CN113437373B - Equipment for repairing porous nano carbon repairing energy storage battery by using resonance pulse - Google Patents
Equipment for repairing porous nano carbon repairing energy storage battery by using resonance pulse Download PDFInfo
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/4207—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells for several batteries or cells simultaneously or sequentially
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B82—NANOTECHNOLOGY
- B82Y—SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
- B82Y30/00—Nanotechnology for materials or surface science, e.g. nanocomposites
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- B—PERFORMING OPERATIONS; TRANSPORTING
- B82—NANOTECHNOLOGY
- B82Y—SPECIFIC USES OR APPLICATIONS OF NANOSTRUCTURES; MEASUREMENT OR ANALYSIS OF NANOSTRUCTURES; MANUFACTURE OR TREATMENT OF NANOSTRUCTURES
- B82Y40/00—Manufacture or treatment of nanostructures
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/06—Lead-acid accumulators
- H01M10/12—Construction or manufacture
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- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M50/00—Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
- H01M50/60—Arrangements or processes for filling or topping-up with liquids; Arrangements or processes for draining liquids from casings
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- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
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Abstract
The invention discloses equipment for repairing a porous nano carbon repairing energy storage battery triggered by resonance pulses, which comprises a bearing frame, wherein an injection mechanism is arranged on the bearing frame; the injection mechanism includes: a plurality of bearing plates, a plurality of placing plates, a plurality of balls, a plurality of rollers and an injection structure; the invention has the beneficial effects that the green sustainable development of the lead-acid power battery is realized, the effective life extension and comprehensive performance improvement of the lead-acid power battery are realized, the energy sources are saved, the pollution of the lead-acid power battery is reduced, the scrapping and lead discharge of the battery are reduced, good economic and social benefits are obtained, new and old kinetic energy conversion is assisted, a lead-free emission pollution city is created, and the green sustainable development of the lead-acid power battery industry is promoted.
Description
Technical Field
The invention relates to the technical field of battery repair, in particular to a device for repairing an energy storage battery by triggering porous nano carbon through resonance pulse.
Background
At present, when repairing lead-acid power battery, current repair equipment mostly injects materials into the interior of lead-acid power battery through the syringe, this mode, on the one hand, injection efficiency is lower, simultaneously can not carry out massive injection work to lead-acid power battery, and current repair material has reduced lead-acid power battery's effective life-prolonging and comprehensive properties, wasted resources greatly, the pollution is serious, increased the volume of scrapping of battery and lead emission simultaneously, and the repair effect to lead-acid power battery is minimum, can not satisfy the green sustainable development of lead-acid battery trade, in view of this, to above-mentioned problem intensive research, the scheme has produced.
Disclosure of Invention
The invention aims to solve the problems, designs equipment for repairing the porous nano carbon repairing energy storage battery by using resonance pulse, solves the problems that most of the existing repairing equipment is used for injecting materials into the lead-acid power battery by using an injector, and on one hand, the injection efficiency is low, meanwhile, large-batch injection work cannot be carried out on the lead-acid power battery, the existing repairing material reduces the effective life and comprehensive performance of the lead-acid power battery, greatly wastes resources, causes serious pollution, increases the scrappage of the battery and lead emission, has extremely small repairing effect on the lead-acid power battery, and cannot meet the green sustainable development of the lead-acid battery industry.
The technical scheme of the invention for achieving the purpose is as follows: the device for repairing the porous nano carbon repairing energy storage battery by using the resonance pulse comprises a bearing frame, wherein an injection mechanism is arranged on the bearing frame;
the injection mechanism includes: a plurality of bearing plates, a plurality of placing plates, a plurality of balls, a plurality of rollers and an injection structure;
the bearing plates are respectively arranged on the bearing frame, the placing plates are arranged at the upper ends of the bearing plates, the balls are respectively rotatably arranged on the placing plates, the rollers are respectively arranged at the two ends of the placing plates in a rotating mode through the axes of the rollers, and the injection structure is arranged at the two ends of the bearing frame.
