CN221043565U - Mounting structure of electric power energy storage EMS equipment - Google Patents

Abstract

The utility model provides a mounting structure of electric power energy storage EMS equipment. Relates to the technical field of equipment installation. The utility model provides a mounting structure of electric power energy storage EMS equipment, includes energy storage equipment casing, chamber door and sets up the energy storage subassembly in the energy storage equipment casing, fixed mounting has the mounting bracket on the inner wall of one side of energy storage equipment casing, the energy storage subassembly is close to one side fixed mounting of mounting bracket has two slides, two all seted up the dovetail on the slide, two equal slidable mounting has the forked tail piece in the dovetail, two one side of forked tail piece all with mounting bracket fixed connection, two the buckle groove has all been seted up to one side that the slide kept away from each other, two equal fixed mounting of top and bottom of mounting bracket have two slide. The mounting structure of the electric power energy storage EMS equipment provided by the utility model has the advantages of being capable of being quickly disassembled and assembled, shortening the disassembling and assembling time and being convenient for manual operation.

Description

Mounting structure of electric power energy storage EMS equipment

Technical Field

The utility model relates to the technical field of equipment installation, in particular to an installation structure of electric power energy storage EMS equipment.

Background

The electric charge is a relatively large fee among the production costs of enterprises, and the basic electric charge in the electric charge composition is an important component. How to effectively manage the demand, timely adjust the reporting demand according to the electricity consumption condition of production, and select a reasonable charging mode, thereby saving the basic electricity charge to the maximum extent and being the most concerned problem of enterprise users. At present, demand management combined with energy storage EMS is the most common management mode in the market, and key components of the energy storage EMS system mainly comprise an energy management system, a power supply control system and a battery management system, and the systems are combined into an integral combined algorithm suite, so that in actual use, the combined algorithm suite is installed in a shell of the energy storage EMS, and an independent energy storage EMS device is formed, so that the energy storage EMS device is convenient to carry and use.

However, the whole combined algorithm suite is usually installed in the shell through four corner screws, and the installation mode is more traditional, and the four screws are required to be screwed in sequence for installation or removal, so that time is wasted, the screw position close to the inside of the shell is deeper, space limitation is caused when the screw is screwed by using a screwing tool, and specific disassembly and assembly operations are inconvenient.

Accordingly, there is a need to provide a new installation structure of an electric energy storage EMS device to solve the above technical problems.

Disclosure of utility model

The utility model solves the technical problem of providing the mounting structure of the electric energy storage EMS equipment, which can be quickly disassembled and assembled, shortens the disassembly and assembly time and is convenient for manual operation.

In order to solve the above technical problems, the installation structure of the power energy storage EMS device provided by the present utility model includes: the energy storage device comprises an energy storage device shell, a box door and an energy storage component arranged in the energy storage device shell, wherein an installation frame is fixedly arranged on the inner wall of one side of the energy storage device shell, the energy storage component is close to two sliding strips which are fixedly arranged on one side of the installation frame, dovetail grooves are formed in the sliding strips, dovetail blocks are slidably arranged in the dovetail grooves, one sides of the dovetail blocks are fixedly connected with the installation frame, buckling grooves are formed in one sides, away from each other, of the sliding strips, two sliding columns are fixedly arranged at the top and the bottom of the installation frame, two corresponding sliding plates are slidably arranged on the sliding columns, wedge-shaped clamping blocks are fixedly arranged on one sides, close to each other, of the two wedge-shaped clamping blocks are respectively extended into the buckling grooves, and the wedge-shaped clamping blocks are matched with the buckling grooves.

Preferably, the same connecting plate is fixedly installed on the corresponding two sliding columns, a first spring is fixedly installed on one side, close to each other, of the two connecting plates, and one end, close to each other, of the first springs is fixedly connected with the two linkage plates respectively.

Preferably, the mounting bracket is internally and fixedly provided with a support plate, the two support plates are respectively provided with a tamping rod in a sliding manner, the top and the bottom of the mounting bracket are respectively provided with movable holes, and the two tamping rods are respectively matched with the two movable holes.

Preferably, two equal fixed mounting of one end that the pole is close to each other has the joint block, one side of energy storage equipment casing rotates and installs the pivot, the one end of pivot extends to in the mounting bracket and fixed mounting have the carousel, fixed mounting has two eccentric bars on the carousel, two all rotate on the eccentric bar and install the trace, two the one end that the trace kept away from each other is articulated mutually with two respectively the joint block.

