CN220164765U - Storage battery rack for energy storage box - Google Patents

Abstract

The utility model relates to the storage and transportation field of storage batteries, in particular to a storage battery rack for an energy storage box, which comprises a rack body assembly erected in the energy storage box and a battery tray assembly stacked and stacked on the rack body assembly.

Description

Storage battery rack for energy storage box

Technical Field

The utility model relates to the storage and transportation field of storage batteries, in particular to a storage battery frame for an energy storage box.

Background

Battery transport cases are containers that are specially used to transport batteries, intended to protect the batteries from impact and the external environment. It is typically made of a strong material, such as metal or high strength plastic, to provide adequate protection. The storage battery used in many occasions weighs 230kg, and the storage battery needs to be transported by a special carriage, and the storage battery needs to be prevented from being rubbed with each other during transportation, static electricity needs to be avoided, and heat dissipation needs to be carried out.

Battery crashworthiness refers to measures to prevent damage to the battery caused by collisions during transportation or use. The current transportation is mostly realized by wrapping the battery with shockproof materials or using specially designed supporting structures. While maintaining the battery stationary, the anti-collision measures may also reduce wear and damage to the internal components of the battery. Such packaging is disadvantageous in terms of heat dissipation from the battery and is prone to static electricity generation.

In addition, as many containers are square, the batteries are stacked in the boxes after being subjected to shock absorption and packaging, so that the batteries cannot be well fixed, the batteries are not favorable for heat dissipation, the batteries are heavy, the loading and unloading are very troublesome, and the batteries can be loaded and unloaded by no manpower.

Disclosure of Invention

In order to solve the technical problems, the utility model aims to provide a storage battery frame for an energy storage box, which enables batteries to be stacked neatly, is beneficial to heat dissipation of the batteries and effectively avoids friction between the batteries.

In order to achieve the above object, the technical scheme of the present utility model is as follows:

the storage battery rack for the energy storage box is in a rectangular box body shape, a keel frame is arranged on the side surface and the top of the energy storage box, the storage battery rack comprises a rack body component erected in the energy storage box and a battery tray component stacked and stacked on the rack body component layer by layer,

the frame body component comprises vertical supports, transverse supports and transverse angle irons, the vertical supports are arranged in the energy storage box at equal intervals along the length and width directions of the energy storage box, the upper ends of the vertical supports are propped against the keel frame, the lower ends of the vertical supports are propped against the bottom of the energy storage box, the transverse supports are arranged on the vertical supports of the longitudinal rows at equal intervals along the height directions of the vertical supports, the two rows of vertical supports are used as a group, the transverse supports are positioned on one side of the inner side surfaces of the two rows of vertical supports, the battery tray component is stacked on the transverse supports of one row, the joint of the transverse supports and each vertical support is detachably connected by the transverse angle irons, the upper plane of the transverse support is provided with a pulley track,

the battery tray assembly comprises a tray bottom in a shape of a 'II' -shaped symbol, a battery hoop erected on the tray bottom and pulleys hinged on four feet of the tray bottom, wherein the pulleys are embedded into pulley tracks and are used for slidably connecting the battery tray assembly to a transverse support, and a storage battery is arranged between the tray bottom and the battery hoop.

Further, a group of more than one group of two rows of vertical supports are arranged in the energy storage box, the two rows of vertical supports are arranged in the width direction of the energy storage box, and a passage for pedestrians to pass through is arranged between each group of vertical supports.

Further, the spacing distance between the two vertical supports in each row is equal to or greater than the height of the storage battery, and the storage battery is lodged and embedded between the tray bottom and the battery hoop.

Further, the battery hoop mainly comprises an I-shaped upper cover and supporting legs arranged at four corners of the upper cover, the supporting legs are perpendicular to the upper cover and connected through hinge shafts, and the lower ends of the supporting legs are hinged to the tray bottom through the hinge shafts.

Further, the upper cover, the support legs and the tray bottom are provided with strip-shaped holes with adjustable distances, and the strip-shaped holes are arranged at intervals along the length directions of the upper cover, the support legs and the tray bottom.

Further, the electric hoist and the hanging rail are further included, the hanging rail is installed on the keel frame along the longitudinal direction of the vertical support, the front end of the hanging rail extends out of the storage box, the rear end of the hanging rail at least exceeds the rear of the battery tray assembly stacked in the first row in the storage box, and the electric hoist is installed on the hanging rail.

Further, each group of frame body components is provided with a hanging rail and a hanging hoist, and the hanging rail is positioned in the middle position of the two rows of vertical supports.

Further, the lifting hook of the hoist is hooked at the middle position of the I-shaped upper cover.

