CN109046149A - Stirring structure and stirring formula thick liquids energy memory - Google Patents

Abstract

The invention provides a stirring structure, which comprises a cavity, electromagnets arranged at two ends of the cavity and magnetons arranged in the cavity, wherein the electromagnets are arranged at two ends of the cavity; the electromagnets at the two ends are switched between on and off states, and the magnetons move under the action of the magnetic fields of the electromagnets; the magnetic field is switched by switching on and off the electromagnets at the two ends, so that the magnetons run in different directions, the stirring purpose is achieved, and the magnetic stirring device is simple in structure, easy to operate and good in stirring effect.

Description

Stirring structure and stirring formula thick liquids energy memory

Technical Field

The invention relates to the technical field of slurry energy storage batteries, in particular to a stirring structure suitable for a slurry energy storage battery and a stirring type slurry energy storage device with the stirring structure.

Background

Manufacturing an electrode of a lithium ion battery, wherein positive electrode slurry comprises an adhesive, a conductive agent, a positive electrode material and the like; the negative electrode slurry consists of a binder, graphite carbon powder and the like. The semi-solid state flow battery is a novel battery structure combining a flow battery and a lithium ion battery, adopts the structure of the flow battery and a solid active substance, has the advantages of the flow battery such as power and capacity separation characteristic and high specific energy density of the solid active substance, and is concerned by academia and industry. .

In the prior art, in order to prevent the occurrence of dead flowing corners and channeling of the suspension liquid in the reactor and improve the fluidity and power density of the positive and negative suspension liquids, an auxiliary stirring component is generally added to the semi-solid flow battery.

If the shell of the prior device is adhered and fixed with an ultrasonic emitting head of an ultrasonic generating device, the ultrasonic generating device can generate ultrasonic wave intermittently or continuously, thereby stirring the internal slurry. However, the installation of the ultrasonic emitter on the outer shell not only has the problem of uneven stirring, but also has a great damage effect on the SEI film of the negative electrode material due to ultrasonic waves.

Meanwhile, in the prior art, contradiction exists between the fluidity of the suspension and the solid content of the suspension, the solid content of the electrolyte needs to be increased for improving the overall energy density, but the fluidity of the electrolyte is deteriorated, if the solid content is low, not only is the energy density greatly reduced, but also the overall conductivity of the electrode is low, and large polarization and the like are caused in the reaction process. Secondly, the stability of the suspension is difficult to guarantee, and local sedimentation is easily formed to block flow channels and membranes, which greatly increases the difficulty of equipment design and manufacture. However, if the slurry is completely static during operation, the electrochemical environment of the active material in different regions of the electrode will be greatly different, which may lead to increased device polarization and possible dendrite problems.

Therefore, the stirring structure suitable for the slurry energy storage battery and the stirring type slurry energy storage device with the stirring structure are provided.

Disclosure of Invention

The invention aims to provide a stirring structure suitable for a slurry energy storage battery and a stirring type slurry energy storage device with the stirring structure.

In order to achieve the purpose, the invention provides a stirring structure, which comprises a cavity, electromagnets arranged at two ends of the cavity and magnets arranged in the cavity; the electromagnets at the two ends are switched between on and off states, and the magnetons move under the action of the magnetic fields of the electromagnets.

The magnetons are made of iron, cobalt, nickel or ferrite and other magnetic materials, have one or more different diameters, and have the diameter range of 10 mu m-1mm.

Further, a stirring type slurry energy storage device is provided, which comprises an electrochemical reactor and stirring structures arranged in a positive electrode chamber and a negative electrode chamber of the electrochemical reactor, wherein the stirring structures are designed as the stirring structures; and the electromagnets at the two ends are switched between power-on and power-off according to a driving working system, and the magnetons move under the action of the magnetic field of the electromagnets to stir the slurry in the cavity.

The surface of the magneton is coated with a layer of insulating coating.

The electrochemical reactor comprises a positive electrode cavity, a negative electrode cavity, a diaphragm arranged between the positive electrode cavity and the negative electrode cavity, a positive electrode current collector and a negative electrode current collector.

The heat dissipation structure is used for dissipating heat of the cavity.

The heat radiation structure comprises a heat radiation fin which is arranged outside the cavity and connected with the positive current collector and the negative current collector.

The radiating fin is connected with the positive current collector and/or the negative current collector through welding, gluing or mechanical contact, and the joint is sealed by adopting insulating glue; or the heat sink is integrally manufactured with the positive electrode current collector and/or the negative electrode current collector.

