CN115133174B - AC/DC power supply system battery is with concatenation formula heat radiation structure - Google Patents

Abstract

The invention relates to the technical field of battery heat dissipation, in particular to a splicing type heat dissipation structure for a storage battery of an alternating current-direct current power supply system. When the existing equipment is used for radiating the storage battery, the fan generates flowing air flow to remove heat generated by the storage battery, but in the method, the temperature of the air flow is increased when the air flow flows through the other end after radiating the heat of one end of the storage battery, so that the radiating effect of the air flow is reduced. The spliced heat dissipation structure for the storage battery of the alternating current-direct current power supply system provided by the invention adopts the plurality of cooling devices to commonly dissipate heat of the surface of the storage battery, and each cooling device only circularly cools the corresponding area, so that the phenomenon of high temperature caused by excessive flowing of cooling liquid through the area is avoided, and the heat dissipation effect of the surface of the storage battery is improved.

Description

AC/DC power supply system battery is with concatenation formula heat radiation structure

Technical Field

The invention relates to the technical field of battery heat dissipation, in particular to a splicing type heat dissipation structure for a storage battery of an alternating current and direct current power supply system.

Background

The AC/DC power supply system is a digital power supply software platform which is established by uniformly designing an AC power supply for a station, a DC operating power supply, a UPS (uninterrupted Power supply) special for electric power, an inverter power supply and a communication power supply, and realizing communication networking of all subsystems of the power supply for the station through an integrated monitoring device to realize information sharing of the power supply for the station.

The phenomenon that generates heat can appear in the use in current battery, influence the life of battery, the phenomenon of battery spontaneous combustion can appear under the serious condition, thereby the battery needs to carry out the heat dissipation in the use, chinese utility model patent that publication is CN213278239U is a battery with heat dissipation function, place the battery in the battery box main part when using, then start the fan, send into the inside of battery box main part with outside gas through the fan, refrigerate through the semiconductor refrigeration piece, can dispel the heat to the battery fast, the battery temperature rise has been avoided, thereby realize the radiating function of battery, the radiating efficiency of battery has been ensured.

However, when the heat dissipation treatment is performed on the storage battery in the above patent, the storage battery placed in the battery box main body can move transversely when being subjected to external force, so that the stability of the storage battery is reduced, the air flow generated in the battery box main body in the above patent usually moves from one end to the other end, the temperature of the air flow rises when the air flow flows through the other end after the air flow dissipates the heat of one end of the storage battery, the heat dissipation effect of the air flow is reduced, the heat dissipation effects at the two ends of the storage battery are inconsistent, and the heat dissipation effect of the storage battery is reduced.

Disclosure of Invention

The technical problem to be solved is as follows: the invention provides a splicing type heat dissipation structure for a storage battery of an alternating current and direct current power supply system, which can solve the problems existing in the process of heat dissipation of the storage battery.

The technical scheme is as follows: in order to achieve the purpose, the invention adopts the following technical scheme that the spliced heat dissipation structure for the storage battery of the alternating current-direct current power supply system comprises four supporting devices which are uniformly distributed on the upper end of the ground in a rectangular shape, a placing device for placing the storage battery is installed between every two adjacent supporting devices, a plurality of cooling devices for cooling the storage battery are spliced between every two adjacent supporting devices, and an exhaust device is jointly placed at the upper ends of the plurality of cooling devices.

The supporting device comprises a rectangular frame with a liquid containing cavity arranged inside.

Be located one of them diagonal two the circular recess has been seted up to the rectangle frame upper end, installs electric putter in the circular recess, and the connecting block is installed to the electric putter upper end, and the inserting groove has all been seted up to two adjacent terminal surfaces that are close to cooling device on the connecting block, is located another diagonal two the water injection pipe is installed to the rectangle frame upper end, and threaded connection has the jam lid on the water injection pipe.

