CN113027179B

CN113027179B - Fault-redundant energy storage power station multi-branch system

Info

Publication number: CN113027179B
Application number: CN202110464348.6A
Authority: CN
Inventors: 刘涛; 高洪江
Original assignee: Shengyu Electric Co ltd
Current assignee: Shengyu Electric Co ltd
Priority date: 2021-04-28
Filing date: 2021-04-28
Publication date: 2022-07-29
Anticipated expiration: 2041-04-28
Also published as: CN113027179A

Abstract

The invention relates to the technical field of energy storage power stations, and discloses a fault-redundant energy storage power station multi-branch system, which solves the problems that an energy storage power station system cannot perform comprehensive and effective heat dissipation when the internal temperature is higher, and meanwhile, a sun-shading mechanism is not simple and convenient to use and operate; this energy storage power station multi-branch system can dispel the heat and ventilate the operation when high temperature weather and inside temperature are higher to can carry out comprehensive effectual heat dissipation and ventilation to the energy storage power station, thereby ensure that the energy storage power station can be safe use and stable operation.

Description

Fault-redundant energy storage power station multi-branch system

Technical Field

The invention belongs to the technical field of energy storage power stations, and particularly relates to a multi-branch system of a fault-redundant energy storage power station.

Background

In the prior art, a battery-based electrochemical energy storage power station generally adopts a design of outdoor arrangement of a (container type) prefabricated cabin, and an air conditioning system is arranged in the prefabricated cabin to maintain stable operation of the energy storage power station; because the temperature is influenced by four seasons under outdoor conditions, the energy consumption of the air conditioning system is high, and meanwhile, the change of the external environment temperature can also influence the internal temperature of the prefabricated cabin to a certain extent.

The patent application with publication number CN212725452U discloses an energy storage power station system, which is composed of the following structures: 1. an energy storage battery prefabricated cabin; 101. an accident disposal internal interface; 102. a battery module; 103. an energy storage battery prefabricated cabin in which an accident occurs; 2. a wall body; 201. a foundation; 202. a side wall; 203. a back wall body; 3. a ceiling; 301. a thermally insulating structure; 302. a light-transmitting structure; 303. a sunshade mechanism; 304. an accident disposal external interface; 305. a support structure; 4. inspecting the channel; 401. a step or an elevator; 5. a sealing door; this energy storage power station system can effectually utilize solar heat energy to heat the energy storage power station, also can effectually carry out the sunshade simultaneously and insulate against heat.

However, the energy storage power station system cannot perform comprehensive and effective heat dissipation when the internal temperature is high, so that hidden dangers are brought to safe and stable use of the energy storage power station, and meanwhile, the use and operation of a sun-shading mechanism of the energy storage power station system are not simple and convenient; therefore, improvements are now needed in view of the current situation.

Disclosure of Invention

In view of the above situation, in order to overcome the defects in the prior art, the invention provides a fault-tolerant energy storage power station multi-branch system, which effectively solves the problems that in the background art, an energy storage power station system cannot perform comprehensive and effective heat dissipation when the internal temperature is high, and meanwhile, a sun-shading mechanism is not simple and convenient to use and operate.

In order to achieve the purpose, the invention provides the following technical scheme: a fault-redundancy energy storage power station multi-branch system comprises a foundation boss, wherein U-shaped walls are arranged on two sides of the top of the foundation boss, a ceiling is arranged between the tops of the two U-shaped walls, and a movable wall is arranged between two ends of each U-shaped wall;

both ends of the top of the boss of the foundation and both ends of the bottom of the ceiling are provided with long grooves, one end of the top and the bottom of the two movable walls are provided with support shafts, the support shafts are movably inserted in the long grooves, and the end part of the supporting shaft is provided with a large ball, one end of the outer sides of the two movable walls is provided with a long vertical groove, the top and the bottom of the long vertical groove are provided with auxiliary grooves, a rotating rod is rotatably arranged between the long vertical groove and the two auxiliary grooves, the surfaces of the rotating rod positioned at the two sides of the long vertical groove are provided with first gears, the upper parts and the lower parts of the inner sides of the two movable walls are provided with racks, the first gears are meshed and connected with the racks, the inside of the foundation boss is provided with two installation cavities, the two installation cavities are positioned under the two rotating rods, the two rotating rods respectively extend into the two mounting cavities and are fixedly connected with the output end of the first motor;

The dwang is located the inside surface mounting of two subslots and all installs the second gear, and the inside of subslot all rotates and installs the third gear, and sector gear is all installed to the inboard upper portion of two enclosure and the one end of lower part, and the third gear is connected with second gear and sector gear meshing.

