WO2018177138A1 - Ensemble plaque de recouvrement de batterie, batterie unique, module de batterie, bloc-batterie d'alimentation et voiture électrique - Google Patents

Ensemble plaque de recouvrement de batterie, batterie unique, module de batterie, bloc-batterie d'alimentation et voiture électrique Download PDF

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Publication number
WO2018177138A1
WO2018177138A1 PCT/CN2018/079240 CN2018079240W WO2018177138A1 WO 2018177138 A1 WO2018177138 A1 WO 2018177138A1 CN 2018079240 W CN2018079240 W CN 2018079240W WO 2018177138 A1 WO2018177138 A1 WO 2018177138A1
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WIPO (PCT)
Prior art keywords
battery
electrode
gas
terminal
cover
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Application number
PCT/CN2018/079240
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English (en)
Chinese (zh)
Inventor
杨珂利
蒋露霞
鲁鹏
程晗
胡世超
朱建华
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比亚迪股份有限公司
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Publication of WO2018177138A1 publication Critical patent/WO2018177138A1/fr

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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60LPROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
    • B60L50/00Electric propulsion with power supplied within the vehicle
    • B60L50/50Electric propulsion with power supplied within the vehicle using propulsion power supplied by batteries or fuel cells
    • B60L50/60Electric propulsion with power supplied within the vehicle using propulsion power supplied by batteries or fuel cells using power supplied by batteries
    • B60L50/64Constructional details of batteries specially adapted for electric vehicles
    • BPERFORMING OPERATIONS; TRANSPORTING
    • B60VEHICLES IN GENERAL
    • B60LPROPULSION OF ELECTRICALLY-PROPELLED VEHICLES; SUPPLYING ELECTRIC POWER FOR AUXILIARY EQUIPMENT OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRODYNAMIC BRAKE SYSTEMS FOR VEHICLES IN GENERAL; MAGNETIC SUSPENSION OR LEVITATION FOR VEHICLES; MONITORING OPERATING VARIABLES OF ELECTRICALLY-PROPELLED VEHICLES; ELECTRIC SAFETY DEVICES FOR ELECTRICALLY-PROPELLED VEHICLES
    • B60L50/00Electric propulsion with power supplied within the vehicle
    • B60L50/50Electric propulsion with power supplied within the vehicle using propulsion power supplied by batteries or fuel cells
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M10/00Secondary cells; Manufacture thereof
    • H01M10/04Construction or manufacture in general
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M50/00Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
    • H01M50/10Primary casings; Jackets or wrappings
    • H01M50/147Lids or covers
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M50/00Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
    • H01M50/50Current conducting connections for cells or batteries
    • H01M50/543Terminals
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M50/00Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
    • H01M50/50Current conducting connections for cells or batteries
    • H01M50/572Means for preventing undesired use or discharge
    • H01M50/574Devices or arrangements for the interruption of current
    • H01M50/578Devices or arrangements for the interruption of current in response to pressure
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M50/00Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
    • H01M50/50Current conducting connections for cells or batteries
    • H01M50/572Means for preventing undesired use or discharge
    • H01M50/574Devices or arrangements for the interruption of current
    • H01M50/581Devices or arrangements for the interruption of current in response to temperature
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M50/00Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
    • H01M50/30Arrangements for facilitating escape of gases
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M50/00Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
    • H01M50/50Current conducting connections for cells or batteries
    • H01M50/531Electrode connections inside a battery casing
    • H01M50/536Electrode connections inside a battery casing characterised by the method of fixing the leads to the electrodes, e.g. by welding
    • HELECTRICITY
    • H01ELECTRIC ELEMENTS
    • H01MPROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
    • H01M50/00Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
    • H01M50/50Current conducting connections for cells or batteries
    • H01M50/572Means for preventing undesired use or discharge
    • H01M50/584Means for preventing undesired use or discharge for preventing incorrect connections inside or outside the batteries
    • H01M50/586Means for preventing undesired use or discharge for preventing incorrect connections inside or outside the batteries inside the batteries, e.g. incorrect connections of electrodes
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/10Energy storage using batteries
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02PCLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
    • Y02P70/00Climate change mitigation technologies in the production process for final industrial or consumer products
    • Y02P70/50Manufacturing or production processes characterised by the final manufactured product
    • YGENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02TCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
    • Y02T10/00Road transport of goods or passengers
    • Y02T10/60Other road transportation technologies with climate change mitigation effect
    • Y02T10/70Energy storage systems for electromobility, e.g. batteries