The cooling device comprises a strip-shaped plate, a cooling cavity is arranged in the strip-shaped plate, a partition plate used for separating the cooling cavity into two cavities is arranged in the cooling cavity, two round through holes are symmetrically formed in the partition plate in the vertical direction, a heat-conducting plate which is T-shaped is installed at one end, close to a rectangular distribution center, of the strip-shaped plate, a heat-conducting sticker is pasted on the heat-conducting plate, a cooling groove is formed in one end, close to the cooling cavity, of the heat-conducting plate, an extrusion mechanism is connected to the upper wall of the strip-shaped plate in a sliding penetrating mode, the strip-shaped plate is located on the same side, a connecting column is jointly penetrated through the extrusion mechanism, and the connecting column is in inserting connection with an inserting groove in the connecting block.

As a preferable technical scheme of the invention, a first sunken groove is formed in one end, close to one side strip-shaped plate, of the rectangular frame, a first connecting connector is installed in the first sunken groove, and a first strip-shaped connecting pipe is installed at one end, close to the other side strip-shaped plate, of the rectangular frame.

As a preferred technical scheme of the invention, one end of each strip-shaped plate, which is close to a rectangular frame on any one side, is provided with a second concave groove, a second connector is installed in the second concave groove, one end of each strip-shaped plate, which is far away from the second concave groove, is provided with a second strip-shaped connecting pipe, two adjacent strip-shaped plates are in plug fit with the second concave groove and the second connector through the second strip-shaped connecting pipes, the strip-shaped plates which are positioned on the same side and close to the rectangular frame are in plug fit with the first strip-shaped connecting pipes through the second concave grooves and the second connectors, and the strip-shaped plates which are positioned on the same side and close to the other rectangular frame are in plug fit with the first concave grooves and the first connectors through the second strip-shaped connecting pipes.

According to a preferable technical scheme, the extrusion mechanism comprises a sliding rod which is connected to the upper wall of the strip-shaped plate in a sliding penetrating mode, a pushing plate is mounted at the lower end of the sliding rod and located in a large cavity of the separation plate, the large cavity is far away from the heat conducting plate, two water passing through holes are symmetrically formed in the pushing plate, a rotating cover plate is arranged below the water passing through holes and is rotatably connected with the pushing plate through a torsion spring, an adjusting block is mounted at the upper end of the sliding rod, and a connecting circular hole for penetrating a connecting column is formed in the middle of the adjusting block.

As a preferable technical scheme of the invention, the connecting column is formed by splicing a plurality of threaded connecting rods in a threaded manner.

As a preferred technical solution of the present invention, a first cover plate is disposed on one side of the circular through hole located at the lower side of the partition plate, which is close to the heat conducting plate, the first cover plate is rotatably connected to the partition plate through a torsion spring, and a second cover plate is disposed on one side of the circular through hole located at the upper side of the partition plate, which is far from the heat conducting plate, the second cover plate is rotatably connected to the partition plate through a torsion spring.

As a preferred technical scheme, the placing device comprises a guide frame arranged on the rectangular frame, a plurality of uniformly distributed inserting and connecting through holes are transversely formed in the wall, close to the rectangular distribution center, of the guide frame, a rectangular moving rod is connected to one end, far away from the rectangular frame, of the guide frame in a sliding mode, one end, far away from the guide frame, of the rectangular moving rod is fixedly connected with the other rectangular frame, a placing rod is arranged at one end, close to the rectangular distribution center, of the rectangular moving rod, far away from the guide frame, of the rectangular moving rod, a positioning rod is inserted into any inserting and connecting through hole in the guide frame, and the positioning rod is matched with the rectangular moving rod in an inserting mode.

According to a preferred technical scheme, the exhaust device comprises a plurality of box cover plates which are uniformly arranged at the upper ends of a plurality of strip-shaped plates, magnetic stripes are arranged on four sides of the lower ends of the box cover plates and are in magnetic attraction fit with the strip-shaped plates, a cover film is arranged between every two adjacent box cover plates, the left end and the right end of each cover film are rotatably connected with winding rollers, the winding rollers are rotatably connected with the box cover plates through torsion springs, a heat dissipation fan is arranged in the middle of the middle box cover plate, and two through holes are symmetrically formed in the middle of the middle box cover plate in a front-back mode.

Has the advantages that: 1. the cooling device adopted by the splicing type heat dissipation structure for the storage battery of the alternating current-direct current power supply system can be spliced and matched with the storage batteries with different sizes in a certain range, so that the storage batteries with different sizes can be cooled and dissipated conveniently, the use flexibility of the heat dissipation structure is improved, the use occasions of the heat dissipation structure are increased, the cooling device is tightly attached to the storage batteries, the phenomenon that the storage batteries are stressed to shake can be avoided, and the use stability of the storage batteries is ensured.