The driving working system comprises the following steps: during stirring, the electromagnet at the first end of the chamber is powered on, the electromagnet at the second end of the chamber is powered off, the magnetons move under the action of a magnetic field and reach the first end, then the electromagnet at the first end is powered off, the electromagnet at the second end of the chamber is powered on, and the magnetons move reversely under the action of the magnetic field and reach the second end; and then the cycle repeats.

Compared with the prior art, the invention has the following advantages:

in the invention, the magnetic field is switched by switching on and off the electromagnets at the two ends, so that the magnetons run in different directions, thereby achieving the purpose of stirring.

Additional features and advantages of the invention will be set forth in the detailed description which follows.

Drawings

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

FIG. 1 is a schematic cross-sectional view of an electromagnetic stirring type slurry energy storage device according to the present invention;

FIG. 2 is a schematic view of a part of the electromagnetic stirring type slurry energy storage device according to the present invention;

fig. 3 is a schematic diagram of a partially disassembled structure of the electromagnetic stirring type slurry energy storage device according to the present invention;

FIG. 4 is a schematic cross-sectional view of a composite diaphragm according to the present invention;

description of the attached labels: 1-positive current collector; 2-positive electrode leading-out end; 3-a positive electrode chamber; 4-negative current collector; 5-a negative leading-out end; 6-a negative electrode chamber; 7-a composite membrane; 8-a heat sink; 9-magnetons; 10-an electromagnet; 11-a feed inlet; 12-a discharge hole; 13-positive plate frame; 14-negative plate frame; 15-diaphragm plate frame; 16-an isolation layer; 17-a conductive layer; 18-insulating coating.

Detailed Description

The following describes in detail embodiments of the present invention with reference to the drawings. It should be understood that the detailed description and specific examples, while indicating the preferred embodiment of the invention, are given by way of illustration and explanation only, not limitation.

Example 1

The embodiment provides a stirring structure, which comprises a cavity, electromagnets 10 arranged at two ends of the cavity, and magnets 9 arranged in the cavity; the electromagnets 10 at the two ends are switched between on and off states, and the magnetons 9 move under the action of the magnetic fields of the electromagnets 10.

The magnetons 9 are provided as magnetons 9 made of iron, cobalt, nickel or ferrite as well as other magnetic materials, having one or more different diameters, in the range of 10 μm-1mm.

In this embodiment, the electromagnet 10 at both ends is switched to the magnetic field when the electromagnet is switched on or off, so that the magneton 9 runs in different directions, thereby achieving the purpose of stirring.

Example 2

As shown in fig. 1, 2 and 3, this embodiment provides a stirring type slurry energy storage device, which includes an electrochemical reactor, and further includes stirring structures disposed in a positive electrode chamber 3 and a negative electrode chamber 6 of the electrochemical reactor, where the stirring structures include electromagnets 10 disposed at two ends of the chambers and magnetons 9 disposed in the chambers; the electromagnets 10 at the two ends are switched on and off according to a driving working system, and the magnetons 9 move under the action of the magnetic fields of the electromagnets 10 to stir the slurry in the cavity.

In the embodiment, the electromagnet 10 at the two ends is switched on and off to switch the magnetic field, so that the magneton 9 runs in different directions, and the stirring purpose is achieved; meanwhile, intermittent stirring can be optimized, energy consumption is reduced, and the influence on the output power of the device is small; therefore, the energy density can be ensured on the basis of no solid content of the electrolyte, and meanwhile, the internal local sedimentation can be prevented, and the generation of polarization and dendritic crystals is reduced.

In the embodiment, the active slurry enters through the feed port 11, and is discharged through the discharge port 12 after reaction, and the active slurry does not need to flow in a chamber or a pipeline, so that the circulation resistance of the active slurry is greatly reduced, the energy storage efficiency of an energy storage system is improved, and the electrochemical reactor can adopt a narrow flow channel design; the bulk density of active materials in the electrochemical reactor is high, and the internal resistance and polarization phenomena are far smaller than those of the lithium ion flow battery.

On the basis of the above, the magnetons 9 are made of iron, cobalt, nickel or ferrite and other magnetic materials, and have one or more different diameters, and the diameter range is 10 μm-1mm. In this embodiment, the magneton 9 is preferably a steel ball, and the diameter thereof is set to be 0.3mm. In a preferred embodiment, the surface of the magneton 9 is coated with an insulating coating, so as to avoid the direct contact of the steel balls with the active material or the electrolyte.

