CN116782546A - Energy storage contravariant all-in-one - Google Patents

Abstract

The application relates to the technical field of energy storage, in particular to an energy storage inversion integrated machine, which comprises a machine shell, an inverter and a plurality of batteries, wherein a first installation station for installing the inverter is arranged above the machine shell, the inverter is fixedly installed at the first installation station, a plurality of second installation stations for installing the batteries are arranged below the machine shell, a wire connector is arranged at one side of the machine shell, and the inverter and the batteries are connected to the wire connector: and the convenience of assembling the energy storage product is improved.

Description

Energy storage contravariant all-in-one

Technical Field

The application relates to the technical field of energy storage, in particular to an energy storage inversion integrated machine.

Background

The development of energy storage technology has become the focus of global attention and support in the current power and new energy fields, energy storage is to store electric energy when the generated power of renewable energy sources is larger than that of loads, and to provide replenishment of electric energy when they cannot meet the load demands, and to collect and utilize renewable energy sources with maximum efficiency, which is necessary for renewable energy distributed power generation systems, and is the basis for establishing stable local power supply. Many countries have located energy storage technologies as strategic technologies that support the development of new energy sources. Energy storage technology is a technology which can bring about revolutionary changes to the development and operation of future energy systems, and among a plurality of energy storage technologies, electrochemical energy storage technology is the fastest technology. Compared with other modes, the electrochemical energy storage has the advantages of convenient use, less environmental pollution, no limitation of regions, no limitation of other circulation in energy conversion, high conversion efficiency, high specific energy, high specific power and the like.

The energy storage type product is not uniform in appearance because the components come from different factories, so that the energy storage type product needs to be debugged and adapted in the assembly process, and the electric quantity of the product is usually fixed, so that the energy storage type product has no selectivity and cannot be flexibly adjusted, and the problems are to be solved.

Disclosure of Invention

In order to improve the assembly convenience of energy storage products, the application provides an energy storage inversion integrated machine, which adopts the following technical scheme:

the utility model provides an energy storage contravariant all-in-one, includes casing, dc-to-ac converter and a plurality of battery, the top in the casing is provided with the first installation station that is used for installing the dc-to-ac converter, dc-to-ac converter fixed mounting is in first installation station, the below in the casing is provided with the second installation station that a plurality of is used for installing the battery, one side of casing is provided with the connector, dc-to-ac converter and battery all are connected in the connector.

Through adopting above-mentioned scheme, the dc-to-ac converter is installed in first installation station to integrate in the casing, the operator is through the electric quantity that needs the adaptation, installs the battery in the second installation station, makes dc-to-ac converter and battery can match the installation of casing inside the casing, reduces the debugging and the adaptation operation of battery and dc-to-ac converter, and battery and dc-to-ac converter rethread connector are connected, and can electric connection external equipment, reach the effect that promotes the equipment convenience of energy storage product.

Preferably, the second installation stations are all provided with telescopic accommodating components, the machine shell is provided with guide grooves for guiding the telescopic accommodating components, and the telescopic accommodating components are installed in the guide grooves.

Through adopting above-mentioned scheme, flexible subassembly of putting is used for installing the battery that corresponds, and flexible subassembly of putting stretches out and has placed the battery after, and the operating personnel is with flexible subassembly of putting push into to the second installation station along the guide way in to play the effect of being convenient for place the installation battery, reach the equipment convenience that promotes the energy storage product.

Preferably, the telescopic accommodating assembly comprises a sliding bearing piece and a spring piece, the sliding bearing piece is slidably connected to the guide groove, one end of the spring piece is fixedly connected to one side in the casing, and the other end of the spring piece is fixedly connected to one side of the sliding bearing piece.

Through adopting above-mentioned scheme, the bearing piece that slides is used for placing the battery, and the battery is placed and is realized the location of horizontal direction at the bearing piece that slides, and the battery is placed steadily back, and the operator presses the bearing piece that slides, makes the bearing piece that slides overcome the elasticity of spring part, removes along the guide way, until the bearing piece card that slides in the second installation station, reaches the process that reduces the installation battery, makes the simple and convenient effect of the installation step of energy storage contravariant all-in-one.