2. The electric push rod adopted by the spliced heat dissipation structure for the storage battery of the alternating current-direct current power supply system drives the connecting column and the extrusion mechanism to extrude the cooling liquid through the connecting block, so that the recycling of the cooling liquid is realized, the cooling liquid can be ensured to continuously dissipate heat of the storage battery, and the heat dissipation effect of the storage battery is improved.

3. The spliced heat dissipation structure for the storage battery of the alternating current-direct current power supply system provided by the invention adopts the plurality of cooling devices to commonly dissipate heat of the surface of the storage battery, and each cooling device only circularly cools the corresponding area, so that the phenomenon of high temperature caused by excessive flowing of cooling liquid through the area is avoided, and the heat dissipation effect of the surface of the storage battery is improved.

4. The cooling device and the exhaust device adopted by the spliced heat dissipation structure for the storage battery of the alternating current-direct current power supply system are matched, and the storage battery can be subjected to heat dissipation treatment from the upper end and the side edge, so that the multi-directional heat dissipation of the storage battery is realized, and the heat dissipation effect of the storage battery is improved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

Fig. 1 is a perspective view of the present invention from a first perspective.

Fig. 2 is a schematic perspective view of a second perspective view of the present invention.

Fig. 3 is a front view of the present invention.

Fig. 4 is a top view of the present invention.

Fig. 5 isbase:Sub>A cross-sectional viewbase:Sub>A-base:Sub>A of fig. 3 of the present invention.

Fig. 6 is a cross-sectional view of B-B of fig. 4 in accordance with the present invention.

Fig. 7 is an enlarged view of the invention at X in fig. 6.

Fig. 8 is a schematic structural sectional view of the supporting device of the present invention.

Fig. 9 is a schematic sectional view of a first perspective structure of the cooling device of the present invention.

Fig. 10 is a schematic sectional view of a second perspective structure of the cooling device of the present invention.

In the figure: 1. a support device; 11. a rectangular frame; 12. a first recess groove; 13. a first connector; 14. a first bar-shaped connecting pipe; 2. a placement device; 21. a guide frame; 22. a rectangular travel bar; 23. placing a rod; 24. positioning a rod; 3. a cooling device; 31. a strip plate; 311. a second recess groove; 312. a second connector; 313. a second strip-shaped connecting pipe; 32. a partition plate; 321. a first cover plate; 322. a second cover plate; 33. a heat conducting plate; 34. an extrusion mechanism; 341. a slide bar; 342. pushing the extrusion plate; 343. rotating the cover plate; 344. a regulating block; 4. an exhaust device; 41. a box cover plate; 42. a magnetic strip; 43. covering the film; 44. a wind-up roll; 45. a heat dissipation fan; 5. an electric push rod; 6. connecting blocks; 7. a water injection pipe; 71. a plugging cover; 8. connecting columns.

Detailed Description

The embodiments of the invention will be described in detail below with reference to the drawings, but the invention can be implemented in many different ways as defined and covered by the claims.

Referring to fig. 1-4, a splicing type heat dissipation structure for a storage battery of an alternating current-direct current power supply system comprises four supporting devices 1 which are uniformly distributed in a rectangular shape and are placed on the upper end of the ground, a placing device 2 used for placing the storage battery is installed between every two adjacent supporting devices 1, a plurality of cooling devices 3 used for cooling the storage battery are spliced between every two adjacent supporting devices 1, and an exhaust device 4 is placed at the upper end of each cooling device 3.

Referring to fig. 1 and 8, the supporting device 1 includes a rectangular frame 11 having a fluid containing cavity therein.

Referring to fig. 1 and 3, circular grooves are formed in the upper ends of two rectangular frames 11 located on one diagonal line, electric push rods 5 are installed in the circular grooves, connecting blocks 6 are installed at the upper ends of the electric push rods 5, inserting grooves are formed in two adjacent end faces, close to the cooling device 3, of the connecting blocks 6, water injection pipes 7 are installed at the upper ends of the rectangular frames 11 located on the other diagonal line, and blocking covers 71 are connected to the water injection pipes 7 through threads.

