CN219457839U - New energy rack with anti-drop structure - Google Patents

Abstract

The utility model discloses a new energy rack with an anti-falling structure, which comprises a first rack body, a second rack body and a third rack body, wherein the first rack body and the second rack body are respectively provided with four outer frames for forming the new energy rack, and the third rack body is vertically connected between the first rack body and the second rack body; further comprises: the battery mounting plates are arranged between the adjacent third frame bodies, two sides of each battery mounting plate are in sliding fit with the sliding grooves on the inner sides of the third frame bodies, and four battery limiting grooves which are distributed at equal intervals in sequence are formed in the upper end faces of the battery mounting plates; the damping mechanism is arranged at four corners of the upper end face and the lower end face of the outer frame, and comprises a connecting plate, a second through hole, a fixed column, a movable column, a damping spring and a damping buffer.

Description

New energy rack with anti-drop structure

Technical Field

The utility model relates to the technical field of new energy racks, in particular to a new energy rack with an anti-falling structure.

Background

The new energy rack is suitable for a rack body for installing batteries, and the rack is a rack with a specification model made of metals such as iron, aluminum and the like according to the size of the batteries. The machine frame is widely applied in industry, and has important application in a telecommunication room and medical equipment, and the machine frame is mainly divided into: 2V series battery rack, 12V battery series battery rack, FT series battery rack. Such most common rack applications are popular.

For example, chinese issued patent CN216872168U, a new energy battery rack structure, includes a bottom beam assembly and a top beam assembly, a first vertical beam assembly, a second vertical beam assembly and a middle vertical beam assembly are fixedly welded between the bottom beam assembly and the top beam assembly, the middle vertical beam assembly is provided with a plurality of vertical beam assemblies, and the middle vertical beam assemblies are located between the first vertical beam assembly and the second vertical beam assembly, and the first vertical beam assembly, the second vertical beam assembly, the middle vertical beam assembly, the bottom beam assembly and the top beam assembly are all provided with conductive connection areas. The new energy battery rack structure is light in weight, good in structural strength, convenient to assemble, firm in fixation and high in precision, meets stacking requirements of battery packs, and can provide racks with different layers and columns according to market demands.

The prior art can realize the installation of the battery, but equipment can vibrate in the use process, the vibration can cause looseness between connecting pieces on the new energy rack, and the rack can cause the falling of the battery after being scattered, so that potential safety hazards and economic losses are formed, the existing requirements are not met, and the new energy rack with the falling-preventing structure is provided.

Disclosure of Invention

The utility model aims to provide a new energy rack with an anti-drop structure, so as to solve the problem that the new energy rack is loose and scattered due to vibration in the equipment provided in the background technology, and a battery is dropped.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the new energy rack with the anti-falling structure comprises a first rack body, a second rack body and a third rack body, wherein four first rack bodies and four second rack bodies are arranged to form an external frame of the new energy rack, and the third rack body is vertically connected between the first rack body and the second rack body; further comprises:

the battery mounting plates are arranged between the adjacent third frame bodies, two sides of each battery mounting plate are in sliding fit with the sliding grooves on the inner sides of the third frame bodies, and four battery limiting grooves which are distributed at equal intervals in sequence are formed in the upper end faces of the battery mounting plates;

the damping mechanism is arranged at four corners of the upper end face and the lower end face of the outer frame and comprises a connecting plate, a second through hole, a fixed column, a movable column, a damping spring and a damping buffer.

Preferably, the two sides of the front end of the battery mounting plate are uniformly provided with positioning blocks, two first through holes are formed in the positioning blocks, positioning grooves are formed in the third frame body at the front end, the positioning grooves are matched with the positioning blocks, and two threaded holes are formed in the positioning grooves.

Preferably, one end of the movable column is located inside the fixed column, the movable column is in sliding connection with the fixed column, the fixed end of the damping buffer is fixed with the fixed column, the movable end of the damping buffer is fixed with the movable column, and the damping spring is arranged outside the damping buffer.

Preferably, the connecting plate is welded and fixed with the fixed column, and the second through hole is fixed with the connecting device through bolts.

Preferably, the both sides of battery spacing groove all are provided with the bolt connecting block, and the bolt connecting block is fixed with the welding of battery spacing groove, the inside of bolt connecting block is equipped with the screw.

Preferably, the new energy rack can be stacked in multiple layers, and the third rack body provides connection support.

