CN218371229U - Energy storage battery hoisting structure, fire control unit and energy storage system - Google Patents

Abstract

The utility model discloses an energy storage battery hoisting structure, a fire fighting device and an energy storage system, which comprises a supporting mechanism, a constraint mechanism and a hoisting mechanism; the energy storage battery is connected with the supporting mechanism through the constraint mechanism and/or the hoisting mechanism; the constraint mechanism is configured with a force holding state for connecting the energy storage battery and the support mechanism and a force releasing state for releasing the energy storage battery to be separated from the support mechanism; the hoisting mechanism is configured with a hoisting state and a non-hoisting state, and the energy storage battery is separated from the support mechanism by a preset distance in the hoisting state; and in a non-hoisting state, the distance between the energy storage battery and the supporting mechanism is less than the preset distance. When the restraint mechanism is switched to the force release state, and after the energy storage battery is separated from the supporting mechanism by the preset distance, the hoisting mechanism is in the hoisting state, the hoisting equipment can hoist the whole energy storage battery hoisting structure by the hoisting supporting mechanism, the energy storage battery is conveniently taken out, and therefore the production efficiency of the energy storage battery is improved.

Description

Energy storage battery hoisting structure, fire control unit and energy storage system

Technical Field

The utility model relates to an energy storage battery technical field, in particular to energy storage battery hoisting structure, fire control unit and energy storage system.

Background

At present, the emergent response scheme of energy storage battery fire control is in releasing the energy storage battery to the fire control pond, but, the energy storage battery after releasing to the fire control pond is difficult for taking out, influences the production efficiency of energy storage battery. Therefore, how to improve the production efficiency of the energy storage battery becomes a technical problem to be solved urgently by those skilled in the art.

SUMMERY OF THE UTILITY MODEL

In view of this, in an aspect, the utility model provides an energy storage battery hoisting structure, it can conveniently carry energy storage battery to improve energy storage battery's production efficiency. In another aspect, the utility model provides a fire fighting device, it is after energy storage battery releases to fire control pond, conveniently takes out. Additionally, the utility model also provides an energy storage system who has above-mentioned fire control unit.

In order to achieve the above object, the utility model provides a following technical scheme:

in a first aspect, the utility model provides an energy storage battery hoisting structure, which can hoist an energy storage battery, and comprises a supporting mechanism, a restraining mechanism and a hoisting mechanism;

the energy storage battery is connected with the supporting mechanism through the constraint mechanism and/or the hoisting mechanism;

the constraint mechanism is configured with a force keeping state for connecting the energy storage battery and the support mechanism and a force releasing state for releasing the energy storage battery to be separated from the support mechanism;

the hoisting mechanism is configured with a hoisting state and a non-hoisting state, and the energy storage battery is separated from the support mechanism by a preset distance in the hoisting state; and in a non-hoisting state, the distance between the energy storage battery and the supporting mechanism is less than a preset distance.

Preferably, the utility model discloses an among the energy storage battery hoisting structure, the energy storage battery passes through the mounting panel and constructs and/or hoisting machine and construct and be connected.

Preferably, the utility model discloses an among the energy storage battery hoisting structure, hoisting machine constructs including fire-resistant rope, and fire-resistant rope's middle part sets up in supporting mechanism, and fire-resistant rope's both ends are connected with the mounting panel respectively to when hoisting machine constructs to be in hoist and mount state, fire-resistant rope was tightened.

Preferably, the utility model discloses an among the energy storage battery hoisting structure, the both ends of mounting panel are provided with the first rings of fixed fire-resistant rope.

Preferably, the utility model discloses an among the energy storage battery hoisting structure, the mounting panel both ends are provided with the spacing groove with lifting rope looks adaptation, and the face of mounting panel installation spacing groove and the face mutual disposition of the first rings of installation.

Preferably, the utility model discloses an among the energy storage battery hoisting structure, the region that is located between two first rings on the mounting panel still is provided with the card wire casing, and fire-resistant rope passes the card wire casing.

Preferably, the utility model discloses an among the energy storage battery hoisting structure, the card wire casing is rotatable to be set up on the side of mounting panel.

Preferably, the utility model discloses an among the energy storage battery hoisting structure, supporting mechanism includes the bearing crossbeam, and restraint mechanism and/or hoisting mechanism pass through the second rings and are connected with the bearing crossbeam.

Preferably, the utility model discloses an among the energy storage battery hoisting structure, supporting mechanism is still including the fastener of connecting mounting panel and bearing crossbeam, and the fastener can be dismantled with the mounting panel and be connected.