Compared with the prior art, the utility model has the beneficial effects that: because each battery is up to 230KG, the battery rack adopts the mode design of layering track and special tray, and this mode not only is favorable to the installation of battery but also special tray can protect the battery, prevents to collide with, and the battery can be stably fixed in battery tray subassembly simultaneously, can not rock wantonly to avoid friction, the collision each other, effectively protect the battery not damaged in the transportation.

In addition, the batteries are arranged in a layered manner, are stacked in a layered manner, and are separated by an effective interval distance, so that heat dissipation of the batteries is facilitated, static electricity is effectively prevented, and the batteries are effectively protected.

In addition, the detachable electric hoist and the hanging rail are designed, the storage battery can be lifted together with the whole battery tray assembly, the storage battery is conveniently stacked on the frame assembly, the storage battery is also conveniently and rapidly unloaded from the frame assembly, and the loading and unloading are convenient and labor-saving.

Drawings

Fig. 1 is a schematic diagram of a front view structure of the present utility model:

FIG. 2 is a schematic perspective view of the present utility model;

fig. 3 is a schematic perspective view of a battery tray assembly according to the present utility model.

Detailed Description

In order that the manner in which the utility model is attained, as well as the features and advantages thereof, will be readily understood, a more particular description of the utility model will be rendered by reference to specific embodiments thereof.

As shown in fig. 1, fig. 2 and fig. 3, a storage battery frame for an energy storage box is shown, the energy storage box 1 is in a rectangular box shape, a keel frame 2 is arranged on the side surface and the top of the energy storage box, the storage battery frame comprises a frame body component 3 erected in the energy storage box and a battery tray component 4 stacked and stacked on the frame body component, a hanging rail 5 can be built on the keel frame 2 along the length direction of the energy storage box 1, the front end of the hanging rail 5 extends out of the energy storage box 1, a hanging hoist 6 is arranged on the hanging rail 5, and the storage battery outside the hanging box is lifted and then moved to the frame body component 3 to be stacked with the battery tray component 4. The hanging rail 5 and the hanging hoist 6 can be detached, and the opening and closing door of the energy storage box 1 is not affected.

The frame body assembly 3 comprises vertical supports 30, transverse supports 31 and transverse angle irons 32, the vertical supports 30 are arranged in the energy storage box 1 at equal intervals along the length and width directions of the energy storage box 1, the upper ends of the vertical supports 30 are propped against the keel frame 2, the lower ends of the vertical supports 30 are propped against the bottom of the energy storage box 1, the transverse supports 31 are arranged on the vertical supports 30 of the longitudinal rows at equal intervals along the height directions of the vertical supports 30, the two rows of vertical supports 30 are used as a group, the transverse supports 31 are positioned on one side of the inner side surfaces of the two rows of vertical supports, the battery tray assembly 4 is stacked on the transverse supports 31 of the row, the joint of the transverse supports 31 and each vertical support 30 is detachably connected by the transverse angle iron 32, and pulley tracks are arranged on the upper plane of the transverse supports 31.

A group of more than one group of two rows of vertical supports 30 are arranged in the energy storage box 1, the two rows of vertical supports 30 are arranged along the width direction of the energy storage box 1, the interval distance between the two vertical supports 30 in each row is equal to or greater than the height of the storage battery, and the storage battery is lodged and embedded between the tray bottom and the battery hoop. Every group erects and is equipped with passageway 7 that the pedestrian passed through between the support 30, passageway 7 in the centre, and two sets of support body subassemblies are leaned on the side wall of energy storage case, and energy storage case 1 is longer, and hoist 6 can only hang the battery tray subassembly 4 that takes the battery to be close to the cross support 31 of chamber door department, later when stacking up to the more deep place of energy storage case 1, need the manpower to promote battery tray subassembly 4 and remove to the energy storage case depths.

The battery tray assembly 4 comprises a tray bottom 40 in a shape of a 'II' -shaped symbol, a battery hoop 41 erected on the tray bottom 40 and pulleys 42 hinged on four feet of the tray bottom 40, wherein the battery hoop 41 is mainly erected on two longitudinal rods of the tray bottom 40 and forms an accommodating space with the tray bottom 40, the pulleys 42 are embedded into pulley tracks and are used for slidably connecting the battery tray assembly 4 to the transverse support 31, and a storage battery of the battery tray assembly is installed in the accommodating space between the tray bottom 40 and the battery hoop 41.

The battery collar 41 is mainly composed of an i-shaped upper cover 410 and legs 411 mounted at four corner positions of the upper cover 410, the legs 411 being perpendicular to the upper cover 410 and connected by hinge shafts, the lower ends of the legs 411 being hinged to the tray bottom 40 by the hinge shafts. The upper cover 410, the legs 411 and the tray bottom 40 are provided with bar-shaped holes of which the distances can be adjusted, and the bar-shaped holes are arranged at intervals along the length directions of the upper cover, the legs and the tray bottom.

