CN220873763U - Modularized battery rack with adjusting function - Google Patents

Abstract

The utility model belongs to the technical field of battery frames, and discloses a modularized battery frame with an adjusting function, which comprises: the bearing frames are four in total and form a quadrilateral shape; the bearing frame is provided with two groups of fixing holes, namely a first fixing hole group and a second fixing hole group, wherein the hole spacing between adjacent fixing holes of each group is the same; the layer frames are movably arranged on the bearing frames and are vertically and uniformly arranged; the side frames are arranged on the bearing frames, and the number and the intervals of the side frames are consistent with those of the layer frames; the modularized design is used, the bearing frame, the layer frame and the side frames can be detached, and related design and matched construction workload are reduced; the module inner layer plates can be adjusted to adapt to small changes in the specifications and number of the storage batteries in different projects.

Description

Modularized battery rack with adjusting function

Technical Field

The utility model relates to the technical field of battery frames, in particular to a modularized battery frame with an adjusting function.

Background

This patent is numerous to data center lead acid battery specification, and the specification of using always has 24AH, 38Ah, 65AH, 100AH, 120AH, 150AH, 200Ah. The number of the storage batteries is often required to be adjusted according to different projects, and the common number is configured by 8 sections, 16 sections, 20 sections, 32 sections, 34 sections, 36 sections, 38 sections and 40 sections. The open cell frame for mounting the secondary cell has a large number of specifications, and often requires customization.

The currently used schemes result in excessive battery rack specifications, and almost every project needs to select battery racks with different specifications according to the number of battery nodes configured by the project. The workload of model selection is increased, and meanwhile, because the size of the battery rack is changed frequently, the layout of a machine room and a bearing base cannot be standardized, and the workload of design and matched construction is increased.

The customization processing is often long in period, and is difficult to meet the requirement of machine room construction on timeliness

Therefore, the application provides a modularized battery rack with an adjusting function, so as to solve the problems.

Disclosure of utility model

In order to solve the problems, the application provides a modularized battery rack with an adjusting function.

The application provides a modularized battery rack with an adjusting function, which adopts the following technical scheme:

a modular battery rack with adjustment function, comprising:

The bearing frames are four in total and form a quadrilateral shape; the bearing frame is provided with two groups of fixing holes, namely a first fixing hole group and a second fixing hole group, wherein the hole spacing between adjacent fixing holes of each group is the same;

The layer frames are movably arranged on the bearing frames and are vertically and uniformly arranged;

the side frames are arranged on the bearing frames, and the number and the interval of the side frames are consistent with those of the layer frames.

Through the technical scheme, the modularized design is adopted, and the bearing frame, the layer frame and the side frames can be detached, so that the related design and the matched construction workload are reduced; the module inner layer plates can be adjusted to adapt to small changes in the specifications and number of the storage batteries in different projects.

Further, the number of the shelves is 4 or 5, and when the number of the shelves is 4, the interval between every two adjacent shelves is 400mm by using a fixed hole group; when the number of the shelves is 5, the interval between two adjacent shelves by using the fixing hole group is 300mm.

Through the technical scheme, based on the size of the 12V100AH storage battery which is most commonly used in a data center, 4 layers and 5 layers of structures are designed to be adjustable, 4 sections of 12V100AH storage batteries can be placed on each layer, and at most 4 sections of 5 layers = 20 sections of 12V100AH lead-acid storage batteries can be placed on each standard battery frame.

The battery frame laminate can be freely changed between a 4-layer structure and a 5-layer structure through the positions of the reserved screw holes of the stand columns according to project requirements. 4-layer architecture matching: section 8 200AH, section 8 150AH, section 16 120AH, section 16 100AH, section 16 65AH, section 32 38AH, section 32 24AH, and the like. 5-layer architecture matching: 10-200 AH, 10-150 AH, 20-120 AH, 20-100 AH, 20-65 AH, 34-40 38AH, 34-40 24AH and other project requirements.

Furthermore, the side frames are symmetrically provided with bolt pairs, and the number of the bolt pairs connected with each side of the bearing frame in a detachable mode through the bolt pairs is at least two.

Through the technical scheme, two or more bolt pairs on each side can provide effective supporting force so as to ensure the normal operation of safe production.

Further, the bottom of layer frame is provided with the U-shaped notch, the U-shaped notch block is in on the bolt of bolt pair, the nut on the bolt pair is closely to the U-shaped notch.

Through above-mentioned technical scheme, this kind of setting can be fixed bearing frame, layer frame and sideframe together through the bolt pair only, also is convenient for get when later stage change layer frame position and puts the layer frame.

Furthermore, the layer frames are also uniformly arranged with raised strips, and the highest point of the side frames is higher than the highest point of the raised strips.

Through above-mentioned technical scheme, the setting of sand grip can reduce the contact surface of battery and layer frame, increases the circulation of air and does benefit to the heat dissipation of battery, and frictional force also can effectively reduce when getting the discharge cell.