Specifically, the electrochemical reactor comprises a positive electrode chamber 3, a negative electrode chamber 6, a diaphragm arranged between the positive electrode chamber 3 and the negative electrode chamber 6, and a positive electrode current collector 1 and a negative electrode current collector 4. The electrochemical reactor is a plate structure or a tubular structure or is formed by laminating a plurality of sub electrochemical reactors, and the electrochemical reactor can be designed into other structures.

On the basis, the embodiment further comprises a heat dissipation structure for dissipating heat of the cavity. Specifically, the heat radiation structure includes the fin 8 that locates outside the cavity and with the anodal mass flow body 1, the negative current collector 4 is connected. In this embodiment, the positive electrode current collector 1 and/or the negative electrode current collector 4 may be optionally extended to the outside of the electrochemical reactor. In this embodiment, the heat dissipation structure can timely draw out internal heat in the electrochemical reactor, and the electrochemical environment and the temperature environment in which the active slurry is drawn out in the working process are obviously better than those of a semi-solid flow battery, so that the semi-solid flow battery has higher safety and longer service life.

Specifically, the heat sink 8 is connected with the positive current collector 1 and/or the negative current collector 4 by welding, gluing or mechanical contact, and the joint is sealed by using an insulating glue; or the heat sink 8 is integrally manufactured with the positive electrode current collector 1 and/or the negative electrode current collector 4.

In this embodiment, as a preferred embodiment, the driving operation system is: during stirring, the electromagnet 10 at the first end of the chamber is powered on, the electromagnet 10 at the second end of the chamber is powered off, the magnetons 9 move under the action of a magnetic field and reach the first end, then the electromagnet 10 at the first end is powered off, the electromagnet 10 at the second end of the chamber is powered on, and the magnetons 9 move in the opposite direction under the action of the magnetic field and reach the second end; then the operation is repeated circularly; of course, other drive regimes may be selected.

On the basis, the diaphragm in the embodiment is a composite diaphragm 7 made of one or more materials of a porous polymer film, a porous ceramic diaphragm, non-woven fabrics, various fabrics, fiber paper, a metal mesh, a carbon fiber mesh, a carbon felt, a polymer felt and the like.

As shown in fig. 4, the composite diaphragm 7 includes an isolation layer 16, a conductive layer 17 disposed on both sides of the isolation layer 16, and an insulating coating 18 disposed between the conductive layer 17 and the isolation layer 16; the conductive layer 17, the insulating coating 18, the isolation layer 16, the insulating coating 18 and the conductive layer 17 are sequentially stacked and bonded into a whole, and a gap between every two adjacent layers is not more than 10 micrometers.

In this embodiment, two conductive layers 17 and one isolation layer 16 form the conductive composite membrane 7, and the insulating coating 18 is disposed between the conductive layers 17 and the isolation layer 16, so that one side of the conductive layer 17 close to the isolation layer 16 is in a state of being coated by the insulating coating 18, thereby preventing ions from producing dendrites between the conductive layer 17 and the isolation layer 16, preventing the isolation layer 16 from being punctured, and improving the safety performance of a battery system; meanwhile, the conductive composite diaphragm 7 realizes the integration of the isolation layer 16 and the conductive layer 17, simplifies the battery structure of the fluidized slurry battery, improves the utilization rate of the internal volume of the battery, and improves the mechanical strength and the service life of the conductive composite diaphragm 7.

Specifically, the thickness of the insulating coating 18 of the present embodiment is 0.1 to 50 μm; wherein, two adjacent layers adopt vacuum evaporation plating or electroplating or chemical plating or casting or spin coating or spray coating or hot pressing or screen printing or ink-jet printing or bonding or mechanical pressing to be compounded into a whole, thereby ensuring that the conductive layer 17 and the isolation layer 16 can be tightly jointed to form the conductive composite diaphragm 7 and ensuring that the gap between the two adjacent layers is not more than 10 μm.

Specifically, in the present embodiment, the isolation layer 16 is made of polyethylene, polypropylene, polyvinylidene fluoride, or other electronically nonconductive porous polymer material;

as an alternative embodiment, the isolation layer 16 can also be made of glass fiber non-woven fabric, synthetic fiber non-woven fabric, ceramic fiber paper, or other electronic non-conductive inorganic non-metallic material and organic polymer composite porous material;

further, as an alternative embodiment, the isolation layer 16 may be a gel polymer electrolyte composite material formed by compounding an electronically nonconductive polymer matrix, a liquid organic plasticizer, and a lithium salt.

