WO2022171015A1 - 电池和电子设备 - Google Patents
电池和电子设备 Download PDFInfo
- Publication number
- WO2022171015A1 WO2022171015A1 PCT/CN2022/074807 CN2022074807W WO2022171015A1 WO 2022171015 A1 WO2022171015 A1 WO 2022171015A1 CN 2022074807 W CN2022074807 W CN 2022074807W WO 2022171015 A1 WO2022171015 A1 WO 2022171015A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- bare cell
- battery
- cell part
- cell portion
- charging
- Prior art date
Links
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Classifications
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- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
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- H01M10/04—Construction or manufacture in general
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- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M50/00—Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
- H01M50/50—Current conducting connections for cells or batteries
- H01M50/531—Electrode connections inside a battery casing
- H01M50/538—Connection of several leads or tabs of wound or folded electrode stacks
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
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- H01M50/20—Mountings; Secondary casings or frames; Racks, modules or packs; Suspension devices; Shock absorbers; Transport or carrying devices; Holders
- H01M50/247—Mountings; Secondary casings or frames; Racks, modules or packs; Suspension devices; Shock absorbers; Transport or carrying devices; Holders specially adapted for portable devices, e.g. mobile phones, computers, hand tools or pacemakers
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- H01M10/0436—Small-sized flat cells or batteries for portable equipment
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- H01M10/4257—Smart batteries, e.g. electronic circuits inside the housing of the cells or batteries
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- H01M50/102—Primary casings; Jackets or wrappings characterised by their shape or physical structure
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- H01M50/10—Primary casings; Jackets or wrappings
- H01M50/102—Primary casings; Jackets or wrappings characterised by their shape or physical structure
- H01M50/103—Primary casings; Jackets or wrappings characterised by their shape or physical structure prismatic or rectangular
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- H01M50/14—Primary casings; Jackets or wrappings for protecting against damage caused by external factors
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- H01M50/10—Primary casings; Jackets or wrappings
- H01M50/172—Arrangements of electric connectors penetrating the casing
- H01M50/174—Arrangements of electric connectors penetrating the casing adapted for the shape of the cells
- H01M50/176—Arrangements of electric connectors penetrating the casing adapted for the shape of the cells for prismatic or rectangular cells
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- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M50/00—Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
- H01M50/20—Mountings; Secondary casings or frames; Racks, modules or packs; Suspension devices; Shock absorbers; Transport or carrying devices; Holders
- H01M50/204—Racks, modules or packs for multiple batteries or multiple cells
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- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M50/00—Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
- H01M50/20—Mountings; Secondary casings or frames; Racks, modules or packs; Suspension devices; Shock absorbers; Transport or carrying devices; Holders
- H01M50/267—Mountings; Secondary casings or frames; Racks, modules or packs; Suspension devices; Shock absorbers; Transport or carrying devices; Holders having means for adapting to batteries or cells of different types or different sizes
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M50/00—Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
- H01M50/20—Mountings; Secondary casings or frames; Racks, modules or packs; Suspension devices; Shock absorbers; Transport or carrying devices; Holders
- H01M50/269—Mechanical means for varying the arrangement of batteries or cells for different uses, e.g. for changing the number of batteries or for switching between series and parallel wiring
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- H—ELECTRICITY
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- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M50/00—Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
- H01M50/50—Current conducting connections for cells or batteries
- H01M50/543—Terminals
- H01M50/552—Terminals characterised by their shape
- H01M50/553—Terminals adapted for prismatic, pouch or rectangular cells
- H01M50/557—Plate-shaped terminals
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- H—ELECTRICITY
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- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M50/00—Constructional details or processes of manufacture of the non-active parts of electrochemical cells other than fuel cells, e.g. hybrid cells
- H01M50/50—Current conducting connections for cells or batteries
- H01M50/572—Means for preventing undesired use or discharge
- H01M50/574—Devices or arrangements for the interruption of current
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J7/00—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries
- H02J7/0042—Circuit arrangements for charging or depolarising batteries or for supplying loads from batteries characterised by the mechanical construction
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/425—Structural combination with electronic components, e.g. electronic circuits integrated to the outside of the casing
- H01M2010/4271—Battery management systems including electronic circuits, e.g. control of current or voltage to keep battery in healthy state, cell balancing
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M2220/00—Batteries for particular applications
- H01M2220/20—Batteries in motive systems, e.g. vehicle, ship, plane
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M2220/00—Batteries for particular applications
- H01M2220/30—Batteries in portable systems, e.g. mobile phone, laptop
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- Y—GENERAL 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
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
Definitions
- the present application relates to the technical field of electronic devices, and in particular, to a battery and an electronic device.
- batteries are widely used in various electronic devices to provide electrical energy for the electronic devices.
- the capacity of the batteries required by the electronic devices increases.
- the high-capacity battery has a higher risk of internal short-circuit and burning due to the puncture of foreign objects such as broken back covers and screwdrivers in scenarios such as drops and repairs. As a result, the safety performance of the battery is low.
- the embodiments of the present application provide a battery and an electronic device, which are beneficial to improve the use safety of the battery.
- some embodiments of the present application provide a battery including: a first bare cell part and a second bare cell part.
- the first bare cell part has a first surface and a side surface connected to the first surface, the first surface is used for the same orientation as the opening of the battery compartment when the battery is installed in the battery compartment of the electronic device, and the side surface is used for installing the battery in the battery compartment of the electronic device.
- the second bare cell part When in the battery compartment of the electronic device, it faces the inner side of the battery compartment; the second bare cell part is located on the side facing the first surface, and the orthographic projection of the second bare cell part on the first surface has the same relationship with the first surface.
- Overlapping, and/or, the second bare cell portion is located on the side to which the side face faces, and the orthographic projection of the second bare cell portion on the side face overlaps the side face.
- the first bare cell part and the second bare cell part are provided at the same time, compared with the battery provided with one bare cell part in the related art, on the one hand, the total battery is not reduced.
- the first bare cell part and the second bare cell part can be used for capacity division, so that the capacities of the first bare cell part and the second bare cell part are both smaller than those of the related art.