Preferably, the utility model discloses an among the energy storage battery hoisting structure, the quantity of fastener is two, and two fasteners are in the length direction of mounting panel both sides of living in restraint mechanism.

Preferably, the energy storage battery hoisting structure of the utility model further comprises an electric control releasing mechanism, the electric control releasing mechanism comprises a monitoring part, a force application part and a triggering part, the monitoring part is used for monitoring whether the energy storage battery reaches dangerous conditions and is arranged on the bearing beam; the force application part is connected with the constraint mechanism through the trigger part and is configured in a force static state and a force action state; when the state of the energy storage battery reaches a dangerous condition, the force application part is switched from a force static state to a force action state, and the force application part adjusts the state of the constraint mechanism through the trigger part so that the constraint mechanism is switched from a force keeping state to a force releasing state.

Preferably, the utility model discloses an among the energy storage battery hoisting structure, the control portion is smoke monitor.

Preferably, the energy storage battery hoisting structure of the utility model further comprises a mechanical releasing mechanism, the mechanical releasing mechanism comprises a balancing weight, a force application rope and a trigger rope, the balancing weight is suspended on the bearing cross beam through the force application rope, and the trigger rope is connected with the constraint mechanism and the balancing weight; when the force application rope is broken, the counterweight block adjusts the state of the constraint mechanism through the trigger rope, so that the constraint mechanism is switched from a force maintaining state to a force releasing state.

Preferably, the utility model discloses an among the energy storage battery hoisting structure, restraint mechanism is the detacher.

The second aspect, the utility model provides an energy storage battery fire control unit, including fire control pond and foretell energy storage battery hoisting structure, the fire control pond is located energy storage battery hoisting structure's below.

The third aspect, the utility model provides an energy storage system, including energy storage battery and the energy storage battery fire control unit as above-mentioned.

The utility model provides an energy storage battery hoisting structure when restraint mechanism switches to power release state, and energy storage battery breaks away from the supporting mechanism and predetermines the distance after, hoisting mechanism is in hoist and mount state, and hoisting equipment can hoist and mount supporting mechanism just can hoist and mount whole energy storage battery hoisting structure, makes things convenient for energy storage battery to take out to energy storage battery's production efficiency has been improved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the provided drawings without creative efforts.

Fig. 1 is a schematic view of a constraint mechanism in an energy storage battery hoisting structure according to an embodiment of the present invention in a force holding state;

fig. 2 is a schematic view of a constraint mechanism in an energy storage battery hoisting structure according to an embodiment of the present invention in a force release state;

fig. 3 is a schematic view of a hoisting mechanism in an energy storage battery hoisting structure provided by an embodiment of the present invention in a hoisting state;

fig. 4 is a schematic view of another energy storage battery hoisting structure according to an embodiment of the present invention when the constraint mechanism is in a force maintaining state;

fig. 5 is a schematic view of another energy storage battery hoisting structure according to an embodiment of the present invention when the constraint mechanism is in a force release state;

fig. 6 is a schematic view of another energy storage battery hoisting structure provided by the embodiment of the present invention when the hoisting mechanism is in a hoisting state;

fig. 7 is a schematic view of an installation process of an energy storage battery hoisting structure provided by an embodiment of the present invention;

fig. 8 is a schematic view of a hoisting process of an energy storage battery hoisting structure provided by an embodiment of the present invention;

fig. 9 and fig. 10 are schematic diagrams of an energy storage battery fire fighting device applied to an underground energy storage system according to an embodiment of the present invention;

fig. 11 and 12 are schematic diagrams of an energy storage battery fire fighting device applied to an above-ground energy storage system according to an embodiment of the present invention;

in fig. 1-12:

100 is a supporting mechanism, 200 is a constraint mechanism, 300 is a hoisting mechanism, 400 is an energy storage battery, 500 is a mounting plate, 600 is an electric control release mechanism, 700 is a mechanical release mechanism, 800 is a fire pool, and 900 is a supporting column;

101 is a bearing beam, 102 is a fastener, 601 is a monitoring part, 602 is a force application part, 603 is a trigger part, 701 is a counterweight block, 702 is a force application rope, 703 is a trigger rope, 200a is a second lifting ring, 500a is a first lifting ring, 500b is a limiting groove, and 500c is a wire clamping groove.