Referring to fig. 2, 5 and 9, cooling device 3 includes inside bar plate 31 that is provided with the cooling cavity, install the division board 32 that is used for separating the cooling cavity for two big or small cavities in the cooling cavity, two circular through-holes have been seted up to division board 32 upper and lower symmetry, bar plate 31 is close to the one end at rectangle distribution center and installs the heat-conducting plate 33 that is the T type, the last heat-conducting sticker that pastes of heat-conducting plate 33, the cooling tank has been seted up to the one end that heat-conducting plate 33 is close to the cooling cavity, bar plate 31 upper wall slip through connection has extrusion mechanism 34, lie in a plurality of with one side wear to be equipped with spliced pole 8 jointly on the extrusion mechanism 34, spliced pole 8 and the inserting groove grafting cooperation on the connecting block 6, spliced pole 8 is formed by a plurality of threaded connection pole screw thread splice.

Referring to fig. 5 and 8, a first concave groove 12 is formed in one end of the rectangular frame 11 close to the strip-shaped plate 31 on one side, a first connecting joint 13 is installed in the first concave groove 12, and a first strip-shaped connecting pipe 14 is installed in one end of the rectangular frame 11 close to the strip-shaped plate 31 on the other side.

Referring to fig. 6, the placing device 2 includes and installs guide frame 21 on the rectangular frame 11, a plurality of evenly distributed's grafting through-hole has transversely been seted up to the frame wall that guide frame 21 is close to rectangular distribution center, the one end sliding connection that rectangular frame 11 was kept away from to guide frame 21 has a rectangular movable rod 22, the one end and another rectangular frame 11 fixed connection that guide frame 21 was kept away from to rectangular movable rod 22, the one end that rectangular movable rod 22 is close to rectangular distribution center is kept away from guide frame 21 and is installed and place pole 23, it has locating lever 24 to peg graft in the arbitrary grafting through-hole on the guide frame 21, locating lever 24 and rectangular movable rod 22 are pegged graft and are cooperated.

Referring to fig. 1 and 6, in a specific operation, according to the size of the battery to be cooled, the guide frame 21 and the rectangular moving rod 22 are manually adjusted in a sliding manner, and the rectangular moving rod 22 slides in the guide frame 21, so that the distance between two adjacent rectangular frames 11 is adjusted, and the storage battery with a corresponding size is conveniently placed.

Referring to fig. 9, the one end that the strip shaped plate 31 is close to arbitrary one side rectangle frame 11 has seted up second depressed groove 311, installs second connector 312 in the second depressed groove 311, and the one end that the strip shaped plate 31 kept away from second depressed groove 311 installs second bar connecting pipe 313, adjacent two peg graft the cooperation through second bar connecting pipe 313 and second depressed groove 311 and second connector 312 between the strip shaped plate 31, lie in with one side and be close to the cooperation of pegging graft of strip shaped plate 31 of rectangle frame 11 through second depressed groove 311 and second connector 312 and first bar connecting pipe 14 is located with one side and be close to another the cooperation of pegging graft of strip shaped plate 31 of rectangle frame 11 through second bar connecting pipe 313 and first depressed groove 12 and first connector 13.