On the basis of the above embodiments, the conductive layer 17 of the present embodiment is a conductive layer 17 formed by mechanically stamping or chemically etching a metal sheet or a metal foil having multiple through holes, where the through holes are in a circular shape, an oval shape, a semicircular shape, a square shape, a hexagonal shape, a triangular shape, a diamond shape, a trapezoid shape, or an irregular polygon shape; wherein the surface of the metal thin plate or the metal foil is coated with a conductive carbon material coating; when the conductive layer 17 is used for a positive current collector, the metal sheet or metal foil is a metal sheet or metal foil made of aluminum, aluminum alloy, stainless steel, silver, tin, nickel, or titanium; when the conductive layer 17 is used for a negative current collector, the metal thin plate or the metal foil is a metal thin plate or a metal foil made of copper, stainless steel, nickel, titanium, silver, tin-plated copper, nickel-plated copper, or silver-plated copper.

As a switchable embodiment, the conductive layer 17 may also be an electronic conductive layer 17 having a plurality of through holes, the electronic conductive layer 17 is a conductive layer 17 made of one or more of porous polyester fiber conductive cloth, carbon fiber conductive cloth, and metal wire and organic fiber mixed conductive cloth, or the electronic conductive layer 17 is a conductive layer 17 made of an organic material with a conductive carbon material coating or a metal film coated on the surface, the organic material including natural cotton, polyester, aramid, nylon, polypropylene, polyethylene, polytetrafluoroethylene, and other organic substances with good electrolyte resistance; wherein, the through hole is round, oval, semicircular, square, hexagonal, triangular, rhombic, trapezoidal or irregular polygon.

As another alternative embodiment, the conductive layer 17 may be a conductive layer 17 having a single-layer mesh structure or a multi-layer mesh structure woven with conductive fibers, or the conductive layer 17 may be a foamed metal conductive layer 17 having a plurality of through holes; the through holes are circular, oval, semicircular, square, hexagonal, triangular, rhombic, trapezoidal or irregular polygons.

Further, the through hole of the conductive layer 17 of the present embodiment is filled with an insulating porous material, a gel polymer electrolyte plasma conductor material, so as to prevent an active slurry from entering the through hole of the conductive layer 17, thereby further improving the safety of the separator layer.

In this embodiment, it is preferable that the insulating coating 18 is physically and chemically coated on the side of the conductive layer 17 close to the insulating layer; wherein, the coating of the insulating coating 18 is provided by organic polymer material or inorganic ceramic material or other insulating material, the physical method comprises mechanical coating or electroplating or local soaking or vapor deposition method or laser, and the chemical method comprises electron beam surface treatment or thermal spraying.

Of course, as an alternative embodiment, the insulating coating 18 may also completely coat the conductive layer 17 by physical and chemical methods, and the side of the conductive layer 17 close to the slurry is cleaned by polishing, heat treatment, and chemical corrosion to expose the coating of the insulating coating 18;

wherein, the coating of the insulating coating 18 is provided by organic polymer material or inorganic ceramic material or other insulating material, the physical method comprises mechanical coating or electroplating or local soaking or vapor deposition method or laser, and the chemical method comprises electron beam surface treatment or thermal spraying; and then the insulating coating 18 close to one side of the slurry is removed by physical and chemical means such as polishing, heat treatment, chemical corrosion and the like, so that the conductive layer 17 is exposed.

On the basis of the above, the positive electrode current collector 1 and the negative electrode current collector 4 in the present embodiment may be made of one or more of filament, mesh, plate, rod, foam sponge, and fiber, depending on the energy storage active material in the active slurry; the positive electrode current collector 1 and the negative electrode current collector 4 may have the same structure or different materials.

Further, it is preferable that the energy storage active material in the active paste according to this embodiment is a particulate solid; the fixed shape of the particles is one or a mixture of a plurality of porous microsphere structures sintered by spherical, cylindrical, irregular sheet and micro particles.

The active slurry is composed of energy storage active substances, electrolyte, additives and the like, the energy storage active substances can be selected to have polydisperse particle size distribution, and the proportion of the energy storage active substances with different particle sizes is determined according to the slurry state required by the device. In this embodiment, the solid content of the active slurry is preferably 50% or more.