Preferably, the two tamping rods are respectively sleeved with a second spring, one ends of the second springs, which are close to each other, are respectively fixedly connected with the two fixedly connected blocks, and one ends of the second springs, which are far away from each other, are respectively fixedly connected with the two support plates.

Preferably, the rotating shaft is located at one end outside the energy storage equipment shell and is fixedly provided with a hand-operated wheel, a T-shaped annular groove is formed in the outer wall of one side of the energy storage equipment shell, two T rods are slidably installed in the T-shaped annular groove, and the ends of the two T rods extend out of the T-shaped annular groove and are fixedly connected with the hand-operated wheel.

Preferably, the mounting frame is fixedly provided with two positioning sheets, and the two positioning sheets are respectively contacted with the two sliding strips.

Compared with the related art, the mounting structure of the electric power energy storage EMS equipment has the following beneficial effects:

The utility model provides a mounting structure of electric power energy storage EMS equipment, which is characterized in that an energy storage component can be limited on two dovetail blocks through the insertion connection between the dovetail grooves and the dovetail blocks, so that the energy storage component is limited in the vertical direction, and then the energy storage component can be limited in the horizontal direction through the insertion connection between a wedge-shaped clamping block and a clamping groove.

Drawings

Fig. 1 is a schematic structural diagram of a preferred embodiment of a mounting structure of an electric energy storage EMS device according to the present utility model;

FIG. 2 is a schematic diagram of the internal structure of the housing of the energy storage device according to the present utility model;

FIG. 3 is a schematic cross-sectional view of a housing of an energy storage device of the present utility model;

FIG. 4 is an enlarged schematic view of portion A shown in FIG. 3;

FIG. 5 is a schematic diagram of an assembled structure of an energy storage assembly, a mounting bracket and a rotating shaft according to the present utility model;

FIG. 6 is a schematic diagram of an exploded view of the energy storage assembly, mounting bracket and shaft of the present utility model;

FIG. 7 is a schematic view of the attachment of the mounting bracket to the dovetail block of the present utility model;

Fig. 8 is a schematic diagram of a connection structure of a turntable and two eccentric rods in the present utility model.

Reference numerals in the drawings: 1. an energy storage device housing; 2. an energy storage assembly; 3. a mounting frame; 4. a slide bar; 5. a dovetail groove; 6. dovetail blocks; 7. a buckle groove; 8. a spool; 9. a linkage plate; 10. wedge-shaped clamping blocks; 11. a connecting plate; 12. a first spring; 13. a support plate; 14. a tamper; 15. a rotating shaft; 16. a turntable; 17. an eccentric rod; 18. a linkage rod; 19. a fixing block; 20. and a second spring.

Detailed Description

The utility model will be further described with reference to the drawings and embodiments.

Please refer to fig. 1-8 in combination. The mounting structure of the power storage EMS device includes: the energy storage equipment casing 1, the chamber door and the energy storage component 2 of setting in the energy storage equipment casing 1, and be fixed with mounting bracket 3 on the inner wall of one side of energy storage equipment casing 1, and one side that energy storage component 2 is close to mounting bracket 3 is fixed with two draw-bars 4, dovetail 5 has all been seted up on two draw-bars 4, and equal slidable mounting has dovetail 6 in two dovetail 5, and one side that energy storage component 2 was kept away from to two dovetail 6 all with mounting bracket 3 fixed connection, like this alright be connected the formation between mounting bracket 3 and the energy storage component 2, and for the steady fixing of draw-bar 4 on dovetail 6, buckle groove 7 has all been seted up on one side that two draw-bars 4 kept away from each other, and the top and the bottom of mounting bracket 3 all are fixed with two slide posts 8, slidable mounting bracket 9 on two corresponding slide posts 8 have same linkage board 9, one side that two linkage board 9 are close to each other all is fixed with wedge fixture block 10, and one side that two wedge fixture 10 are close to each other extends to two in buckle groove 7 respectively, like this with draw-bar 4 card on dovetail 6, and just so can be connected with the buckle piece, and the wedge 10 is in order to take place between the wedge 7 and the corresponding position and the wedge 7, thereby the two position and the wedge-shaped piece can take place between the two and the wedge-shaped 7 is in order to touch down, and the position between the two wedge-shaped 7, and the position clip piece is in order to have realized, and the position clip 4 is more than the position and is in between the corresponding to be in between the wedge position and the wedge 7.

In the above manner, in order to tightly insert the wedge-shaped clamping block 10 into the clamping groove 7, the same connecting plate 11 is fixed on the two corresponding slide posts 8, the first springs 12 are fixed on the sides of the two connecting plates 11, which are close to each other, one ends of the first springs 12, which are close to each other, are respectively fixedly connected with the two linkage plates 9, and the wedge-shaped clamping block 10 can be tightly propped against the clamping groove 7 through the elasticity of the first springs 12.