Referring to fig. 1, 5, 6, 8 and 9, in operation, according to the size of the battery to be cooled, a plurality of strip-shaped plates 31 are manually selected, and then the second strip-shaped connecting pipe 313 on one strip-shaped plate 31 is inserted into the second concave groove 311 on another strip-shaped plate 31, at this time, the second connecting head 312 is located in the second strip-shaped connecting pipe 313, thereby realizing the function of splicing and communicating two strip-shaped plates 31, repeating the previous steps, splicing the selected plurality of strip-shaped plates 31 into four strip-shaped plate link plates with the length matched with the size of the storage battery, splicing and matching the second concave groove 311 on the strip-shaped plate 31 at one end of the strip-shaped plate link plate with the first strip-shaped connecting pipe 14 on the corresponding rectangular frame 11, splicing and matching the second strip-shaped connecting pipe 313 on the strip-shaped plate 31 at the other end of the strip-shaped plate link plate with the first concave groove 12 on the other corresponding rectangular frame 11, thereby splicing the strip-shaped plate link plates between the two rectangular frames 11, repeating the previous steps, splicing the four strip-shaped plate link plates on the four rectangular frames 11, thereby forming a cooling space for cooling the storage battery, the cooling space being matched with the size of the storage battery, and then inserting the positioning rods 24 into the corresponding insertion through holes of the guide frame 21, and then into the rectangular moving rod 22, thereby limiting two adjacent rectangular frames 11, ensuring the firmness of the connection of the strip-shaped plate chain plates and the rectangular frames 11, splicing a plurality of strip-shaped plates 31, being capable of being tightly attached to storage batteries with different sizes, thereby improved the flexibility of equipment usage, the manual work splices into four spliced poles 8 with the threaded connection pole screw thread of corresponding quantity, again with four spliced poles 8 respectively pass with a plurality of extrusion mechanisms 34 of one side and with the inserting groove grafting cooperation on the connecting block 6, make things convenient for electric putter 5 to drive a plurality of extrusion mechanisms 34 and remove simultaneously through connecting block 6 and spliced pole 8.

Referring to fig. 6 and 7, exhaust apparatus 4 is including evenly placing a plurality of box cover plate 41 of bar shaped plate 31 upper end, magnetic stripe 42 is all installed to box cover plate 41 lower extreme four sides department, magnetic stripe 42 and bar shaped plate 31 magnetism inhale the cooperation, be provided with between two adjacent box cover plate 41 and cover film 43, cover film 43 and control both ends and all rotate and be connected with wind-up roll 44, wind-up roll 44 passes through the torsional spring and is connected with box cover plate 41 rotation, it has heat dissipation fan 45 to be located 41 mid-mounting of box cover plate in the middle of, it has seted up two through-holes to be located the symmetry around on the box cover plate 41 in the middle of.

Referring to fig. 5-7, in specific operation, after the assembly of the strip link plate and the rectangular frame 11, the storage battery is manually placed in the cooling space, the storage battery is supported by the placing rod 23 and the positioning rod 24, the heat conducting sticker on the heat conducting plate 33 is attached to the surface of the storage battery, the box cover plates 41 with matched sizes are selected according to the size of the storage battery, the distance between the box cover plates 41 is adjusted, two adjacent box cover plates 41 are connected by the cover film 43, when the distance between the two box cover plates 41 is adjusted, the cover film 43 is unreeled and reeled by the reeling roller 44, then the box cover plates 41 with adjusted distances are placed above the strip plates 31, the magnetic strips 42 on the box cover plates 41 are adsorbed on the strip plates 31, so that the box cover plates 41 are fixed on the strip plates 31, two penetrating holes on the box cover plate 41 at the middle are sleeved on the electrode posts of the storage battery, and the position of the box cover plates 41 is further limited.

Referring to fig. 9 and 10, the extruding mechanism 34 includes a sliding rod 341 slidably connected to the upper wall of the strip-shaped plate 31, a pushing plate 342 is installed at the lower end of the sliding rod 341, the pushing plate 342 is located in a large chamber of the partition plate 32 far away from the heat conducting plate 33, two water passing through holes are symmetrically formed in the pushing plate 342, a rotary cover plate 343 is arranged below the water passing through holes, the rotary cover plate 343 is rotatably connected with the pushing plate 342 through a torsion spring, an adjusting block 344 is installed at the upper end of the sliding rod 341, and a connecting circular hole for penetrating the connecting column 8 is formed in the middle of the adjusting block 344.

Referring to fig. 10, a first cover plate 321 is disposed on a side of the circular through hole on the lower side of the partition plate 32 close to the heat conducting plate 33, the first cover plate 321 is rotatably connected to the partition plate 32 by a torsion spring, a second cover plate 322 is disposed on a side of the circular through hole on the upper side of the partition plate 32 far from the heat conducting plate 33, and the second cover plate 322 is rotatably connected to the partition plate 32 by a torsion spring.