Preferably, protective screens are arranged between the end parts of the two U-shaped walls, first heat-preservation heat-insulation plates are arranged on the inner sides of the two U-shaped walls, and the first heat-preservation heat-insulation plates are made of aluminum silicate fiberboards.

Preferably, the bottom of each of the two movable walls is provided with a long plate, and the bottoms of the long plates are provided with small balls at equal intervals.

Preferably, the baffle is all installed at the both ends at ground base boss top, and two long recesses are located between two baffles.

Preferably, the light through groove has all been seted up to the both sides at ceiling top, and glass is all installed to the inside in two light through grooves, and two chute boards are all installed at the top at the inboard both ends of ceiling, and the one end fixed mounting of chute board has first fixed axle, and folding light screen is installed in the rotation of the surface of first fixed axle, and folding light screen is aluminium membrane PVC material, and the impartial distance in inside of chute board is installed and is removed the wheel, and the axle center department that removes the wheel is connected with first connecting piece, and first connecting piece rotates with the side of folding light screen to be connected.

Preferably, the one end fixed mounting of folding light screen has the connecting axle, and first connecting plate strip is all installed at the both ends of connecting axle, and two set horns are all installed on the upper portion at the inboard both ends of ceiling, and first adjustment tank has all been seted up on the inclined plane at set horn top, and first threaded rod is all installed to the inside of first adjustment tank, and the equal threaded connection in surface of first threaded rod has first movable block, the one end of first connecting plate strip and the top fixed connection of first movable block, and first bevel gear is installed to the one end of first threaded rod.

Preferably, a second adjusting groove is formed in the lower portion of one side of the triangular plate and communicated with the first adjusting groove, a second threaded rod is rotatably mounted inside the second adjusting groove, a second bevel gear is mounted at one end of the second threaded rod and meshed with the first bevel gear, a second moving block is connected to the surface of the second threaded rod in a threaded mode, and a second connecting plate strip is mounted at one end of the bottom of the second moving block.

Preferably, two the fixed block is all installed on the upper portion at the inboard both ends of U-shaped wall body, and two U-shaped wall bodies all rotate between two fixed blocks of same end and install folding heat preservation heat insulating board, and two slide bars are all installed at the top at the inboard middle part of two U-shaped wall bodies, and the lantern ring is installed to the impartial distance in surface of slide bar, and the second connection piece is installed to the impartial distance in both sides of two folding heat preservation heat insulating boards, and the lantern ring is connected through the connecting strip with the second connection piece, and folding heat preservation heat insulating board is the preparation of aluminium silicate fiberboard.

Preferably, the lower parts of the two ends of the inner side of the ceiling are both provided with a double-shaft motor, the two ends of the double-shaft motor are fixedly connected with one ends of the two second threaded rods, the two ends of the two opposite sides of the two folding heat-insulation plates are both provided with a third connecting piece, and the top of the third connecting piece is connected with the bottom of the second connecting lath.