Preferably, the casing is provided with upset and keeps out the board and be used for dodging the position groove that keeps out of the board that keeps out of the way that the upset kept out of the way, the upset keeps out the board and rotates to be connected in keeping away from one side of spring part in the position groove, the upset keeps out the board and is used for the butt to inject the position of sliding bearing piece.

Through adopting above-mentioned scheme, when the bearing piece stretches out outside the second installation station that slides, the bearing piece that slides covers the surface of keeping out the board at the upset for the board is kept out to the upset rotates to keeping away the position inslot, and the battery is placed to the operating personnel this moment in the bearing piece that slides, and will slide the bearing piece and press to in the second installation station, the bearing piece that slides does not cover at the upset surface of keeping out the board this moment, the upset keeps out the board and stands up to reset, the spring piece makes the bearing piece butt that slides in one side of the board is kept out to the upset makes the bearing piece that slides spacing in the second installation station, reaches convenient effect of fixed battery in the second installation station.

Preferably, the second installation station is further provided with a limiting component, the sliding bearing piece is connected to the limiting component, one side of the shell is provided with a limiting installation portion for placing the limiting component, and the limiting component is installed on the limiting installation portion.

Through adopting above-mentioned scheme, spacing installation department is used for the installation to place spacing subassembly, and spacing subassembly is used for restricting the vertical direction of battery for place the battery of putting the subassembly in flexible production vertical direction's rocking, reach the effect of firm installation battery.

Preferably, the spacing subassembly includes first positioning rack, second positioning rack, first gear, second gear and lift limiting plate, the one end fixed connection of first positioning rack is in the support piece that slides, the spring cover is located first positioning rack, the other end of first positioning rack runs through spacing installation department, just first positioning rack is located spacing installation department, first gear and second gear all rotate and connect in spacing installation department, first positioning rack meshing is in first gear, second positioning rack slides and is connected in spacing installation department, second positioning rack meshing is in first gear and second gear, the lift limiting plate slides and is connected in spacing installation department, the one end meshing of lift limiting plate is in second gear, the other end of lift limiting plate is located the top of support piece that slides.

Through adopting above-mentioned scheme, when the bearing piece slides to the inside of second installation station that slides, first positioning rack inserts in spacing installation department, drives first gear piece and rotates, and first gear piece rotates and drives the second positioning rack and move down to drive the second gear piece and rotate, the second gear piece rotates and makes the lift limiting plate move down gradually, until moving to the height that limits battery vertical direction position, makes the height that removes the bearing piece and adjusts the lift limiting plate that slides, reaches the effect that reduces the debugging process and can stabilize the battery position.

Preferably, the casing is provided with side baffles for limiting the position of the battery, and the side baffles are fixedly arranged on two sides below the inside of the casing.

Through adopting above-mentioned scheme, the side shield is used for leading the bearing piece that slides to make the battery more steady press and carry to in the second installation station, reach the effect of more steady installation battery.

Preferably, the first installation station is provided with mount and support, the mount is located the both sides of first installation station, the support is located the bottom of first installation station, the dc-to-ac converter is placed in the support, the both sides fixed connection of dc-to-ac converter is in the mount.

Through adopting above-mentioned scheme, the support is used for initially placing the installation dc-to-ac converter, makes the mount is aimed at to the installation position of dc-to-ac converter both sides, again with dc-to-ac converter fixed mounting in the mount, the operating personnel of being convenient for installs the battery of appointed model in to the casing according to the specification of dc-to-ac converter, reaches the effect of promoting the equipment convenience of energy storage product.

Preferably, a heat dissipation hole is formed in one side of the casing, and the heat dissipation hole is formed in one side of the inverter.

Through adopting above-mentioned scheme, the in-process of dc-to-ac converter work dispels the heat through the louvre to promote energy storage contravariant all-in-one's working property.

Preferably, the casing is provided with a plurality of guide wheels.

Through adopting above-mentioned scheme, the leading wheel makes the casing be convenient for adjust the direction, at the in-process of dc-to-ac converter and battery installation, the direction of the casing of being convenient for shifts, and makes energy storage contravariant all-in-one use more convenient, reaches the effect that promotes the convenience of use of energy storage contravariant all-in-one.