Referring to fig. 1, 7, 8, 9 and 10, in specific operation, the plugging cover 71 on one side is manually taken down from the water injection pipe 7, and then the cooling liquid is injected into the liquid containing cavity of the rectangular frame 11 through the existing pump body, one end of the liquid containing cavity of the rectangular frame 11 is communicated with the second connector 312 on the strip-shaped plate 31 through the first strip-shaped connecting pipe 14, the other end of the liquid containing cavity of the rectangular frame 11 is communicated with the second strip-shaped connecting pipe 313 on the strip-shaped plate 31 through the first connector 13, the adjacent strip-shaped plate 31 is communicated with the second strip-shaped connecting pipe 313 through the second connector 312, so that the four rectangular frames 11 are communicated with the four strip-shaped plate chain plates, the cooling liquid is gradually injected into the four liquid containing cavities and the plurality of cooling cavities, then the pump body is closed, and then the plugging cover 71 is connected to the water injection pipe 7, when the storage battery is used, the heat conducting plate 33 and the heat conducting paster on the heat conducting plate 33 guide the heat generated by the storage battery to the cooling liquid in the cooling cavity, the cooling liquid guides the heat into the cooling liquid, thereby realizing the function of cooling the storage battery, two electric push rods 5 are started simultaneously, the two electric push rods 5 drive four connecting posts 8 to reciprocate up and down through two connecting blocks 6, the connecting posts 8 drive a plurality of adjusting blocks 344 on the same side to move up and down, the adjusting blocks 344 drive a pushing plate 342 to reciprocate up and down through a sliding rod 341, when the pushing plate 342 moves down, the pushing plate 342 pushes the cooling liquid, the cooling liquid pushes a first cover plate 321 on the lower side of the partition plate 32, the first cover plate 321 is rotated by force and opens a circular through hole on the lower side, the cooling liquid in the large cavity moves into the small cavity, and the cooling liquid used in the small cavity pushes a second cover plate 322 on the upper side of the partition plate 32 by the extrusion, the second cover plate 322 is rotated by force and opens the upper circular through hole, the coolant used in the small cavity enters the large cavity through the upper circular through hole, the pushing plate 342 moves downwards and is static, the second cover plate 322 and the first cover plate 321 reset through the torsion spring and seal the two circular through holes, then the sliding rod 341 drives the pushing plate 342 to move upwards, the rotating cover plate 343 at the lower end of the pushing plate 342 is pushed by the coolant to rotate, so that the water through hole is opened, the pushing plate 342 moves upwards conveniently, the used coolant moved to the large cavity is naturally cooled, the unused coolant moved to the small cavity is contacted with the cooling groove on the heat conducting plate 33 and cools the storage battery, the pushing plate 342 reciprocating up and down can realize the recycling of the coolant, the cooling effect of the coolant is improved, the cooling effect of the cooling structure is improved, the cooling fan 45 is started while the storage battery is used, and the cooling fan 45 carries out heat dissipation on the upper end of the storage battery, thereby realizing the heat dissipation of the storage battery in multiple directions, and improving the heat dissipation effect of the storage battery.

When in use: s1: according to the size of the battery to be cooled, the guide frame 21 and the rectangular moving rod 22 are slidably adjusted, and the rectangular moving rod 22 slides in the guide frame 21, so that the distance between the two adjacent rectangular frames 11 is adjusted.

S2: artificially selecting a plurality of strip-shaped plates 31, inserting a second strip-shaped connecting pipe 313 on one strip-shaped plate 31 into a second concave groove 311 on another strip-shaped plate 31, wherein a second connector 312 is positioned in the second strip-shaped connecting pipe 313, thereby realizing the splicing and communicating functions of the two strip-shaped plates 31, repeating the previous steps, splicing the selected plurality of strip-shaped plates 31 into four strip-shaped plate link plates with the length matched with the size of the storage battery, splicing and matching the second concave groove 311 on the strip-shaped plate 31 at one end of each strip-shaped plate link plate with a first strip-shaped connecting pipe 14 on a corresponding rectangular frame 11, splicing and matching a second strip-shaped connecting pipe 313 on the strip-shaped plate 31 at the other end of each strip-shaped plate link plate with a first concave groove 12 on another corresponding rectangular frame 11, thereby splicing the strip-shaped plate link plates between the two rectangular frames 11, repeating the previous steps, splicing the four strip-shaped plate link plates on the four rectangular frames 11, thereby forming a cooling space for cooling the storage battery.