Compared with the prior art, the invention has the beneficial effects that:

(1) the multi-branch system of the energy storage power station can perform heat dissipation and ventilation operation in high-temperature weather and when the internal temperature is high, and can perform comprehensive and effective heat dissipation and ventilation on the energy storage power station, so that the energy storage power station can be safely used and stably operated, and meanwhile, the multi-branch system of the energy storage power station is provided with a sun-shading and heat-insulating mechanism which is convenient to operate and use, so that the energy storage power station can meet the use requirement of constant-temperature operation;

(2) during work, the movable wall can be effectively moved and rotationally adjusted by arranging the long groove, the support shaft, the large ball, the long vertical groove, the auxiliary groove, the rotating rod, the first gear, the rack, the mounting cavity, the first motor, the second gear, the third gear and the sector gear; the rotating rod drives the first gear to rotate by starting the first motor, the rack is driven by the rotation of the first gear, so that the rack drives the movable wall to move, the support shaft can move in the long groove by the rolling of the large ball of the movable wall, the movable wall is moved away from the end parts of the two U-shaped walls, the two U-shaped walls can be effectively ventilated and cooled by moving away the two movable walls, the ventilation area is large, and the cooling effect is good; when the movable wall moves to separate the first gear from the rack and enable the sector gear to be meshed with the third gear, the movable wall stops moving, the second gear can drive the sector gear through the third gear along with the rotation of the rotating rod, the movable wall can rotate through the rotation of the supporting shaft and the large ball inside the long groove through the drive of the sector gear, and finally the movable wall rotates to be attached to the outer side of the U-shaped wall;

(3) During work, the foldable shading plate and the foldable heat-insulation board can be effectively folded, contracted and moved and adjusted by arranging the light-transmitting groove, the glass, the chute plate, the moving wheel, the first connecting piece, the first fixed shaft, the connecting shaft, the first connecting plate strip, the triangular plate, the first adjusting groove, the first threaded rod, the first moving block, the first bevel gear, the second adjusting groove, the second threaded rod, the second bevel gear, the second moving block, the second connecting plate strip, the double-output-shaft motor, the fixed block, the sliding rod, the lantern ring, the connecting strip, the second connecting piece and the third connecting piece; the double-output-shaft motor is started to drive the second threaded rod to rotate, the second threaded rod can rotate to drive the second movable block to drive the second connecting plate strip to move, the second connecting plate strip can move to carry out movement folding operation on the folding heat-insulation plate through the third connecting plate, the lantern ring can slide and adjust on the surface of the sliding rod by carrying out movement folding operation on the folding heat-insulation plate, meanwhile, the second threaded rod can rotate to drive the second bevel gear to rotate, the first threaded rod can rotate through the first bevel gear by driving the second bevel gear, the first movable block can move towards the first bevel gear in the first adjusting groove by driving the first movable block to move, meanwhile, the first connecting plate strip can move by driving the first connecting plate strip to move, and the first connecting plate strip can move to drive the folding light-shielding plate to move and fold through the connecting shaft, and the first connecting piece can drive the moving wheel to move in the sliding chute plate by the moving and folding of the folding light screen, and finally the folding light screen is folded.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the principles of the invention and not to limit the invention.

In the drawings:

FIG. 1 is a schematic view of the structure of the present invention;

FIG. 2 is a schematic cross-sectional view of FIG. 1 according to the present invention;

FIG. 3 is a schematic view of a portion of the structure of FIG. 2 according to the present invention;

FIG. 4 is an enlarged view of the structure at A of FIG. 3 according to the present invention;

FIG. 5 is an enlarged view of the structure at B of FIG. 3 according to the present invention;

FIG. 6 is a schematic top view of a foundation boss according to the present invention;

FIG. 7 is a schematic top view of the movable wall of the present invention;

FIG. 8 is a schematic cross-sectional view of the canopy of the present invention;

FIG. 9 is an enlarged view of FIG. 8 at C according to the present invention;

FIG. 10 is an enlarged view of FIG. 8 at D according to the present invention;

FIG. 11 is an enlarged view of the structure of FIG. 8 at E according to the present invention;

FIG. 12 is an enlarged view of the structure of FIG. 8 at F according to the present invention;

FIG. 13 is a schematic structural view of a U-shaped wall according to the present invention;

FIG. 14 is an enlarged view of FIG. 13 at G according to the present invention;

FIG. 15 is an enlarged view taken at H of FIG. 13 in accordance with the present invention;