- the capacity of the battery in the bare cell part can at least to a certain extent reduce the risk of internal short circuit burning of the battery caused by the large capacity of the first bare cell part and the second bare cell part, and improve the safety of the battery; On the other hand, it is beneficial to realize the independent operation of the first bare cell part and the second bare cell part, so that the second bare cell part can be used to protect the first bare cell part during the use of the battery , will not cause the overall damage of the battery to be scrapped.
- the first bare cell portion is a high-energy bare cell portion
- the second bare cell portion is a fast-charging bare cell portion. Since the volume energy density of the fast charging bare cell part is usually low, the second bare cell part is set as the fast charging bare cell part under the premise that the volume of the second bare cell part in the battery is constant. The capacity of the second bare cell part can be reduced, less electricity is released when a short circuit occurs, the safety of the battery can be improved to a certain extent, and the possibility of the battery being blown up and exploding can be reduced. Due to the high volume energy density of the high-energy bare cell part, the battery life can be guaranteed. As a result, the battery can take into account both fast charging characteristics and high-energy characteristics.
- the thickness of the negative electrode sheet of the second bare cell portion is smaller than the thickness of the negative electrode sheet of the first bare cell portion.
- the second bare cell part includes a first sub-section, the first sub-section is located on the side to which the first surface faces, and the first sub-section is located on the first surface
- the orthographic projection of overlaps the first surface
- the orthographic projection of the first subsection on the first surface coincides with the first surface.
- the side surface includes a first side surface and a second side surface, and the second side surface and the first side surface are arranged and connected in the circumferential direction of the first surface;
- the first bare cell part The tab is arranged on the first side;
- the second bare cell part includes a second sub-section, the second sub-section is located on the side facing the second side, and the orthographic projection of the second sub-section on the second side and the second side There is overlap.
- the orthographic projection of the second subsection on the second side surface coincides with the second side surface.
- the side surface further includes a third side surface, and the third side surface is opposite to the second side surface; the second bare cell part further includes a third sub-part, and the third sub-part is located on the first side.
- the orthographic projection of the third subsection on the third side surface overlaps with the third side surface.
- the orthographic projection of the third subsection on the third side surface coincides with the third side surface.
- the side surface further includes a fourth side surface, and the fourth side surface is opposite to the first side surface;
- the second bare cell part further includes a fourth sub-part, the fourth sub-part It is located on the side to which the fourth side faces, and the orthographic projection of the fourth subsection on the fourth side overlaps with the fourth side.
- the orthographic projection of the fourth subsection on the fourth side surface coincides with the fourth side surface.
- the side surface includes a first side surface and a fourth side surface, and the first side surface and the fourth side surface are opposite to each other; the tabs of the first bare cell part are arranged on the first side surface, and the The two bare cell parts further include a fourth sub-section, the fourth sub-section is located on the side facing the fourth side, and the orthographic projection of the fourth sub-section on the fourth side overlaps the fourth side.
- the orthographic projection of the fourth subsection on the fourth side surface coincides with the fourth side surface.
- the first bare cell part further has a second surface, and the second surface is opposite to the first surface;
- the battery further includes: a third bare cell part, the third bare cell part is The cell part is located on the side facing the second surface, and the orthographic projection of the third bare cell part on the second surface overlaps the second surface.
- the orthographic projection of the third bare cell portion on the second surface coincides with the second surface.
- the value range of the thickness of the positive electrode sheet of the first bare cell part is: 80 ⁇ m to 120 ⁇ m; the value range of the thickness of the negative electrode sheet of the first bare cell part is 110 ⁇ m ⁇ 160 ⁇ m.
- the value range of the thickness of the positive electrode sheet of the second bare cell part is: 40 ⁇ m to 80 ⁇ m; the value range of the thickness of the negative electrode sheet of the second bare cell part is 70 ⁇ m ⁇ 110 ⁇ m.
- the battery further includes: a case, and the first bare cell part and the second bare cell part are located in the case.
- an accommodating cavity is formed in the housing, and both the first bare cell part and the second bare cell part are located in the accommodating cavity. This arrangement is beneficial to reduce the volume of the battery.
- the casing includes a first casing unit and a second casing unit; a first accommodating cavity is formed in the first casing unit, and the first bare cell is partially accommodated in the first casing unit.
- the second shell unit is located outside the first shell unit and is relatively fixed with the first shell unit, a second accommodating cavity is formed in the second shell unit, and the second bare cell is partially accommodated in the second accommodating cavity intracavity.
- the tabs of the first bare cell portion and the tabs of the second bare cell portion extend through the casing to the outside of the casing, and the first bare cell portion
- the tabs of the first charge and discharge ports form the first charge and discharge ports
- the tabs of the second bare cell portion form the second charge and discharge ports.
- the battery also includes a protection board, the protection board has a first charge and discharge circuit, a second charge and discharge circuit, a third charge and discharge port and a fourth charge and discharge port.
- the first charging and discharging circuit is electrically connected to the first bare cell part by means of the first charging and discharging port, the third charging and discharging port is located on the first charging and discharging circuit, and the protection board is used for connecting with the power management module, charging and discharging by means of the third charging and discharging port.
- the management module and the charger are electrically connected to form a charge-discharge link.
- the second charging and discharging circuit is electrically connected to the second bare cell part via the second charging and discharging port, the fourth charging and discharging port is located on the second charging and discharging circuit, and the protection board is used for connecting with the power management module, charging and discharging via the fourth charging and discharging port.
- the management module and the charger are electrically connected to form another charge-discharge link.
- the battery forms at least two independent charge and discharge links.
- the battery can be charged and discharged at the same time through the two charge-discharge links, which can improve the charge-discharge speed of the battery.
- one of the first bare cell part and the second bare cell part can be respectively managed for charge and discharge, and parameters such as capacity, cycle times, and state of health can be detected, or at the same time.
- Charge and discharge management and detection of parameters such as capacity, cycle times, and health status are performed on both the first bare cell part and the second bare cell part. To maximize the utilization of battery performance and state of health, it is also possible to charge one bare cell and discharge another bare cell at the same time.
- some embodiments of the present application provide an electronic device, including: a casing and a battery.
- the casing is provided with a battery compartment, and the battery compartment has an opening.
- the battery is installed in the battery compartment, and the orientation of the first surface of the first bare cell part in the battery is the same as the orientation of the opening of the battery compartment. Similarly, the side of the first bare cell portion faces the inner side of the battery compartment.