Detailed Description

The utility model discloses in, on the one hand, the utility model provides an energy storage battery hoisting structure, it can conveniently carry energy storage battery to improve energy storage battery's production efficiency. In another aspect, the utility model provides a fire fighting device, it is after energy storage battery releases to fire control pond, conveniently takes out. Additionally, the utility model also provides an energy storage system who has above-mentioned fire control unit.

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

As shown in fig. 1-12, the energy storage battery hoisting structure according to the embodiment of the present invention can hoist the energy storage battery 400, and the energy storage battery hoisting structure includes a supporting mechanism 100, a constraining mechanism 200, and a hoisting mechanism 300; wherein: the energy storage battery 400 is connected with the supporting mechanism 100 through the constraint mechanism 200 and/or the hoisting mechanism 300; the restraint mechanism 200 is configured with a force holding state for connecting the energy storage battery 400 with the support mechanism 100, and a force releasing state for releasing the energy storage battery 400 from the support mechanism 100; the hoisting mechanism 300 is configured with a hoisting state and a non-hoisting state, and in the hoisting state, the energy storage battery 400 is separated from the support mechanism 100 by a preset distance; in the non-hoisting state, the distance between the energy storage battery 400 and the support mechanism 100 is less than the preset distance.

When the constraint mechanism 200 is switched to the force releasing state, and after the energy storage battery 400 is separated from the support mechanism 100 by a preset distance, the hoisting mechanism 300 is in the hoisting state, the hoisting device can hoist the support mechanism 100 to hoist the whole energy storage battery hoisting structure, so that the energy storage battery 400 is conveniently taken out, and the production efficiency of the energy storage battery 400 is improved.

It should be noted that energy storage battery 400 is connected with restraint mechanism 200 and/or hoisting machine structure 300 directly or indirectly, in order to improve the utility model discloses an energy storage battery hoisting structure integrated nature, energy storage battery 400 passes through mounting panel 500 and is connected with restraint mechanism 200 and/or hoisting machine structure 300. In other words, the states of the constraining mechanism 200 and the hoisting mechanism 300 are switched to directly act on the mounting plate 500 instead of the energy storage battery 400, so that the energy storage battery 400 does not need to be provided with a structure for mounting the constraining mechanism 200 and the hoisting mechanism 300, and the requirement on the processing technology of the energy storage battery 400 is low.

The frame of the energy storage battery 400 is mounted on the mounting plate 500 through a bolt or a screw, and the mounting plate 500 is provided with a fastening hole matched with the bolt or the screw.

The hoisting mechanism 300 is configured with a hoisting state and a non-hoisting state, wherein in the hoisting state, the hoisting mechanism 300 is stressed, and the supporting mechanisms 100 are hoisted together by the hoisting mechanism 300 when the supporting mechanisms 100 are hoisted; in the non-hoisting state, the hoisting mechanism 300 is not stressed. Because the utility model discloses an energy storage battery hoisting structure mainly is applied to fire control unit. Therefore, the hoisting mechanism 300 may include a fire-resistant rope, the middle portion of the fire-resistant rope is disposed on the supporting mechanism 100, and both ends of the fire-resistant rope are respectively connected to the mounting plates 500, and the fire-resistant rope is tightened when the hoisting mechanism 300 is in a hoisting state. The fire resistant rope has fire resistant properties and may be, for example, a sling rope.

In order to improve the stability of the mounting plate 500 when it is stressed, first rings 500a for fixing fire-resistant ropes are provided at both ends of the mounting plate 500. When the fire-resistant rope was in hoist and mount state, lifted by crane mounting panel 500 both ends, mounting panel 500 has two degrees of freedom restraints to can reduce and rock.

The utility model discloses in some embodiments, when passing through lifting rope hoist and mount mounting panel 500 in order to reduce hoisting equipment, the phenomenon that the lifting rope drops easily, the mounting panel 500 both ends be provided with the spacing groove 500b of lifting rope looks adaptation, and the face of mounting panel 500 installation spacing groove 500b and the face mutual disposition of the first rings 500a of installation. When the mounting plate 500 is hoisted, the lifting rope is arranged in the limiting groove 500b, and when the lifting rope is restrained in the height direction, the lifting rope is not easy to fall off from the limiting groove 500 b.