In summary, the present application includes at least one of the following beneficial technical effects:

the casing is used for integrating the dc-to-ac converter and battery as an organic whole, and the dc-to-ac converter is installed at first installation station, and the battery is installed in the second installation station according to the specification of dc-to-ac converter and required electric quantity size for inside installing in the casing that dc-to-ac converter and battery homoenergetic match the casing specification, reduce the debugging and the adaptation operation of battery and dc-to-ac converter, battery and dc-to-ac converter rethread connector are connected, and can electric connection external equipment, reach the effect that promotes the equipment convenience of energy storage product.

Drawings

Fig. 1 is a schematic structural diagram of an energy storage inversion integrated machine according to an embodiment of the application.

Fig. 2 is a schematic diagram of an internal structure of an energy storage inversion integrated machine according to an embodiment of the application.

Fig. 3 is a schematic side perspective view of a second installation station according to an embodiment of the present application.

Reference numerals illustrate: 1. a housing; 11. a first mounting station; 111. a fixing frame; 112. a bracket; 12. a second mounting station; 13. a wire connector; 14. a telescoping assembly; 141. a sliding support; 142. a spring member; 15. a guide groove; 16. turning over the abutting plate; 17. a clearance groove; 18. a limit component; 181. a first positioning rack; 182. a second positioning rack; 183. a first gear member; 184. a second gear member; 185. lifting the limiting plate; 19. a limit mounting part; 110. side baffles; 2. an inverter; 3. a battery; 4. a heat radiation hole; 5. and a guide wheel.

Detailed Description

The application is described in further detail below with reference to fig. 1-3.

The embodiment of the application discloses an energy storage inversion integrated machine, which comprises a machine shell 1, wherein the machine shell 1 is provided with a first installation station 11 and a plurality of second installation stations 12, the first installation station 11 is positioned above the machine shell 1, the first installation station 11 is provided with an inverter 2, and the inverter 2 is fixedly installed at the first installation station 11. The second mounting station 12 is located below within the cabinet 1, and the second mounting station 12 is below the first mounting station 11. The second installation station 12 is provided with the battery 3, and the battery 3 can be fast dismantled and assembled install in the second installation station 12 for the installation of casing 1 is inside in the casing 1 can be matchd to dc-to-ac converter 2 and battery 3, reduces the debugging and the adaptation operation of battery 3 and dc-to-ac converter 2. A connector 13 is provided at one side of the casing 1, and the inverter 2 and the battery 3 are both connected to the connector 13, so that the inverter 2 and the battery 3 can be electrically connected to external devices. Reducing the debugging and adaptation of the battery 3 and the inverter 2 can promote the convenience of assembly of the energy storage product.

Specifically, one side of the casing 1 is a detachable shielding plate, and is fixed on one side of an opening of the casing 1 through a screw, so that an operator can conveniently carry out loading and unloading operations on the first installation station 11 and the second installation station 12 through one side of the opening of the casing 1. The second mounting stations 12 include, but are not limited to, four and two rows of placements, each row being provided with two second mounting stations 12.

The bottom of casing 1 is provided with a plurality of leading wheel 5, and concrete leading wheel 5 is provided with four, and equal fixed mounting of leading wheel 5 is in the bottom of casing 1, and leading wheel 5 makes casing 1 be convenient for adjust the direction, at the in-process of dc-to-ac converter 2 and battery 3 installation, is convenient for shift the direction of casing 1, and makes energy storage contravariant all-in-one more convenient to use.

The first installation station 11 is provided with a fixing frame 111 and a support 112, the fixing frame 111 is located at two sides of the first installation station 11, the support 112 is located at the bottom of the first installation station 11, the support 112 is used for initially placing and installing the inverter 2, and installation positions at two sides of the inverter 2 are aligned with the fixing frame 111. The inverter 2 is placed on the bracket 112, and both sides of the inverter 2 are fixedly connected to the fixing frame 111. The operator of being convenient for installs the battery 3 of appointed model to casing 1 in accordance with the specification of dc-to-ac converter 2, promotes the equipment convenience of energy storage product.

Specifically, the bracket 112 is a supporting plate at the bottom of the inverter 2, specifically is a transverse supporting plate integrally formed by connecting the side walls of the first installation station 11, and is used for supporting the bottom of the inverter 2, so that both hands of an operator can conveniently align screw holes of the inverter 2 with screw holes formed in the fixing frame 111, and then the screw holes are fixed through screws.