S3: place the battery in the cooling space, place pole 23 and locating lever 24 and support the battery, heat conduction sticker on the heat-conducting plate 33 is hugged closely with the battery surface, adjust the interval between a plurality of box cover boards 41 afterwards, two adjacent box cover boards 41 are connected through covering membrane 43, place a plurality of box cover boards 41 after the roll adjustment in a plurality of bar boards 31 tops, magnetic stripe 42 on the box cover board 41 adsorbs on bar board 31, thereby fix box cover board 41 on bar board 31.

S4: the plugging cover 71 on one side is taken down from the water injection pipe 7, then the cooling liquid is injected into the liquid placing cavities of the rectangular frame 11 through the existing pump body, the cooling liquid is gradually injected into the four liquid placing cavities and the plurality of cooling cavities, then the pump body is closed, the plugging cover 71 is connected onto the water injection pipe 7, when the storage battery is used, the heat conducting paster on the heat conducting plate 33 guides the temperature generated by the storage battery into the cooling liquid of the cooling cavities, the cooling liquid guides the heat into the cooling liquid, thereby realizing the function of cooling the storage battery, the two electric push rods 5 are simultaneously started, the two electric push rods 5 drive the four connecting columns 8 to reciprocate up and down through the two connecting blocks 6, the connecting columns 8 drive the plurality of adjusting blocks 344 on the same side to move up and down, the adjusting blocks 344 drive the pushing plate 342 to reciprocate up and down through the sliding rods 341, when the pushing plate 342 moves down, the pushing plate 342 pushes the cooling liquid, the pushing plate 342 which reciprocates up and down can realize the recycling of the cooling liquid, the cooling effect of the cooling liquid is improved, the heat dissipation effect of the storage battery heat dissipation structure is improved, when the storage battery is used, the heat dissipation fan 45 is started, and the heat dissipation fan 45 is further improved.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (8)

1. The utility model provides an AC/DC power supply system battery is with concatenation formula heat radiation structure which characterized in that: the storage battery cooling device comprises four supporting devices (1) which are uniformly distributed on the upper end of the ground in a rectangular shape, a placing device (2) for placing a storage battery is arranged between every two adjacent supporting devices (1), a plurality of cooling devices (3) for cooling the storage battery are spliced between every two adjacent supporting devices (1), and an exhaust device (4) is placed at the upper end of each cooling device (3); wherein:

the supporting device (1) comprises a rectangular frame (11) with a liquid containing cavity arranged inside;

the upper ends of two rectangular frames (11) positioned on one diagonal line are provided with circular grooves, electric push rods (5) are arranged in the circular grooves, the upper ends of the electric push rods (5) are provided with connecting blocks (6), two adjacent end surfaces, close to the cooling device (3), on the connecting blocks (6) are provided with inserting grooves, the upper ends of two rectangular frames (11) positioned on the other diagonal line are provided with water injection pipes (7), and the water injection pipes (7) are in threaded connection with plugging covers (71);

the cooling device (3) comprises a strip-shaped plate (31) with a cooling cavity arranged inside, a partition plate (32) used for dividing the cooling cavity into a large cavity and a small cavity is arranged in the cooling cavity, two circular through holes are symmetrically formed in the partition plate (32) from top to bottom, a T-shaped heat conducting plate (33) is arranged at one end, close to a rectangular distribution center, of the strip-shaped plate (31), and an extrusion mechanism (34) is connected to the upper wall of the strip-shaped plate (31) in a sliding penetrating mode;

a plurality of squeezing mechanisms (34) positioned on the same side are provided with connecting columns (8) in a penetrating way, and the connecting columns (8) are matched with the inserting grooves on the connecting block (6) in an inserting way;

splice into four strip shaped plate link joints that length and battery size match with a plurality of strip shaped plates (31) of choosing, splice the strip shaped plate link joint between two rectangle frames (11), repeat preceding step, splice four strip shaped plate link joints on four rectangle frames (11) to form a cooling space that is used for cooling off the battery, place the battery in the cooling space.

2. The spliced heat dissipation structure for the storage battery of the alternating-current and direct-current power supply system according to claim 1, is characterized in that: first depressed groove (12) have been seted up to the one end that rectangle frame (11) are close to one side bar (31), install first connector (13) in first depressed groove (12), and rectangle frame (11) are close to the one end of opposite side bar (31) and install first bar connecting pipe (14).