Definitions

  • the present application relates to the field of batteries, and in particular to a battery cover assembly, a battery using the battery cover assembly, a battery module including the battery, a power battery package including the battery module, and the like Electric battery pack for electric vehicles.
  • the existing CID (Current Interrupt Device) technical solution usually has a pull-off structure with an induced air pressure in the battery, and the reaction between the internal electrolyte and the electrode material is caused by the battery in an extreme case such as thermal runaway. A large amount of gas is generated inside the battery. When the internal gas of the battery increases, the internal pressure increases, and the increased pressure causes the flipper in the pull-off structure to be turned outward, thereby breaking the broken piece having local thinning.
  • the above structure is particularly unsuitable for ternary materials. Because of the high activity of ternary materials, thermal runaway can easily occur in a short period of time in extreme cases. At the beginning of the battery overcharging, the pressure generated by the inside is too small to cause the flipper to be turned over to break the fracture piece. When the internal pressure of the battery is too high, the battery is often in a state of thermal runaway. At this time, although the circuit can be pulled off, the mutual reaction between the materials inside the battery cannot be terminated, and the battery cannot be protected.
  • An object of the present disclosure is to provide a battery cover assembly capable of improving battery safety, a single battery using the battery cover assembly, a battery module including the same, a power battery package including the battery module, and An electric car including the power battery pack.
  • the present disclosure provides a battery cover assembly including a cover plate, an electrode inner terminal and an electrode outer terminal, wherein the electrode inner terminal and the electrode outer terminal are electrically connected by a current interrupting structure mounted on the cover plate,
  • the battery cover assembly further includes a sealed cavity for filling a gas-producing medium and mounted on an outer side of the cover plate, the sealed cavity being configured such that the gas-producing medium is electrically connected to the positive and negative electrodes of the battery, respectively.
  • the gas-producing medium is capable of generating a gas to break the sealed chamber under the pressure of the gas to cause the Gas enters the interior of the battery and circulates to the current interrupting structure to break the electrical connection between the electrode inner terminal and the electrode outer terminal by air pressure.
  • the rating ranges from 4.5 volt to 5 volts.
  • the gas-producing medium comprises at least one of biphenyl, tert-amyl, cyclohexylbenzene, terphenyl, cyclohexylbiphenyl and dibenzofuran.
  • the battery cover assembly includes a first polarity member and a second polarity member respectively in contact with the gas-producing medium, wherein the first polarity member and the second polarity member One for electrically connecting to the battery positive electrode and the other for electrically connecting to the battery negative electrode, the first polarity member being sealed and insulatedly connected to the second polarity member to be integrally formed toward the battery interior
  • An open cover-like structure, the opening in the cover structure is also sealingly connected with a pressure relief member to enclose the sealed cavity, and the pressure relief member can be broken under the air pressure to allow the gas to flow to the The inside of the battery.
  • the second polar member is fixed to the cover plate to be electrically connected to the battery positive electrode or the battery negative electrode through the cover plate.
  • a mounting hole is formed in the cover plate, and the second polarity member is mounted to an inner wall of the mounting hole such that an opening of the cover structure faces the inside of the battery.
  • the first polarity member is electrically connected to the electrode terminal exposing the cover plate through the conductive connection piece.
  • a first notch is formed on the pressure relief member, and the first score can be broken under the air pressure to allow the gas to escape through the pressure relief member.
  • the pressure relief member is formed as a pressure relief plate having the first indentation, and the pressure relief plate is formed with a weakening sinking groove, and the first notch is located on the bottom wall of the groove of the weakening sinking groove.
  • the first score is formed as a non-linear structure spaced apart at both ends.
  • the non-linear structure is formed as a superior arc structure.
  • an annular insulating strip having an H-shaped longitudinal section is disposed between the first polarity member and the second polarity member to insulate the first polarity member from the second polarity member, the cover
  • the structure includes a cover structure as the first polar member, and a cover structure as the second polar member, the edge of the cover structure and the cover edge structure being respectively embedded and sealed to the H-shaped In the U-shaped groove at opposite ends of the structure, the outer periphery of the cover edge structure is fixedly connected to the cover plate.
  • the cover body structure is formed with a medium injection hole, and the medium injection hole is blocked with a detachable sealing plug.
  • a first electrode terminal and the second electrode terminal are mounted on the cover plate, and the first polarity member is disposed adjacent to the first electrode terminal of the battery and electrically connected to the first electrode terminal And the cover plate is electrically connected to the second electrode terminal of the battery, and the current interruption structure is mounted on the first electrode terminal or the second electrode terminal.
  • the current interruption structure further includes a flip member electrically connected between the electrode inner terminal and the electrode outer terminal, and an outer circumference of the flip member is sealingly and insulatively connected to the cover plate,
  • the seal pack is in gaseous communication with the inner surface of the flip member to actuate the electrical connection to the terminal within the electrode under the action of the gas pressure of the gas.
  • a conductive member is fixed on an outer end surface of the electrode inner terminal, the flip member is electrically connected to the conductive member, and the conductive member is formed with a gas pressure capable of being disconnected by the gas.
  • a score that is disposed around a connection point for connecting the flip member.
  • the flip member is further covered with a cover member electrically connected to the flip member to form the electrode outer terminal.
  • the cover member is formed with air holes communicating with the outside.
  • the present disclosure also provides a single battery comprising a housing, a battery core housed in the housing, the unit battery is a battery cover assembly provided by the disclosure, and the cover encloses the housing
  • the battery cell is electrically connected to the inner terminal of the electrode.
  • the present disclosure also provides a battery module in which the unit battery provided by the present disclosure is disposed.
  • the present disclosure also provides a power battery package including a package body and a battery module disposed in the package body, the battery module being the battery module provided by the present disclosure.
  • the present disclosure also provides an electric vehicle provided with a power battery pack provided by the present disclosure.
  • the gas production of the sealed cavity in the cover plate assembly can be generated independently of the gas inside the battery, so that the air pressure can be established for the current interruption structure in time, thereby breaking the current interruption structure in time and improving the safety of the battery.
  • FIG. 1 is a cross-sectional schematic view of a current interrupting structure provided in accordance with a first embodiment of the present disclosure
  • FIG. 2 is a top plan view of a second polar member according to a first embodiment of the present disclosure
  • FIG. 3 is a cross-sectional view of a current interrupting structure provided in accordance with a second embodiment of the present disclosure, wherein a voltage difference between the first polarity member and the second polarity member does not exceed a rating;
  • FIG. 4 is a top plan view of an insulating ring provided in accordance with a second embodiment of the present disclosure.
  • FIG. 5 is a cross-sectional view of a current interrupting structure provided in accordance with a second embodiment of the present disclosure, wherein a voltage difference between the first polarity member and the second polarity member exceeds a nominal value;
  • FIG. 6 is a cross-sectional view of a current interrupting structure provided in accordance with a second embodiment of the present disclosure, wherein the sealed chamber is filled with a gas-producing medium;
  • FIG. 7 is a cross-sectional view of a current interrupting structure provided in accordance with a third embodiment of the present disclosure, wherein a voltage difference between the first polarity member and the second polarity member does not exceed a rating;
  • FIG. 8 is a top plan view of an inner insulating ring provided in accordance with a third embodiment of the present disclosure.
  • FIG. 9 is a cross-sectional view of a current interrupting structure provided in accordance with a third embodiment of the present disclosure, wherein a voltage difference between the first polar member and the second polar member exceeds a nominal value;
  • FIG. 10 is a cross-sectional view of a current interrupting structure provided in accordance with a third embodiment of the present disclosure, wherein the sealed chamber is filled with a gas generating medium;
  • FIG. 11 is a cross-sectional view of a current interrupting structure provided in accordance with a fourth embodiment of the present disclosure, wherein a voltage difference between the first polarity member and the second polarity member does not exceed a rating;
  • FIG. 12 is a cross-sectional view of a current interrupting structure provided in accordance with a fourth embodiment of the present disclosure, wherein a voltage difference between the first polar member and the second polar member exceeds a nominal value;
  • FIG. 13 is a cross-sectional schematic view of a first embodiment of a current interrupting structure provided in accordance with a fifth embodiment of the present disclosure
  • FIG. 14 is a cross-sectional schematic view of a second embodiment of a current interrupting structure provided in accordance with a fifth embodiment of the present disclosure.
  • FIG. 15 is a partial cross-sectional view of a unit cell provided in a position according to a sixth embodiment of the present disclosure.
  • Figure 16 is a partial enlarged view of a portion A in Figure 15;
  • 17 is a partial cross-sectional view of the unit cell in another position according to a sixth embodiment of the present disclosure.
  • FIG. 18 is a partial perspective view, in section, of a unit cell provided in accordance with a sixth embodiment of the present disclosure.
  • FIG. 19 is a partial perspective view of a unit cell provided in accordance with a sixth embodiment of the present disclosure.
  • FIG. 20 is a perspective structural schematic view of a pressure relief member according to a sixth embodiment of the present disclosure.
  • 21 is a partial cross-sectional, partially cutaway view of a unit cell according to a seventh embodiment of the present disclosure.
  • Figure 22 is a partial schematic view of the left end of Figure 21;
  • Figure 23 is a partial schematic view of the right end of Figure 21;
  • FIG. 24 is a side elevational view of a sealed package provided in accordance with a seventh embodiment of the present disclosure.
  • Figure 25 is a schematic cross-sectional view taken along line A-A of Figure 24.
  • orientation words used are generally defined on the basis of the direction of the drawing of the corresponding drawing, and "inside and outside” means Inside and outside of the contour of the corresponding part.
  • the description of the outer end, the inner end, the inner and outer directions, such as the inner terminal, the outer terminal, the inner end surface and the outer end surface are in the axial direction of the pole relative to the inner and outer sides of the battery, and relative to the ring shape
  • the “inside and outside” of the piece such as the outer circumference, the outer ring, and the inner ring, are defined in the radial direction with respect to the center of the ring.
  • the present disclosure provides a battery cover assembly, a single battery using the battery cover assembly, a battery module using the battery, a power battery package using the battery module, and use
  • the power battery packs the technical solution of the electric vehicle.
  • the battery cover assembly is disposed on the single battery, and the plurality of single batteries are connected into the battery module in series or in parallel, and can be placed in the battery package to form a power battery package.
  • various technical solutions provided in the present invention can be widely applied to other battery fields.
  • the battery cover assembly of the present disclosure may be either a component assembly that can be assembled to a housing of a single battery to constitute a unit battery, or may be formed not to be integral with other parts of the unit cell, such as a battery cell.
  • the partial structure of the divided overall structure is not limited by the disclosure, and is all within the scope of protection of the present disclosure.
  • the provided battery cover assembly may include a cover plate and an electrode terminal mounted on the cover plate, the electrode terminal further including an electrode inner terminal and an electrode outer terminal, wherein the electrode is The terminal is used for electrically connecting with the battery core, and the external electrode terminal is used for connecting with other single battery cells or battery modules, etc., and realizing the input and output of the current of the battery cells of the single battery.
  • an electrical interruption structure is electrically connected between the electrode inner terminal and the electrode outer terminal, and the current interruption structure can be pulled off under the action of air pressure, thereby disconnecting the input and output of the current of the single battery.
  • the cover plate assembly provided by the invention has a gas generation mechanism independent of the inside of the battery, thereby establishing a gas pressure for the current interruption structure by generating gas in time, thereby breaking the current interruption structure in time and improving the safety of the battery.
  • the gas can be generated by previously storing a gas-producing medium in the battery cover assembly, such as establishing a sealed chamber to store the gas-producing medium, and placing the gas-producing medium in the middle and the negative of the battery. That is, the voltage can be established for the gas-producing medium. Due to the accident such as overcharging of the battery, the voltage difference between the positive and negative electrodes of the battery will gradually increase, so that only the design of the gas-producing medium can be applied to the positive and negative of the battery. When the voltage difference between the poles exceeds the rated value, gas can be generated, that is, the electrical connection of the current interruption structure between the electrode inner terminal and the electrode outer terminal can be disconnected in time under the action of the gas pressure.
  • the rated value may be set to an operating voltage corresponding to the initial stage of the thermal runaway of the battery, in other words, the rated value is set to be lower than the decomposition voltage of the electrolyte in the battery, for example, the rated value may be taken.
  • the range is 4.5v to 5v. Therefore, when the single cell is in a normal state, the voltage difference generated by the gas-producing medium does not exceed the rated value, so the gas-producing medium does not react and does not generate gas, so that the single cell can be normally charged.
  • Discharge operation when the unit cell is about to approach a dangerous state, for example, the battery is in the early stage of thermal runaway, the voltage difference generated by the gas-producing medium exceeds the rated value, so the gas-producing medium can decompose to generate a large amount of gas in the gas
  • the current interruption structure is pulled off under the action of air pressure, thereby disconnecting the current input or output of the battery in time.
  • the structure of any one of the components in the current interruption structure or the electrical connection relationship between any two adjacent components can be disconnected.
  • the battery cover assembly provided by the various embodiments of the present disclosure can ensure that the battery is quickly cut off at the initial stage of overcharging, and is particularly suitable for electrode materials having high activity (such as ternary materials, etc.).
  • the gas-producing medium provided by the present disclosure does not contact the positive and negative materials of the battery and the electrolyte, and does not cause side reactions, and has no adverse effect on battery capacity and life.
  • the amount of the gas-producing medium used is small, much smaller than the electrolyte of the battery, and the safety of the battery is further improved.
  • the gas-producing medium in order to make the decomposition voltage of the gas-producing medium take a value ranging from 4.5 to 5 v, the gas-producing medium generates a large amount of gas at a decomposition voltage lower than the electrolyte, specifically,
  • the gas generating medium may include biphenyl (decomposition voltage 4.5v), tert-amyl basically (decomposition voltage 4.7v), cyclohexylbenzene (decomposition voltage 4.7v), terphenyl (decomposition voltage 4.5v), cyclohexylbiphenyl (decomposition) At least one of a voltage of 4.5 v) and a dibenzofuran (decomposition voltage of 4.5 v).
