame 28 of battery frame 2 slides and sets up on mounting plate 27, and the bottom of the support frame 28 of battery frame 2 is provided with spacing, is provided with the spacing groove on mounting plate 27, spacing and spacing groove adaptation, is provided with movable assembly 29 in the box 1, and movable assembly 29 sets up between battery frame 2 and mounting plate 27, and movable assembly 29 is used for driving the removal of battery frame 2 for adjust the interval between the adjacent battery frame 2.

In this embodiment, two groups of moving assemblies 29 are provided, a group of moving assemblies 29 are provided in a gap between every two adjacent battery frames 2, each moving assembly 29 comprises a track rod 30, a bevel gear group 35, a rotating shaft 34, a ball screw 36, a screw slider 37 and a driving rod 38, the track rod 30 is vertically and rotatably arranged on the side wall of the installation box 4, the track rod 30 corresponds to the vertical track of the positioning track 5, a first vertical track groove 31, a spiral track groove 32 and a second vertical track groove 33 are sequentially formed in the track rod 30 from top to bottom, the lower end of the first vertical track groove 31 is communicated with the upper end of the spiral track groove 32, the lower end of the spiral track groove 32 is communicated with the upper end of the second vertical track groove 33, driving protrusions are arranged on the guide rail 20, and the driving protrusions correspond to the track rod 30. The pivot 34 rotates and sets up on mounting plate 27, pass through bevel gear group 35 transmission between pivot 34 and the trace pole 30, ball screw 36 coaxial fixation is on pivot 34, the lead screw slider 37 is fit for on the ball screw 36, drive lever 38 is provided with two, two drive levers 38 are provided with the symmetry setting about lead screw slider 37, drive lever 38 one end rotate connect with lead screw slider 37 on, one end rotate connect on the support frame 28 of battery frame 2, the axis of rotation of drive lever 38 is all vertical.

Working principle: in the initial state, that is, the operation of all the batteries in the box body 1 is in a normal state, that is, the temperature state of each battery pack 3 is normal, at this time, the temperature in the box body 1 can be ensured to be in a preset range under the action of the temperature control system. At this time, the distance between the adjacent battery frames 2 is moderate, as shown in fig. 3, at this time, the guide rail 20 is located at the uppermost end of the limit rail 9, the driving protrusion is vertically arranged, and the air outlet 26 is in a vertical direction, and in this state, in order to make the temperature in the box 1 more uniform, the second servo motor 23 is driven to move along the guide rail 20, so that the air outlet 26 moves along the length direction of the box 1 and blows cold air.

When abnormal overheat occurs to the temperature of a certain battery pack 3, the temperature sensor detects that the temperature difference between the temperature and the preset temperature is large or the temperature of the battery pack 3 is raised rapidly, at this time, the controller firstly controls the first servo motor 15 to work, so that the first servo motor 15 drives the guide rail 20 to move to a gap between the battery frame 2 where the battery pack 3 with abnormal temperature is located and the adjacent battery frame 2, and the air outlet 26 and the battery pack 3 with abnormal temperature are located on the same horizontal plane. In the above process, the first servo motor 15 works, so that the limit mounting block 16 drives the guide rail 20 to rotate 90 degrees and then vertically move, as shown in fig. 4 or fig. 5, so that the air outlet 26 rotates from a vertical state to a horizontal state. Meanwhile, the driving protrusion on the guide rail 20 rotates from the first vertical track groove 31 of the track rod 30 to the communication position of the first vertical track groove 31 and the spiral track groove 32, and along with the continuous vertical downward movement of the guide rail 20, the driving protrusion vertically moves downwards, so that the track rod 30 rotates, under the action of the bevel gear set 35, the rotating shaft 34 rotates, the lead screw sliding block 37 moves along the ball screw 36, and adjacent battery frames 2 are mutually far away under the action of the driving rod 38.

When the air outlet 26 and the battery pack 3 with abnormal temperature are located on the same horizontal plane, the second servo motor 23 is started to enable the air outlet 26 to move to a position corresponding to the battery pack 3 with abnormal temperature, the battery pack 3 is rapidly and accurately cooled, the temperature can be adjusted to be lower at the moment, after the temperature sensor detects that the temperature is in a normal state, the controller controls the second servo motor 23 and the first servo motor 15 to be started, the air outlet 26 and the guide rail 20 are enabled to be in an initial state, and the distance between the battery frames 2 is also enabled to be in an initial state.

The foregoing is only a preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and those skilled in the art should appreciate that the technical scheme and the inventive concept according to the present invention are equivalent or changed within the scope of the present invention.