- the electronic device provided in the embodiment of the present application includes the battery described in any of the above technical solutions, the two can solve the same technical problem and achieve the same effect.
- the electronic device further includes: a power management module, the power management module is electrically connected to the battery, and the power management module is configured to release the electric power of the second bare cell part of the battery to the first When a preset threshold is reached, the first bare cell part is discharged again.
- the power in the second bare cell part can be reduced, even if the second bare cell part is damaged due to being close to the opening of the battery compartment and the inner side of the battery compartment, it will The second bare cell part has less power, which reduces the risk of burning and improves the safety of the battery.
- the value interval range of the first preset threshold is [0, 80% SOC].
- the value interval range of the first preset threshold is [0, 70% SOC].
- the electronic device further includes: a charge management module, the charge management module is electrically connected to the battery, and the charge management module is configured to charge the second bare cell part of the battery to the first
- the charge management module is configured to charge the second bare cell part of the battery to the first
- the charging speed of the second bare cell part is faster.
- the second bare cell part is charged first, which is beneficial to the charging of the second bare cell part.
- the timely replenishment of battery power is convenient for users, and the battery management is more intelligent.
- the value interval range of the second preset threshold is: [60% SOC, 100% SOC].
- FIG. 1 is a perspective view of an electronic device provided by some embodiments of the present application.
- Fig. 2 is an exploded view of the electronic device shown in Fig. 1;
- FIG. 3 is a perspective view of a battery provided by some embodiments of the present application.
- Figure 4 is an exploded view of the battery shown in Figure 3;
- FIG. 5 is a perspective view of a battery provided by other embodiments of the present application.
- Figure 6 is an exploded view of the battery shown in Figure 5;
- FIG. 7a is a schematic diagram of the diaphragm of the first bare cell part provided by some embodiments of the present application.
- FIG. 7b is a schematic diagram of a connection structure between the first bare cell part body and the first tab shown in FIG. 7a;
- FIG. 7c is a schematic diagram of another connection structure between the first bare cell part body and the first tab shown in FIG. 7a;
- FIG. 7d is a schematic diagram of a connection structure of the first pole piece and the first tab in the unfolded state of the first bare cell part body shown in FIG. 7a;
- FIG. 7e is a schematic structural diagram of the first pole piece shown in FIG. 7d after the first diaphragm, the second pole piece and the second diaphragm are wound to form a bare cell;
- FIG. 7f is a schematic diagram of another connection structure between the first pole piece and the first pole tab in the unfolded state of the first bare cell part body shown in FIG. 7a;
- FIG. 7g is a schematic structural diagram of the first pole piece shown in FIG. 7f after the first diaphragm, the second pole piece and the second diaphragm are wound to form a bare cell;
- FIG. 8 is a schematic diagram of the diaphragm of the second bare cell part provided by some embodiments of the present application.
- FIG. 9 is a perspective cross-sectional view of the battery shown in FIG. 5;
- FIG. 10 is a partial structural schematic diagram of the battery shown in FIG. 5, and the casing is not shown in FIG. 10;
- FIG. 11 is a perspective cross-sectional view of a battery provided by further embodiments of the present application.
- FIG. 12 is an exploded view of a battery provided by further embodiments of the present application.
- FIG. 13 is a perspective cross-sectional view of a battery provided by some other embodiments of the present application.
- 15 is a perspective cross-sectional view of a battery provided by other embodiments of the present application.
- 16 is an exploded view of a battery provided by other embodiments of the present application.
- FIG. 17 is a partial structural schematic diagram of a battery provided by other embodiments of the present application, and the casing is not shown in FIG. 17 ;
- FIG. 18 is an exploded view of a battery provided by other embodiments of the present application.
- FIG. 19 is a perspective cross-sectional view of a battery provided by other embodiments of the present application.
- FIG. 21 is a schematic partial structure diagram of a battery provided by other embodiments of the present application, and the casing is not shown in FIG. 21;
- FIG. 22 is a perspective cross-sectional view after adding a third bare cell part on the basis of the battery shown in FIG. 9;
- Fig. 23 is a partial structural schematic diagram of the battery shown in Fig. 22, and the casing is not shown in Fig. 23;
- 24 is a schematic diagram of a front structure of an electronic device provided by some embodiments of the present application.
- FIG. 25 is a schematic cross-sectional structure diagram of the electronic device shown in FIG. 24 at the line A-A;
- FIG. 26 is another schematic cross-sectional structure diagram of the electronic device shown in FIG. 24 at the line A-A.
- first”, “second”, “third” and “fourth” are only used for description purposes, and cannot be understood as indicating or implying relative importance or implying the indicated Number of technical features.
- a feature defined as “first”, “second”, “third”, “fourth” may expressly or implicitly include one or more of that feature.
- the terms “comprising”, “comprising” or any other variation thereof are intended to encompass non-exclusive inclusion, such that a process, method, article or device comprising a series of elements includes not only those elements, but also Include other elements not expressly listed, or which are inherent to such a process, method, article or apparatus.
- an element qualified by the phrase “comprising a" does not preclude the presence of additional identical elements in a process, method, article or apparatus that includes the element.
- the present application provides an electronic device.
- the electronic device involved in the embodiments of the present application may be any device including the battery 40, and the electronic device includes but is not limited to a mobile phone, a tablet personal computer, a laptop computer, a personal digital assistant ( electronic devices such as personal digital assistant, PDA), personal computers, notebook computers, in-vehicle devices and wearable devices.
- FIG. 1 is a perspective view of an electronic device provided by some embodiments of the present application
- FIG. 2 is an exploded view of the electronic device shown in FIG. 1
- the electronic device may include a housing 10 , a powered device 20 , a circuit board 30 , a charge management module 51 , a power management module 52 and a battery 40 .
- the electrical device 20 is used to realize one or more functions of the electronic device.
- the electrical device 20 includes but is not limited to a processor, a camera module and a display screen.
- the housing 10 is a structure composed of a front cover plate 15 , a middle plate 14 , a frame 11 and a rear cover 12 .
- the front cover 15 is a light-transmitting member, and the electrical device 20 includes a display screen, and the display screen is used for displaying images, videos, and the like.