Preferably, the implantation structure includes: a plurality of screws, a plurality of mounting plates, a plurality of injection pipes, a plurality of injection ports, a feeding part and a driving part;
the screw rods are respectively arranged at two ends of the bearing frame in a rotating mode through the axis of the screw rods, the two ends of the mounting plates are respectively connected with the screw threads of the screw rods in a threaded mode, the injection pipes are distributed in the mounting plates, the injection ports are arranged at the lower ends of the mounting plates and are communicated with the injection pipes, the feeding portions are arranged on the bearing frame, and the driving portions are arranged at the lower ends of the bearing frame.
Preferably, the feeding part includes: a plurality of liquid storage tanks, a plurality of liquid delivery pumps, a plurality of telescopic pipes and a mixing assembly;
the liquid storage tanks are arranged on the bearing frame, the water inlet ends of the liquid delivery pumps are communicated with the lower ends of the liquid storage tanks, the upper ends of the telescopic pipes are communicated with the water outlet ends of the liquid delivery pumps, the other ends of the telescopic pipes are communicated with the injection pipes, and the mixing components are arranged inside the liquid storage tanks.
Preferably, the driving part includes: the device comprises a first rotating motor, a plurality of belt pulleys and a connecting belt;
the first rotating motor is rotatably arranged in the supporting frame, the pulleys are sleeved on the screw rods and the driving ends of the rotating motor respectively, and the connecting belts are sleeved on the outer sides of the pulleys respectively.
Preferably, the mixing assembly comprises: a plurality of second rotating motors, a plurality of stirring shafts and a plurality of stirring blades;
the second rotating motors are respectively embedded at the lower ends of the interiors of the liquid storage tanks, the stirring shafts are arranged at the driving ends of the second rotating motors, and the stirring fan blades are respectively arranged on the stirring shafts.
Preferably, the lower ends of the injection ports are provided with pistons, the pistons are provided with vent holes, and the vent holes are provided with liquid level meters.
Preferably, rubber pads are arranged on the outer wall surfaces of the plurality of rollers.
Preferably, the shape of the plurality of placing plates is U-shaped.
Preferably, the upper ends of the liquid storage tanks are respectively provided with a feeding port.
The method for repairing the porous nano carbon repairing energy storage battery triggered by the resonance pulse comprises the following steps: the method comprises the following operation steps: step S1, preparing a nano porous carbon composite hydrosol multicomponent synergistic desulfurization material, step S2, optimizing a synergistic repair process, step S3, preparing nano porous carbon repair hydrosol, step S4, optimizing synergistic repair of resonance pulse repair equipment and the nano porous carbon composite hydrosol, and step S5, and injecting by an injection device;
step S1, preparing a three-dimensional metal organic crystalline material (ZIF) constructed by metal ions and imidazole ligands; preparing a porous carbon material by calcining the ZIF at a high temperature, and carrying out surface hydrophilic treatment on the porous carbon material; preparing a porous carbon host-guest composite material (ZIFC) by in-situ encapsulation of different metal oxygen clusters; the ZIFC is coated with the conductive high polymer, so that the water solubility is further enhanced; adding functional micromolecular synergistic auxiliary agents, and preparing nano porous carbon composite hydrosol through formula optimization;
step S2, the lead-acid power battery performance degradation causes are diversified due to different use environments and modes, and the restoration value of the storage battery is required to be integrally pre-judged during restoration; then, according to the failure mode of the repairable battery, targeted repair is carried out, the optimal process of the composite resonance pulse and the nano porous carbon composite hydrosol for synergistically repairing the lead-acid battery is optimized, and a comprehensive innovative technical system for marketing operation is formed;
s3, preparing ZIFs by using a normal-temperature aqueous solution method; preparing a nano porous carbon material by adopting high-temperature reaction under the protection of inert gas, and performing oxidization hydrophilic treatment on the porous carbon material by using strong acid or hydrogen peroxide and the like; then, in-situ encapsulation of the metal oxygen clusters in the water phase by utilizing an acid-induced self-assembly mode to prepare ZIFC; the surface of the porous carbon is modified with a soluble conductive polymer to further enhance the water solubility of the ZIFC; adding functional micromolecular synergistic auxiliary agents to prepare nano porous carbon composite hydrosol, and optimizing a formula;
step S4, (a) detecting a battery, detecting appearance damage, and measuring specific gravity, voltage and internal resistance of the electrolyte; (b) Initial capacity measurement, discharging a full-charge battery, discharging a standard C10, and stopping the battery at a voltage of 1.8V, (C) adding a porous carbon composite hydrosol into the battery, wherein the adding ratio is 1Ah about 1mL, standing the battery for 12 h, (d) charging and activating the battery, repairing the battery by using a resonance pulser, (e) pulse, repairing the battery for 72h by using the resonance pulser, discharging the nuclear capacity, discharging the repaired battery, discharging the standard C10, and stopping the battery at a voltage of 1.8V, (g) delivering the battery in a matched mode;
and S5, injecting the solutions prepared in the steps S1, S2 and S3 into the lead-acid power battery through the repairing device by the repairing device.