Claims (7)

1. The utility model provides an energy storage power station temperature control device, includes box (1), sets up battery frame (2), battery management system, energy storage converter, temperature control system in box (1), its characterized in that still includes fixed point cooling system, battery frame (2) are followed box (1) length direction sets up side by side, battery frame (2) are provided with three at least rows, and adjacent two rows have the clearance between battery frame (2), the lateral wall of box (1) rather than adjacent have the clearance between battery frame (2), fixed point cooling system sets up in box (1), fixed point cooling system is used for cooling down to battery package (3) of temperature anomaly, be provided with install bin (4) in box (1), install bin (4) are vertical to be set up, install bin (4) are located one side of battery frame (2) length direction, set up location track (5) on install bin (4), location track (5) rather than battery frame (2) have the clearance between side wall rather than adjacent battery frame (2), fixed point cooling system sets up in box (1) temperature sensor (20), temperature sensor (20) are in connection to temperature sensor (20) on temperature sensor (20), the guide rail (20) moves along the positioning rail (5), the air outlet (26) moves along the length direction of the guide rail (20), one end of the air guide pipe (25) is communicated with the air outlet (26), and the other end of the air guide pipe is communicated with an air conditioner air outlet of the temperature control system.

2. The energy storage power station temperature control device of claim 1, wherein: the utility model discloses a transmission gear, which is characterized in that a limit track (9), a track rack (14), a traveling gear (17), a limit mounting block (16) and a first servo motor (15) are arranged in the mounting box (4), the limit track (9) comprises an outer limit plate (10) and an inner limit plate (11), the positioning track (5) is positioned between the outer limit plate (10) and the inner limit plate (11), an arch-shaped track groove (12) is formed between the outer limit plate (10) and the inner limit plate (11) and corresponds to the positioning track (5), a support plate (13) and the track rack (14) are arranged in the arch-shaped track groove (12), the support plate (13) is arranged along the inner limit plate (11), the track rack (14) is arranged along the outer limit plate (10), the limit mounting block (16) is arranged in the arch-shaped track groove (12) of the limit track (9) in a sliding mode, the first servo motor (15) is fixed on the limit mounting block (16), the first servo motor (15) is connected with the first servo motor (16) and is connected with the first servo motor (17) through a coaxial output shaft (17) which is arranged on the output shaft, the walking gear (17) is meshed with the track rack (14), the side surface, away from the first servo motor (15), of the limiting installation block (16) is provided with a connecting rod (18), the connecting rod (18) penetrates through the positioning track (5), one end, away from the limiting installation block (16), of the connecting rod (18) is provided with a connecting block (19), and the guide rail (20) is fixedly arranged on the connecting block (19).

3. The energy storage power station temperature control device of claim 1, wherein: the guide rail (20) is the back font, be provided with positioning rack (21) along its length direction in guide rail (20), be provided with on guide rail (20) and remove seat (22), it establishes to remove seat (22) slip cap on guide rail (20), it is provided with second servo motor (23) on seat (22) to remove, second servo motor (23) with the controller is connected, be fixed with guide gear (24) on the output shaft of second servo motor (23), guide gear (24) with positioning rack (21) meshing, air outlet (26) are fixed to be set up on moving seat (22).

4. A temperature control device for an energy storage power station as defined in claim 3, wherein: the air guide pipe (25) is a universal telescopic pipe, and the air outlet (26) is a bidirectional opening air outlet structure.

5. The energy storage power station temperature control device of claim 1, wherein: still be provided with mounting plate (27) in box (1), mounting plate (27) tiling is in the bottom surface of box (1), support frame (28) of battery rack (2) slide and set up on mounting plate (27), be provided with in box (1) and remove subassembly (29), remove subassembly (29) setting and be in battery rack (2) with between mounting plate (27), remove subassembly (29) are used for the drive the removal of battery rack (2) is used for adjusting adjacent interval between battery rack (2).

6. The energy storage power station temperature control device of claim 5, wherein: the utility model provides a movable assembly (29) is including track pole (30), bevel gear group (35), pivot (34), ball (36), lead screw slider (37), actuating lever (38), track pole (30) vertical rotation sets up the lateral wall of mounting box (4), track pole (30) with the vertical track of location track (5) corresponds, pivot (34) rotate set up on mounting plate (27), pivot (34) with be provided with between track pole (30) bevel gear group (35), ball (36) coaxial fixation is in on pivot (34), lead screw slider (37) adaptation is on ball (36), actuating lever (38) are provided with two, two actuating lever (38) are about lead screw slider (37) symmetry sets up, actuating lever (38) one end rotate connect in lead screw slider (37), the other end rotate connect in on support frame (28) of battery frame (2), actuating lever (38) coaxial fixation is in on pivot (34), actuating lever (38) rotate track (20) under.

7. The energy storage power station temperature control device of claim 6, wherein: track groove is provided with on track pole (30), track groove is first vertical track groove (31), spiral track groove (32), second vertical track groove (33) from top to bottom in proper order, the lower extreme in first vertical track groove (31) with the upper end intercommunication in spiral track groove (32), the lower extreme in spiral track groove (32) with the upper end intercommunication in second vertical track groove (33), be provided with the drive arch on guide rail (20), the drive arch with track pole (30) the track groove corresponds.