  • the above-mentioned gas-producing medium and lithium salt can be dissolved as a solute into the organic solvent, for example, for example, for example, Dissolved into DMC (Dimethyl Carbonate) as a solvent, the lithium salt can increase the electrical conductivity, thereby greatly increasing the decomposition rate of the gas-producing medium and improving the sensitivity of interrupting the structure breaking current.
  • the above lithium salt, DMC and gas generating medium can be mixed and filled into the sealed chamber 103 in any suitable ratio.
  • the content of the lithium salt is 5% to 30%, and the content of the DMC is 5% to 30%, based on 100% by volume of the sealed chamber 103.
  • the solution composed of the lithium salt, the gas-producing medium, and the organic solvent has a certain thermal conductivity, it is possible to reduce the heat generation at the connection point between adjacent two components in the current interrupting structure in which the current needs to flow.
  • the over-current temperature rises, especially when the battery has a large instantaneous current in use, the heat transfer effect is particularly obvious, thereby further improving the safety of the battery.
  • the gas-producing medium has a certain gasification point.
  • the heat generated by the accumulation can also vaporize the gas-producing medium, increase the internal gas pressure of the sealed chamber, and thereby break through the mechanical structure.
  • the current transfer of the battery is turned on to protect against overcurrent.
  • the above solution is not limited to a liquid state, and may be a sol. For example, it may be formed into a gel-like solution.
  • the current interrupting structures may each be a mechanical structure capable of sensing air pressure.
  • the mechanical structure when the battery is in the early stage of thermal runaway, the mechanical structure is capable of breaking the current flowing through the gas generated by the gas generating medium.
  • the transfer of current can be interrupted by disconnecting the internal components, thereby cutting off the charge and discharge of the battery in time.
  • the manner in which the gas can be produced by the gas generating medium may include various methods. For example, when the battery is in the initial stage of overcharging, the gas generating medium generates gas under the voltage difference between the positive and negative electrodes of the battery, and then the internal pressure of the battery rises.
  • the heat generated by the battery short-circuit can also make The gas generating medium is vaporized to release gas, thereby generating a pneumatic power that drives the current interruption structure.
  • various embodiments of the present disclosure also provide a unit battery including a housing, a battery core housed in the housing, and a battery cover assembly in the present disclosure, wherein the cover plate is used to encapsulate the housing, and the battery core is Corresponding electrode terminals are connected to establish the input and output current paths of the respective cells.
  • the battery core is connected to the electrode inner terminal through an internal lead-out member or the like.
  • the electrode terminal that is not provided with the current interruption structure may be electrically connected to the cover plate, and the cover plate is used to establish a voltage of one pole of the gas-producing medium in the sealed cavity, that is, the cover plate is charged.
  • the method is, for example, the second embodiment.
  • the electrode terminal not provided with the current interruption structure may be directly connected to the gas-producing medium in the sealed cavity through the connecting piece of the conductive sheet to establish the voltage of the pole, for example, the first cover is not charged.
  • a battery module using the unit battery, a power battery pack using the battery module, and an electric vehicle using the power battery pack are also provided.
  • the present disclosure introduces the battery cover assembly 100, 200, 300, 400, 500, 600, 700 to the first to seventh embodiments by referring to the corresponding drawings.
  • the battery interrupting structure 100 has a sealed cavity 103 for filling the above-mentioned gas-producing medium, and the sealed cavity 103 is configured to allow gas production.
  • the medium is electrically connected to the positive and negative electrodes of the battery respectively, and when the voltage difference between the positive and negative electrodes of the battery exceeds the rated value, the gas generating medium can generate a gas to disconnect the terminal and the electrode outside the electrode under the pressure of the gas. The current between the terminals interrupts the electrical connection of the structure to enhance the safety of the battery.
  • the battery cover assembly includes a first polar member 101 and a second polar member 102 respectively in contact with the gas-producing medium, and one of the first polar member 101 and the second polar member 102 is used for The positive pole of the battery is connected, and the other is connected to the negative pole of the battery, that is, the voltage difference is established by the two polar parts for the gas-producing medium.
  • the first polar member 101 is formed by the inner terminal of the electrode and insulated from the cover 104
  • the second polar member 102 is sealed and insulated from the cover 104.
  • the voltage is established by the inner electrode terminal and the additional second polarity member for the gas-producing medium, so that the cover plate 104 can be charged without an electric charge by the additional second polarity member, thereby improving the cover plate. 104 lifetime and improved battery safety.
  • the current interruption structure further has a flip member 105 for a part of the cavity wall of the sealed cavity 103, wherein the electrode inner terminal and the electrode outer terminal are The electric connection is electrically connected by the inverting member 105, and under the action of the gas pressure of the gas, since the gas is accumulated in the sealed chamber 103, the air pressure is increased, so that the inverting member as the wall of the sealed chamber 103 can be operated to open the terminal and the electrode.
  • the electrical connection between the external terminals of the electrodes can be disconnected from the electrical connections with the terminals in the electrodes, or the electrical connection to the external terminals of the electrodes can be broken, or the structure itself can be broken.
  • the electrical connection between the inverting member 105 and the terminal inside the electrode is broken.
  • the manner of breaking the electrical connection between the terminal and the inverting member of the electrode may be different, wherein the conductive structure between the conductive member and the flip member may be disconnected, or both of them may be At least one of its own structure is broken.
  • the conductive member 106 is fixed on the outer end surface of the electrode inner terminal, and the flip member 105 is electrically connected to the conductive member 106, so that some broken structures can be disposed on the conductive member.
  • a score 115 capable of being broken by the gas pressure of the gas may be formed on the conductive member 106, and the score 115 is disposed around a connection point for connecting the flip member 105.
  • the structure of the conductive member 106 itself will be broken along the score 115, thereby causing the flip member 105 and the electrode inner terminal to be disconnected.
  • the structure is broken by means of scoring or the like, it is also possible to achieve a disconnection of the electrical connection by, for example, pulling off the solder joint between the two.
  • the rupture piece connected between the two is broken to achieve disconnection of the electrical connection.
  • it can be described in detail in the fifth embodiment of the present disclosure described below. Therefore, the purpose of the present disclosure to break the mechanical structure under the action of air pressure to cut off the transmission of current is achieved.
  • the gas generating medium when the battery is in the initial stage of overcharging, the gas generating medium generates gas and then seals under the voltage difference between the first polarity member (electrode inner terminal) and the second polarity member.
  • the air pressure in the cavity 103 is raised.
  • the flip member 105 under a certain air pressure, the flip member 105 is turned off by the inversion action to break the conductive member 106 along the score, thereby disconnecting the electrical connection between the electrode inner terminal and the electrode outer terminal, thereby The circuit connection between the single battery and the outside is interrupted, and the charging of the battery is stopped, thereby avoiding the continuous increase of the air pressure due to the decomposition of the electrolyte inside the battery, thereby ensuring the safety of the battery.
  • the electrode inner terminal as the first polar member 101 is formed by a pole extending in the inner and outer directions, and the conductive members 106 are connected to the outer end faces of the poles, for example, by welding to each other. Electrical connection.
  • the pole can be electrically connected to the battery cell through an inner lead-out member, a current collecting conductive sheet, or the like, thereby achieving connection between the first polar member 101 and the positive electrode or the negative electrode of the battery.
  • the mechanical structure capable of inducing air pressure composed of the conductive member 106 and the inverting member 105 is mounted on the pole and can directly pass through the pole.
  • the air pressure in the sealed chamber 103 has high sensitivity, and the mechanical structure and the pole are not separately connected to facilitate the processing.
  • the manner in which the sealed chambers are formed in different embodiments may be different. It may be enclosed by a first polar member, a second polar member, and/or a mechanical structure for inductive air pressure. That is, the first polarity member and the second polarity member can achieve dual use, which can serve as both positive and negative electrodes applied to the gas-producing medium, and can be used to assist in forming the sealed chamber; correspondingly, can be induced
  • the mechanical structure of the air pressure can also achieve dual use, which can be used to disconnect the current input or output of the battery, and can also assist in forming the sealed cavity, thereby reducing the number of components of the single battery and saving costs.
  • the sealed chamber can also be formed separately via additional components, for example a sealed cavity formed in the package can serve as the sealed chamber.
  • the mechanical structure of the induced air pressure is used to enclose the sealed cavity
  • part of the cavity wall of the sealed cavity is always in contact with the mechanical structure to constitute the closed sealed cavity.
  • the mechanical structure is in contact with the cavity wall of the sealed cavity under the pressure generated by the gas generating medium, when the battery is in In the normal state, the mechanical structure is always isolated from the sealed chamber.
  • the flipper 105 is disposed coaxially with the pole and extends radially outward from the pole, the side of the pole being sealed and insulated from the outer periphery of the flipper 105 such that the seal
  • the cavity 103 is formed as an annular cavity disposed around the axis of the pole. Therefore, when the air pressure in the sealed chamber 103 is increased, the inverting member 105 can be operated to be electrically disconnected from the pole.
  • the sealing and insulating connection between the pole and the inverting member can be realized by their own structure, or by adding an insulating ring, a sealing member or the like. In this way, the existing structure of the battery can be reasonably and fully utilized, so that the purpose of disconnecting the current in time in the initial stage of overcharging of the battery can be achieved while improving the existing battery structure as little as possible.
  • the first polar member 101 electrode inner terminal, or pole
  • the second polar member 102 the flip member 105
  • the conductive member 106 are all used to enclose the sealed cavity 103.
  • the pole in order to avoid the charging of the cover 104, the pole needs to be insulated from the cover plate while being fixedly connected to the cover.
  • the inner end of the cover plate 104 and the pole has a radial flange 107, and the outer end surface of the radial flange 107 is sealingly connected with an inner insulating ring 108, and the cover 104 is sealingly connected to the outer insulating ring 108.
  • the end face is insulated from the pole. That is, in FIG. 1, the inner insulating ring 108 is located on the lower side of the cover.
  • the insulating ring can be made of ceramic or plastic.
  • the radial flange 107 and the inner insulating ring 108, the inner insulating ring 108 and the cover plate may be joined by ceramic brazing. In this way, the reliability and durability are stronger than those achieved by plastics, rubber, etc., and not only the stable sealing connection of the current interrupting structure but also the insulation of both can be achieved.
  • the plastic can be integrally formed on the pole by an injection molding process to reduce assembly time.
  • the radial flange 107 is formed with a medium injection for communicating the annular cavity. Hole 109. That is, the gas-producing medium can be filled into the interior of the sealed chamber 103 at the inner end of the pole.
  • the gas generating medium is injected from the inner end of the pole into the annular cavity through the medium injection hole 109, and then the medium injection hole 109 is sealed.
  • the medium injection hole can be blocked by a sealing plug such as an aluminum bead. Or welded to the medium injection hole by a sealing member such as a round bar.
  • the cover plate equipped with the current interruption structure can be mounted on the battery.
  • the medium injection hole can also be designed on one side of the flip member, that is, a manner of injecting a gas-producing medium from the outer end of the pole to the sealed chamber. This is specifically described in detail in the second embodiment.
  • the outer end surface of the radial flange 107 is formed as a stepped structure.
  • the stepped structure has an inner ring close to the axis of the pole and an outer ring away from the axis of the pole.
  • the thickness of the inner ring is greater than the thickness of the outer ring.
  • the thickness refers to the dimension along the extending direction of the pole, and the inner insulating ring 108 is fixed to
  • the medium injection hole 109 extends from the inner end surface of the radial flange 107 to the inner ring.
  • the inner insulating ring 108 is fixed on the thinner portion of the radial flange 107, thereby facilitating the enclosing a larger annular cavity. So that as much gas-producing medium as possible is filled in the annular cavity to improve the sensitivity of the current interruption structure.
  • the medium injection hole 109 is formed in a thinner region of the radial flange 107 than the medium injection hole 109, and the medium injection hole 109 is provided on the inner ring having a thick thickness of the radial flange 107, and the medium can be elongated. The depth of the injection hole 109 makes it easier to achieve the sealing reliability of the medium injection hole 109 when the gas-producing medium is injected into the sealed chamber.
  • the second polarity member 102 is formed as an annular conductive sheet surrounding the annular cavity, and the inner surface of the annular conductive sheet is sealingly connected with the first outer insulating ring 111, and the cover is closed.
  • the plate 104 is sealingly coupled to the inner end surface of the first outer insulating ring 111 to be insulated from the annular conductive sheet.
  • the first outer insulating ring 111 may also be made of ceramic or plastic, and the first outer insulating ring 111 is fixedly connected to its adjacent components in the same process as the inner insulating ring. That is, it can be realized by ceramic brazing or injection molding, and will not be described herein. Further, as shown in FIG.
  • the annular conductive piece is further provided with a protruding pole.
  • the ear 1020, in particular, the tab 1020 can be integrally formed on the annular conductive sheet.
  • the outer end surface of the annular conductive piece is sealingly connected with the second outer insulating ring 112, and the outer peripheral edge of the inverting member 105 is sealingly connected to the outer side of the second outer insulating ring 112.
  • the end face is insulated from the annular conductive sheet.
  • the electrical connection with the conductive member 106 is broken, and the current input or output of the battery is cut off in time.
  • the material of the second outer insulating ring 112 and the first outer insulating ring 111 may be the same, the shape may be the same, and the processing process of fixing the second outer insulating ring 112 and its adjacent components is also the same.
  • the outer insulating ring 11 is the same and will not be described herein.
  • the outer end surface of the second outer insulating ring 112 is sealingly connected with a sealing ring 110, and the outer peripheral edge of the inverting member 105 is sealingly connected to the sealing ring 110, that is, the flipping member 105 is sealed.
  • the ring 110 is attached to the second outer insulating ring 112 to ensure the sealing of the sealing chamber 103 so that the air pressure inside the sealing chamber can act on the flip member without leaking.
  • the sealing ring can be provided as a conductive ring, so that the flipping member establishes a current loop with the outside through the sealing ring, that is, the sealing ring 110 can be used as the electrode outer terminal in this embodiment.
  • the battery cover assembly further includes a cover member 113 for sealingly connecting the outer periphery of the flip member 105 to the seal ring 110.