The device for repairing the porous nano carbon repairing energy storage battery by using the resonance pulse produced by the technical scheme of the invention realizes the green sustainable development of the lead-acid power battery, and the device repairs the waste lead-acid power battery by using the novel composite resonance pulse synergistic nano porous carbon composite hydrosol technology, realizes the effective life prolonging and comprehensive performance improvement of the lead-acid power battery, saves energy and reduces the pollution of the lead-acid power battery. After a complete technical system is formed, an operation center is established nationwide to repair the lead-acid power battery, waste is changed into valuable, renewable energy is obtained, battery scrapping and lead emission are reduced, good economic and social benefits are obtained, new and old kinetic energy conversion is assisted, a lead-free emission pollution city is created, and green sustainable development of the lead-acid power battery industry is promoted.
Drawings
Fig. 1 is a schematic diagram of a front view cross-section structure of a device for repairing a porous nanocarbon repairing energy storage battery triggered by resonance pulses.
Fig. 2 is a schematic diagram of a side-view cross-sectional structure of a device for repairing a porous nanocarbon repair energy storage battery triggered by resonance pulses.
Fig. 3 is a schematic diagram of a partial enlarged structure of the device for repairing the porous nanocarbon repairing energy storage battery triggered by the resonance pulse according to the present invention.
Fig. 4 is a schematic diagram of a partial enlarged structure of the device for repairing the porous nanocarbon repairing energy storage battery triggered by the resonance pulse according to the present invention.
Fig. 5 is a schematic diagram of a bottom cross-sectional structure of a device for repairing a porous nanocarbon-triggered repair energy storage battery according to the present invention.
Fig. 6 is a schematic diagram of a ball partial enlarged structure of a device for repairing a porous nanocarbon repairing energy storage battery triggered by resonance pulses.
In the figure: 1. the device comprises a bearing frame, 2, a bearing plate, 3, a placing plate, 4, balls, 5, rollers, 6, screws, 7, a mounting plate, 8, an injection pipe, 9, an injection port, 10, a liquid storage tank, 11, a rubber pad, 12, an infusion pump, 13, a telescopic pipe, 14, a first rotating motor, 15, a belt pulley, 16, a connecting belt, 17, a piston, 18, a second rotating motor, 19, a stirring shaft, 20, stirring blades, 21, a feed inlet, 22, a vent hole, 23 and a liquid level meter.
Detailed Description
The invention is specifically described below with reference to the accompanying drawings, as shown in fig. 1-6, a device for repairing a porous nano carbon repairing energy storage battery triggered by resonance pulse comprises a bearing frame 1, wherein an injection mechanism is arranged on the bearing frame 1;
the injection mechanism includes: a plurality of bearing plates 2, a plurality of placing plates 3, a plurality of balls 4, a plurality of rollers 5 and an injection structure;
the bearing plates 2 are respectively arranged on the bearing frame 1, the placing plates 3 are arranged at the upper ends of the bearing plates 2, the balls 4 are respectively rotatably arranged on the placing plates 3, the rollers 5 are respectively arranged at the two ends of the placing plates in a rotating way along the axis of the rollers, and the injection structure is arranged at the two ends of the bearing frame 1.