Furthermore, the shelf is also provided with a fence, and the height of the fence is higher than that of the side shelf.

Through above-mentioned technical scheme, enclose the setting that keeps off and can guarantee battery safety effectively and avoid battery displacement to fall etc. simultaneously avoid having other large-scale equipment large tracts of land to collide the battery.

Further, the square shape size of the bearing frame is 500mm x 800mm x 160 mm.

Through above-mentioned technical scheme, standard battery frame size convenient transportation and secondary transport can pass through most elevator door, machine room door, stair and transport passageway smoothly.

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

(1) The modularized design is used, the bearing frame, the layer frame and the side frames can be detached, and related design and matched construction workload are reduced; the inner layer plates of the modules can be adjusted to adapt to small changes of the specifications and the quantity of the storage batteries in different projects;

(2) The number of the shelves is 4 or 5, and when the number of the shelves is 4, the interval between two adjacent shelves by using the fixed hole group is 400mm; when the number of the layer frames is 5, the interval between two adjacent layer frames in the fixed hole group is 300mm; based on the most common 12V100AH storage battery size of the data center, 4 layers and 5 layers of structures are designed to be adjustable, 4 sections of 12V100AH storage batteries can be placed on each layer, and at most 4 sections of 5 layers = 20 sections of 12V100AH lead-acid storage batteries can be placed on each standard battery rack.

Drawings

FIG. 1 is a schematic diagram of a four-layer structure of the present application;

FIG. 2 is a schematic diagram of a five-layer structure of the present application;

FIG. 3 is a schematic view of a layer rack;

fig. 4 is an enlarged schematic view at a in fig. 3.

The reference numerals in the figures illustrate: 1. a bearing frame; 2. a first fixed hole group; 3. a second fixed hole group; 4. a layer rack; 5. a side frame; 6. a bolt pair; 7. a U-shaped notch; 8. a convex strip; 9. and (5) enclosing.

Detailed Description

The technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present application; it is apparent that the described embodiments are only some embodiments of the present application, not all embodiments, and that all other embodiments obtained by persons of ordinary skill in the art without making creative efforts based on the embodiments in the present application are within the protection scope of the present application.

In the description of the present application, it should be noted that the positional or positional relationship indicated by the terms such as "upper", "lower", "inner", "outer", "top/bottom", etc. are based on the positional or positional relationship shown in the drawings, are merely for convenience of describing the present application and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present application. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present application, unless explicitly specified and limited otherwise, the terms "mounted," "configured to," "engaged with," "connected to," and the like are to be construed broadly and include, for example, "connected" as either a fixed connection, a removable connection, or an integral connection; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present application will be understood in specific cases by those of ordinary skill in the art.

Examples:

the application is described in further detail below with reference to fig. 1-4.

The embodiment of the application discloses a modularized battery rack with an adjusting function, which comprises the following components:

The bearing frame 1, the bearing frame 1 totally four form the quadrilateral shape; the bearing frame 1 is provided with two groups of fixing holes, namely a first fixing hole group 2 and a second fixing hole group 3, wherein the hole spacing between adjacent fixing holes in each group is the same;

The layer frames 4 are movably arranged on the bearing frames 1 and are vertically and uniformly arranged;

The side frames 5 are arranged on the bearing frame 1, and the number and the interval of the side frames 5 are consistent with those of the layer frames 4.

Referring to fig. 1 and 2, the number of shelves 4 is 4 or 5, and the interval between 2 adjacent shelves 4 using the fixing hole group when the number of shelves 4 is 400mm; when the number of shelves 4 is 5, the interval between two adjacent shelves 4 using the fixing hole group two 3 is 300mm.

It is worth mentioning that, because of the interval reason, the first fixed hole group 2 and the second fixed hole group 3 have coincident fixed holes, so that the punching on the bearing frame 1 can be reduced, the rigidity and bearing capacity of the bearing frame 1 are ensured, and the time and labor are saved when the structure of the layer frame 4 is adjusted; based on the size of the 12V100AH storage battery most commonly used in a data center, 4 layers and 5 layers of frames 4 are designed, 4 sections of 12V100AH storage batteries can be placed on each layer, and at most 4 sections of 5 layers = 20 sections of 12V100AH lead-acid storage batteries can be placed on each standard battery frame.

The battery rack laminate can be freely changed between the 4-layer rack 4-structure and the 5-layer rack 4-structure through the reserved screw hole positions of the stand columns according to project requirements. 4-layer frame 4 structure matching: section 8 200AH, section 8 150AH, section 16 120AH, section 16 100AH, section 16 65AH, section 32 38AH, section 32 24AH, and the like. 5-layer frame 4 structure matching: 10-200 AH, 10-150 AH, 20-120 AH, 20-100 AH, 20-65 AH, 34-40 38AH, 34-40 24AH and other project requirements.