In this mode, for the convenience is once only brought out corresponding buckle groove 7 with two wedge fixture blocks 10, with the improvement demolishment convenience, be fixed with extension board 13 on mounting bracket 3, equal slidable mounting has tamper 14 on two extension boards 13, and movable hole has all been seted up to the top and the bottom of mounting bracket 3, two tamper 14 respectively with two movable hole looks adaptations, and, all be fixed with rigid coupling piece 19 in the one end that two tamper 14 are close to each other, one side rotation of energy storage device casing 1 is installed pivot 15, its one end extends to in the mounting bracket 3 and is fixed with carousel 16, and be fixed with two symmetrical eccentric bars 17 on carousel 16, and all rotate on two eccentric bars 17 and install carrier 18, the one end that two carrier 18 kept away from each other is articulated with two rigid coupling pieces 19 respectively, like this alright through the mode of rotatory carousel 16, under the continuous band of eccentric bars 17 and carrier 18, make two tamper 14 keep away from each other, and pass from the movable hole that corresponds each, then, push up the board 9, take out buckle groove 7 with wedge fixture block 10.

In addition, in the above manner, in order to enable the two tamper bars 14 to automatically return to the original position after the use, the two tamper bars 14 are respectively sleeved with the two springs 20, one ends of the two springs 20, which are close to each other, are respectively fixedly connected with the two fixing blocks 19, one ends of the two springs 20, which are far away from each other, are respectively fixedly connected with the two support plates 13, and when the rotation force applied to the rotation shaft 15 is removed, the turntable 16 can automatically rotate by utilizing the elasticity of the two springs 20, so that the two tamper bars 14 are brought back to the original position.

In addition, in order to facilitate rotating the rotating shaft 15, a hand crank wheel is fixed at one end of the rotating shaft 15 positioned outside the energy storage device shell 1, so that people can hold and rotate conveniently, and in order to ensure the stability of rotation of the hand crank wheel, a T-shaped annular groove is formed in the outer wall of one side of the energy storage device shell 1, two T rods are mounted in the T-shaped annular groove in a sliding manner, and the end parts of the two T rods extend out of the T-shaped annular groove and are fixedly connected with the hand crank wheel.

The working principle of the installation structure of the electric power energy storage EMS equipment provided by the utility model is as follows:

When the energy storage component 2 is required to be overhauled or replaced in the later period, the hand-operated wheel can be directly rotated, the turntable 16 drives the two eccentric rods 17 to rotate through the connection of the rotating shaft 15, and the two linkage rods 18 drive the two tamping rods 14 to vertically move under the sliding limit between the tamping rods 14 and the support plates 13 along with the rotation of the eccentric rods 17, the two tamping rods 14 move in the direction away from each other at the moment, then the two tamping rods 14 respectively pass through the corresponding movable holes, and when the two tamping rods 14 respectively contact the two linkage plates 9, the linkage plates 9 are jacked, so that the two linkage plates 9 move in the direction away from each other, and the two wedge-shaped clamping blocks 10 are away from each other, finally, the two wedge-shaped clamping blocks 10 are respectively brought out of the two clamping grooves 7, at the moment, the first spring 12 and the second spring 20 are in a compressed state, meanwhile, the clamping limit between the slide bar 4 and the dovetail block 6 is lost, then the energy storage component 2 is directly pulled out of the dovetail block 6, the hand-operated wheel is released, the compressed second spring 20 releases the elastic force, the turntable 16 rotates, the two tamping rods 14 are brought back to the original position again, meanwhile, the two linkage plates 9 lose the external force pushing along with the withdrawal of the tamping rods 14, the first spring 12 releases the elastic force to bring the two wedge-shaped clamping blocks 10 back to the original position, and then the energy storage component 2 can be overhauled or replaced;

When the maintenance is finished or a new energy storage component 2 is reinstalled on the dovetail blocks 6, the two dovetail grooves 5 can be directly aligned with the two dovetail blocks 6 and then inserted, in the process of insertion, the edges of the side surfaces of the sliding bars 4 can contact the wedge-shaped parts of the wedge-shaped clamping blocks 10, so that pushing is formed on the wedge-shaped parts, the two wedge-shaped clamping blocks 10 are automatically separated, along with the continuous pushing of the sliding bars 4, the sides, close to each other, of the two wedge-shaped clamping blocks 10 are respectively contacted with the sides, away from each other, of the two sliding bars 4, at the moment, the two springs I12 are in a slight compression state until the two sliding bars 4 are in contact with the two positioning pieces, the wedge-shaped clamping blocks 10 vertically correspond to the clamping grooves 7, at the moment, the compressed springs I12 release elasticity, bring the wedge-shaped clamping blocks 10 into the clamping grooves 7, and form clamping between the sliding bars 4 and the dovetail blocks 6, so that the installation of the energy storage component 2 is completed.