FIG. 16 is an enlarged view of the structure at I of FIG. 13 according to the present invention;

in the figure: 1. a foundation boss; 2. a U-shaped wall body; 3. a ceiling; 4. a movable wall; 5. a long groove; 6. a support shaft; 7. a large ball; 8. a long vertical slot; 9. a secondary groove; 10. rotating the rod; 11. a first gear; 12. a rack; 13. a mounting cavity; 14. a first motor; 15. a second gear; 16. a third gear; 17. a sector gear; 18. a protective net; 19. a first heat insulation board; 20. a long plate; 21. a small ball; 22. a baffle plate; 23. a light-transmitting groove; 24. glass; 25. a chute plate; 2501. a moving wheel; 2502. a first connecting piece; 26. a first fixed shaft; 27. folding the shading plate; 28. a connecting shaft; 29. a first connecting panel; 30. a set square; 31. a first regulating groove; 32. a first threaded rod; 33. a first moving block; 34. a first bevel gear; 35. a second regulating groove; 36. a second threaded rod; 37. a second bevel gear; 38. a second moving block; 39. a second connecting panel; 40. a double output shaft motor; 41. a fixed block; 42. folding the heat-insulating plate; 43. a slide bar; 44. a collar; 45. a connecting strip; 46. a second connecting sheet; 47. and a third connecting sheet.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments, which can be obtained by a person skilled in the art without making any creative effort based on the embodiments in the present invention, belong to the protection scope of the present invention.

In the first embodiment, as shown in fig. 1 to 9 and fig. 11 to 15, the invention includes a foundation boss 1, U-shaped walls 2 are installed on both sides of the top of the foundation boss 1, a ceiling 3 is installed between the tops of the two U-shaped walls 2, and a movable wall 4 is installed between both ends of the two U-shaped walls 2, so that an energy storage power station and a multi-branch system of the energy storage power station can be installed in an area enclosed by the two U-shaped walls 2 and the two movable walls 4, that is, on the top of the foundation boss 1 and below the ceiling 3;

the two ends of the top of the foundation boss 1 and the two ends of the bottom of the ceiling 3 are both provided with long grooves 5, the top and one end of the bottom of each movable wall 4 are both provided with a support shaft 6, the support shaft 6 is movably inserted in the long grooves 5, the end part of the support shaft 6 is provided with a large ball 7, one end of the outer side of each movable wall 4 is provided with a long vertical groove 8, the top and the bottom of each long vertical groove 8 are both provided with auxiliary grooves 9, a rotating rod 10 is rotatably arranged between each long vertical groove 8 and each auxiliary groove 9, the surfaces of the rotating rods 10 positioned at the two sides of each long vertical groove 8 are both provided with a first gear 11, the upper parts and the lower parts of the inner sides of the two movable walls 4 are both provided with racks 12, the first gears 11 are meshed with the racks 12 and connected, two installation cavities 13 are arranged in the foundation boss 1, the two installation cavities 13 are positioned under the two rotating rods 10, and the first motors 14 are arranged in the two installation cavities 13, the two rotating rods 10 respectively extend into the two installation cavities 13 and are fixedly connected with the output end of the first motor 14, so that the movable wall 4 can be opened in a moving manner; by starting the first motor 14, the rotating rod 10 drives the first gear 11 to rotate, the rotation of the first gear 11 can drive the rack 12, so that the rack 12 drives the movable wall 4 to move, the movable wall 4 can drive the supporting shaft 6 to move in the long groove 5 through the rolling of the large ball 7, so that the movable wall 4 can be moved away from the end parts of the two U-shaped walls 2, the two movable walls 4 can be moved away from the end parts of the two U-shaped walls 2, the two U-shaped walls 2 can be effectively ventilated and cooled, the ventilation area is large, and the cooling effect is good;