  • the cover member may be made of a conductive material such as a metal, that is, the electrode outer terminal in the embodiment is formed by the cover member 113.
  • the outer end surface of the cover member 113 may be formed with a conductive transmission member such as an electrode lead-out piece. Raised.
  • the electrode lead-out piece can establish a current path between, for example, an adjacent unit cell or an adjacent battery module.
  • the cover 113 is formed with an air hole 114 communicating with the outside to make the inside of the sealed cavity
  • the gas can be leaked after the flip member and the conductive member are electrically disconnected to prevent the battery from exploding.
  • the air holes on the cover member can also cause the current interruption structure to directly establish a pressure difference with the atmosphere, thereby realizing the action of the flip member.
  • the cover member 113 is formed as a cap structure, and an outer end surface of the seal ring 110 is formed with an L-shaped stopper, and an inner end surface thereof is used to connect the second outer insulating ring 112.
  • the outer peripheral edge of the inverting member 105 is embedded and supported in the L-shaped opening, and the outer peripheral edge is sealingly connected to the L-shaped opening by a cap structure covering the inverting member 105. Therefore, the cover member 113 can protect the current interruption structure while achieving a stable sealing assembly of the flip member 105.
  • one of the inverting member 105 and the conductive member 106 is formed with a boss, and the other is formed with a connecting hole 117 for receiving the boss 116, the boss 116 and the connection. Holes 117 pass between the ring welds.
  • the boss 116 may be formed on the conductive member 106, and the connection hole 117 may be formed on the flip member 105.
  • the ring-shaped solder joint means that when the connecting hole is sleeved outside the boss, the ring-shaped solder joint is integrally welded with the boss, so that the welding stability and the sealing property can be provided.
  • the close contact between the boss and the connecting hole on the one hand, it can be ensured that the ring-shaped solder joint can stably weld the boss 116 accommodated in the connecting hole 117 firmly, and the flow area of the current can be increased to ensure the passage of a large current.
  • the sealing between the two can be increased, that is, in the case where the conductive member and the flip member together serve as a part of the cavity wall of the sealed cavity 103, the sealing between the two can be ensured by increasing the contact area between the two. Thereby, the conductive member 106 is more easily pulled off from the score 115.
  • the flip member and the conductive member may also be welded by laser penetration welding or the like.
  • the manner in which the electrical connection is disconnected between the flip member and the conductive member can be achieved by scoring. That is, a weak portion having a smaller strength than the other regions is processed in the corresponding portion, wherein in order to complete the complete disconnection of the conductive member and the flip member, the score is usually a connection point around the conductive member and the flip member, for example, the ring structure of the above-mentioned boss welded structure . Thereby, the disconnection of the electrical connection is achieved by the disconnection of the conductive member or the flip member itself, wherein the score can be formed on the flip member or on the conductive member.
  • the conductive member 106 is formed with a score. 115, the score 115 is disposed around a connection point for connecting the flip member 105, that is, an annular score around the boss 116 is provided on the conductive member 106.
  • a score can also be formed on the flipper 105.
  • the score 115 thereon can also be broken.
  • the outer end surface of the pole is formed with a receiving hole 118, and the outer periphery of the conductive member 106. It is fixed to the inner wall of the receiving hole 118.
  • the conductive member 106 can be stably fixed by the outer circumference of the ring, and the region inside the score 115 is not connected to the pole to be pulled under an external force such as the tension of the flip member 105 or the direct pressure of the air pressure.
  • the battery cover assembly and the unit battery according to the first embodiment of the present invention are described above, and the features of the first embodiment are, for example, the boss welding structure, the flipping sheet, and the insulating ring, without departing from the inventive concept.
  • the same can be applied to the following or other possible embodiments of the present disclosure, and the battery cover assembly provided by the second embodiment of the present disclosure will be described below with reference to FIGS. 3 to 6.
  • a second embodiment of the present disclosure provides a battery cover assembly 200 in which a current interrupting structure has a sealed chamber 203 for filling a gas-producing medium, and the battery cover assembly further includes a first polarity member 201 and a second polarity member 202 respectively contacting the gas-producing medium, one of the first polarity member 201 and the second polarity member 202 is connected to the battery positive pole, and the other It is connected to the negative pole of the battery.
  • the gas generating medium can generate a gas to disconnect the electrode inner terminal and the electrode outer terminal under the gas pressure of the gas. Electrical connection between the two.
  • the first polarity member 201 is formed by the electrode inner terminal and is insulated from the cover plate
  • the second polarity member 202 is formed by the cover plate, that is, the cover plate used in the embodiment is charged.
  • the manner in which the cover plate is charged may be that it is electrically connected to the cover plate and another electrode terminal having no current interruption structure. In this way, the existing component structure of the battery can be fully utilized, and the use of an additional polar member can be applied to apply a voltage difference to the gas-producing medium.
  • the current interrupting structure further has a flip member 205 for a part of the cavity wall of the sealed cavity 203, and the electrode inner terminal and the electrode outer terminal are electrically connected by the flip member, and Under the action of the gas pressure, the flipper acts to break the electrical connection between the electrode inner terminal and the electrode outer terminal.
  • the flipper acts to break the electrical connection between the flip member and the electrode inner terminal, that is, the first polar member 201, is broken.
  • the outer end surface of the terminal of the electrode is fixed with a conductive member 206, and the flip member 205 is electrically connected to the conductive member 206, and the conductive member 206 is formed to be disconnected by the gas pressure of the gas.
  • the score 215 is disposed around the connection point for connecting the flip member 205, that is, the conductive member 206 is pulled to achieve electrical connection between the flip member 205 and the terminal inside the electrode.
  • a bump is formed on one of the flip member and the conductive member, and the other is formed with a connecting hole for receiving the boss, and the boss and the connecting hole are connected by a ring-shaped solder joint, thereby lifting current through Stability and sealing.
  • the electrode inner terminal is formed by a pole extending in the inner and outer directions, and is sealed and insulatedly connected to the cover plate, and the inverting member is coaxially disposed with the pole and radially from the pole. Extending outwardly, the sides of the pole are sealed and insulated from the outer periphery of the flip member such that the seal cavity is formed as an annular cavity disposed about the axis of the pole. That is, in the present embodiment, similar to the first embodiment, the first polar member (pole) 201, the second polar member 202, the flip member 205, and the conductive member 206 are both used to enclose the sealed chamber 203. As shown in FIGS.
  • the side of the pole is sealed and insulated from the outer periphery of the flip member 205 such that the seal chamber 203 is formed as an annular cavity disposed about the axis of the pole.
  • the boss 216 and the pole are provided with a medium injection hole 209 connected to the sealing cavity end to end to be outside the pole.
  • the gas-generating medium is injected into the annular cavity.
  • the medium injection hole 209 includes a first section extending from the boss 216 in the axial direction of the electrode inner terminal, and a second section extending radially from the first section to the pole side wall to communicate to the sealed cavity 203 That is, the integral medium injection hole 209 is formed in a vertical L-shaped structure, and the conductive member has a portion of the first segment, and the pole portion is formed with another portion of the first segment and the second segment.
  • the outer end surface of the pole is formed with a receiving hole 218, and the outer periphery of the conductive member 206 is fixed to the inner wall of the receiving hole 218.
  • the conductive member 206 can be stably fixed by the outer circumference of the ring, and the region inside the score 215 is not connected to the pole to be pulled under an external force such as the tension of the flip member 205 or the direct pressure of the air pressure.
  • the medium injection hole 209 is formed substantially as an L-shaped through hole having a vertical section and a horizontal section, so that the solvent can quickly flow into the sealed cavity under the action of gravity, thereby improving the assembly of the current interruption structure. effectiveness.
  • the cover plate since the function of the cover plate in the first embodiment is not completely the same, in the second embodiment of the present disclosure, the cover plate is charged, that is, it can also serve as an electrode applied to the gas-producing medium.
  • the current interrupting structure is fixed to the cover plate, and the cover plate serves as the second polarity member 202 and is sealed and insulated from the outer periphery of the pole and the flip member 205, respectively.
  • the cover plate can realize the encapsulation function of the battery case and serve as an electrode in contact with the gas-producing medium, the number of components of the current interruption structure is reduced, and the assembly man-hour of the battery is reduced.
  • the overall structure of the current interruption structure is more compact.
  • the outer surface of the cover plate is sealed and connected with an insulating ring 208.
  • the outer periphery of the flip member 205 and the side of the pole are sealingly connected to the insulating ring 208 to be insulated from the cover, respectively, and the outer periphery of the flip member 205 and the post are insulated by the insulating ring 208. That is, the annular cavity is enclosed by a cover plate, a pole, a flip member 205, and an insulating ring 208.
  • the current interrupting structure can realize the outer circumference of the pole and the cover plate, the cover plate and the flip member, the outer periphery of the flip member, and the pole by the single insulating ring 208.
  • the insulation and sealing connections between each other significantly reduce the number of components of the current interrupting structure, reduce the assembly man-hours of the battery, and increase the compactness of the overall structure of the current interrupting structure.
  • the manufacturing process of the insulating ring 208 and the process of fixing the same to the adjacent components are the same as those of the insulating ring in the first embodiment, and will not be described herein.
  • the seal ring is still electrically connected to the pole, thereby losing the current interruption function.
  • the outer end surface of the insulating ring 208 is formed to have an inner ring and an outer ring.
  • the stepped structure of the ring, the side of the pole is formed with an L-shaped stop embedded in the inner ring, thereby ensuring that the insulating ring 208 is stably fixed on the pole.
  • the outer periphery of the flip member 205 is sealingly coupled to the outer ring to be insulated from the pole, i.e., the pole and seal ring 210 are insulated by an insulating ring 208.
  • sealingly connecting the seal ring 210 to the insulating ring 208 allows the outer peripheral edge of the flip member to be sealed, so that the internal air pressure of the seal chamber can act on the flip member without leaking.
  • the cover plate may also be in contact with the gas-producing medium 207.
  • the insulating ring 208 is formed.
  • the through hole 2080 that communicates the annular cavity and the cover, that is, the portion of the cover, can be directly exposed to the annular cavity.
  • the gas-producing medium 207 can be filled in the through-hole 2080 so as to be in direct contact with the cover plate such that the cover plate functions as the first polarity member.
  • the through hole 2080 extends from the inner end surface of the insulating ring 208 to the inner ring. In other variations, the through hole may also extend from the inner end surface of the insulating ring to the outer ring. Further, in order to ensure a sufficiently sufficient contact area between the gas-producing medium and the cover plate to increase the sensitivity, the through-holes 2080 have a plurality of circumferentially spaced intervals along the insulating ring. Further, in order to achieve both the connection stability and the sufficient contact area of the cover plate and the gas-producing medium, the through holes 2080 are four which are disposed at equal intervals in the circumferential direction. In other embodiments, the number of through holes may also be other numbers, such as three or more.
  • the outer end surface of the insulating ring 208 is sealingly connected with the sealing ring 210, and the outer periphery of the flipping member 205 is sealingly connected to the sealing ring 210, and the sealing ring 210 is sealingly attached to the outer ring to insulate the pole. That is, the flip member 205 is attached to the insulating ring 208 through a seal ring, and the outer peripheral edges of the pole and the flip member are respectively fixed to the inner and outer rings on both sides of the through hole 2080.
  • the seal ring 210 is made of a conductive material, the seal ring can establish a current loop with the flip member, that is, form an electrode outer terminal.
  • the sealing ring 210 is sealingly connected to the insulating ring 208 to seal the outer periphery of the flip member, so that the air pressure inside the sealing chamber can act on the flip member without leaking.
  • the current interrupting structure can be protected.
  • the flip member 205 is further covered with a cover member 213, and the cover member is electrically connected with the flip member to form an electrode outer terminal.
  • the cover member can be used as an external terminal of the electrode, that is, the terminal boss can be disposed and a current loop is established with the outside through a connecting member such as an electrode lead-out piece, for example, between adjacent battery cells or between adjacent battery modules. They can all be connected by electrode lead sheets.
  • the outer peripheral edge of the cover member may be sealingly connected to the seal ring 210.
  • the cover member 213 is formed with an air hole 214 communicating with the outside.
  • the air holes on the cover member can also cause the current interruption structure to directly establish a pressure difference with the atmosphere, thereby realizing the action of the flip member.
  • the cover member 213 is formed as a cap structure, and an outer end surface of the seal ring 210 is formed with an L-shaped opening, and an inner end surface thereof is used for connecting the insulating ring 208.
  • the outer periphery of the flip member 205 is embedded and supported in the L-shaped opening, and the outer periphery is sealingly connected to the L-shaped opening by a cap structure covering the flip member 205. Therefore, while realizing the stable sealing assembly of the flip member 205, the current interrupting structure can be protected.
  • the medium injection hole 209 is formed on the conductive member 206, it can be assembled as follows: First, the cover plate, the pole and the seal ring 210 are sequentially fixed to the insulating ring 208 by, for example, ceramic brazing, that is, The four can be first formed into a separate assembly, and then the conductive member 206 is fixed to the pole by, for example, laser welding.
  • the flip member and the conductive member can be connected by laser penetration welding or the above-mentioned boss welding structure.
  • the flip member and the seal ring can be connected by laser welding.
  • the gas-producing medium can then be injected into the sealed chamber through the medium injection hole 209. After the injection is completed, the medium injection hole 209 is sealed by welding or a sealing plug or the like.
  • the cap structure and the flip member are connected by, for example, laser welding, thereby completing the assembly and operation of the entire battery cover assembly.
  • the battery cover assembly provided by the second embodiment of the present disclosure has been described above, and a battery cover assembly provided by the third embodiment of the present disclosure will be described below with reference to FIGS. 7 to 10.
  • the battery cover assembly 300 has a sealed cavity 303 for filling the gas-producing medium 308, wherein the sealed cavity 303 is configured such that the gas-producing medium 308 is electrically connected to the positive and negative terminals of the battery, respectively, and When the voltage difference between the positive and negative electrodes of the battery exceeds the rated value, the gas generating medium 308 can generate a gas to disconnect the electrical connection between the terminal inside the electrode and the external terminal of the electrode under the pressure of the gas, the cover plate An inner insulating ring 311 is sealingly connected between the inner end surface and the inner terminal of the electrode, and an outer insulating ring 312 is sealingly connected between the outer end surface of the cover plate and the outer electrode terminal, so that the sealing cavity 303 forms an annular space surrounding the axis of the inner terminal of the electrode. Cavity. That is, in the case where the electrode inner terminal and the electrode outer terminal are respectively insulated from the cover plate, the sealed cavity 303 in the disclosure is enclosed.