In the specific implementation process, it is to be noted that, firstly, the lead-acid power battery is placed on the placement plate 3 in sequence, when the placement is performed, the lead-acid power battery is pushed from the front side of the placement plate 3, the lower end of the lead-acid power battery moves through a plurality of balls 4, and the two ends move through rollers 5, so that the lead-acid power battery is placed on the placement plate 3.
Preferably, the implantation structure further comprises: a plurality of screws 6, a plurality of mounting plates 7, a plurality of injection pipes 8, a plurality of injection ports 9, a feeding part and a driving part;
the screw rods 6 are respectively arranged at two ends of the bearing frame 1 in a rotating mode through the axis of the screw rods 6, the two ends of the mounting plates 7 are respectively connected with the screw threads of the screw rods 6 in a threaded mode, the injection pipes 8 are distributed in the mounting plates 7, the injection openings are arranged at the lower ends of the mounting plates 7 and are communicated with the injection pipes 8, the feeding portions are arranged on the bearing frame 1, and the driving portions are arranged at the lower ends of the bearing frame 1.
In the specific implementation process, the feeding part starts feeding, the material enters the injection port 9 through the injection pipe 8, the driving part drives the screw rod 6 to rotate, the mounting plate 7 is driven by the screw rod 6 to fill the material at the injection port 9 into the lead-acid power battery.
Preferably, further, the feeding part includes: a plurality of liquid storage tanks 10, a plurality of infusion pumps 12, a plurality of telescopic pipes 13 and a mixing assembly;
the liquid storage tanks 10 are arranged on the bearing frame 1, the water inlet ends of the liquid delivery pumps 12 are communicated with the lower ends of the liquid storage tanks 10, the upper ends of the telescopic pipes 13 are communicated with the water outlet ends of the liquid delivery pumps 12, the other ends of the telescopic pipes are communicated with the injection pipes 8, and the mixing components are arranged inside the liquid storage tanks 10.
In the specific implementation process, it should be noted that when the material is poured into the liquid storage tank 10, the material mixing assembly is started, so that the material is more uniform in the liquid storage tank 10, after the material mixing is completed, the infusion pump 12 starts to start, the material in the liquid storage tank 10 is conveyed into the liquid outlet pipe 11 from the telescopic pipe 13, and finally the material can be filled into the lead-acid power battery through the injection port 9.
Preferably, further, the driving section includes: a first rotating electric machine 14, a plurality of pulleys 15, and a connecting belt 16;
the first rotating motor 14 is rotatably arranged in the lower end of the supporting frame, the plurality of belt pulleys 15 are respectively sleeved on the plurality of screw rods 6 and the driving end of the rotating motor, and the connecting belt 16 is respectively sleeved on the outer sides of the plurality of belt pulleys 15.
In the specific implementation process, it should be noted that the screws 6 rotate under the interaction of the belt pulley 15 and the connecting belt 16 driven by the first rotating motor 14 by the plurality of screws 6,
preferably, further, the mixing assembly comprises: a plurality of second rotating motors 18, a plurality of stirring shafts 19 and a plurality of stirring blades 20;
the second rotating motors 18 are respectively embedded at the lower ends of the inside of the liquid storage tank 10, the stirring shafts 19 are arranged at the driving ends of the second rotating motors 18, and the stirring blades 20 are respectively arranged on the stirring shafts 19.
In a specific implementation process, when the material mixing is needed, the second rotating motor 18 rotates to drive the stirring shaft 19 to rotate, and the plurality of stirring blades 20 rotate under the drive of the stirring shaft 19, so that the material inside the liquid storage tank 10 is mixed.
Preferably, further, the lower ends of the injection ports 9 are provided with pistons 17, the pistons are provided with vent holes 22, and the vent holes 22 are provided with liquid level gauges 23.
In the specific implementation process, as the mounting plate 7 descends, the injection port 9 is driven to descend, then the injection port 9 descends to a port at the upper end of the lead-acid power battery, and in the injection process, the ventilation hole 22 is used for ventilation, so that materials are injected into the interior of the lead-acid power battery more rapidly.
Preferably, further, rubber pads 11 are mounted on the outer wall surfaces of the plurality of rollers 5.