- the front cover 15 is stacked and fixedly connected to the display screen.
- the front cover 15 is mainly used to protect the display screen and to prevent dust.
- the material of the front cover 15 includes but is not limited to glass, plastic or ceramic.
- the display can be a flexible display or a rigid display.
- the display can be an organic light-emitting diode (OLED) display, an active matrix organic light emitting diode or an active matrix organic light-emitting diode (active-matrix organic light-emitting diode, AMOLED) display screen, mini organic light-emitting diode (mini organic light-emitting diode) display, micro light-emitting diode (micro organic light-emitting diode) display, micro organic light-emitting diode (micro organic light-emitting diode) display, quantum dot light-emitting diode ( quantum dot light emitting diodes, QLED) display, liquid crystal display (liquid crystal display, LCD).
- OLED organic light-emitting diode
- AMOLED active matrix organic light-emitting diode
- mini organic light-emitting diode mini organic
- the middle plate 14 is located on the side of the display screen away from the front cover plate 15 .
- the rear cover 12 is provided on the side of the middle plate 14 away from the display screen.
- the frame 11 is located between the rear cover 12 and the front cover 15 and surrounds the outer circumference of the middle plate 14 .
- the frame 11 may be fixedly connected to the back cover 12 by gluing or welding.
- the frame 11 and the rear cover 12 can also be formed into an integral structure, that is, the frame 11 and the rear cover 12 are an integral structure.
- the frame 11 can also be fixed on the middle plate 14 by gluing or welding.
- the frame 11 and the middle plate 14 may also be formed into an integral structure, that is, the frame 11 and the middle plate 14 are an integral structure.
- the casing 10 is provided with a battery compartment 13 .
- the battery compartment 13 has an opening.
- the middle plate 14 and the frame 11 may define a battery compartment 13 with an opening after splicing.
- the battery compartment 13 may be formed by a side surface of the middle plate 14 that is away from the display screen and is recessed toward the side surface close to the display screen.
- the cover 12 is closed.
- the circuit board 30 is disposed on the casing 10 and is located on one side of the battery compartment 13 in the circumferential direction. Specifically, the circuit board 30 is located between the middle board 14 and the rear cover 12 , and the circuit board 30 is located on the upper side of the battery compartment 13 .
- the power management module 52 may be provided on the circuit board 30 .
- the power management module 52 is electrically connected to the battery 40 .
- the power management module 52 is configured to receive the input of the battery 40 and discharge the powered device 20 to supply power to the powered device 20 .
- the power management module 52 can also be used to monitor parameters such as the capacity of the battery 40 , the number of cycles of the battery 40 , and the health status (leakage, impedance) of the battery 40 .
- the charging management module 51 may be provided on the circuit board 30 .
- the charging management module 51 is electrically connected to the battery 40 .
- the charging management module 51 is configured to receive charging input from the charger.
- the charger can be a wireless charger or a wired charger.
- the charging management module 51 may receive charging input from a wired charger through a USB interface.
- the charging management module 51 may receive wireless charging input through a wireless charging coil of the electronic device.
- the power management module 52 and the charging management module 51 may be integrated into one body, or may be provided separately.
- the battery 40 is disposed in the battery compartment 13 , and the battery 40 is electrically connected to the circuit board 30 .
- the battery 40 may include, but is not limited to, a nickel-cadmium battery, a nickel-metal hydride battery, a lithium battery, or other types of batteries that include bare cells.
- the number of batteries 40 in the embodiment of the present application may be multiple or one, and the specific number and arrangement of the batteries 40 in the embodiment of the present application may be set according to actual needs. In the following description, the battery 40 is described as an example of a lithium battery.
- FIG. 3 is a perspective view of a battery 40 provided by some embodiments of the present application
- FIG. 4 is an exploded view of the battery 40 shown in FIG. 3
- the battery 40 includes a casing 41 , an electrolyte (not shown in the figure), a bare cell 44 and a protection plate 45 .
- the casing 41 is used to encapsulate and protect the bare cell 44 and the electrolyte, and the shape of the casing 41 includes but is not limited to a rectangular parallelepiped, a cylinder, a truncated cone, and the like.
- the material of the casing 41 may be a steel shell or a composite membrane.
- the material of the casing 41 is a composite film.
- the composite membrane is divided into at least three layers, the middle layer is a metal coating layer, which plays the role of isolating moisture, the outer layer is a plastic coating layer, which prevents the permeation of air, especially oxygen; the inner layer is a sealing layer, which acts as a sealing layer. And prevent the electrolyte from corroding the metal coating layer.
- the material of the sealing layer is selected from at least one of polyethylene, polypropylene, polyethylene or polypropylene esters, polyethylene or polypropylene ionomers, and polyethylene is selected from low density polyethylene, medium density polyethylene or high density polyethylene; polypropylene is selected from homopolypropylene, block polypropylene or random polypropylene.
- the material of the metal coating layer is selected from at least one of metals, metal alloys, metal oxides or ceramics, and the metal is selected from aluminum, iron, silver, copper, nickel, manganese, tin, titanium, zirconium or vanadium;
- the material is selected from at least one of polyamide resin, polyolefin, polycarbonate or fluororesin.
- the composite film can be specifically an aluminum-plastic film, the middle layer of the aluminum-plastic film is an aluminum layer, which acts as a moisture barrier, and the outer layer of the aluminum-plastic film is polyamide, which prevents the penetration of air, especially oxygen; the inner layer of the aluminum-plastic film
- the layer is a polypropylene layer that acts as a seal and prevents the electrolyte from corroding the aluminum layer.
- the electrolyte is a carrier for transporting lithium ions in the battery 40, and the electrolyte is generally prepared from raw materials such as high-purity organic solvents, electrolyte lithium salts, and necessary additives under certain conditions and in certain proportions.
- the protection board 45 can be an integrated circuit board that protects the battery 40 , for example, the protection board 45 is a BTB connector, and the protection board 45 is used to realize the electrical connection between the battery 40 and the circuit board 30 .