  • the battery cover assembly includes a first polarity member 301 and a second polarity member 302 respectively in contact with the gas-producing medium, the first polarity One of the member 301 and the second polarity member 302 is for connecting to the positive electrode of the battery, the other is for connecting to the negative electrode of the battery, the first polar member 301 is formed by the inner terminal of the electrode, and the second polar member 302 is covered by the cover.
  • the plate is formed. That is, the cover is charged and in contact with the gas-producing medium.
  • the cover plate has an annular plate protruding radially from the inner insulating ring 311 and the outer insulating ring 312.
  • the cover plate can be brought into contact with the gas-producing medium in the sealed chamber 303 through the annular plate over a larger area, thereby improving the gas generating sensitivity.
  • the annular plate may relate to the uneven portion which can increase the surface roughness in the following embodiment, thereby further increasing the gas generating sensitivity. Specific uneven portions will be described in detail in the following embodiments.
  • the pole as the inner terminal of the electrode extends in the inner and outer directions, and the through hole is formed in the cover plate through which the pole is passed, and the inner insulating ring 311 and the outer insulating ring 312 are disposed around the through hole.
  • the inner annular surface of the inner insulating ring 311 and the inner annular surface of the outer insulating ring 312 may be designed to be axially aligned such that the annular plate of the cover plate has a larger contact area with the gas-producing medium.
  • the current interrupting structure further has a flip member 305 as a portion of the cavity wall of the sealed cavity 303, and the electrode inner terminal and the electrode outer terminal are electrically connected by the flip member 305, and Under the action of the gas pressure, the flipper acts to break the electrical connection between the electrode inner terminal and the electrode outer terminal.
  • a conductive member 306 is fixed on the outer end surface of the terminal of the electrode, and the flip member 305 is electrically connected to the conductive member 306, and the conductive member 306 is formed with a score 315 which can be broken under the pressure of the gas, and the score 315 surrounds the score.
  • a connection point setting for connecting the flip member 305 is provided on the outer end surface of the terminal of the electrode, and the flip member 305 is electrically connected to the conductive member 306, and the conductive member 306 is formed with a score 315 which can be broken under the pressure of the gas, and the score 315 surrounds the score.
  • a boss 316 is formed on one of the flip member 305 and the conductive member 306, and the other has a connecting hole 317 for receiving the boss 316.
  • the boss 316 and the connecting hole 317 are connected by a ring-shaped solder joint. Thereby, the air pressure from the sealed chamber can be felt in time, and the electrical connection between the inner terminal of the electrode and the outer terminal of the electrode can be disconnected.
  • the flip member 305 is disposed coaxially with the pole and extends radially outward from the pole, the side of the pole being sealed and insulated to the inside
  • the outer periphery of the flip member 305 is fixed between the electrode outer terminal and the outer insulating ring 312, and is sealingly connected to the outer insulating ring 312 to be insulated from the cap plate and form an annular cavity. That is, the first polar member (pole) 301, the second polar member 302, the flip member 305, and the conductive member 306 are both used to enclose the sealed cavity 303. As shown in FIG.
  • the side of the pole is sealed and insulated from the outer periphery of the flip member 305 such that the seal cavity 303 is formed as an annular cavity disposed about the axis of the pole.
  • the cover plate can also serve as an electrode applied to the gas-producing medium, that is, The cover is charged.
  • the current interrupting structure is fixed to the cover of the battery, and the cover plate serves as the second polarity member 302, and is sealed and insulated from the outer periphery of the pole and the flip member 305, respectively.
  • the cover plate can realize the packaging function of the battery case and serve as an electrode in contact with the gas-producing medium, the number of parts of the battery cover assembly is reduced, and the assembly man-hour of the battery is reduced.
  • the inner end portion of the pole has a radial flange 307, which is outside the radial flange 307.
  • the end face seal is connected with an inner insulating ring 311, and the cover plate is sealingly connected to the outer end surface of the inner insulating ring 311 to be insulated from the pole. That is, in FIG. 7, the inner insulating ring 311 is located inside the cover.
  • the manufacturing process of the inner insulating ring 311 and the outer insulating ring 312 herein and the manufacturing process of fixing the same to the adjacent components are the same as those of the first embodiment, and will not be described herein.
  • a medium injection hole 309 is formed on the radial flange 307 to extend from the inner end of the pole to the annular cavity enclosed therein. Inject a gas producing medium.
  • the cover plate is sealingly connected to the inner end surface of the outer insulating ring 312. It is insulated from the outer circumference of the flip member 305. In this way, not only the insulation between the outer peripheral edge of the flip member 305 and the cover plate having the opposite polarity can be achieved, but also the short circuit of the battery can be prevented, and the flip member 305 can feel the air pressure, so that the outer peripheral edge can be turned over as a support point.
  • the electrical connection between the opening and the conductive member 306 is opened, and the current input or output of the battery is cut off in time.
  • the third technical solution described above is employed. That is, as shown in FIGS. 7 and 10, the inner annular surface of the inner insulating ring 311 and the inner annular surface of the outer insulating ring 312 are axially aligned, so that the cover plate has a radially protruding inner insulating ring 311 and outer insulation. Annular plate of ring 312. Thus, the hole wall of the through hole of the cover plate and both end faces of the annular plate can be in contact with the gas generating medium, thereby improving the gas generating sensitivity of the gas generating medium 308.
  • the outer end surface of the outer insulating ring 312 is sealingly connected with the sealing ring 310 , and the outer peripheral edge of the flipping member 305 is sealingly connected to the sealing ring 310 , that is, the flipping member 305 is connected through the sealing ring 310 .
  • the sealing ring 312 in this way, when the sealing ring is made of a conductive material, the flipping member can establish a current loop with the outside, that is, as an electrode outer terminal.
  • the sealing ring 310 is sealingly connected to the outer insulating ring 312 to seal the outer periphery of the flip member, so that the air pressure inside the sealing chamber can act on the flip member without leaking.
  • the current interrupting structure can be protected, and the flip member 305 is covered with a cover member 313.
  • the cover member 313 is electrically connected to the flip member 305 to form an electrode outer terminal. Therefore, a current loop is established between the electrode lead-out piece and the outside, for example, between adjacent battery cells, or between adjacent battery modules, and can be connected through the electrode lead-out piece.
  • the outer periphery of the cover member is sealed with the flip member to ensure the sealing of the seal chamber.
  • the cover member 313 is formed with an air hole 314 that communicates with the outside. In this way, the gas in the sealed chamber can be leaked after the flip member and the conductive member are electrically disconnected to prevent the battery from exploding.
  • the air holes on the cover member can also cause the current interruption structure to directly establish a pressure difference with the atmosphere, thereby realizing the action of the flip member.
  • the cover member 313 is formed as a cap structure, and an outer end surface of the seal ring 310 is formed with an L-shaped stopper, and an inner end surface thereof is used to connect the outer insulating ring 312.
  • the outer periphery of the flip member 305 is embedded and supported in the L-shaped opening, and the outer periphery is sealingly coupled to the L-shaped opening by a cap structure covering the flip member 305. Therefore, the cover member 313 can protect the current interruption structure while achieving a stable sealing assembly of the flip member 305.
  • the outer end surface of the pole is formed with a receiving hole 318, and the outer periphery of the conductive member 306 is fixed to the inner wall of the receiving hole 318.
  • the conductive member 306 can be stably fixed by the outer circumference of the ring, and the region inside the score 315 is not connected to the pole to be pulled under an external force such as the tension of the flip member 305 or the direct pressure of the air pressure.
  • the medium injection hole 309 is formed on the radial flange 307 on the pole, so that it can be assembled by first passing the upper end of the pole through the cover and passing the pole and the inner insulating ring 311 through, for example, ceramic brazing.
  • the welding is fixed to the cover plate, and then the sealing ring and the outer insulating ring 312 are fixed to the cover plate by, for example, ceramic brazing, and then the conductive member 306 is fixed to the pole by, for example, laser welding, and the flip member and the conductive member can be used.
  • the laser penetration welding or the above-mentioned boss welding structure is connected by welding, and the inverting member and the sealing ring can be connected by laser welding.
  • the gas-producing medium can then be injected into the sealed chamber through the medium injection hole 309. After the injection is completed, the medium injection hole 309 is sealed by welding or a sealing plug or the like. Finally, the cover structure and the flip member are connected by, for example, laser welding, thereby completing the assembly and operation of the entire battery cover assembly.
  • the battery cover assembly provided by the third embodiment of the present disclosure has been described above, and a battery cover assembly provided by the fourth embodiment of the present disclosure will be described below with reference to FIGS. 11 and 12.
  • the battery cover assembly 400 has a sealed chamber 403 for filling a gas-producing medium, and the sealed chamber 403 is configured such that the gas-producing medium is electrically connected to the positive and negative electrodes of the battery, respectively.
  • the gas generating medium can generate a gas to disconnect the electrical connection between the electrode inner terminal and the electrode outer terminal under the gas pressure of the gas, wherein the sealed cavity A concave-convex portion 408 that increases the surface roughness is formed on the inner cavity wall of 403.
  • the roughness of the inside of the sealed cavity is increased by the uneven portion 408, which can be effectively increased to increase the contact area between the gas-producing medium and the electrode thereof, thereby improving the gas generating sensitivity.
  • the uneven portion 408 may be implemented in various ways, for example, the uneven portion 408 may be formed of a toothed continuous structure and/or a spaced-apart microporous structure.
  • the specific shape of the toothed continuous structure may be formed into at least one of a semicircular structure and a rectangular structure by machining, and arranged in a tooth structure.
  • the concavo-convex portion 408 may also be microporously realized by chemical etching, for example, by spraying the inner wall of the sealing chamber, such as the first polar member and the second polar member, on the surface to be exposed to the sealing chamber 403.
  • Corrosive chemical solvent whereby a chemical reaction occurs between the first polar member and the second polar member by the chemical solvent, so that the surfaces of the first polar member 401 and the second polar member 402 and the like There is a microporous structure on it.
  • the present disclosure does not limit the implementation of the uneven portion.
  • the uneven portion 408 may be formed only on the surface of the first polar member 401 exposed to the sealing cavity 403, or may be formed only on the surface of the second polar member 402 exposed to the sealing cavity 403. In order to increase the gas generating sensitivity, preferably, the uneven portion 408 is simultaneously formed on the surface of the first polar member 401 and the second polar member 402 exposed to the sealing chamber 403.
  • the battery cover assembly includes a first pole that is in contact with the gas-producing medium and that forms at least a portion of the chamber wall of the sealed chamber 4023
  • the member 401 and the second polarity member 402 one of the first polarity member 401 and the second polarity member 402 are for connecting to the positive electrode of the battery, the other is for connecting to the negative electrode of the battery, and the uneven portion 408 is formed.
  • the uneven portion 408 is formed on the surface of the first polar member 401 and/or on the surface of the second polar member 402.
  • the electrode inner terminal is formed by a pole extending in the inner and outer directions, and the pole is used as the first polarity member 401 and is sealed and insulated from the cover.
  • the current interruption structure further has a flip member 405 as a sealed cavity 403, and the pole and the electrode outer terminal are electrically connected by the inverting member, and under the action of the gas pressure, the flipper acts to break the pole and the electrode outer terminal. Electrical connection between.
  • the flip member 405 is disposed coaxially with the pole and extends radially outward from the pole, and the outer circumference of the flip member 305 is sealed and insulated from the side of the pole such that the seal chamber 303 is formed to be disposed around the axis of the pole.
  • the annular cavity is provided to provide a seal chamber 303 and insulated from the side of the pole.
  • a conductive member 406 is fixed on the outer end surface of the pole, and the flip member 405 is electrically connected to the conductive member 406, and the conductive member 406 is formed with a score 415 which can be broken by the gas pressure of the gas.
  • the 415 is disposed around a connection point for connecting the flip member 105.
  • a boss 416 is formed on one of the flip member 405 and the conductive member 406, and the other is formed with a connecting hole 417 for receiving the boss 416.
  • the boss 416 and the connecting hole 417 are connected by a ring-shaped solder joint.
  • the second polar member 402 is formed by a cover plate, and the outer periphery of the flip member 405 is sealed and insulatively connected to the cover plate.
  • the inner end of the pole has a radial flange 407, and the outer end surface of the radial flange 407 is sealingly connected with an inner insulating ring 411, and the cover is sealingly connected to the inner insulating ring 411 to be insulated from the pole.
  • the side surface of the pole has a cylindrical surface perpendicular to the radial flange 407, and the cylindrical surface is covered with the uneven portion 408.
  • the radial flange 407 is formed with a medium injection hole 409 for communicating with the annular cavity to inject a gas generating medium into the annular cavity from the inner end of the pole.
  • an outer insulating ring 412 is sealingly coupled to the outer periphery of the flip member 405, and a cover plate is sealingly coupled to the outer insulating ring 412 to be insulated from the outer periphery of the flip member 405.
  • a through hole through which the pole is passed is formed in the cover plate, and the inner insulating ring 411 and/or the outer insulating ring 412 are disposed around the through hole.
  • the inner annular surface of the inner insulating ring 411 and the inner annular surface of the outer insulating ring 412 are axially aligned such that the cover plate has an annular plate 404 protruding radially from the inner insulating ring 411 and the outer insulating ring 412, The surface of the annular plate 404 exposed to the annular cavity is covered with the above-mentioned uneven portion 408.
  • the outer end surface of the outer insulating ring 412 is sealingly connected with a sealing ring 410.
  • the outer peripheral edge of the flip member 405 is sealingly connected to the sealing ring 410.
  • the flip member 405 is further covered with a cover member 413, and the cover member 413 is electrically connected with the flip member 405 to form an electrode. External terminal.
  • the cover member 413 is formed with an air hole 414 that communicates with the outside.
  • the cover member 413 is formed as a cap structure, and an outer end surface of the seal ring 410 is formed with an L-shaped opening, and an inner end surface thereof is used to connect the outer insulating ring 412.
  • the outer periphery of the flip member 405 is embedded and supported in the L-shaped opening, and the outer periphery is sealingly connected to the L-shaped opening by a cap structure covering the flip member 413.
  • the cover member 413 can protect the current interrupting structure while achieving a stable sealing assembly of the flip member 405.
  • the score 415 thereon can also be broken.
  • the outer end surface of the pole is formed with a receiving hole 417, which is electrically conductive.
  • the outer periphery of the member 406 is fixed to the inner wall of the receiving hole 417.