Furthermore, the energy storage active substance, the electrolyte and the additive can be selected from the anode and the cathode of the existing commercial battery system and the electrolyte material according to actual requirements. The energy storage active material can be selected from lithium ion battery material systems, such as: lithium cobaltate/lithium titanate/lithium salt carbonate, lithium manganate/carbon/lithium salt carbonate, lithium iron phosphate/carbon/lithium salt carbonate, and the like. The energy storage active material can be selected from a lead-acid battery system, such as lead dioxide/metallic lead/lead methylsulfonate aqueous solution, lead dioxide/metallic lead/dilute sulfuric acid and the like. The energy storage active material may also be selected from zinc-nickel battery systems such as: nickel dioxide/metallic zinc and zinc alloy/soluble zincate acidic aqueous solution, nickel dioxide/metallic zinc and zinc alloy/soluble zincate alkaline aqueous solution. The energy storage active material can also be selected from active materials used in a zinc-manganese battery system and an iron-nickel battery system. Or the energy storage active material can also be selected from a mixed system of the above multiple electric pairs or a newly discovered active material electric pair system.

As a preferred embodiment, a functional additive may also be added to the energy storage active material. Wherein, the functional additive can be one or more of conductive agent, thickening agent, antioxidant, SEI film improving additive, flame retardant additive and the like.

Example 3

On the basis of embodiment 2, this embodiment provides a specific stirring formula thick liquids energy memory, as follows:

the installed capacity is designed to be 750kwh, and the maximum power is designed to be 1mw. The whole device is about 0.8m high and occupies 2m of land ² On the left and right sides, the volume energy density of the device is about 469wh/L, which is basically consistent with the volume energy density of the current lithium ion battery. The device stirs the thick liquids intermittently in high-power charge-discharge process to stir the thick liquids after single charge-discharge circulation finishes.

The electrochemical reactor of the device has an inner length and width of 83cm × 200cm × 30cm, and specifically, as shown in fig. 3, grooves are engraved in the upper and lower casings. Wherein, the positive current collector 1 adopts a 100-mesh metal aluminum net, the negative current collector 4 adopts a 100-mesh metal copper net, and the diameters of the metal aluminum net and the metal copper net are 0.5mm. One side of the positive current collector 1 and one side of the negative current collector 4 are welded with the radiating fins 8 with the thickness of 0.5 mm; specifically, the heat sink 8 is made of copper metal, has a size of 50cm × 20cm, and has a surface coated with an insulating paint. The diaphragm is a porous PE diaphragm for an ion battery, wherein the aperture is about 0.08 μm, and the thickness of the diaphragm is 50 μm. The positive electrode current collector 1, the negative electrode current collector 4 and the diaphragm are combined with the corresponding positive plate frame 13, the negative plate frame 14 and the diaphragm plate frame 15 to form a positive plate, a negative plate and a diaphragm plate, the positive plate frame 13, the negative plate frame 14 and the diaphragm plate, and the joint of the positive plate frame 13, the negative plate frame 14 and the diaphragm plate is sealed by adopting insulating glue. Just, negative plate and diaphragm plate assemble according to the order of negative plate, diaphragm plate, positive plate, diaphragm plate, and the positive plate is 1000 pieces altogether, and the negative plate attacks 1001 pieces, and the diaphragm is 1000 pieces altogether, and each board interval is 1mm, and the kneck is sealed with the insulating cement, at the metal filter screen of 200 meshes of business turn over discharge gate 12 installation, shell about the installation to with the bolt lock die.

After the electrochemical reactor is installed, a certain amount of electrolyte wetting chamber is filled into the electrochemical reactor, and then the magnetons 9 are added from the feed port 11. Specifically, about 10000 particles are added into each negative electrode chamber 6, and 3000 particles are distributed in the positive electrode chamber. An electromagnet 10 is arranged on the upper and lower shells of the device; thereby completing the assembly of the device having the positive and negative electrode terminals 2 and 5.