A heat dissipation hole 4 is provided at one side of the casing 1, and the heat dissipation hole 4 is located at one side of the inverter 2. In the process of debugging or working, the energy storage inversion integrated machine can generate certain heat, and the heat is discharged out of the shell 1 from the radiating holes 4, so that the working performance of the energy storage inversion integrated machine is improved.

Referring to fig. 2 and 3, each second mounting station 12 is provided with a telescopic assembly 14, the telescopic assembly 14 being used for preliminary positioning of the batteries 3, functioning to mount the batteries 3. The housing 1 is provided with a guide groove 15 for guiding the telescopic accommodating assembly 14, and the telescopic accommodating assembly 14 is mounted to the guide groove 15. After the telescopic accommodating assembly 14 extends out and the battery 3 is placed, the operator pushes the telescopic accommodating assembly 14 into the second mounting station 12 along the guide groove 15, so that the battery 3 is stably mounted inside the second mounting station 12.

Each telescopic accommodating assembly 14 comprises a sliding supporting member 141 and a spring member 142, the sliding supporting member 141 is a quadrangular supporting plate with vertical edges on four sides, and the batteries 3 with corresponding sizes and shapes are placed in the sliding supporting member 141 to perform preliminary position limiting, so that the batteries 3 are not easy to shake. The bottom of the sliding support 141 is provided with a protruding guide such that the sliding support 141 is slidably coupled to the guide groove 15. One end of the spring member 142 is fixedly connected to one side in the casing 1, and the other end of the spring member 142 is fixedly connected to one side of the sliding support member 141.

Specifically, when the battery 3 needs to be installed, the battery 3 is placed on the sliding support member 141, and after the battery 3 is placed stably, the operator presses the sliding support member 141 to make the sliding support member 141 overcome the elastic force of the spring member 142, and move along the guide groove 15 until the sliding support member 141 slides to a position where the battery 3 is stable.

The casing 1 is further provided with a turnover withstanding plate 16 and a avoiding groove 17 for avoiding the turnover withstanding plate 16, the turnover withstanding plate 16 is rotatably connected to one side of the avoiding groove 17 far away from the spring member 142, and the turnover withstanding plate 16 is used for abutting against a position for limiting the sliding bearing member 141, so that the sliding bearing member 141 is clamped in the second installation station 12.

Specifically, when the sliding bearing member 141 extends out of the second installation station 12, the sliding bearing member 141 is pressed against the surface of the overturning and resisting plate 16, so that the overturning and resisting plate 16 rotates into the avoidance groove 17, at this time, the operator places the battery 3 in the sliding bearing member 141, presses the sliding bearing member 141 into the second installation station 12, the sliding bearing member 141 is not pressed against the surface of the overturning and resisting plate 16 at this time, the overturning and resisting plate 16 stands up and returns, the spring member 142 enables the sliding bearing member 141 to abut against one side of the overturning and resisting plate 16, and therefore the overturning and resisting plate 16 enables the sliding bearing member 141 to be limited in the second installation station 12. When the battery 3 needs to be taken out, the overturning and resisting plate 16 is abutted to one side of the sliding bearing member 141, an operator presses the overturning and resisting plate 16, and at the moment, the overturning and resisting plate 16 is abutted to one side of the sliding bearing member 141, so that the elasticity of the spring member 142 is overcome, the sliding bearing member 141 moves a small distance towards the second installation station 12 until the overturning and resisting plate 16 completely rotates into the avoidance groove 17, the sliding bearing member 141 loses the force exerted by one side, and the elasticity of the spring member 142 ejects the sliding bearing member 141 out of the second installation station 12, so that the operator can conveniently detach the battery 3.

Wherein, the torsion spring is installed to the side of the turnover abutment plate 16 rotatably connected to the space avoiding groove 17, so that the turnover abutment plate 16 maintains an erect state without external force.

The casing 1 is provided with side baffles 110 for limiting the position of the battery 3, the side baffles 110 are fixedly arranged on two sides below in the casing 1, and the side baffles 110 are used for guiding the sliding bearing member 141 so as to enable the battery 3 to be pressed and conveyed into the second installation station 12 more stably.