  • the structure and assembly manner of the battery cover assembly in the present embodiment are similar to those of the first, second, and third embodiments, and will not be described in detail.
  • FIG. 14 illustrate a battery cover assembly 500 provided by two embodiments of a fifth embodiment of the present disclosure.
  • Other features that are different from the first four embodiments are described in detail in the fifth embodiment for the sake of brevity, and the effects and modifications of the same features are not described in detail.
  • the battery cover assembly 500 has a sealed chamber 503 for filling a gas-producing medium, wherein the inner electrode terminal constitutes a portion of the chamber wall of the sealing chamber 503, and the sealing chamber 503 is configured to be produced.
  • the gas medium is electrically connected to the positive and negative electrodes of the battery, respectively, and when the voltage difference between the positive and negative electrodes of the battery exceeds the rated value, the gas generating medium can generate a gas to actuate the internal terminal of the electrode to be disconnected under the pressure of the gas. Electrical connection between the electrode inner terminal and the electrode outer terminal.
  • both are employed.
  • the inner terminal of the electrode acts to break the electrical connection between the terminal and the outer terminal of the electrode.
  • the electrode outer terminal 506 is configured to form a part of the cavity wall of the sealed cavity, and the external environment and the sealed cavity medium injection hole 509 are formed. Both the electrode outer terminal and the electrode inner terminal serve as the cavity wall of the sealed chamber 503. The presence of the medium injection hole 509 solves the problem that the gas generating medium is injected from the outer end.
  • the battery cover assembly includes a first polarity member 501 and a second polarity member 502, respectively, in contact with the gas-producing medium, the first polarity member 501 and the second polarity member 502.
  • One of them is connected to the positive electrode of the battery, the other is connected to the negative electrode of the battery, the first polar member 501 is formed by the inner terminal of the electrode, and the inner terminal of the electrode and the outer terminal of the electrode are electrically connected by a conductive structure, and the inside of the electrode
  • the periphery of the terminal is sealed and insulated from the periphery of the electrode outer terminal 506 such that the sealed cavity 503 is formed as an annular cavity disposed around the conductive structure.
  • the terminal inside the electrode is formed into a sheet-like structure and includes a terminal outer ring 504 which is sealed and insulatedly connected to the outer terminal of the electrode, and a terminal inner ring 517 which is a part of the cavity wall of the sealing cavity 503, the terminal
  • the outer ring 504 is for electrically connecting to the battery core through a connecting member such as an inner lead-out piece, and a conductive structure is disposed between the terminal inner ring 517 and the outer electrode terminal and can be deformed under the action of air pressure to pull off the conductive structure. Due to the formation of the sheet-like structure, the terminal inner ring 517 can be deformed to break the conductive structure under the action of the internal air pressure.
  • the thickness of the inner ring of the terminal is smaller than the thickness of the outer ring of the terminal.
  • the deformation and the breaking of the inner ring of the terminal can be ensured, that is, after the internal terminal of the disconnecting electrode and the external terminal of the electrode are also electrically connected, the inner ring of the terminal itself can be pulled off, thereby making the sealing cavity
  • the gas is leaked inside the battery and can be vented by, for example, an explosion-proof valve mounted on the cover plate, thereby preventing the battery from exploding.
  • the battery cover assembly 500 further includes an explosion-proof valve mounted on the cover.
  • the explosion-proof valve is a component well-known in the art, and is a component that prevents the internal air pressure of the battery from being excessively exploded, and has a set opening pressure. When the internal pressure of the battery is greater than the set opening pressure, the explosion-proof valve opens to release the pressure, thereby Keep the battery safe.
  • the conductive structure includes a terminal conductive piece 516 connected between the terminal inner ring and the electrode outer terminal 506, and the tensile strength of the terminal conductive piece is smaller than the breaking strength of the inner ring of the terminal.
  • the annular sealing cavity is disposed around the terminal conductive piece. Since the tensile strength of the terminal conductive piece is less than the breaking strength of the inner ring of the terminal, the inner ring of the terminal can be first deformed under the action of the internal air pressure, and then the terminal conductive piece is pulled off, thereby Disconnect the electrical connection between the terminal inside the electrode and the terminal outside the electrode. As the pressure continues to increase, the inner ring of the terminal itself will be pulled off, so that the gas leakage of the sealed chamber is guaranteed to be safe.
  • the structure of the terminal conductive sheet may be formed as a Z-shaped sheet, and the first and second segments parallel to each other of the Z-shaped sheet are respectively soldered to the electrode inner terminal and the electrode outer terminal, and may be further increased.
  • the L-shaped sheet which forms a T-shaped structure with the first and second sections of the Z-shaped sheet, respectively, thereby strengthening the strength of the solder joint and preventing the end portion of the terminal conductive sheet from being erroneously disconnected, so that the battery is inoperable.
  • the electrode outer terminal 506 is formed as a cap structure, and the inner end surface of the electrode outer terminal 506 has a terminal boss 518 extending into the sealing cavity, and the terminal boss 518
  • the inner end face is fixed to the inner ring of the terminal by a solder joint 508 formed as a conductive structure. That is, the conductive structure of the two embodiments is only the solder joint 508, so that the electrical connection between the electrode inner terminal and the electrode outer terminal can be disconnected by pulling the solder joint 508 under the action of air pressure.
  • the electrode outer terminal 506 is formed as a cap structure, and the inner end surface of the cap structure has a terminal boss 518 extending into the sealing cavity, and the inner end surface of the terminal boss 518 is formed into the conductive
  • the solder joint 508 of the structure is fixed to the inner ring of the terminal.
  • the sealed chamber is opened and the gas enters the interior of the battery and is vented, for example, through an explosion-proof valve, thereby preventing the battery from exploding. Further, unlike the fifth embodiment, in the present embodiment, it is not necessary to additionally provide the terminal conductive member 516, thereby reducing the number of components and reducing the assembly man-hour of the current interrupting structure.
  • the terminal boss 518 can be soldered to the conductive member 506. To reduce the assembly man-hour and avoid disconnecting the electrode outer terminal from the terminal boss under the action of air pressure, the terminal boss 518 can be integrally formed on the terminal 518.
  • the electrode outer terminal 506 includes a cap structure and a terminal boss 518 integrally formed on the inner end surface of the cap structure.
  • the terminal inner ring is formed as a bowl-like structure 507 protruding toward the terminal boss 518.
  • the outer bottom end surface of the bowl-shaped structure 507 is adjacent to the inner end surface of the terminal boss 518 by a solder joint 508.
  • the outer end surface of the bowl bottom is formed as a bowl bottom flat wall 507a, and the bowl-shaped structure further includes a tapered ring structure 507b extending inward from the periphery of the bowl bottom flat wall 507a, and an inner end surface formed on the cone ring structure 507b.
  • Radial flange 507c, and the radial flange is connected to the outer ring of the terminal.
  • the inflection point of the bowl-shaped structure can be used as the breaking point of the inner ring of the terminal. It can be weakened, such as processing scores and the like.
  • the solder joint 508 is formed in an annular structure, and the annular structure is located inside the periphery of the bowl bottom flat wall 507a. Due to the larger circumference of the annular structure, it is easier to ensure the welding stability of the terminal boss and the inner ring of the terminal, and to prevent the instantaneous high current from blowing the welded structure. On the other hand, when the ring structure is larger, under the action of the air pressure, the ring structure is less likely to be broken, which affects the sensitivity of the current interrupting structure.
  • the annular structure on the inner side of the bowl bottom flat wall 507a, that is, the outer circumference of the bowl bottom flat wall 507a surrounds the annular structure, the sensitivity of the current interruption structure and the welding stability can be balanced.
  • the cover plate acts as a second polarity member 502, i.e., the cover plate, as an electrode applied to the gas-producing medium. Specifically, as shown in FIGS. 13 and 14, it is sealed and insulatedly connected between the periphery of the terminal inside the electrode and the periphery of the electrode outer terminal 506. In this way, since the cover plate can realize the encapsulation function of the battery case and serve as an electrode in contact with the gas-producing medium, the number of components of the current interruption structure is reduced, and the assembly man-hour of the battery is reduced.
  • the inner insulating ring 511 is sealed and connected between the inner terminal of the electrode and the cover, and the outer terminal and the cover of the electric component are
  • An outer insulating ring 512 is attached to the seal, and the inner insulating ring 511 and the outer insulating ring 512 are spaced apart to expose the cap plate to the sealed cavity to serve as the second polar member.
  • the battery cover assembly 500 of the fifth embodiment of the present disclosure has been described above, and the battery cover assembly 600 of the sixth embodiment of the present disclosure will be described below with reference to FIGS. 15 to 20.
  • the battery cover assembly 600 includes a cover plate, an electrode inner terminal and an electrode outer terminal, and the electrode inner terminal and the electrode outer terminal are electrically connected by a current interrupting structure mounted on the cover plate, and the battery cover
  • the plate assembly further includes a sealed cavity 603 for filling the gas-producing medium 604 and mounted on the outer side of the cover plate 612, the sealed cavity 603 being configured such that the gas-producing medium is electrically connected to the positive and negative electrodes of the battery, respectively, and the positive and negative electrodes of the battery are
  • the gas generating medium 604 can generate a gas to break the sealed chamber 603 under the pressure of the gas so that the gas enters the inside of the battery and flows to the current interrupting structure to be disconnected by the air pressure.
  • the sealed cavity 603 is formed on the outside of the battery.
  • the sealed cavity 603 is not disposed inside the battery, it is possible to avoid occupying a space inside the battery and provide a sufficient layout space for components such as the battery cells inside the battery, thereby facilitating an increase in the energy density of the battery.
  • the sealed chamber 603 is disposed outside the battery, it is also convenient to inject the gas-producing medium from the outside of the battery into the sealed chamber 603 which has been enclosed.
  • the current interrupting structure and the cavity surrounding the sealed cavity 603 are two structures independent of each other. And the current interrupting structure can employ a current interrupting device in the prior art.
  • the battery cover assembly includes a first polarity member 601 and a second polarity member 602 respectively in contact with the gas-producing medium, one of the first polarity member 601 and the second polarity member 602 for The battery positive pole is electrically connected and the other is used to electrically connect to the battery negative pole.
  • the first polar member 601 is sealed and insulatedly connected to the second polar member 602 to be integrally formed as a cover-like structure opening toward the inside of the battery, on the cover structure
  • the opening is also sealingly coupled with a pressure relief member 605 to enclose a sealed chamber, and the pressure relief member 605 can be broken under pressure to allow gas to flow to the interior of the battery.
  • the cover-like structure is not only used for two opposite polarity electrodes for establishing a voltage difference for the gas-producing medium, but also provides a large-capacity sealed cavity capable of filling a sufficient amount of gas-producing medium, and also increases
  • the contact area between the gas generating medium and the first polar member 601 and the second polar member 602 is increased to improve the gas generating sensitivity.
  • the gas generating medium 604 is decomposed by the voltage difference between the first polar member 601 and the second polar member 602 to generate gas, and then the air pressure in the sealed cavity 603 is increased. Under a certain air pressure, the pressure relief member 605 is depressurized, and the gas enters the interior of the battery and communicates with the current interruption structure. The air pressure inside the battery continues to rise until the electrical connection between the conductive member 615 and the flip member 614 is broken, thereby interrupting the current transfer of the battery.
  • the pressure relief member 605 can be implemented in various manners.
  • the pressure relief member 605 can be a sealing plate including a sealing structure connected to the cover structure, and a sealing connection on the pressure releasing plate.
  • Pressure relief valve When the gas generated by the gas is greater than or equal to the opening pressure of the pressure relief valve, the pressure relief valve is in an on state. When the gas generated by the gas is lower than the opening pressure of the pressure relief valve, the pressure relief valve is closed.
  • the pressure relief member 605 is formed with a first score 606, the first score 606. It can be broken under the action of air pressure to allow the gas to escape through the pressure relief member 605. That is, by processing a weak portion having a lower strength than the other regions in the corresponding portion of the pressure relief member 605, when the internal air pressure in the sealed chamber 603 rises, the received air pressure can cause the first score 606 to be broken, thereby making the gas
  • the flow through the tearing gap in the pressure relief member flows into the interior of the battery, and the transmission of the breaking current is interrupted by the battery as the air pressure continues to increase.
  • the pressure relief member 605 is formed as a pressure relief plate having a first score 606, and the pressure relief plate is formed with a weakening groove 607, the first score 606 is located on the bottom wall of the groove of the weakening sink 607.
  • the first score 606 is located on the bottom wall of the groove of the weakening sink 607.
  • the pressure releasing member 605 is a conductive member, thereby enhancing the contact area between the gas generating medium and the electrode thereof, and improving the sensitivity of the current interrupting structure.
  • the portion of the pressure relief member that is pulled off falls into the battery to cause a short circuit of the battery.
  • the first score 606 is formed as a non-interrupted end. Straight line structure. That is, the first score 606 is formed into a non-closed structure, so that even if the first score 606 is broken, the portion surrounded by the first score 606 is still attached to the pressure relief member 605, thereby eliminating the cause of the loss.
  • the phenomenon of short circuit inside the battery caused by the falling of the broken piece improves the safety of the battery.
  • the non-linear structure can be formed into a curved structure, and preferably, the sensitivity of the current interruption structure and the safety of the battery are taken into consideration, and the linear structure is formed into an excellent arc structure.
  • the first score 606 can be formed as a Y-shaped structure or a bent line structure.
  • the second polarity member 602 is fixed to the cover.
  • the board is electrically connected to the battery positive or battery negative through the cover.
  • a mounting hole is formed in the cover plate, and the second polarity member 602 is mounted on the inner wall of the mounting hole to make the cover structure The opening faces the inside of the battery.
  • the cover plate can also serve as a second polarity member, and the first polar member is integrally formed as a cover-like structure and sealed to the cover plate to form the sealed cavity.
  • the first polarity member is electrically connected to the electrode terminal of the exposed cover plate through the conductive connection piece 625.
  • the outer end surface of the cover-like structure is designed to be substantially flush with the outer end surface of the electrode terminal exposing the cover plate or slightly lower than the outer end surface of the pole column, and The pole and the cover structure are spaced apart along the extending direction of the battery cover, so that the internal space of the sealed cavity 603 can be increased without increasing the overall height of the battery, thereby improving the gas-producing medium.
  • the filling amount of 604 increases the gas production sensitivity.
  • the first polarity member 601 and the second polarity member 602 can be implemented in a plurality of ways to form a cover-like structure.