- the bare cell 44 includes a bare cell body 441 and tabs. Specifically, the tabs are connected to the bare cell body 441, the tabs include a first tab 442a and a second tab 442b, one of the first tab 442a and the second tab 442b is a positive tab and the other is a positive tab Negative tabs, the bare cell body 441 is located in the casing 41 , and the two tabs are connected to the protection plate 45 through the casing 41 .
- the capacity of the batteries required by the electronic devices increases.
- a battery with a large capacity has a higher risk of burning due to an internal short circuit.
- the battery is caused by external force impact, a broken back cover pierced into the battery or when repairing electronic equipment, and a screwdriver pierced into the battery. internal short circuit of the battery.
- the current improvement solutions focus on optimizing materials such as pole pieces, electrolytes, and separators.
- adding a functional coating to the aluminum foil of the positive electrode or improving the strength of the separator, etc. can prevent the most dangerous short circuit between the aluminum foil and the negative electrode or copper foil, causing the battery to catch fire and burn.
- Another example is to reduce the closed-cell temperature of the separator, or add a heat-resistant coating to the separator to prevent heat from spreading further inside the battery and causing thermal runaway, etc. Although these measures are effective, the energy density of the battery is reduced, and the charging and discharging speed is also reduced.
- FIG. 5 is a perspective view of a battery 40 provided by other embodiments of the present application
- FIG. 6 is an exploded view of the battery 40 shown in FIG. 5 .
- the battery 40 includes a first bare cell portion 42 and a second bare cell portion 43 .
- the first bare cell part 42 and the second bare cell part 43 are located in the casing 41 .
- the material of the casing 41 may be the same as that of the casing 41 in the above-mentioned embodiment.
- the first bare cell portion 42 includes a first bare cell portion body 421 and tabs.
- the shape of the first bare cell part body 421 may include, but is not limited to, a rectangular parallelepiped shape, a cylindrical shape, and a truncated cone shape.
- the first bare cell part body 421 may be wound. Please refer to FIG. 7a.
- FIG. 7a is a schematic cross-sectional structural diagram of the first bare cell part body 421 of the battery 40 shown in FIG. 6 .
- the first bare cell part body 421 is a wound bare cell part.
- the first bare cell part body 421 is formed by winding the film M.
- the diaphragm M includes a first pole piece 4211a, a first diaphragm 4212a, a second pole piece 4211b, and a second diaphragm 4212b that are stacked in sequence.
- One of the first pole piece 4211a and the second pole piece 4211b is a positive pole piece and the other is a negative pole piece.
- the separator arranged between the two adjacent pole pieces can separate the positive pole piece and the negative pole piece, and play the role of insulation and isolation to prevent short circuit between the two poles.
- the pole piece includes a current collecting piece and a polar material arranged on the surface of the current collecting piece, the polar material is a material that participates in charge-discharge reaction, and the current collecting piece is used for collecting current.
- the material for forming the current collector sheet is aluminum (chemical formula: Al).
- the material for forming the current collector sheet is copper (chemical formula: Cu).
- the forming material of the separator is a polyolefin porous film.
- both ends of the diaphragm extend beyond the two ends of the pole piece, thereby insulating and protecting the two ends of the pole piece along the extending direction of the winding axis of the diaphragm.
- the first bare cell part body 421 may also be of a laminated type. Specifically, the first bare cell part body 421 is formed by alternately stacking the first pole pieces and the second pole pieces in turn, and a diaphragm is provided between the adjacent first pole pieces and the second pole pieces. Wherein, one of the first pole piece and the second pole piece is a positive pole piece and the other is a negative pole piece. The structure of the pole pieces in the core part body 421 is the same.
- the diaphragm acts as an insulating isolation.
- the diaphragm can be a diaphragm bag, a diaphragm folded in a zigzag shape, or a plurality of single-piece diaphragms. One pole piece and the second pole piece are sufficient.
- the material of the separator may also be a polyolefin porous membrane.
- the following description only takes the first bare cell part body 421 as a wound bare cell part as an example for description, which should not be regarded as a special limitation to the present application.
- the tabs of the first bare cell portion 42 include a first tab 422a and a second tab 422b, and one of the first tab 422a and the second tab 422b is The positive tab and the other is the negative tab, the first tab 422 a and the second tab 422 b protrude through the casing 41 to the outside of the casing 41 to be connected to the protection plate 45 .
- the first tab 422a and the second tab 422b form a first charging and discharging port B. As shown in FIG.
- first tab 422a is electrically connected to the first pole piece 4211a, and the other end of the first tab 422a extends through the housing 41 to the outside of the housing 41 and is connected to the protection plate 45 .
- One end of the second tab 422b is electrically connected to the second pole piece 4211b, and the other end of the second tab 422b protrudes through the casing 41 to the outside of the casing 41 and is connected to the protection plate 45 .
- the first tab 422a may be connected to the current collector of the first pole piece 4211a by welding, pressing, etc., or may be directly extended from the current collector of the first pole piece 4211a.
- FIG. 7b is a schematic diagram of a connection structure of the first bare cell part body 421 and the first tab 422a shown in FIG. 7a.
- the first pole piece 4211a includes a current collector piece 4211aa and a polar material 4211ab disposed on the current collector piece 4211aa.
- the first tab 422a is connected to the current collector 4211aa of the first pole piece 4211a by welding, pressing or the like.
- FIG. 7c is a schematic diagram of another connection structure of the first bare cell part body 421 and the first tab 422a shown in FIG. 7a.
- the first pole piece 4211a includes a current collector piece 4211aa and a polar material 4211ab disposed on the current collector piece 4211aa.
- the first tab 422a is formed by directly extending the current collecting piece 4211aa of the first pole piece 4211a.
- the second pole piece 4211b includes a current collector piece 4211ba and a polar material 4211bb disposed on the current collector piece 4211ba.
- the second tab 422b can be connected to the current collector 4211ba of the second pole piece 4211b by welding, pressing, etc., or can be directly extended from the current collector 4211ba of the second pole piece 4211b.
- FIG. 7b and FIG. 7c only show an example in which the first tab 422a is a single tab unit, and the structure of the first tab 422a is not limited to this.
- the first tab 422a is 422a may also be formed by fixing a plurality of tab units by welding, pressing, or the like.
- the plurality of tab units are disposed on the current collecting piece 4211aa of the first pole piece 4211a at intervals.