Compared with the prior art, the utility model has the beneficial effects that:

1. according to the utility model, the damping mechanisms are arranged at four corners of the upper end and the lower end of the new energy rack, each damping mechanism consists of the connecting plate, the second through hole, the fixed column, the movable column, the damping springs and the damping buffer, the connecting plate is aligned to the joint of the equipment during installation, the bolts are used for fixing, when vibration is generated in the operation process of the equipment, the vibration force is transmitted to the fixed column through the connecting plate, so that the fixed column and the movable column relatively move, the internal damping springs are compressed, the elastic deformation of the damping springs is generated in the process, the vibration force is effectively slowed down, meanwhile, the damping buffer can reduce the instability of the damping springs caused by rebound, so that the vibration force transmitted to the new energy rack is weakened to the greatest extent, the problem of loosening and scattering can not occur between the new energy racks, and the dropping of an internal battery is effectively avoided.

2. According to the utility model, the battery mounting plate is arranged, the movable design is adopted for the battery mounting plate, the battery mounting plate is only required to be pulled out from between the third frame bodies when the battery is mounted, the fully extended battery mounting plate can improve enough space to enable workers to mount the battery, the battery is only required to be inserted into the battery limiting groove when the battery is mounted, the battery limiting groove can limit the battery to avoid sliding, then the positioning bolt is only required to extend to a screw hole in the screw connection block through a mounting block on the side edge of the battery, the battery mounting plate is pushed to be contracted into the new energy rack, after the battery mounting plate is completely contracted, the positioning block is positioned in the positioning groove, the workers can fix the battery in the screw hole through the first through hole by using the fastening bolt, and the structure not only effectively improves the convenience of battery mounting, but also is strong in firmness, and the battery is not easy to loose in the use process, so that the possibility of falling is reduced.

Drawings

FIG. 1 is a perspective view of the present utility model;

FIG. 2 is a partial perspective view of the battery mounting plate of the present utility model;

FIG. 3 is an enlarged view of a portion of the area A of FIG. 1 in accordance with the present utility model;

fig. 4 is a schematic view of the internal structure of the shock absorbing mechanism of the present utility model.

In the figure: 1. a first frame body; 2. a second frame body; 3. a third frame; 4. a battery mounting plate; 5. a battery limit groove; 6. a damping mechanism; 7. a bolt connecting block; 8. a positioning block; 9. a first through hole; 10. a positioning groove; 11. a threaded hole; 12. a connecting plate; 13. a second through hole; 14. fixing the column; 15. a movable column; 16. a damping spring; 17. damping buffer.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Referring to fig. 1-4, an embodiment of the present utility model is provided: the new energy rack with the anti-drop structure comprises a first rack body 1, a second rack body 2 and a third rack body 3, wherein the first rack body 1 and the second rack body 2 are respectively provided with four external frames for forming the new energy rack, and the third rack body 3 is vertically connected between the first rack body 1 and the second rack body 2; further comprises:

the battery mounting plates 4 are arranged between the adjacent third frame bodies 3, two sides of each battery mounting plate 4 are in sliding fit with the sliding grooves on the inner sides of the third frame bodies 3, and four battery limiting grooves 5 which are distributed at equal intervals in sequence are formed in the upper end faces of the battery mounting plates 4;

and the damping mechanism 6 is arranged at four corners of the upper end surface and the lower end surface of the outer frame, and the damping mechanism 6 comprises a connecting plate 12, a second through hole 13, a fixed column 14, a movable column 15, a damping spring 16 and a damping buffer 17.

When the novel energy rack is used, the battery mounting plate 4 is required to be taken out, a plurality of batteries are installed, the battery mounting plate 4 is pushed after the installation is finished to enter the novel energy rack, and finally, only the connecting plate 12 on the damping mechanism 6 is required to be fixed with equipment.

Referring to fig. 2 and 3, positioning blocks 8 are uniformly formed on two sides of the front end of the battery mounting plate 4, two first through holes 9 are formed in the positioning blocks 8, positioning grooves 10 are formed in the front end third frame 3, the positioning grooves 10 are matched with the positioning blocks 8, two threaded holes 11 are formed in the positioning grooves 10, convenience in battery mounting is effectively improved, firmness is high, and a battery is not prone to loosening in the use process.

Referring to fig. 1 and 4, one end of the movable column 15 is located inside the fixed column 14, the movable column 15 is slidably connected with the fixed column 14, the fixed end of the damping buffer 17 is fixed with the fixed column 14, the movable end of the damping buffer 17 is fixed with the movable column 15, the damping spring 16 is disposed outside the damping buffer 17, and the vibration force transmitted to the new energy rack is attenuated to the greatest extent, so that the problem of loosening and scattering can not occur between the new energy racks.