Second gears 15 are respectively arranged on the surfaces of the rotating rods 10 in the two auxiliary grooves 9, third gears 16 are respectively arranged in the auxiliary grooves 9 in a rotating mode, sector gears 17 are respectively arranged at one ends of the upper portions and the lower portions of the inner sides of the two movable walls 4, and the third gears 16 are meshed with the second gears 15 and the sector gears 17, so that the two movable walls 4 can be adjusted in a rotating mode, the two movable walls 4 are attached to the outer sides of the two U-shaped wall bodies 2, and the two opened movable walls 4 cannot occupy large space; when the movable wall 4 moves to separate the first gear 11 from the rack 12 and to engage the sector gear 17 with the third gear 16, the movable wall 4 stops moving, and the second gear 15 drives the sector gear 17 through the third gear 16 as the rotating rod 10 rotates, and the sector gear 17 drives the movable wall 4 to rotate through the rotation of the support shaft 6 and the large ball 7 inside the long groove 5, so that the movable wall 4 is finally rotated to be attached to the outer side of the U-shaped wall 2.

Embodiment two, on the basis of embodiment one, given by fig. 4, 5 and 13, all install protection network 18 between the tip of two U-shaped wall bodies 2, and the inboard of two U-shaped wall bodies 2 all installs first heat preservation board 19, first heat preservation board 19 is the preparation of aluminium silicate fiberboard, through the setting of protection network 18, can effectively prevent that the fly-wall 4 from entering by mistake and influencing the safe handling in energy storage power station after opening, through the setting of first heat preservation board 19, can play effectual heat preservation thermal-insulated effect in low temperature weather.

In the third embodiment, on the basis of the first embodiment, as shown in fig. 4, the long plates 20 are installed at the bottoms of the two movable walls 4, and the small balls 21 are installed at equal intervals at the bottoms of the long plates 20, so that the movable walls 4 can be effectively moved, and can support the movable walls 4, and when the movable walls 4 move, the small balls 21 can be in rolling contact with the tops of the foundation bosses 1, so that the movable walls 4 can move and rotate more conveniently and stably.

Fourth embodiment, on the basis of the first embodiment, as shown in fig. 4 and 6, the baffles 22 are installed at both ends of the top of the boss 1 of the foundation, and the two long grooves 5 are located between the two baffles 22, so that the movable wall 4 can be limited and fixed, when the movable wall 4 is moved to be closed, the movable wall 4 can keep moving linearly and effectively seal between the two ends of the two U-shaped walls 2, when the movable wall 4 is moved to be closed, the baffles 22 enable the movable wall 4 to rotate the inner side of the baffles 22 and be located above the long grooves 5, and finally, the movable wall 4 can move linearly along the long grooves 5 under the limiting and blocking effects of the baffles 22.

Fifth embodiment, on the basis of the first embodiment, as shown in fig. 9 to 11, light-passing grooves 23 are formed in both sides of the top of the ceiling 3, glass 24 is installed inside the light-passing grooves 23, two chute plates 25 are installed at the tops of both ends inside the ceiling 3, a first fixing shaft 26 is fixedly installed at one end of each chute plate 25, a folding light shielding plate 27 is installed on the surface of the first fixing shaft 26 in a rotating manner, the folding light shielding plate 27 is similar to a folding screen structure, the folding light shielding plate 27 is made of an aluminum film PVC, moving wheels 2501 are installed in the sliding plate 25 at equal distances inside the sliding plate 25, a first connecting plate 2502 is connected to the axis of the moving wheels 2501, and the first connecting plate 2502 is rotatably connected to the side edge of the folding light shielding plate 27, so that the light-passing grooves 23 and the tempered glass 24 can be effectively shielded, and the energy storage power station is exposed to the sun.

Sixth embodiment, on the basis of the fifth embodiment, as shown in fig. 9 to 11, a connecting shaft 28 is fixedly installed at one end of the folding light shielding plate 27, first connecting plate strips 29 are installed at both ends of the connecting shaft 28, two triangular plates 30 are installed at upper portions of both ends of the inner side of the ceiling 3, first adjusting grooves 31 are formed in inclined surfaces of the tops of the triangular plates 30, first threaded rods 32 are installed inside the first adjusting grooves 31, first moving blocks 33 are connected to surfaces of the first threaded rods 32 in a threaded manner, one end of the first connecting plate strip 29 is fixedly connected with the tops of the first moving blocks 33, and first bevel gears 34 are installed at one ends of the first threaded rods 32, so that the folding light shielding plate 27 can be folded and contracted, and sunlight heats the inside of the device through the glass 24; through first threaded rod 32, make first movable block 33 move towards first bevel gear 34 in the inside of first regulation groove 31, the removal of first movable block 33 can drive first connecting lath 29 and move simultaneously, the removal of first connecting lath 29 can drive folding light screen 27 through connecting axle 28 and move foldingly, and folding movement of folding light screen 27 can make first connecting piece 2502 drive and move wheel 2501 and move in the inside of spout board 25, finally make folding light screen 27 fold, and make sunshine shine the inside of this device through glass 24.