- the plurality of tab units are stacked to facilitate fixing.
- the plurality of tab units can be fixed on the current collector 4211aa of the first pole piece 4211a by welding, pressing, etc., or can be directly extended from the current collector 4211aa, which is not specifically limited herein.
- FIG. 7d is a schematic diagram of a connection structure of the first pole piece 4211a and the first tab 422a in the unfolded state of the first bare cell part body 421 shown in FIG. 7a.
- the first tab 422a includes a plurality of tab units 422a1.
- the plurality of tab units 422a1 are fixed on the current collecting piece 4211aa of the first pole piece 4211a at intervals by welding, pressing and other processes.
- FIG. 7e shows the first pole piece 4211a and the first pole piece 4211a and the first A schematic structural diagram of the separator 4212a, the second pole piece 4211b, and the second separator 4212b after winding to form a bare cell.
- a plurality of tab units 422a1 are stacked to form the first tab 422a so as to be fixed together by welding, pressing and other processes.
- FIG. 7f is a schematic diagram of another connection structure of the first pole piece 4211a and the first tab 422a in the unfolded state of the first bare cell part body 421 shown in FIG. 7a.
- the first tab 422a includes a plurality of tab units 422a1.
- the plurality of tab units 422a1 are directly formed by extending the current collector pieces 4211aa of the first pole piece 4211a.
- FIG. 7g shows the first pole piece 4211a and the first pole piece shown in FIG.
- FIG. 7f A schematic structural diagram of the separator 4212a, the second pole piece 4211b, and the second separator 4212b after winding to form a bare cell.
- a plurality of tab units 422a1 are stacked to form the first tab 422a so as to be fixed together by welding, pressing and other processes.
- the second pole piece 4211b includes a current collector piece 4211ba and a polar material 4211bb disposed on the current collector piece 4211ba.
- the second tab 422b may also be formed by fixing a plurality of tab units by welding, pressing, or the like.
- the plurality of tab units are disposed on the current collecting piece 4211ba of the second pole piece 4211b at intervals.
- the plurality of tab units are stacked to facilitate fixing.
- the plurality of tab units can be fixed on the current collecting piece 4211ba of the second pole piece 4211b by welding, pressing, etc., or can be directly formed by extending the current collecting piece 4211ba, which is not specifically limited herein.
- the tabs of the first bare cell part 42 are passed through the casing 41
- the part of the electrode is wrapped with tab glue, and the tab glue plays the role of insulation and isolation, so as to prevent the tabs from contacting with conductive layers such as metal in the casing 41 .
- the tab glue is formed by winding a single-sided tape
- the single-sided tape includes a base material and a glue material arranged on the surface of the base material.
- the forming materials of the base material include but are not limited to polypropylene (PP), polyethylene (polyethylene, PE), polyamide (polyamide, PA), polycarbonate (polycarbonate, PC), polyformaldehyde (polyformaldehyde, POM), polyethylene terephthalate (polyethylene glycol terephthalate, PET), polyethylene terephthalate Polybutylene terephthalate (PBT), polyphenylene oxide (PPO) and other plastics, the adhesive has a certain viscosity, and the adhesive is resistant to chemical solvent corrosion and high temperature (typically 200 °C), Adhesive materials include but are not limited to styrene-butadiene rubber, polyurethane, nitrocellulose, polyvinyl acetate and other solvent-based adhesives, ethylene-vinyl
- the shape of the single-sided tape includes, but is not limited to, rectangle, circle, square, diamond, trapezoid and hexagon.
- the tab glue can also be an insulating sleeve formed by dispensing glue dripped on the tab or sleeved on the tab and formed of insulating materials such as rubber and plastic.
- the first bare cell portion 42 has a first surface 4213 , a second surface 4215 and a side surface 4214 .
- the first surface 4213 and the second surface 4215 are disposed opposite to each other.
- the side surface 4214 is connected between the first surface 4213 and the second surface 4215.
- the first surface 4213 is used for the same orientation as the opening of the battery compartment 13 when the battery 40 is installed in the battery compartment 13 of the electronic device. That is, the first surface 4213 is closer to the aforementioned rear cover 12 .
- the second surface 4215 is used to face the bottom surface of the battery compartment 13 when the battery 40 is installed in the battery compartment 13 of the electronic device.
- the second surface 4215 faces away from the rear cover 12 and faces the bottom of the battery compartment 13 .
- the side surface 4214 is used to face the inner side of the battery compartment 13 when the battery 40 is installed in the battery compartment 13 of the electronic device.
- the second bare cell portion 43 includes a second bare cell portion body 431 and tabs.
- the shape of the second bare cell part body 431 may include, but is not limited to, a rectangular parallelepiped shape, a cylindrical shape, and a truncated cone shape.
- the second bare cell part body 431 may be wound.
- FIG. 8 is a schematic cross-sectional structural diagram of the second bare cell part body 431 of the battery 40 shown in FIG. 6 .
- the second bare cell part body 431 is a wound bare cell part.
- the second bare cell part body 431 is formed by winding the diaphragm N.
- the diaphragm N includes a first pole piece 4311a, a first diaphragm 4312a, a second pole piece 4311b, and a second diaphragm 4312b that are stacked in sequence.
- One of the first pole piece 4311a and the second pole piece 4311b is a positive pole piece and the other is a negative pole piece, and the separator arranged between the two adjacent pole pieces can separate the positive pole piece and the negative pole piece, so that the The role of insulation and isolation to prevent short circuit between the two poles.
- the structure and material of the pole pieces of the second bare cell part body 431 may be the same as those of the above-mentioned pole pieces of the first bare cell part body 421, and the material of the diaphragm of the second bare cell part body 431 may be the same as the above-mentioned pole pieces of the first bare cell part body 421
- the first bare cell part body 421 is the same.
- the second bare cell part body 431 may also be of a laminated type. Specifically, the second bare cell part body 431 is formed by alternately stacking the first pole pieces and the second pole pieces in turn, and a diaphragm is provided between the adjacent first pole pieces and the second pole pieces. Wherein, one of the first pole piece and the second pole piece is a positive pole piece and the other is a negative pole piece.
- the first pole piece and the second pole piece of the laminated second bare cell part 43 may be respectively the same in structure and material as the pole pieces in the above-mentioned wound second bare cell part body 431 .