Referring to fig. 4, the connecting plate 12 is welded to the fixing post 14, the second through hole 13 is fixed to the connecting device by a bolt, and the connecting device is connected to the connecting device by the damping mechanism 6 to provide a damping effect.

Referring to fig. 2, two sides of the battery limit groove 5 are provided with bolt connection blocks 7, and the bolt connection blocks 7 are welded and fixed with the battery limit groove 5, and screw holes are formed in the bolt connection blocks 7 for reinforcing the battery.

Referring to fig. 1, the new energy rack may be stacked in multiple layers, and the third rack 3 provides connection support.

Working principle: during the use, need follow battery mounting panel 4 between the third support body 3, battery mounting panel 4 after the complete extension can improve sufficient space and make the staff install, peg graft the inside at battery spacing groove 5 with the battery, battery spacing groove 5 can provide spacingly to the battery, later pass the installation piece of battery side extend to the inside screw of bolt connecting block 7 can, promote battery mounting panel 4 at last, make its shrink to the inside of new forms of energy frame, after the complete shrink, locating piece 8 can be located the inside of constant head tank 10, the staff uses fastening bolt to pass first through-hole 9 fix in screw hole 11 can, with connecting plate 12 alignment equipment's junction, use the bolt to fix, during the equipment operation in-process produces vibration, vibration force passes through connecting plate 12 and transmits to fixed column 14, make take place relative motion between fixed column 14 and the movable column 15, form and compress to inside damping spring 16, in-process damping spring 16 takes place elastic deformation, effectively slow down vibration force, damping buffer 17 can reduce damping spring 16 and will be weakened by the resilience by the at utmost because of the vibrations that the resilience that causes, then transmit to new forms the new forms.

It will be evident to those skilled in the art that the utility model is not limited to the details of the foregoing illustrative embodiments, and that the present utility model may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the utility model being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (6)

1. The novel energy rack with the anti-drop structure comprises a first rack body (1), a second rack body (2) and a third rack body (3), wherein the first rack body (1) and the second rack body (2) are respectively provided with four external frames for forming the novel energy rack, and the third rack body (3) is vertically connected between the first rack body (1) and the second rack body (2);

the method is characterized in that: further comprises:

the battery mounting plates (4) are arranged between the adjacent third frame bodies (3), two sides of each battery mounting plate (4) are in sliding fit with sliding grooves in the inner sides of the third frame bodies (3), and four battery limiting grooves (5) which are distributed at equal intervals in sequence are formed in the upper end faces of the battery mounting plates (4);

the damping mechanism (6) is arranged at four corners of the upper end face and the lower end face of the outer frame, and the damping mechanism (6) comprises a connecting plate (12), a second through hole (13), a fixed column (14), a movable column (15), a damping spring (16) and a damping buffer (17).

2. The new energy rack with anti-drop structure according to claim 1, wherein: the battery mounting plate is characterized in that positioning blocks (8) are uniformly formed on two sides of the front end of the battery mounting plate (4), two first through holes (9) are formed in the positioning blocks (8), positioning grooves (10) are formed in the third frame body (3) at the front end, the positioning grooves (10) are matched with the positioning blocks (8), and two threaded holes (11) are formed in the positioning grooves (10).

3. The new energy rack with anti-drop structure according to claim 1, wherein: one end of the movable column (15) is located inside the fixed column (14), the movable column (15) is in sliding connection with the fixed column (14), the fixed end of the damping buffer (17) is fixed with the fixed column (14), the movable end of the damping buffer (17) is fixed with the movable column (15), and the damping spring (16) is arranged outside the damping buffer (17).

4. A new energy rack with anti-drop structure according to claim 3, wherein: the connecting plate (12) is welded and fixed with the fixing column (14), and the second through hole (13) is fixed with the connecting equipment through bolts.

5. The new energy rack with anti-drop structure according to claim 1, wherein: both sides of battery spacing groove (5) all are provided with bolt connecting block (7), and bolt connecting block (7) and battery spacing groove (5) welded fastening, the inside of bolt connecting block (7) is equipped with the screw.

6. The new energy rack with anti-drop structure according to claim 1, wherein: the new energy rack can be overlapped in multiple layers, and the third rack body (3) provides connection support.