One A20 battery rack is a minimum module unit, and can be freely combined according to the number of batteries in a specific project, for example, two A20 battery racks are combined together, and screw locking (reserved cabinet combining screw holes) is adopted, and the 4-layer rack 4 structure can meet common project requirements of 16 sections 200AH, 16 sections 150AH, 32 sections 120AH, 32 sections 100AH, 32 sections 65AH, 64 sections 38AH, 64 sections 24AH and the like. The 5-layer frame 4 structure can meet the common project demands of 20 sections 200AH, 20 sections 150AH, 34 sections to 40 sections 120AH, 34 sections to 40 sections 100AH, 34 sections to 40 sections 65AH, 80 sections 38AH, 80 sections 24AH and the like

Referring to fig. 1, 2, 3 and 4, the side frames 5 are symmetrically provided with bolt pairs 6, and the number of the bolt pairs 6 on each side, which are detachably connected with the bearing frame 1 through the bolt pairs 6, is at least two; two or more bolt pairs 6 on each side can provide effective supporting force to ensure the normal operation of safe production.

Referring to fig. 4, a U-shaped notch 7 is formed in the bottom of the layer frame 4, the U-shaped notch 7 is clamped on a bolt of the bolt pair 6, and a nut on the bolt pair 6 is tightly attached to the U-shaped notch 7; the bearing frame 1, the layer frame 4 and the side frames 5 can be fixed together only through the bolt pair 6, and the layer frame 4 is convenient to take and put when the position of the layer frame 4 is changed in the later period.

Referring to fig. 1, 2 and 3, the shelves 4 are further provided with ribs 8 uniformly arranged, and the highest point of the side shelf 5 is higher than the highest point of the ribs 8; the arrangement of the raised strips 8 can reduce the contact surface between the battery and the layer rack 4, increase the ventilation, facilitate the heat dissipation of the battery, and effectively reduce the friction force when taking the discharging pool, thereby being convenient for taking and placing.

Referring to fig. 1, 2 and 3, the shelf 4 is further provided with a fence 9, and the height of the fence 9 is higher than that of the side frame 5; the arrangement of the enclosure 9 can effectively ensure that the battery is safe, so that the battery displacement is avoided from falling, and the like, and meanwhile, the battery is prevented from being collided with other large-scale equipment in a large area.

Referring to fig. 1 and 2, the square shape of the bearing frame 1 is 500mm x 800mm x 160 mm; the standard battery rack is convenient to transport and carry for the second time, and can smoothly pass through most elevator doors, machine room doors, stairs and carrying channels.

The implementation principle of the modularized battery rack with the adjusting function provided by the embodiment of the application is as follows:

According to the actually used battery volume combined battery frame, a first fixing hole group 2 with a spacing of 400mm or a second fixing hole group 3 with a spacing of 300mmm is selected.

Two groups of structures with the width of 800mm are obtained by fixedly connecting adjacent bearing frames 1 with the width of 800mm through side frames 5, then the layer frames 4 are firstly fixed on any structure, and then the other group of bearing frames 1 are fixed, so that a group of battery frames is obtained.

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 (7)

1. A modular battery rack with adjustment function, comprising:

The bearing frame (1), the four bearing frames (1) form a quadrilateral shape altogether; two groups of fixing holes are formed in the bearing frame (1), namely a first fixing hole group (2) and a second fixing hole group (3), and the hole spacing between adjacent fixing holes in each group is the same;

The layer frames (4) are movably arranged on the bearing frames (1) and are vertically and uniformly arranged;

The side frames (5) are arranged on the bearing frames (1), and the number and the interval of the side frames (5) are consistent with those of the layer frames (4).

2. A modular battery rack with adjustment function according to claim 1, characterized in that: the number of the shelves (4) is 4 or 5, and when the number of the shelves (4) is 4, the interval between the adjacent shelves (4) is 400mm by using the fixed hole group I (2); when the number of the shelves (4) is 5, the interval between the adjacent shelves (4) by using the second fixing hole group (3) is 300mm.

3. A modular battery rack with adjustment function according to claim 1, characterized in that: the side frames (5) are symmetrically provided with bolt pairs (6), and the number of the bolt pairs (6) on each side, which are detachably connected with the bearing frame (1), is at least two through the bolt pairs (6).

4. A modular battery rack with adjustment function according to claim 3, characterized in that: the bottom of layer frame (4) is provided with U-shaped notch (7), U-shaped notch (7) block is in on the bolt of bolt pair (6), the nut on the bolt pair (6) is pasted tightly U-shaped notch (7).

5. A modular battery rack with adjustment function according to claim 1, characterized in that: the layer frames (4) are also uniformly provided with raised strips (8), and the highest point of the side frames (5) is higher than the highest point of the raised strips (8).

6. A modular battery rack with adjustment function according to claim 1, characterized in that: the shelf (4) is also provided with a surrounding baffle (9), and the height of the surrounding baffle (9) is higher than that of the side shelf (5).

7. A modular battery rack with adjustment function according to claim 1, characterized in that: the quadrilateral size of the bearing frame (1) is 500mm x 800mm x 160 mm.