3. The spliced heat dissipation structure for the storage battery of the alternating-current and direct-current power supply system according to claim 2, is characterized in that: second depressed groove (311) have been seted up to one end that strip shaped plate (31) are close to arbitrary one side rectangle frame (11), install second connector (312) in second depressed groove (311), and strip shaped plate (31) are kept away from the one end of second depressed groove (311) and are installed second bar connecting pipe (313), adjacent two through second bar connecting pipe (313) and second depressed groove (311) and second connector (312) cooperation of pegging graft between strip shaped plate (31), lie in same one side and be close to strip shaped plate (31) of rectangle frame (11) are through second depressed groove (311) and second connector (312) and first bar connecting pipe (14) cooperation of pegging graft, lie in same one side and be close to another strip shaped plate (31) of rectangle frame (11) are through second bar connecting pipe (313) and first depressed groove (12) and first connector (13) cooperation of pegging graft.

4. The spliced heat dissipation structure for the storage battery of the alternating-current and direct-current power supply system according to claim 1, characterized in that: extrusion mechanism (34) are including sliding through connection in slide bar (341) of strip shaped plate (31) upper wall, slide bar (341) lower extreme is installed and is pushed crowded board (342), it is located division board (32) and keeps away from the big cavity of heat-conducting plate (33) to push crowded board (342), it has seted up two and has crossed the water through-hole to push crowded board (342) to go up the symmetry, it is provided with rotatory apron (343) to cross water through-hole below, rotatory apron (343) rotate with pushing crowded board (342) through the torsional spring and be connected, regulating block (344) are installed to slide bar (341) upper end, regulating block (344) middle part is seted up and is used for wearing to establish the connection round hole of spliced pole (8).

5. The spliced heat dissipation structure for the storage battery of the alternating-current and direct-current power supply system according to claim 1, is characterized in that: the connecting column (8) is formed by splicing a plurality of threaded connecting rods in a threaded manner.

6. The spliced heat dissipation structure for the storage battery of the alternating-current and direct-current power supply system according to claim 1, is characterized in that: one side of the round through hole on the lower side of the partition plate (32) close to the heat conducting plate (33) is provided with a first cover plate (321), the first cover plate (321) is rotatably connected with the partition plate (32) through a torsion spring, one side of the round through hole on the upper side of the partition plate (32) far away from the heat conducting plate (33) is provided with a second cover plate (322), and the second cover plate (322) is rotatably connected with the partition plate (32) through the torsion spring.

7. The spliced heat dissipation structure for the storage battery of the alternating-current and direct-current power supply system according to claim 1, is characterized in that: placer (2) are including installing guide frame (21) on rectangle frame (11), a plurality of evenly distributed's grafting through-hole has transversely been seted up to guide frame (21) frame wall that is close to rectangle distribution center, the one end sliding connection that rectangle frame (11) were kept away from in guide frame (21) has rectangle carriage release lever (22), the one end and another rectangle frame (11) fixed connection that guide frame (21) were kept away from in rectangle carriage release lever (22), rectangle carriage release lever (22) are kept away from the one end at rectangle distribution center and locate to install and place pole (23), it has locating lever (24) to peg graft in the arbitrary grafting through-hole on guide frame (21), locating lever (24) and rectangle carriage release lever (22) cooperation of pegging graft.

8. The spliced heat dissipation structure for the storage battery of the alternating-current and direct-current power supply system according to claim 1, is characterized in that: exhaust apparatus (4) are including evenly placing a plurality ofly a plurality of box cover boards (41) of bar board (31) upper end, magnetic stripe (42) are all installed to box cover board (41) lower extreme four sides department, the cooperation is inhaled with bar board (31) magnetism in magnetic stripe (42), be provided with between two adjacent box cover boards (41) and cover membrane (43), it all rotates at both ends and is connected with wind-up roll (44) to cover membrane (43) left and right sides, wind-up roll (44) rotate with box cover board (41) through the torsional spring and are connected, it has heat dissipation fan (45) to be located box cover board (41) mid-mounting in the middle of, it has seted up two through-going holes to be located symmetry around on box cover board (41) in the middle of.

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