Seventh embodiment, on the basis of the sixth embodiment, as shown in fig. 11 and 12, a second adjusting groove 35 is formed in a lower portion of one side of the triangular plate 30, the second adjusting groove 35 is communicated with the first adjusting groove 31, a second threaded rod 36 is rotatably mounted inside the second adjusting groove 35, a second bevel gear 37 is mounted at one end of the second threaded rod 36, the second bevel gear 37 is meshed with the first bevel gear 34, a second moving block 38 is connected to a surface of the second threaded rod 36 through a thread, and a second connecting plate strip 39 is mounted at one end of the bottom of the second moving block 38, so that transmission adjustment can be effectively performed, the second bevel gear 37 is driven to rotate through rotation of the second threaded rod 36, and rotation of the second bevel gear 37 can drive the first threaded rod 32 to perform rotation adjustment through the first bevel gear 34.

Eighth embodiment, on the basis of the first embodiment, as shown in fig. 14 to 16, the upper portions of the two inner ends of the two U-shaped walls 2 are respectively provided with a fixing block 41, the two fixing blocks 41 at the same end of the two U-shaped walls 2 are respectively rotatably provided with a folding heat-insulating board 42, the top portions of the middle portions of the inner sides of the two U-shaped walls 2 are respectively provided with two sliding rods 43, the surfaces of the sliding rods 43 are respectively provided with a lantern ring 44 at equal distances, the two sides of the two folding heat-insulating boards 42 are respectively provided with a second connecting piece 46 at equal distances, the lantern rings 44 are connected with the second connecting pieces 46 through the connecting strips 45, the folding heat-insulating boards 42 are made of aluminum silicate fiber boards, and the folding heat-insulating boards 42 are similar to a folding screen structure, so that heat insulation and preservation can be effectively performed, and the inside of the device can be kept at a certain constant temperature.

Ninth embodiment, based on the first embodiment, as shown in fig. 12 and 16, a double-shaft motor 40 is installed at the lower part of each of the two ends inside the ceiling 3, the two ends of the double-shaft motor 40 are fixedly connected with one end of the two second threaded rods 36, third connecting pieces 47 are installed at the two ends of the two opposite sides of the two folded heat-preservation and heat-insulation boards 42, and the top of each third connecting piece 47 is connected with the bottom of the second connecting lath 39, so that the folded heat-preservation and heat-insulation boards 42 can be effectively folded, and effective transmission power can be provided; through starting two play axle motors 40, make it drive second threaded rod 36 and rotate, the rotation of second threaded rod 36 can make second movable block 38 drive second connecting strip 39 and move, the removal of second connecting strip 39 can move folding operation to folding heat preservation heat insulating board 42 through third connection piece 47, the rotation of second threaded rod 36 can drive second bevel gear 37 and rotate simultaneously, the rotation of second bevel gear 37 drives first threaded rod 32 through first bevel gear 34 and rotates, the rotation of first threaded rod 32 can make folding light screen 27 move foldingly, thereby be favorable to the inside of sunlight irradiation this equipment.