The second installation station 12 is further provided with a limiting assembly 18, the limiting assembly 18 is arranged on the limiting installation portion 19 in a mounting mode, the limiting assembly 18 is used for limiting the vertical direction of the battery 3, and the limiting assembly 18 is connected with the sliding bearing member 141, so that the battery 3 placed on the telescopic accommodating assembly 14 is not easy to shake in the vertical direction. One side of the casing 1 is provided with a limit installation part 19 for placing a limit assembly 18, the limit installation part 19 is specifically an installation cavity which is fixedly installed on one side of the casing 1, the limit assembly 18 is installed on the limit installation part 19, and the limit installation part 19 plays a role in storing and installing the limit assembly 18.

The limit assembly 18 includes a first positioning rack 181, a second positioning rack 182, a first gear member 183, a second gear member 184, and a lift limit plate 185. The first positioning rack 181 and the second positioning rack 182 are straight racks, wherein the first positioning rack 181 and the second positioning rack 182 are provided with teeth on one side. The first gear member 183 and the second gear member 184 are formed by combining two gears, and specifically, the middle parts of the two gears are provided with connecting rods for fixedly connecting. One end of the first positioning rack 181 is fixedly connected to the sliding bearing member 141, the spring member 142 is sleeved on the first positioning rack 181, the other end of the first positioning rack 181 penetrates through the limiting mounting portion 19, and the first positioning rack 181 is located on the limiting mounting portion 19. When the sliding support member 141 slides, the spring member 142 is always abutted against the inner sidewall of the casing 1, and the first positioning rack 181 can extend through the inner sidewall of the casing 1 to slide. The first gear member 183 is rotatably connected in the limit mounting portion 19, and one end gear of the first gear member 183 is meshed with the first positioning rack 181, so that the first gear member 183 is driven to rotate in the process of extending and retracting the first positioning rack 181. The second positioning rack 182 is slidably connected in the limiting mounting portion 19, and a collar sleeved in the vertical direction of the second positioning rack 182 is arranged in the specific limiting mounting portion 19, so that the second positioning rack 182 is guided. One end of the second positioning rack 182 is engaged with the other end gear of the first gear member 183, so that the second positioning rack 182 descends when the first positioning rack 181 is inserted into the limit mounting portion 19. The second gear member 184 is rotatably connected in the limit mounting portion 19, the other end of the second positioning rack 182 is meshed with a gear at one end of the second gear member 184, one end of the lifting limiting plate 185 vertically arranged is slidingly connected in the limit mounting portion 19, teeth at one end of the lifting limiting plate 185 vertically arranged are meshed with the second gear member 184, and the other end of the lifting limiting plate 185 is transversely arranged and penetrates through the side wall of the limit mounting portion 19 and is located above the sliding bearing member 141.

Specifically, when the sliding support member 141 slides into the second installation station 12, the first positioning rack 181 is inserted into the limit installation portion 19 to drive the first gear member 183 to rotate, and the first gear member 183 rotates to drive the second positioning rack 182 to move downward, so as to drive the second gear member 184 to rotate, and the second gear member 184 rotates to gradually move the lifting limiting plate 185 downward until the lifting limiting plate 185 moves to a height limiting the vertical position of the battery 3, so that the moving sliding support member 141 adjusts the height of the lifting limiting plate 185. When the sliding support member 141 is ejected to the outside due to the elastic force of the spring member 142 to detach the battery 3, the first positioning rack 181 is pulled to the outside of the casing 1 along with the sliding of the sliding support member 141, the first gear member 183 rotates in opposite directions to drive the second rack to move upwards, and the second rack moves upwards to drive the second gear member 184 to rotate in opposite directions, so that the lifting limiting plate 185 is lifted, and the limitation of the position above the battery 3 is released.

The principle of the embodiment of the application is as follows: the first installation station 11 at casing 1 is installed to the dc-to-ac converter 2, and the second installation station 12 at casing 1 is installed to the dc-to-ac converter 2, and wherein battery 3 is when the installation, and battery 3 is placed at the support piece 141 that slides, presses the support piece 141 that slides to the position that upset kept out the board 16 butt for battery 3 joint is in second installation station 12, and the limit component 18 synchronous carries out the restriction of position to the top of battery 3, makes battery 3 more firm the installation at second installation station 12. When the battery 3 needs to be disassembled or replaced, an operator presses the overturning withstanding plate 16, so that the spring piece 142 ejects the sliding bearing piece 141, and the limiting assembly 18 is lifted synchronously, so that the battery 3 is convenient to disassemble by the operator, and the effect of improving the assembly convenience of the energy storage product is achieved.