- the diaphragm may be a diaphragm bag, a diaphragm folded in a zigzag shape, or a plurality of single-piece diaphragms.
- This application does not limit the specific structural form of the diaphragm in the laminated bare cell part.
- the material of the separator may also be a polyolefin porous membrane.
- the second bare cell portion 43 and the first bare cell portion 42 may be independent of each other and physically separated, that is, the two are independent bare cells respectively.
- the diaphragm of the second bare cell part 43 and the diaphragm of the first bare cell part 42 may also be connected into one body.
- the second The bare cell portion 43 is integrally connected with the first bare cell portion 42 .
- the tabs of the second bare cell portion 43 include a first tab 433a and a second tab 433b.
- One of the first tab 433a and the second tab 433b is a positive tab and the other is a negative tab.
- the protective plate 45 is connected.
- the first tab 433a and the second tab 433b form a second charge and discharge port C.
- first tab 433a is electrically connected to the first pole piece 4311a
- the other end of the first tab 433a protrudes through the housing 41 to the outside of the housing 41 and is connected to the protection plate 45
- the second tab 433a is connected to the protection plate 45
- One end of the second pole piece 433b is electrically connected to the second pole piece 4311b, and the other end of the second pole tab 433b extends through the casing 41 to the outside of the casing 41 and is connected to the protection plate 45.
- first tab 433a is connected to the current collector of the first pole piece 4311a
- second tab 433b is connected to the current collector of the second pole piece 4311b
- first tab 433a and the second tab 433b can be connected to the current collector of the first pole piece 4311a and the current collector of the second pole piece 4311b by welding, pressing, etc.
- the collector piece of the first pole piece 4311a and the collector piece of the second pole piece 4311b are directly formed by extending, which is not specifically limited herein.
- the tabs of the second bare cell part 43 are pierced through the casing 41
- the part of the electrode is wrapped with tab glue, and the tab glue plays the role of insulation and isolation, so as to prevent the tabs from contacting with conductive layers such as metal in the casing 41 .
- the material and shape of the tab glue are the same as the material and shape of the tab glue used to wrap the first bare cell part 42 described above, and will not be repeated here.
- the second bare cell part 43 is used to resist the penetration of items such as a broken back cover, a screwdriver, etc., and at the same time, these items are prevented from piercing into the second bare cell part 43 and the first bare cell part 42 at the same time. This prevents the first bare cell portion 42 and the second bare cell portion 43 from being short-circuited at the same time, resulting in a large amount of energy released at the same time, thereby reducing the possibility of safety problems such as fire and explosion.
- the azimuth relationship between the first bare cell part 42 and the second bare cell part 43 needs to be reasonably arranged, so that the second bare cell part 43 can be used to protect the first bare cell part 42 and reduce the The first bare cell portion 42 and the second bare cell portion 43 are simultaneously pierced to cause the possibility of a short circuit.
- the azimuthal relationship between the first bare cell portion 42 and the second bare cell portion 43 may include the following examples one to three.
- This example is improved from the viewpoint that the second bare cell portion 43 only protects the first bare cell portion 42 from the first surface 4213 side.
- FIG. 9 is a three-dimensional cross-sectional view of the battery shown in FIG. 5
- FIG. 10 is a partial structural schematic view of the battery shown in FIG.
- the second bare cell portion 43 is located on the side facing the first surface 4213, and the orthographic projection of the second bare cell portion 43 on the first surface 4213 overlaps the first surface 4213.
- a part of the orthographic projection of the second bare cell part 43 on the first surface 4213 coincides with a part of the first surface 4213;
- the surface 4213 coincides; the entire orthographic projection of the second bare cell portion 43 on the first surface 4213 coincides with a part of the first surface 4213 ; or, the orthographic projection of the second bare cell portion 43 on the first surface 4213 coincides with
- the surfaces 4213 are completely coincident, that is, the outer circumference of the surface of the second bare cell portion 43 facing the first surface 4213 is flush with the outer circumference of the first surface 4213 . In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the first surface 4213 side, thereby improving the safety of the battery 40 .
- a housing cavity is formed in the housing 41 , and the first bare cell part 42 and the second bare cell part 43 can be located in the housing cavity of the housing 41 , that is The first bare cell part 42 and the second bare cell part 43 share the accommodating cavity, which is beneficial to improve the space utilization of the battery 40 .
- FIG. 11 is a three-dimensional cross-sectional view of a battery according to further embodiments of the present application. In the example shown in FIG. 11 , the first bare cell part 42 and the second bare cell part 43 are located in different accommodating cavities of the housing 41 .
- the housing 41 includes a first housing unit 41a and a second housing unit 41b.
- the material of the first casing unit 41 a and the second casing unit 41 b may be the same as the material of the casing 41 described above.
- the shape of the first housing unit 41a includes, but is not limited to, a rectangular parallelepiped, a cylinder, or a truncated cone
- the shape of the second housing unit 41b includes, but is not limited to, a rectangular parallelepiped, a cylinder, or a truncated cone.
- the second case unit 41b and the first case unit 41a are stacked and disposed, and the second case unit 41b is located on the side of the first case unit 41a facing the opening of the battery compartment 13 and is relatively fixed to the first case unit 41a
- the second housing unit 41b is fixed to the first housing unit 41a by means of gluing, clamping, screwing, welding or the like.
- a first accommodating cavity is formed in the first housing unit 41a, and a second accommodating cavity is formed in the second housing unit 41b.
- the first bare cell portion 42 is accommodated in the first accommodating cavity, and the shape of the first bare cell portion 42 can be adapted to the shape of the first housing unit 41a.
- the second bare cell portion 43 is accommodated in the second accommodating cavity, and the shape of the second bare cell portion 43 can be adapted to the shape of the second housing unit 41b. In this way, the first bare cell portion 42 and the second bare cell portion 43 can be independent of each other, thereby improving the safety of the first bare cell portion 42 and the second bare cell portion 43 in operation.
- This example is an improvement from the viewpoint that the second bare cell portion 43 protects the first bare cell portion 42 from the first surface 4213 side and the side surface 4214 side.