In the specific implementation, it should be noted that, when the lead-acid power battery is pushed onto the placement plate 3, the rubber pad 11 is used to prevent the lead-acid power battery from wearing.
Preferably, further, the shape of the plurality of placing plates 3 is U-shaped, and the U-shaped placing plates 3 can limit the lead-acid power battery.
Preferably, further, the upper ends of the plurality of liquid storage tanks 10 are respectively provided with a feed inlet 21.
The method for repairing the porous nano carbon repairing energy storage battery triggered by the resonance pulse comprises the following steps: the method comprises the following operation steps: step S1, preparing a nano porous carbon composite hydrosol multicomponent synergistic desulfurization material, step S2, optimizing a synergistic repair process, step S3, preparing nano porous carbon repair hydrosol, step S4, optimizing synergistic repair of resonance pulse repair equipment and the nano porous carbon composite hydrosol, and step S5, and injecting by an injection device;
step S1, preparing a three-dimensional metal organic crystalline material (ZIF) constructed by metal ions and imidazole ligands; preparing a porous carbon material by calcining the ZIF at a high temperature, and carrying out surface hydrophilic treatment on the porous carbon material; preparing a porous carbon host-guest composite material (ZIFC) by in-situ encapsulation of different metal oxygen clusters; the ZIFC is coated with the conductive high polymer, so that the water solubility is further enhanced; adding functional micromolecular synergistic auxiliary agents, and preparing nano porous carbon composite hydrosol through formula optimization;
step S2, the lead-acid power battery performance degradation causes are diversified due to different use environments and modes, and the restoration value of the storage battery is required to be integrally pre-judged during restoration; then, according to the failure mode of the repairable battery, targeted repair is carried out, the optimal process of the composite resonance pulse and the nano porous carbon composite hydrosol for synergistically repairing the lead-acid battery is optimized, and a comprehensive innovative technical system for marketing operation is formed;
s3, preparing ZIFs by using a normal-temperature aqueous solution method; preparing a nano porous carbon material by adopting high-temperature reaction under the protection of inert gas, and performing oxidization hydrophilic treatment on the porous carbon material by using strong acid or hydrogen peroxide and the like; then, in-situ encapsulation of the metal oxygen clusters in the water phase by utilizing an acid-induced self-assembly mode to prepare ZIFC; the surface of the porous carbon is modified with a soluble conductive polymer to further enhance the water solubility of the ZIFC; adding functional micromolecular synergistic auxiliary agents to prepare nano porous carbon composite hydrosol, and optimizing a formula;
step S4, (a) detecting a battery, detecting appearance damage, and measuring specific gravity, voltage and internal resistance of the electrolyte; (b) Initial capacity measurement, discharging a full-charge battery, discharging a standard C10, and stopping the battery at a voltage of 1.8V, (C) adding a porous carbon composite hydrosol into the battery, wherein the adding ratio is 1Ah about 1mL, standing the battery for 12 h, (d) charging and activating the battery, repairing the battery by using a resonance pulse instrument, (e) pulse, repairing the battery for 72h by using the resonance pulse instrument, discharging the nuclear capacity, discharging the repaired battery, discharging the standard C10, and stopping the battery at a voltage of 1.8V, and (g) delivering the battery in a matched mode;
and S5, injecting the solutions prepared in the steps S1, S2 and S3 into the lead-acid power battery through the repairing device by the repairing device.
The above technical solution only represents the preferred technical solution of the present invention, and some changes that may be made by those skilled in the art to some parts of the technical solution represent the principles of the present invention, and the technical solution falls within the scope of the present invention.