  • the first polarity member 601 and the second polarity member 602 can be docked by left and right. The way to achieve it.
  • the first polar member 601 and the second polar member 602 may be formed by stacking the upper and lower sides. structure.
  • an annular insulating strip 608 having an H-shaped longitudinal section is disposed between the first polar member 601 and the second polar member 602 such that the first polar member 601 and the second member
  • the polar member 602 is insulated
  • the cover-like structure includes a cover structure as the first polar member 601, and a cover structure as the second polar member 602, the cover structure and the edge of the cover edge structure are respectively embedded and Sealed into the U-shaped grooves at opposite ends of the H-shaped structure, the outer periphery of the rim structure is fixedly coupled to the cover.
  • the insulation and sealing between the first polar member 601 and the second polar member 602 can be ensured at the same time. Sex.
  • the annular sealing strip 608 can be assembled between the first polar member 601 and the second polar member 602.
  • the annular insulating strip 608 is integrally formed on the first polar member 601 and the second polar member 602.
  • the annular insulating strip 608 can be integrally formed between the first polar member 601 and the second polar member 602 by injection molding.
  • the cover body structure is formed with a medium injection hole 609, and the medium injection hole 609 is blocked with a sealing plug 610. In this way, after the current interruption structure is assembled on the battery, the solution injection operation is performed from the outside of the battery, and the liquid injection method is more flexible and convenient to operate.
  • the cover plate is provided with a first electrode terminal 611 and a second electrode terminal 613, and the first polarity member 601 is disposed adjacent to the first electrode terminal 611 of the battery, and The first electrode terminal 611 is electrically connected, and the cover plate 612 is electrically connected to the second electrode terminal 613 of the battery, and the current interruption structure is mounted on the first electrode terminal 611 or the second electrode terminal 613.
  • the first polarity member 601 can be electrically connected to the first electrode terminal 611
  • the second polarity member 602 can be electrically connected to the second electrode terminal 613.
  • the gaseous medium is electrically connected to the positive or negative electrode of the battery and simplifies the overall structure of the battery cover assembly.
  • the cover structure may pass through the conductive connecting piece 625. Electrically connected to the first electrode terminal 611. Further, the cover edge structure is fixed to the cover 612 of the battery to establish an electrical connection relationship with the second electrode terminal 613 through the cover.
  • the current interruption structure further includes a flip member 614 electrically connected between the electrode inner terminal and the electrode outer terminal, and the outer periphery of the flip member 614
  • the rim is sealed and insulatively attached to the cover plate, and the seal pack is in gaseous communication with the inner surface of the flip member to actuate the flip member 614 to break the electrical connection with the terminals within the electrode under the pressure of the gas.
  • a conductive member 615 is fixed on the outer end surface of the inner terminal of the electrode, and the flip member 614 is electrically connected to the conductive member 615, and the conductive member 615 is formed with a score 616 which can be broken by the gas pressure of the gas, and the score 616 is surrounded by Set at the connection point of the connection flip 614.
  • a boss 617 is formed on one of the flip member 614 and the conductive member 712, and the other is formed with a connecting hole 618 for receiving the boss 617.
  • the boss 617 and the connecting hole 618 are connected by a ring-shaped solder joint. .
  • the current interrupting structure can be protected.
  • the flip member 614 is further covered with a cover member 622, and the cover member 622 is electrically connected with the flip member 614 to form an electrode outer terminal.
  • the cover member 622 can be used as an external terminal of the electrode, that is, the terminal boss can be disposed to establish a current loop with the outside through a connecting member such as an electrode lead-out piece, for example, with an adjacent unit battery, or an adjacent battery module. Both can be connected by electrode lead sheets.
  • the outer peripheral edge of the cover member may be sealingly connected to the seal ring 620.
  • the cover member 622 is formed with an air hole 623 communicating with the outside.
  • the air holes on the cover member can also cause the current interruption structure to directly establish a pressure difference with the atmosphere, thereby realizing the action of the flip member.
  • the cover plate 612 of the battery is formed with the second electrode terminal 613 through.
  • the through hole, the second electrode terminal 613 is fixed to the cap plate 612 by an insulating ring 619 passing through the through hole to be insulated from the cap plate 612, and the outer peripheral edge of the flip member 614 is sealed by the seal ring 620 surrounding the insulating ring 619 and electrically Connected to the cover 612, and the cover 612 is formed with an air vent 621 between the seal ring 620 and the insulating ring 619.
  • the second electrode terminal 613 is electrically connected to the cap plate 612 through the conductive member 615, the flip member 614, and the seal ring 620 in sequence, and is insulated from the second electrode terminal 613 through the insulating ring 619, and the cover plate 612 is formed in communication.
  • the air pressure inside the battery continues to rise until the electrical connection between the conductive member 615 and the flip member 614 is broken, and the second electrode terminal 613 cannot establish an electrical connection with the seal ring 620 and the cover 612, that is, the flip member 614 and the seal ring. Both the 620 and the cover 612 are uncharged, thereby interrupting the current flow of the battery.
  • the battery cover assembly of the sixth embodiment of the present disclosure has been described above, and a current interruption assembly provided by the seventh embodiment of the present disclosure will be described below with reference to FIGS. 21 to 25.
  • the current interrupting structure 700 includes a cap plate, an electrode inner terminal, and an electrode outer terminal, and the electrode inner terminal and the electrode outer terminal are electrically connected by a current interrupting structure mounted on the cap plate, and the battery is
  • the cover assembly further includes a first current take-up tab 705 and a second current take-up tab 709 for electrically connecting the positive and negative electrodes of the battery cell, and a sealed package for filling the gas-producing medium and located inside the cover plate 704, the sealing bag is provided with a first polarity member 701 and a second polarity member 702 respectively in contact with the gas-producing medium, and the first polarity member is electrically connected to the first current collecting piece, the second polarity The piece is electrically connected to the second current collecting lead piece.
  • the gas generating medium can generate gas, and the gas pressure of the gas
  • the seal pack 704 is torn down so that gas escapes from the seal pack 704 and flows to the current interrupting structure to break the electrical connection between the electrode inner terminal and the electrode outer terminal by air pressure. That is, unlike the battery cover assembly of the other various embodiments described above, the sealed chamber of the present disclosure is enclosed by a sealed package. In this way, the sealed package structure capable of decomposing the gas can be separately produced and assembled onto the battery cell, thereby avoiding the use of the structural member of the battery cell to enclose the sealed cavity, simplifying the assembly process of the battery cell, and simplifying the battery.
  • the overall structure of the monomer is described in this way, the sealed package structure capable of decomposing the gas can be separately produced and assembled onto the battery cell, thereby avoiding the use of the structural member of the battery cell to enclose the sealed cavity, simplifying the assembly process of the battery cell, and simplifying the battery.
  • the seal pack surrounding the seal chamber and the current interrupting structure are independent of each other. Therefore, when the unit cell is in a normal state, as shown in FIGS. 21 to 23, the gas-producing medium in the sealed bag does not react, the chemical stability is good, and no gas is generated, and the sealed bag is in a sealed state. Therefore, the single cell can normally perform charging and discharging work; and when the single cell is about to approach a dangerous state, for example, the battery is in the early stage of thermal runaway, the gas generating medium 703 can be decomposed to generate a large amount of gas to be torn under the pressure of the gas. The seal pack 704 is ruptured, at which time the seal pack is in a non-sealed state, thereby breaking the electrical connection between the electrode inner terminal and the electrode outer terminal by the current interrupting structure under the action of the air pressure.
  • the sealed package 704 may be formed as a package, and the package opening of the package is set.
  • a weak point that can be torn by the air pressure is applied.
  • the package may also be made of, for example, an aluminum plastic film that is insoluble in an electrolyte.
  • the weak point that can be torn by the air pressure may also be a scoring structure formed on the seal bag that is thinner than other regions.
  • the first pole The member 701 and the second polarity member 702 are both located inside the sealed package. Specifically, as shown in FIG. 24, the first polar member 701 has a first tab 707 passing through the sealed package 704, and the second polar member 702 has a second tab 708 passing through the sealed package 704. A tab 707 is soldered to the first current collecting tab 705 of the battery such that the first polar member 701 is electrically connected to the first current collecting tab 705, and the second tab 708 is soldered to the second current collecting of the battery.
  • the sheet 709 is pulled out to establish an electrical connection relationship between the second polarity member 702 and the second current collecting tab 709, so that the gas-producing medium in the sealed package is connected to the positive and negative electrodes of the battery.
  • the first tab 707 and the second tab 708 may be soldered to the first polar member 701 and the second polar member 702, respectively.
  • the first tab 707 and the second tab 708 may be integrally formed on the first polar member 701 and the second polar member 702, respectively, for example, by the first polar member 701 and the second The polar member 702 integrally forms a tab structure.
  • the contact area between the gas generating medium and the first polarity member 701 and the second polarity member 702 can be increased.
  • the first polarity member 701 and the second polarity member 702 can be in contact with the gas-producing medium in the package as long as at least partially encapsulated in the package, so in other variants, the first The polar member 701 and the second polarity member 702 can also be electrically connected to the positive and negative terminals of the battery through the package, that is, portions of the two are located inside the package.
  • the package port has a first package port 706 and a second package port 716 at opposite ends of the package package 704.
  • the first tab 707 passes through and is sealed and connected to the first package.
  • the second tab 708 is passed through and hermetically connected to the second package port 716.
  • the package is formed into a strip structure extending along the length direction of the battery, and the first package port 706 and the second package port 716 are respectively located at different ends of the strip structure.
  • the extending direction of the elongated structure coincides with the longitudinal direction of the battery, the space inside the battery can be fully utilized, and the internal space of the battery is not occupied, and the internal components of the battery are not caused to be defective. influences.
  • the first tab 707 and the second tab 708 are both formed to have a level.
  • the L-shaped conductive sheets of the segments and the vertical segments, the vertical segments of the first tabs 707 are attached and fixed to the first current collecting tabs 705, and the vertical segments of the second tabs 708 are attached and fixed to the second set.
  • the horizontal sections of the first tab 707 and the second tab 708 are connected to the first polar member 701 and the second polar member 702, respectively.
  • the strip structure can be vertically connected between the current collecting tabs on both sides of the battery, and the vertical section provides a sufficient contact area between the current collecting tab and the tab, thereby making the sealing package secure
  • the ground is fixed to the current collecting piece.
  • the first polarity member 701 and the second polarity member 702 are respectively formed to be opposite in polarity.
  • a current collecting conductive strip and a second current collecting conductive sheet the inner side of the package further has an insulating sheet 710, and the first current collecting conductive sheet, the insulating sheet 710, and the second current collecting conductive sheet are sequentially stacked and wound to form a lining A flat structure in which the battery extends in the longitudinal direction.
  • the flat structure can enhance the package on the one hand.
  • the overall structural strength, on the other hand, the flat structure extends along the length of the battery, and can fully utilize the internal space of the battery to avoid occupying too much space inside the battery, so that the package structure is more compact.
  • the internal structure of the package provided by the present embodiment is substantially the same as the internal structure of the lithium ion battery in the prior art, and the internal components of the lithium ion battery in the prior art are the same without departing from the concept of the present invention. It can be applied to the package structure in the present embodiment. Here we only introduce the differences between the two. Specifically, in the present embodiment, the first and second polar members 701 and 702 do not need to be provided with positive and negative electrodes coated on the positive and negative electrodes of the lithium ion battery. In addition, the inside of the package of the present disclosure is filled with the solution containing the gas-producing medium described in detail above, and thus is also different from the electrolyte component inside the lithium ion battery of the prior art.
  • the first current collecting conductive sheet may be, for example, a copper foil
  • the second current collecting conductive sheet may be, for example, an aluminum foil
  • the insulating sheet may be, for example, a PE (polyethylene) composite film or a PP (Polypropylene, polypropylene) composite film.
  • the manufacturing method of the package provided by the present disclosure is basically the same as the manufacturing method of the lithium ion battery, and only one of the manufacturing methods will be briefly described herein.
  • the insulating sheet may be disposed between a first current collecting conductive sheet such as a copper foil not coated with a positive electrode material and a second current collecting conductive sheet such as an aluminum foil, and the three are wound into a similar
  • the conductive core structure of a lithium ion battery is, for example, packaged by an aluminum plastic film, and the two tabs are taken out and soldered to the current collecting and outputting sheets of the battery, thereby achieving parallel connection with the external battery cells.
  • a solution obtained by mixing the above-mentioned lithium salt, an organic solvent, and a gas-producing medium is injected into the aluminum plastic film to achieve the purpose of decomposing and generating a gas at a rated voltage.
  • the gas generating medium can generate a large amount of gas, so that the sealing of the aluminum plastic film is opened, and the package is enclosed.
  • the gas is discharged, thereby forcing the mechanical structure to disconnect the current flow of the battery, achieving an open circuit with the battery and the external circuit, and improving the safety of the battery.
  • it may be an explosion-proof valve provided on the battery.
  • the current interruption structure may further include a flip member 711 electrically connected between the electrode inner terminal and the electrode outer terminal, and the flip member The outer periphery is sealed and insulatively coupled to the cover plate, and the seal pack is in gas communication with the inner surface of the flip member to actuate the flip member 711 to break the electrical connection with the terminals in the electrode under the action of gas pressure.
  • a conductive member 712 is fixed on the outer end surface of the terminal of the electrode, and the flip member 711 is electrically connected to the conductive member 712, and the conductive member 712 is formed with a score 713 which can be broken by the gas pressure of the gas, and the score 713 is surrounded by It is set at the connection point of the connection flip 711.
  • a boss 714 is formed on one of the flip member 711 and the conductive member 712, and the other is formed with a connecting hole 715 for receiving the boss 714.
  • the boss 714 and the connecting hole 715 are connected by a ring-shaped solder joint.
  • the flip member 711 is further covered with a cover member 716, and the cover member 716 is electrically connected with the flip member 711 to form an electrode outer terminal.
  • the cover member 716 is formed with an air hole 718 that communicates with the outside.