In a normal state, the constraint mechanism 200 is in a force maintaining state, the energy storage battery 400 is connected with the support mechanism 100 through the constraint mechanism 200, and the hoisting mechanism 300 is in a non-hoisting state; only under dangerous conditions, the constraining mechanism 200 can be switched to the force releasing state, and the hoisting mechanism 300 can be switched to the hoisting state. Therefore, in a normal state, when the hoisting mechanism 300 is in a non-hoisting state, the fire-resistant rope is not stressed, the installation plate 500 is further provided with a wire clamping groove 500c in a region between the two first hoisting rings 500a, and the fire-resistant rope passes through the wire clamping groove 500c. The fire-resistant rope can be preliminarily fixed to prevent being touched by other equipment.

Further, the wire-locking groove 500c may be rotatably disposed on a side surface of the mounting plate 500. On the one hand, the cable management is facilitated, and on the other hand, when the energy storage battery 400 is in a dangerous condition, the fire-resistant cable is easy to fall off from the cable clamping groove 500c.

Supporting mechanism 100 acts on support restraint mechanism 200, hoisting mechanism 300 and energy storage battery 400, the utility model discloses some embodiments, supporting mechanism 100 can include bearing beam 101, and restraint mechanism 200 and/or hoisting mechanism 300 are connected with bearing beam 101 through second rings 200 a. The load-bearing cross beam 101 may be made of steel with excellent load-bearing capacity, such as i-shaped steel, H-shaped steel, and the like.

Further, in order to reduce the shaking generated in the process of carrying the lifting equipment, the supporting mechanism 100 further comprises a fastener 102 for connecting the mounting plate 500 and the load-bearing cross beam 101, and the fastener 102 is detachably connected with the mounting plate 500. When carrying this energy storage battery hoisting structure to appointed position, bearing beam 101 is connected with mounting panel 500 through fastener 102, has increased the tie point between bearing beam 101 and the mounting panel 500, consequently, reduces the rocking of mounting panel 500 for bearing beam 101 in handling to reduce energy storage battery 400 and rock for bearing beam 101.

The number of the fastening members 102 may be one or more, and in the illustration, the number of the fastening members 102 is two, and two fastening members 102 are disposed on both sides of the restriction mechanism 200 in the longitudinal direction of the mounting plate 500.

As shown in fig. 1 to fig. 3, in some embodiments of the present invention, the energy storage battery hoisting structure further includes an electric control releasing mechanism 600, the electric control releasing mechanism 600 includes a monitoring portion 601, a force applying portion 602 and a triggering portion 603, the monitoring portion 601 is used for monitoring whether the energy storage battery 400 reaches a dangerous condition, and is disposed on the bearing beam 101; the urging unit 602 is connected to the restraint mechanism 200 via the trigger 603, and the urging unit 602 is configured in a force rest state and a force operation state; when the state of the energy storage battery 400 reaches a dangerous condition, the force application portion 602 switches from the force rest state to the force operation state, and the force application portion 602 adjusts the state of the restraint mechanism 200 through the trigger portion 603, so that the restraint mechanism 200 switches from the force retention state to the force release state. When the state of the energy storage battery 400 reaches a dangerous condition, the force application portion 602 switches from the force rest state to the force action state, and the force application portion 602 adjusts the state of the restraint mechanism 200 through the trigger portion 603, so that the restraint mechanism 200 switches from the force retention state to the force release state, and the energy storage battery 400 is released.

The dangerous condition is that the energy storage battery 400 burns, when the energy storage battery 400 burns, the temperature of the energy storage battery 400 rises, and smoke is also generated, and when the monitored temperature reaches a temperature threshold, the energy storage battery 400 is in the dangerous condition; when the smoke concentration reaches the smoke concentration threshold, the energy storage battery 400 is in a dangerous condition. Therefore, whether the smoke is in a dangerous condition can be judged by monitoring the temperature or the smoke. The monitoring unit 601 is a temperature sensor or a smoke monitor. The utility model discloses, better adoption smoke detector.

On the basis of the technical solutions disclosed in fig. 1 to fig. 3, the energy storage battery hoisting structure of some embodiments of the present invention further includes a mechanical release mechanism 700, the mechanical release mechanism 700 includes a weight block 701, a force application rope 702 and a trigger rope 703, the weight block 701 is suspended on the bearing beam through the force application rope 702, and the trigger rope 703 connects the constraint mechanism 200 and the weight block 701; when the force application rope 702 is burned off, the weight block 701 adjusts the state of the restraining mechanism 200 through the trigger rope 703, so that the restraining mechanism 200 is switched from the force maintaining state to the force releasing state, as shown in fig. 4 to 6.