Compared with the related art, the mounting structure of the electric power energy storage EMS equipment has the following beneficial effects:

The utility model provides an installation structure of electric power energy storage EMS equipment, which can limit an energy storage component 2 on two dovetail blocks 6 through the insertion connection between the dovetail grooves 5 and the dovetail blocks 6, so that the energy storage component 2 is limited in the vertical direction, and then the energy storage component 2 can be limited in the horizontal direction through the insertion connection between a wedge-shaped clamping block 10 and a clamping groove 7, so that the fixation of the energy storage component 2 is finished, and when the energy storage component 2 is dismantled, the wedge-shaped clamping block 10 can be quickly brought out of the clamping groove 7 by only rotating a hand wheel to drive a turntable 16, and then the energy storage component 2 can be pulled out, and when the energy storage component 2 is installed, the wedge-shaped clamping block 10 can be automatically inserted into the clamping groove 7 by only horizontally pushing a sliding strip 4 on the dovetail block 6.

The foregoing description is only illustrative of the present utility model and is not intended to limit the scope of the utility model, and all equivalent structures or equivalent processes or direct or indirect application in other related technical fields are included in the scope of the present utility model.

Claims (7)

1. The utility model provides a mounting structure of electric power energy storage EMS equipment, includes energy storage equipment casing, chamber door and sets up the energy storage subassembly in the energy storage equipment casing, its characterized in that, fixed mounting has the mounting bracket on the inner wall of one side of energy storage equipment casing, the energy storage subassembly is close to one side fixed mounting of mounting bracket has two slides, two all seted up the dovetail on the slide, two equal slidable mounting has the dovetail in the dovetail, two one side of dovetail all with mounting bracket fixed connection, two the buckle groove has all been seted up to one side that the slide kept away from each other, the equal fixed mounting in top and the bottom of mounting bracket has two slide, corresponding two slidable mounting has same linkage board on the slide, two equal fixed mounting has wedge fixture block in one side that the linkage board is close to each other, two wedge fixture block is close to each other one side extends respectively to two in the buckle groove, wedge fixture block with buckle groove looks adaptation.

2. The mounting structure of a power energy storage EMS device according to claim 1, wherein the same connecting plate is fixedly mounted on the corresponding two sliding posts, a first spring is fixedly mounted on one side of the two connecting plates, which is close to each other, and one end of the first spring, which is close to each other, is fixedly connected with the two linkage plates respectively.

3. The mounting structure of an electric power energy storage EMS device according to claim 1, wherein a support plate is fixedly mounted in the mounting frame, two tamper bars are slidably mounted on the support plates, movable holes are formed in the top and bottom of the mounting frame, and the tamper bars are respectively matched with the two movable holes.

4. The mounting structure of an electric power energy storage EMS device according to claim 3, wherein two ends of the tamper that are close to each other are fixedly provided with a fixing block, one side of the energy storage device housing is rotatably provided with a rotating shaft, one end of the rotating shaft extends into the mounting frame and is fixedly provided with a turntable, two eccentric rods are fixedly provided with the turntable, two eccentric rods are rotatably provided with a linkage rod, and two ends of the linkage rod that are far away from each other are respectively hinged with the two fixing blocks.

5. The mounting structure of an electric energy storage EMS device according to claim 4, wherein two tamper bars are respectively sleeved with a second spring, one ends of the second springs, which are close to each other, are respectively and fixedly connected with two fixedly connected blocks, and one ends of the second springs, which are far away from each other, are respectively and fixedly connected with two support plates.

6. The mounting structure of an electrical energy storage EMS device according to claim 4, wherein a hand crank is fixedly mounted at one end of the rotating shaft located outside the energy storage device housing, a T-shaped ring groove is formed in an outer wall of one side of the energy storage device housing, two T-bars are slidably mounted in the T-shaped ring groove, and ends of the two T-bars extend out of the T-shaped ring groove and are fixedly connected with the hand crank.

7. The mounting structure of a power energy storage EMS device according to claim 1, wherein two positioning pieces are fixedly mounted on the mounting frame, and the two positioning pieces are respectively contacted with the two sliding strips.