The working principle is as follows: when the internal temperature of the device is low, the temperature inside the device can be raised by sun drying; firstly, the double-output-shaft motor 40 is started to drive the second threaded rod 36 to rotate, the rotation of the second threaded rod 36 can enable the second moving block 38 to drive the second connecting strip 39 to move, the movement of the second connecting strip 39 can enable the folding heat-insulation board 42 to move and fold through the third connecting piece 47, the folding heat-insulation board 42 can move and fold to enable the lantern ring 44 to perform sliding adjustment on the surface of the sliding rod 43, meanwhile, the rotation of the second threaded rod 36 can drive the second bevel gear 37 to rotate, the rotation of the second bevel gear 37 can drive the first threaded rod 32 to rotate through the first bevel gear 34, the rotation of the first threaded rod 32 can enable the first moving block 33 to move towards the first bevel gear 34 in the first adjusting groove 31, meanwhile, the movement of the first moving block 33 can drive the first connecting strip 29 to move, the movement of the first connecting strip 29 can drive the folding shading plate 27 to move and fold through the connecting shaft 28, the movable folding of the folding shading plate 27 can enable the first connecting plate 2502 to drive the movable wheel 2501 to move inside the sliding chute plate 25, and finally the folding shading plate 27 is folded, the folding shading plate 27 and the folding heat-insulation board 42 are moved and folded, and sunlight can heat the inside of the device through the light-transmitting groove 23 and the toughened glass 24; when the internal temperature of the device is high, the device can be ventilated, radiated and cooled by moving the movable wall 4, the rotating rod 10 drives the first gear 11 to rotate by starting the first motor 14, the rack 12 is driven by the rotation of the first gear 11, so that the movable wall 4 is driven by the rack 12 to move, the support shaft 6 can move in the long groove 5 by the rolling of the large ball 7 of the movable wall 4, the movable wall 4 is moved away from the end parts of the two U-shaped wall bodies 2, the two movable walls 4 can be moved away to effectively ventilate and radiate the heat between the two U-shaped wall bodies 2, the ventilation area is large, and the heat radiation effect is good; when the movable wall 4 moves to separate the first gear 11 from the rack 12 and enable the sector gear 17 to be meshed with the third gear 16, the movable wall 4 stops moving, the second gear 15 can drive the sector gear 17 through the third gear 16 along with the rotation of the rotating rod 10, the movable wall 4 can rotate through the rotation of the supporting shaft 6 and the large ball 7 inside the long groove 5 through the drive of the sector gear 17, finally the movable wall 4 rotates to be attached to the outer side of the U-shaped wall 2, and the two movable walls 4 can be moved away to effectively ventilate and radiate heat between the two U-shaped walls 2, so that the ventilation area is large and the heat radiation effect is good.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

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

1. The utility model provides a but redundant energy storage power station multi-branch system of trouble, includes ground boss (1), its characterized in that: u-shaped walls (2) are arranged on two sides of the top of the foundation boss (1), a ceiling (3) is arranged between the tops of the two U-shaped walls (2), and a movable wall (4) is arranged between two ends of each U-shaped wall (2);

Both ends of the top of a foundation boss (1) and both ends of the bottom of a ceiling (3) are respectively provided with a long groove (5), supporting shafts (6) are respectively arranged at the top and one end of the bottom of two movable walls (4), the supporting shafts (6) are movably inserted in the long grooves (5), large balls (7) are arranged at the end parts of the supporting shafts (6), long vertical grooves (8) are respectively arranged at one ends of the outer sides of the two movable walls (4), auxiliary grooves (9) are respectively arranged at the top and the bottom of the long vertical grooves (8), rotating rods (10) are rotatably arranged between the long vertical grooves (8) and the two auxiliary grooves (9), first gears (11) are respectively arranged on the surfaces of the rotating rods (10) at both sides of the long vertical grooves (8), racks (12) are respectively arranged at the upper parts and the lower parts of the inner sides of the two movable walls (4), the first gears (11) are meshed with the racks (12), two installation cavities (13) are arranged in the foundation boss (1), the two installation cavities (13) are positioned under the two rotating rods (10), the first motors (14) are installed in the two installation cavities (13), and the two rotating rods (10) respectively extend into the two installation cavities (13) and are fixedly connected with the output ends of the first motors (14);

second gear (15) are all installed on the surface that dwang (10) are located two subslot (9) inside, and third gear (16) are all installed in the inside of subslot (9) rotation, and sector gear (17) are all installed to two activity wall (4) inboard upper portion and the one end of lower part, and third gear (16) are connected with second gear (15) and sector gear (17) meshing.