Landscapes

  • Engineering & Computer Science (AREA)
  • Chemical & Material Sciences (AREA)
  • General Chemical & Material Sciences (AREA)
  • Electrochemistry (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Sustainable Energy (AREA)
  • Mechanical Engineering (AREA)
  • Transportation (AREA)
  • Power Engineering (AREA)
  • Life Sciences & Earth Sciences (AREA)
  • Sustainable Development (AREA)
  • Manufacturing & Machinery (AREA)
  • Connection Of Batteries Or Terminals (AREA)
  • Gas Exhaust Devices For Batteries (AREA)
  • Sealing Battery Cases Or Jackets (AREA)

Abstract

La présente invention concerne un ensemble plaque de recouvrement de batterie, une batterie unique, un module de batterie, un bloc-batterie d'alimentation et une voiture électrique. L'ensemble plaque de recouvrement de batterie comprend une plaque de recouvrement (104), une borne interne d'électrode (101) et une borne externe d'électrode (110), la borne interne d'électrode (101) et la borne externe d'électrode (110) étant électriquement connectées au moyen d'une structure d'interruption de courant (105), l'ensemble plaque de recouvrement de batterie comprenant une chambre étanche (103) remplie d'un diélectrique permettant de produire du gaz et montée à l'extérieur de la plaque de recouvrement (104), et la chambre étanche (103) étant construite de telle sorte que le diélectrique permettant de produire du gaz est respectivement connecté électriquement à une cathode et à une anode d'une batterie. Lorsque la différence de tension entre la cathode et l'anode de la batterie dépasse une valeur nominale, le diélectrique produit un gaz, la chambre étanche (103) est rompue sous l'effet de la pression gazeuse du gaz de telle sorte que le gaz entre à l'intérieur de la batterie et circule vers la structure d'interruption de courant (105), et l'effet de la pression gazeuse est de couper la connexion électrique entre la borne interne d'électrode (101) et la borne externe d'électrode (110).
PCT/CN2018/079240 2017-03-31 2018-03-16 Ensemble plaque de recouvrement de batterie, batterie unique, module de batterie, bloc-batterie d'alimentation et voiture électrique WO2018177138A1 (fr)

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CN201710209510.3 2017-03-31
CN201710209510.3A CN108666458B (zh) 2017-03-31 2017-03-31 电池盖板组件、单体电池、电池模组、动力电池包和电动汽车

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WO2018177138A1 true WO2018177138A1 (fr) 2018-10-04

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CN113948815A (zh) * 2020-07-16 2022-01-18 上海汽车集团股份有限公司 泄压装置以及电池蓄能系统
CN114361705A (zh) * 2021-12-17 2022-04-15 薛玉明 一种泄压式锂离子电池
CN114865184A (zh) * 2022-03-29 2022-08-05 联动天翼新能源有限公司 电池盖板翻转入壳装置和翻转设备
CN115803962A (zh) * 2020-09-07 2023-03-14 宁德时代新能源科技股份有限公司 端盖组件、壳体组件、电池单体、电池及用电装置
CN116075968A (zh) * 2021-08-30 2023-05-05 宁德时代新能源科技股份有限公司 电池、用电装置以及制备电池的方法和装置
CN116157959A (zh) * 2021-09-22 2023-05-23 宁德时代新能源科技股份有限公司 电池的箱体、电池、用电设备、制备电池的方法和设备

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KR20230061460A (ko) * 2021-09-30 2023-05-08 컨템포러리 엠퍼렉스 테크놀로지 씨오., 리미티드 배터리 셀, 배터리 및 전기기기

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CN113948815A (zh) * 2020-07-16 2022-01-18 上海汽车集团股份有限公司 泄压装置以及电池蓄能系统
CN113948815B (zh) * 2020-07-16 2024-02-20 上海汽车集团股份有限公司 泄压装置以及电池蓄能系统
CN115803962A (zh) * 2020-09-07 2023-03-14 宁德时代新能源科技股份有限公司 端盖组件、壳体组件、电池单体、电池及用电装置
CN116075968A (zh) * 2021-08-30 2023-05-05 宁德时代新能源科技股份有限公司 电池、用电装置以及制备电池的方法和装置
CN116157959A (zh) * 2021-09-22 2023-05-23 宁德时代新能源科技股份有限公司 电池的箱体、电池、用电设备、制备电池的方法和设备
CN114361705A (zh) * 2021-12-17 2022-04-15 薛玉明 一种泄压式锂离子电池
CN114361705B (zh) * 2021-12-17 2023-11-03 浙江华研新能源有限公司 一种泄压式锂离子电池
CN114865184A (zh) * 2022-03-29 2022-08-05 联动天翼新能源有限公司 电池盖板翻转入壳装置和翻转设备
CN114865184B (zh) * 2022-03-29 2024-05-31 联动天翼新能源有限公司 电池盖板翻转入壳装置和翻转设备

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