The device adopts deposition type slurry prepared by commercial lithium ion battery system materials in the market, wherein the positive electrode material adopts positive electrode active substance particles composed of spinel lithium manganate powder, graphite powder and a binder, the particle size is between 5 and 500 mu m, and the negative electrode material adopts negative electrode active substance particles composed of graphite material, copper powder and a binder, the particle size is between 5 and 500 mu m. Electrolyte adopts the carbonic ester that has added lithium-containing electrolyte, mixes the stirring of above-mentioned material and becomes suspension type thick liquids, and in the injection device corresponds the cavity respectively, the deposit formed deposit type thick liquids, and positive pole active paste injection volume is 500L, is full of anodal cavity 3, and negative pole active paste injection volume is 500L and is full of negative pole cavity 6, fills up feed inlet 11 space with the electrolyte, makes the whole system keep isolated with the external world. The electromagnet 10 is started to enable the magneton 9 and the slurry to be mixed uniformly.

The device has the advantages of large energy storage capacity at one time and low preparation precision. In the embodiment, the active substance and the electrolyte can be replaced, the separated active substance can be directly recovered, the recovery cost is greatly reduced, the requirement on the service life of the used active substance can also be greatly reduced, and the cheaper active substance can be used. The reaction device is separated from the active substance, and the service life of the whole system is greatly prolonged because the service life of the reaction device is far longer than that of the active substance, and only the active substance needs to be updated at lower cost and little maintenance is needed during work.

Meanwhile, compared with the traditional winding lamination or polar plate type energy storage battery, the device can save a large amount of diaphragm, positive and negative pole current collector materials, the volume energy density and the mass energy density of the battery are also obviously improved, and the battery preparation does not need expensive battery manufacturing equipment such as a coating machine, a slicing machine, a lamination machine and the like, so the raw material cost and the manufacturing cost of the battery are greatly reduced, and compared with the current commercial lithium ion energy storage battery with the same scale, the cost of the device can be reduced by more than 30%.

It should be understood that the above embodiments are only examples for clearly illustrating the present invention, and are not intended to limit the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. And obvious variations or modifications therefrom are within the scope of the invention.

Claims (9)

1. Stirring structure, its characterized in that: the device comprises a cavity, electromagnets (10) arranged at two ends of the cavity, and magnetons (9) arranged in the cavity; the electromagnets (10) at the two ends are switched on and off, and the magnetons (9) move under the action of the magnetic fields of the electromagnets (10).

2. The stirring structure according to claim 1, wherein: the magnetons (9) are designed as magnetons (9) made of iron, cobalt, nickel or ferrite and other magnetic materials, which have one or more different diameters in the range of 10 [ mu ] m to 1mm.

3. Stirring formula thick liquids energy memory, it includes electrochemical reactor, its characterized in that: the device also comprises a stirring structure arranged in a positive electrode chamber (3) and a negative electrode chamber (6) of the electrochemical reactor, wherein the stirring structure is the stirring structure of claim 1 or 2; the electromagnets (10) at the two ends are switched between power-on and power-off according to a driving working system, and the magnetons (9) move under the action of the magnetic fields of the electromagnets (10) to stir the slurry in the cavity.

4. The agitated slurry energy storage device of claim 3, wherein: the surface of the magneton (9) is coated with a layer of insulating paint.

5. The agitated slurry energy storage device of claim 3 or 4, wherein: the electrochemical reactor comprises a positive electrode cavity (3), a negative electrode cavity (6), a diaphragm arranged between the positive electrode cavity (3) and the negative electrode cavity (6), a positive electrode current collector (1) and a negative electrode current collector (4).

6. The agitated slurry energy storage device of claim 5, wherein: the heat dissipation structure is used for dissipating heat of the cavity.

7. The agitated slurry energy storage device of claim 6, wherein: the heat radiation structure comprises a heat radiation fin (8) which is arranged outside the cavity and connected with the positive current collector (1) and the negative current collector (4).

8. The agitated slurry energy storage device of claim 7, wherein: the radiating fins (8) are connected with the positive current collector (1) and/or the negative current collector (4) through welding, gluing or mechanical contact, and the joints are sealed by adopting insulating glue; or the radiating fin (8) and the positive current collector (1) and/or the negative current collector (4) are integrally manufactured.

9. The agitated slurry energy storage device of claim 3, wherein: the driving working system comprises the following steps: during stirring, the electromagnet (10) at the first end of the chamber is electrified, the electromagnet (10) at the second end of the chamber is powered off, the magnetons (9) move under the action of a magnetic field and reach the first end, then the electromagnet (10) at the first end is powered off, the electromagnet (10) at the second end of the chamber is electrified, and the magnetons (9) move in the opposite direction under the action of the magnetic field and reach the second end; and then the cycle repeats.