Claims (10)
1. The method for repairing the porous nano carbon repairing energy storage battery triggered by the resonance pulse comprises the following steps: the method comprises the following operation steps: step S1, preparing a nano porous carbon composite hydrosol multicomponent synergistic desulphurized material, and step S2, optimizing a synergistic restoration process;
in the step S1 of the method,
preparing ZIF by using a normal-temperature aqueous solution method; preparing a nano porous carbon material by adopting high-temperature reaction under the protection of inert gas, and performing oxidization hydrophilic treatment on the porous carbon material by using strong acid or hydrogen peroxide and the like; then, in-situ encapsulation of the metal oxygen clusters in the water phase by utilizing an acid-induced self-assembly mode to prepare ZIFC; the surface of the porous carbon is modified with a soluble conductive polymer to further enhance the water solubility of the ZIFC; adding functional micromolecular synergistic auxiliary agents to prepare nano porous carbon composite hydrosol, and optimizing a formula;
in the step S2 of the method,
(a) Detecting a battery, detecting appearance damage, and measuring specific gravity, voltage and internal resistance of electrolyte; (b) Initial capacity measurement, discharging a full-charge battery, discharging a standard C10, and stopping the voltage at 1.8V, (C) adding liquid into the battery, adding porous carbon composite hydrosol, filling the sol prepared in the step S1 into the lead-acid power battery through repairing equipment, wherein the liquid adding ratio is about 1mL of 1Ah, standing for 12 h, (d) charging and activating, using a resonance pulser, (e) pulse repairing, using the resonance pulser, repairing the battery for 72h, (f) nuclear capacity discharging, discharging the battery after repairing, discharging the standard C10, and stopping the voltage at 1.8V, (g) matching and delivering for use.
2. The device for repairing the porous nanocarbon repairing energy storage battery triggered by the resonance pulse applied to the method as claimed in claim 1 comprises a bearing frame (1), and is characterized in that an injection mechanism is arranged on the bearing frame (1);
the injection mechanism includes: a plurality of bearing plates (2), a plurality of placing plates (3), a plurality of balls (4), a plurality of rollers (5) and an injection structure;
the bearing plates (2) are respectively arranged on the bearing frame (1), the placing plates (3) are arranged at the upper ends of the bearing plates (2), the balls (4) are respectively rotatably arranged on the placing plates (3), the rollers (5) are respectively arranged at the two ends of the placing plates in a rotating mode through the axes of the rollers, and the injection structure is arranged at the two ends of the bearing frame (1).
3. The device for repairing a porous nanocarbon repair energy storage cell triggered by a resonance pulse according to claim 2, wherein the injection structure comprises: a plurality of screws (6), a plurality of mounting plates (7), a plurality of injection pipes (8), a plurality of injection ports (9), a feeding part and a driving part;
the screw rods (6) are respectively arranged at two ends of the bearing frame (1) in a rotating mode through the axes of the screw rods (6), the two ends of the mounting plates (7) are respectively connected with the screw threads of the screw rods (6) in a threaded mode, the injection pipes (8) are distributed in the mounting plates (7), the injection ports (9) are arranged at the lower ends of the mounting plates (7) and are communicated with the injection pipes (8), the feeding portions are arranged on the bearing frame (1), and the driving portions are arranged at the lower ends of the bearing frame (1).
4. The apparatus for repairing a porous nanocarbon-triggered repair energy storage cell of claim 3, wherein the feed portion comprises: a plurality of liquid storage tanks (10), a plurality of liquid delivery pumps (12), a plurality of telescopic pipes (13) and a mixing assembly;
the liquid storage tanks (10) are arranged on the bearing frame (1), the water inlet ends of the liquid delivery pumps (12) are communicated with the lower ends of the liquid storage tanks (10), the upper ends of the telescopic pipes (13) are communicated with the water outlet ends of the liquid delivery pumps (12), the other ends of the telescopic pipes are communicated with the injection pipes (8), and the mixing components are arranged inside the liquid storage tanks (10).
5. The device for repairing a porous nanocarbon repair energy storage cell triggered by a resonance pulse according to claim 3, wherein the driving part comprises: a first rotating electric machine (14), a plurality of pulleys (15) and a connecting belt (16);
the first rotating motor (14) is rotatably arranged in the supporting frame, the belt pulleys (15) are respectively sleeved on the screw rods (6) and the driving ends of the rotating motor, and the connecting belts (16) are respectively sleeved on the outer sides of the belt pulleys (15).