The weight of the balancing weight 701 can meet the acting force of the separation of the restraint mechanism 200 and the support mechanism 100, the connecting end can be a flexible rope, wherein the force application rope 702 is hung on the support mechanism 100, two ends of the trigger rope 703 are respectively connected with the balancing weight 701 and the restraint mechanism 200, when the force application rope 702 is in a stressed and tightened state, the force application rope 702 applies a lifting acting force to the balancing weight 701, when the force application rope 702 is in a burned-out state in the combustion process of the energy storage battery 400, the balancing weight 701 instantly falls under the action of the self gravity, and the balancing weight 701 applies an acting force to the restraint mechanism 200 through the trigger rope 703, so that the restraint mechanism 200 is switched from a force holding state to a force releasing state, and the energy storage battery 400 correspondingly in a high risk situation can fall off; alternatively, the force application rope 702 may be a nylon rope, and the trigger rope 703 may be a steel wire rope.

Due to the existence of the mechanical release mechanism 700, when the electronic control release mechanism 600 fails, the mechanical release mechanism 700 supplements, when the force application rope 702 is broken, which indicates that the state of the energy storage battery 400 is a dangerous condition, the counterweight 701 adjusts the state of the constraint mechanism 200 through the trigger rope 703, so that the constraint mechanism 200 is switched from the force maintaining state to the force releasing state.

Preferably, in the energy storage battery hoisting structure of the present invention, the constraint mechanism 200 is a detacher, and the detacher may be a lever structure, that is, when the connecting end drives the detacher to rotate relative to the fixed connecting arm through the trigger link of the detacher, the detacher is separated from the hook portion of the connecting hook at this time; or the unhooking device can also be a bolt type connecting structure, namely a trigger connecting rod of the unhooking device is a bolt, the end part of the bolt is connected with the connecting end, and the bolt is driven to be pulled out by the acting force of the counterweight end, so that the bolt type connecting structure is separated; it should be noted that, since the detacher is a conventional known structure, the detacher is not limited herein, and only needs to be capable of disengaging the connection hook by an external force, which is not described herein again.

When the energy storage battery hoisting structure shown in fig. 1 to 3 is used to transport the energy storage battery 400 to a specific position, please refer to fig. 7:

the energy storage battery 400 is mounted on the mounting plate 500 by bolts.

Moving the load-bearing beam 101 and mounting the fastener 102 on the mounting plate 500 near one end of the mounting plate 500, and rotating the nut on the fastener 102 to move the mounting plate 500 further in the direction near the load-bearing beam 101 until the restraining mechanism 200 is coupled to the mounting plate 500 to remove the nut on the fastener 102.

And (3) the fire-resistant rope passes through the second hanging ring 200a, and the two ends of the fire-resistant rope are fastened on the first hanging ring 500a of the mounting plate 500, so that the mounting is completed. The lifting rope of the lifting device is matched with the limiting groove 500b, and the energy storage battery lifting structure is conveyed to a designated position.

As shown in fig. 8, when the energy storage battery 400 is in a dangerous state and the monitoring of the electronic control release mechanism 600 monitors that the smoke concentration reaches the concentration threshold, the electronic control release mechanism 600 drives the restraint mechanism 200 to switch to the force release state, and the energy storage battery 400 falls off. When the distance between the energy storage battery 400 and the bearing beam 101 reaches a preset distance, the hoisting mechanism 300 is in a hoisting state.

The utility model provides an energy storage battery fire control unit, including fire control pond 800 and foretell energy storage battery hoisting structure, fire control pond 800 is located energy storage battery hoisting structure's below. Because above-mentioned energy storage battery hoisting structure has above beneficial effect, the energy storage battery fire control unit including above-mentioned energy storage battery hoisting structure has corresponding effect, and this is no longer repeated here.

The fire fighting device described above may be used in an underground energy storage system, as shown in fig. 9 and 10; the fire fighting device described above may also be used in an above ground energy storage system, as shown in figures 11 and 12, and when used in an above ground energy storage system, further comprises a support 900, the support 900 being used to support the load carrying beam 101.

Including this energy storage battery hoisting structure's energy storage battery fire control unit can be quick take out energy storage battery 400 from fire control pond 800 to energy storage battery 400's production efficiency has been improved.

The utility model provides an energy storage system, include energy storage battery 400 and as above-mentioned energy storage battery fire control unit. Because above-mentioned energy storage battery fire control unit has above effect, the energy storage system including this energy storage battery fire control unit has corresponding effect, and this no longer gives details here.

The energy storage battery 400 may be a stepped battery, a rechargeable battery, or the like.