The above embodiments are not intended to limit the scope of the present application, so: all equivalent changes in structure, shape and principle of the application should be covered in the scope of protection of the application.

Claims (10)

1. The utility model provides an energy storage contravariant all-in-one, its characterized in that, including casing (1), dc-to-ac converter (2) and a plurality of battery (3), the top in casing (1) is provided with first installation station (11) that are used for installing dc-to-ac converter (2), dc-to-ac converter (2) fixed mounting is in first installation station (11), the below in casing (1) is provided with second installation station (12) that a plurality of is used for installing battery (3), one side of casing (1) is provided with connector (13), dc-to-ac converter (2) and battery (3) all are connected in connector (13).

2. An energy storage inversion integrated machine according to claim 1, wherein the second installation stations (12) are each provided with a telescopic accommodating assembly (14), the casing (1) is provided with a guide groove (15) for guiding the telescopic accommodating assembly (14), and the telescopic accommodating assembly (14) is installed in the guide groove (15).

3. The energy storage inversion integrated machine according to claim 2, wherein the telescopic accommodating assembly (14) comprises a sliding supporting member (141) and a spring member (142), the sliding supporting member (141) is slidably connected to the guide groove (15), one end of the spring member (142) is fixedly connected to one side in the casing (1), and the other end of the spring member (142) is fixedly connected to one side of the sliding supporting member (141).

4. An energy storage inversion integrated machine according to claim 3, characterized in that the casing (1) is provided with a turning abutment plate (16) and a avoidance groove (17) for avoiding the turning abutment plate (16), the turning abutment plate (16) is rotatably connected to a side of the avoidance groove (17) away from the spring member (142), and the turning abutment plate (16) is adapted to abut against a position defining the sliding support member (141).

5. An energy storage inversion all-in-one machine according to claim 3, wherein the second installation station (12) is further provided with a limiting component (18), the sliding bearing (141) is connected to the limiting component (18), one side of the casing (1) is provided with a limiting installation portion (19) for placing the limiting component (18), and the limiting component (18) is installed on the limiting installation portion (19).

6. The energy storage inversion all-in-one machine according to claim 5, wherein the limiting component (18) comprises a first positioning rack (181), a second positioning rack (182), a first gear piece (183), a second gear piece (184) and a lifting limiting plate (185), one end of the first positioning rack (181) is fixedly connected to the sliding bearing piece (141), the spring piece (142) is sleeved on the first positioning rack (181), the other end of the first positioning rack (181) penetrates through the limiting mounting portion (19), the first positioning rack (181) is located at the limiting mounting portion (19), the first gear piece (183) and the second gear piece (184) are both rotationally connected to the limiting mounting portion (19), the first positioning rack (181) is meshed with the first gear piece (183), the second positioning rack (182) is slidingly connected to the limiting mounting portion (19), the second positioning rack (182) is meshed with the first gear piece (185) and the second gear piece (185), the other end of the first positioning rack (184) is meshed with the lifting limiting plate (185), and the lifting limiting plate (184) is meshed with the lifting limiting plate (141).

7. The energy storage and inversion integrated machine according to claim 1, wherein the casing (1) is provided with side baffles (110) for limiting the position of the battery (3), and the side baffles (110) are fixedly installed on two sides below in the casing (1).

8. The energy storage inversion integrated machine according to claim 1, wherein the first installation station (11) is provided with a fixing frame (111) and a support (112), the fixing frame (111) is located at two sides of the first installation station (11), the support (112) is located at the bottom of the first installation station (11), the inverter (2) is placed on the support (112), and two sides of the inverter (2) are fixedly connected to the fixing frame (111).

9. The energy storage inversion integrated machine according to claim 1, wherein a heat dissipation hole (4) is formed in one side of the casing (1), and the heat dissipation hole (4) is located on one side of the inverter (2).

10. An energy storage inversion integrated machine according to claim 1, characterized in that the housing (1) is provided with a number of guide wheels (5).