6. The apparatus for repairing a porous nanocarbon repair energy storage cell triggered by a resonant pulse of claim 4, wherein the mixing assembly comprises: a plurality of second rotating motors (18), a plurality of stirring shafts (19) and a plurality of stirring blades (20);
the second rotating motors (18) are respectively embedded at the lower ends of the interiors of the liquid storage tanks (10), the stirring shafts (19) are arranged at the driving ends of the second rotating motors (18), and the stirring blades (20) are respectively arranged on the stirring shafts (19).
7. The device for repairing the porous nano carbon repairing energy storage battery triggered by the resonance pulse according to claim 3, wherein a plurality of pistons (17) are arranged at the lower ends of a plurality of injection ports (9), a plurality of vent holes (22) are formed in the plurality of pistons, and a plurality of liquid level meters (23) are arranged at the positions of the plurality of vent holes (22).
8. The device for repairing the porous nano carbon repairing energy storage battery triggered by the resonance pulse according to claim 2, wherein rubber pads (11) are arranged on the outer wall surfaces of the plurality of rollers (5).
9. Device for repairing a porous nanocarbon repair energy storage cell triggered by a resonance pulse according to claim 2, characterized in that several of said placement plates (3) are U-shaped in shape.
10. The device for repairing the porous nano carbon repairing energy storage battery triggered by the resonance pulse according to claim 4, wherein the upper ends of the plurality of liquid storage tanks (10) are respectively provided with a feed inlet (21).
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Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104518248A (en) * | 2014-10-23 | 2015-04-15 | 方占兵 | Nano carbon sol lead-acid storage battery devulcanization repairing liquid |
CN108493503A (en) * | 2017-11-13 | 2018-09-04 | 天能集团(濮阳)再生资源有限公司 | A kind of lead-acid accumulator repairs liquid and preparation method thereof |
CN110581319A (en) * | 2018-06-11 | 2019-12-17 | 沈阳一正能源科技有限公司 | neutral repair liquid for lead-acid storage battery and preparation process thereof |
CN112054253A (en) * | 2020-07-30 | 2020-12-08 | 济南大学 | Preparation method and application of activated compatibilizer for repairing failed lead-acid storage battery |
Family Cites Families (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN108123136B (en) * | 2016-11-26 | 2020-07-07 | 中国科学院大连化学物理研究所 | Lead-carbon battery composite negative electrode additive, lead-carbon battery negative electrode, preparation and application |
CN110444823A (en) * | 2018-05-03 | 2019-11-12 | 山东承泽能源科技有限公司 | A kind of lead-acid accumulator off-line type resonant pulses restorative procedure |
CN108574122A (en) * | 2018-06-08 | 2018-09-25 | 南京陶特思软件科技有限公司 | A kind of reparation water replanishing device of accumulator |
CN111082168A (en) * | 2019-12-04 | 2020-04-28 | 缙云洛伊电子科技有限公司 | Electric motor car lead acid battery repair equipment |
CN211879554U (en) * | 2020-04-14 | 2020-11-06 | 四川三合顺通科技有限公司 | Novel lead-acid storage battery repairing device |
CN212783707U (en) * | 2020-06-17 | 2021-03-23 | 天能电池集团(安徽)有限公司 | Independent battery acidification area lifting platform mechanism |
CN112421132B (en) * | 2020-10-27 | 2023-07-28 | 盐城工学院 | Lead-acid battery repair liquid and preparation method and application thereof |
-
2021
- 2021-06-26 CN CN202110713948.1A patent/CN113437373B/en active Active
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104518248A (en) * | 2014-10-23 | 2015-04-15 | 方占兵 | Nano carbon sol lead-acid storage battery devulcanization repairing liquid |
CN108493503A (en) * | 2017-11-13 | 2018-09-04 | 天能集团(濮阳)再生资源有限公司 | A kind of lead-acid accumulator repairs liquid and preparation method thereof |
CN110581319A (en) * | 2018-06-11 | 2019-12-17 | 沈阳一正能源科技有限公司 | neutral repair liquid for lead-acid storage battery and preparation process thereof |
CN112054253A (en) * | 2020-07-30 | 2020-12-08 | 济南大学 | Preparation method and application of activated compatibilizer for repairing failed lead-acid storage battery |
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