In the specification, structures of all parts are described in a progressive mode, the structure of each part is mainly described to be different from the existing structure, and the energy storage battery hoisting structure, the whole energy storage system and the part structure can be obtained by combining the structures of the parts.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (16)

1. The energy storage battery hoisting structure is characterized by being capable of hoisting an energy storage battery and comprising a supporting mechanism, a constraint mechanism and a hoisting mechanism;

the energy storage battery is connected with the supporting mechanism through the constraint mechanism and/or the hoisting mechanism;

the restraining mechanism is configured with a force holding state for connecting the energy storage battery with the supporting mechanism and a force releasing state for releasing the energy storage battery from the supporting mechanism;

the hoisting mechanism is configured with a hoisting state and a non-hoisting state, and the energy storage battery is separated from the support mechanism by a preset distance in the hoisting state; and in a non-hoisting state, the distance between the energy storage battery and the supporting mechanism is smaller than a preset distance.

2. The energy storage battery hoisting structure of claim 1, wherein the energy storage battery is connected with the constraining mechanism and/or the hoisting mechanism through a mounting plate.

3. The energy storage battery hoisting structure of claim 2, wherein the hoisting mechanism comprises a fire-resistant rope, the middle part of the fire-resistant rope is arranged on the support mechanism, two ends of the fire-resistant rope are respectively connected with the mounting plate, and the fire-resistant rope is tightened when the hoisting mechanism is in a hoisting state.

4. The energy storage battery hoisting structure of claim 3, wherein the mounting plate is provided with first hanging rings at both ends thereof for fixing the fire-resistant rope.

5. The energy storage battery hoisting structure according to claim 4, wherein the mounting plate is provided with limiting grooves adapted to the lifting rope at two ends, and the surface of the mounting plate for mounting the limiting grooves is arranged opposite to the surface for mounting the first hanging ring.

6. The energy storage battery hoisting structure of claim 4, wherein a line clamping groove is further formed in the mounting plate in a region between the two first hoisting rings, and the fire-resistant rope penetrates through the line clamping groove.

7. The energy storage battery hoisting structure of claim 6, wherein the wire clamping groove is rotatably arranged on the side surface of the mounting plate.

8. The energy storage battery hoisting structure according to claim 2, wherein the support mechanism comprises a load-bearing cross beam, and the restraining mechanism and/or the hoisting mechanism are connected with the load-bearing cross beam through a second hoisting ring.

9. The energy storage battery hoisting structure of claim 8, wherein the support mechanism further comprises a fastener connecting the mounting plate and the load-bearing beam, and the fastener is detachably connected with the mounting plate.

10. The energy storage battery hoisting structure of claim 9, wherein the number of the fasteners is two, and two of the fasteners are spaced apart from the restraining mechanism in the length direction of the mounting plate.

11. The energy storage battery hoisting structure according to claim 10, further comprising an electrically controlled release mechanism, wherein the electrically controlled release mechanism comprises a monitoring part, a force application part and a trigger part, the monitoring part is used for monitoring whether the energy storage battery reaches a dangerous condition and is arranged on the bearing cross beam; the force application part is connected with the constraint mechanism through the trigger part, and is configured in a force static state and a force action state; when the state of the energy storage battery reaches a dangerous condition, the force application part is switched from a force static state to a force action state, and the force application part adjusts the state of the constraint mechanism through the trigger part, so that the constraint mechanism is switched from a force keeping state to a force releasing state.

12. The energy storage battery hoisting structure of claim 11, wherein the monitoring portion is a smoke monitor.

13. The energy storage battery hoisting structure of claim 11, further comprising a mechanical release mechanism, wherein the mechanical release mechanism comprises a counterweight, a force application rope, and a trigger rope, wherein the counterweight is suspended on the load-bearing cross beam through the force application rope, and the trigger rope connects the constraint mechanism and the counterweight; when the force application rope is broken, the balancing weight adjusts the state of the constraint mechanism through the trigger rope, so that the constraint mechanism is switched from a force maintaining state to a force releasing state.

14. The energy storage battery hoisting structure of any one of claims 1 to 13, wherein the restraining mechanism is a detacher.

15. An energy storage battery fire fighting device, characterized by comprising a fire fighting pool and an energy storage battery hoisting structure according to any one of claims 1 to 14, wherein the fire fighting pool is located below the energy storage battery hoisting structure.

16. An energy storage system, characterized by comprising an energy storage battery and an energy storage battery fire fighting device as defined in claim 15.

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