2. The fault-tolerant energy storage plant multi-branch system according to claim 1, characterized in that: protective screens (18) are installed between the end portions of the two U-shaped walls (2), first heat-preservation and heat-insulation plates (19) are installed on the inner sides of the two U-shaped walls (2), and the first heat-preservation and heat-insulation plates (19) are made of aluminum silicate fiber boards.

3. The fault-tolerant energy storage power station multi-branch system of claim 1, characterized in that: the bottom of each of the two movable walls (4) is provided with a long plate (20), and the bottom of each long plate (20) is provided with small balls (21) at equal intervals.

4. The fault-tolerant energy storage power station multi-branch system of claim 1, characterized in that: baffle plates (22) are installed at two ends of the top of the foundation boss (1), and the two long grooves (5) are located between the two baffle plates (22).

5. The fault-tolerant energy storage power station multi-branch system of claim 1, characterized in that: light groove (23) have all been seted up to the both sides at ceiling (3) top, glass (24) are all installed to the inside of two light grooves (23) that lead to, two chute board (25) are all installed at the top at ceiling (3) inboard both ends, the one end fixed mounting of chute board (25) has first fixed axle (26), folding light screen (27) are installed in the rotation of surface of first fixed axle (26), folding light screen (27) are aluminium membrane PVC material, the impartial distance in inside of chute board (25) is installed and is removed wheel (2501), the axle center department of removing wheel (2501) is connected with first connecting piece (2502), first connecting piece (2502) rotate with the side of folding light screen (27) and be connected.

6. The fault-tolerant energy storage power station multi-branch system according to claim 5, characterized in that: one end fixed mounting of folding light screen (27) has connecting axle (28), first connecting lath (29) are all installed at the both ends of connecting axle (28), two set-square (30) are all installed on the upper portion at ceiling (3) inboard both ends, first adjustment tank (31) have all been seted up on the inclined plane at set-square (30) top, first threaded rod (32) are all installed to the inside of first adjustment tank (31), the equal threaded connection in surface of first threaded rod (32) has first movable block (33), the one end of first connecting lath (29) and the top fixed connection of first movable block (33), and first bevel gear (34) are installed to the one end of first threaded rod (32).

7. The fault-tolerant energy storage power station multi-branch system of claim 6, characterized in that: second adjustment tank (35) have all been seted up to the lower part of set-square (30) one side, second adjustment tank (35) are linked together with first adjustment tank (31), second threaded rod (36) are all installed in the inside of second adjustment tank (35) rotation, second bevel gear (37) are installed to the one end of second threaded rod (36), second bevel gear (37) are connected with first bevel gear (34) meshing, the surperficial threaded connection of second threaded rod (36) has second movable block (38), second connecting lath (39) are installed to the one end of second movable block (38) bottom.

8. The fault-tolerant energy storage power station multi-branch system of claim 7, characterized in that: two fixed block (41) are all installed on the upper portion at U-shaped wall body (2) inboard both ends, all rotate between two fixed block (41) of two U-shaped wall bodies (2) same end and install folding heat preservation heat insulating board (42), two slide bar (43) are all installed at the top at two U-shaped wall body (2) inboard middle parts, lantern ring (44) are installed to the impartial distance in surface of slide bar (43), second connection piece (46) are installed to the impartial distance in both sides of two folding heat preservation heat insulating board (42), lantern ring (44) are connected through connecting strip (45) with second connection piece (46), folding heat preservation heat insulating board (42) are the preparation of aluminium silicate fiberboard.

9. The fault-tolerant energy storage power station multi-branch system of claim 8, wherein: two output shaft motors (40) are installed on the lower portions of the two ends of the inner side of the ceiling (3), two ends of each output shaft motor (40) are fixedly connected with one ends of the two second threaded rods (36), third connecting pieces (47) are installed at the two end portions of the opposite sides of the two folding heat-preservation heat-insulation plates (42), and the tops of the third connecting pieces (47) are connected with the bottoms of the second connecting laths (39).