Each group of frame body components 3 is provided with a hanging rail 5 and a hanging hoist 6, the hanging rail 5 is positioned at the middle position of the two rows of vertical supports 30, and the hanging hook of the hanging hoist 6 is hooked at the middle position of the I-shaped upper cover 410. The storage battery which is favorable for the hoisting of the hoist 6 can directly stay at the transverse supports 31 with different layers, the battery tray assembly 4 is manually pushed onto the transverse supports 31 after the storage battery stays, and hundreds of kilograms of storage battery are easily stacked on the frame body assembly 3 of each layer by utilizing the pulleys.

The larger the storage battery is, the fewer the two rows of firm supports 30 groups in the energy storage box 1 are, in this embodiment, the energy storage box 1 is equal to the size of a container, and about 250kg storage batteries need to be transported, so that two groups of frame body assemblies 3 are arranged in the energy storage box 1, four rows of vertical supports 30 are arranged, a battery tray assembly 4 is arranged between the two rows of vertical supports 30, a passageway is reserved in the middle, and after the battery tray assembly 3 is lifted up by the hoist 6 to reach the transverse support 31 of each layer, the battery tray assembly 4 is pushed to move behind the energy storage box and is orderly stacked.

The battery rack for the energy storage box provided by the utility model is described in detail above. The description of the specific embodiments is only intended to aid in understanding the method of the utility model and its core concept, and it should be understood that it will be apparent to those skilled in the art that various changes and modifications can be made herein without departing from the principles of the utility model, and such changes and modifications will fall within the scope of the appended claims.

Claims (8)

1. A battery frame for energy storage case, energy storage case are rectangle box shape, are equipped with dragon's skeleton, its characterized in that at the side and the top of energy storage case: the storage battery rack comprises a rack body component erected in the energy storage box and a battery tray component stacked on the rack body component,

the frame body component comprises vertical supports, transverse supports and transverse angle irons, the vertical supports are arranged in the energy storage box at equal intervals along the length and width directions of the energy storage box, the upper ends of the vertical supports are propped against the keel frame, the lower ends of the vertical supports are propped against the bottom of the energy storage box, the transverse supports are arranged on the vertical supports of the longitudinal rows at equal intervals along the height directions of the vertical supports, the two rows of vertical supports are used as a group, the transverse supports are positioned on one side of the inner side surfaces of the two rows of vertical supports, the battery tray component is stacked on the transverse supports of one row, the joint of the transverse supports and each vertical support is detachably connected by the transverse angle irons, the upper plane of the transverse support is provided with a pulley track,

the battery tray assembly comprises a tray bottom in a shape of a 'II' -shaped symbol, a battery hoop erected on the tray bottom and pulleys hinged on four feet of the tray bottom, wherein the pulleys are embedded into pulley tracks and are used for slidably connecting the battery tray assembly to a transverse support, and a storage battery is arranged between the tray bottom and the battery hoop.

2. The battery rack for an energy storage tank of claim 1, wherein: the energy storage box is internally provided with a group of more than one group of two rows of vertical supports, the two rows of vertical supports are arranged along the width direction of the energy storage box, and a passage for pedestrians to pass through is arranged between each group of vertical supports.

3. The battery rack for an energy storage tank of claim 2, wherein: the spacing distance between the two vertical supports in each row is equal to or greater than the height of the storage battery, and the storage battery is lodged and embedded between the tray bottom and the battery hoop.

4. The battery rack for an energy storage tank of claim 1, wherein: the battery hoop mainly comprises an I-shaped upper cover and supporting legs arranged at four corners of the upper cover, wherein the supporting legs are perpendicular to the upper cover and are connected through hinge shafts, and the lower ends of the supporting legs are hinged on the bottom of the tray through the hinge shafts.

5. The battery rack for an energy storage tank of claim 4, wherein: the upper cover, the support legs and the tray bottom are provided with strip-shaped holes with adjustable distances, and the strip-shaped holes are arranged at intervals along the length directions of the upper cover, the support legs and the tray bottom.

6. A battery rack for an energy storage tank as in any one of claims 1-4, wherein: the electric hoist is characterized by further comprising an electric hoist and a hanging rail, wherein the hanging rail is arranged on the keel frame along the longitudinal direction of the vertical support, the front end of the hanging rail extends out of the storage box, the rear end of the hanging rail at least exceeds the rear of the battery tray assembly stacked in the first row in the storage box, and the electric hoist is arranged on the hanging rail.

7. The battery rack for an energy storage tank of claim 6, wherein: and each group of frame body components is provided with a hanging rail and a hanging hoist, and the hanging rail is positioned in the middle position of two rows of vertical supports.

8. The battery rack for an energy storage tank of claim 7, wherein: the lifting hook of the hoist is hooked at the middle position of the I-shaped upper cover.