- the protection of the second bare cell portion 43 to the side surface 4214 of the first bare cell portion 42 may be for any side surface 4214 of the plurality of side surfaces 4214 arranged along the circumferential direction of the first surface 4213 , or any of several sides 4214, or all sides 4214.
- FIG. 12 is an exploded view of a battery according to further embodiments of the present application.
- the second bare cell portion 43 includes a first sub-portion 4313 and a second sub-portion 4314 .
- the first sub-section 4313 is located on the side to which the first surface 4213 faces, and the orthographic projection of the first sub-section 4313 on the first surface 4213 overlaps the first surface 4213 . That is, a part of the orthographic projection of the first subsection 4313 on the first surface 4213 coincides with a part of the first surface 4213; a part of the orthographic projection of the first subsection 4313 on the first surface 4213 coincides with the first surface 4213; The entire orthographic projection of the first subsection 4313 on the first surface 4213 coincides with a part of the first surface 4213; or, the orthographic projection of the first subsection 4313 on the first surface 4213 completely coincides with the first surface 4213, namely The perimeter of the surface of a sub-portion 4313 facing the first surface 4213 is flush with the perimeter of the first surface 4213 . In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the first surface 4213 side, thereby improving the safety of the battery 40 .
- the side surfaces 4214 include a first side surface 42141 and a second side surface 42142 .
- the first side surface 42141 and the second side surface 42142 are arranged and connected in the circumferential direction of the first surface 4213 .
- the tabs of the first bare cell portion 42 are disposed on the first side surface 42141 .
- the second sub-section 4314 is located on the side to which the second side surface 42142 faces, and the orthographic projection of the second sub-section 4314 on the second side surface 42142 overlaps the second side surface 42142 .
- a part of the orthographic projection of the second subsection 4314 on the second side 42142 coincides with a part of the second side 42142; a part of the orthographic projection of the second subsection 4314 on the second side 42142 coincides with the second side 42142;
- the entire orthographic projection of the second subsection 4314 on the second side 42142 coincides with a part of the second side 42142; or, the orthographic projection of the second subsection 4314 on the second side 42142 completely coincides with the second side 42142, that is
- the surfaces of the two sub-sections 4314 facing the second side 42142 have the same thickness as the second side 42142 , and the outer circumferences of the surfaces of the second sub-sections 4314 facing the second side 42142 are flush with the outer circumference of the second side 42142 .
- the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the second side 42142 side, thereby improving the safety of the battery 40 .
- first sub-section 4313 and the second sub-section 4314 may be independent of each other and physically separated, that is, the two are independent bare cells.
- first sub-section 4313 and the second sub-section 4314 may be an integral structure.
- an accommodating cavity is formed in the housing 41 , and the first bare cell part 42 and the second bare cell part 43 can be located in the accommodating cavity, so that the first bare cell part 42 Sharing the accommodating cavity with the second bare cell part 43 not only helps to reduce the overall volume of the battery 40 but also reduces the cost.
- FIG. 13 is a three-dimensional cross-sectional view of a battery provided by other embodiments of the present application.
- the first bare cell part 42 and the second bare cell part 43 may also be located in different accommodating cavities of the housing 41 .
- FIG. 13 is a three-dimensional cross-sectional view of a battery provided by other embodiments of the present application.
- the first bare cell part 42 and the second bare cell part 43 may also be located in different accommodating cavities of the housing 41 .
- FIG. 12 is a three-dimensional cross-sectional view of a battery provided by other embodiments of the present application.
- the housing 41 includes a first housing unit 41a and a second housing unit 41b.
- a part of the second case unit 41b is located on the side of the first case unit 41a facing the opening of the battery compartment 13 and the other part of the second case unit 41b is located on the inner side of the first case unit 41a facing the battery compartment 13 side.
- a first accommodating cavity is formed in the first housing unit 41a, and a second accommodating cavity is formed in the second housing unit 41b.
- the first bare cell portion 42 is accommodated in the first accommodating cavity, and the shape of the first bare cell portion 42 can be adapted to the shape of the first housing unit 41a.
- the second bare cell portion 43 is accommodated in the second accommodating cavity, and the shape of the second bare cell portion 43 can be adapted to the shape of the second housing unit 41b.
- FIG. 14 is an exploded view of a battery provided by other other embodiments of the present application.
- the second bare cell portion 43 includes a first sub-portion 4313 , a second sub-portion 4314 and a third sub-portion 4315 .
- the first sub-section 4313 is located on the side to which the first surface 4213 faces, and the orthographic projection of the first sub-section 4313 on the first surface 4213 overlaps the first surface 4213 . That is, a part of the orthographic projection of the first subsection 4313 on the first surface 4213 coincides with a part of the first surface 4213; a part of the orthographic projection of the first subsection 4313 on the first surface 4213 coincides with the first surface 4213; The entire orthographic projection of the first subsection 4313 on the first surface 4213 coincides with a part of the first surface 4213 ; or, the orthographic projection of the first subsection 4313 on the first surface 4213 completely coincides with the first surface 4213 . In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the first surface 4213 side, thereby improving the safety of the battery 40.
- the side surfaces 4214 include a first side surface 42141 , a second side surface 42142 and a third side surface 42143 .
- the first side surface 42141 and the second side surface 42142 are arranged and connected in the circumferential direction of the first surface 4213 .
- the third side surface 42143 is opposite to the second side surface 42142 .
- the tabs of the first bare cell portion 42 are disposed on the first side surface 42141 .
- the second sub-section 4314 is located on the side to which the second side surface 42142 faces, and the orthographic projection of the second sub-section 4314 on the second side surface 42142 overlaps the second side surface 42142 . That is, a part of the orthographic projection of the second subsection 4314 on the second side 42142 coincides with a part of the second side 42142; a part of the orthographic projection of the second subsection 4314 on the second side 42142 coincides with the second side 42142; The entire orthographic projection of the second subsection 4314 on the second side surface 42142 coincides with a part of the second side surface 42142; In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the second side 42142 side, thereby improving the safety of the battery 40 .
- the third sub-section 4315 is located on the side to which the third side surface 42143 faces, and the orthographic projection of the third sub-section 4315 on the third side surface 42143 overlaps the third side surface 42143 . That is, a part of the orthographic projection of the third subsection 4315 on the third side 42143 coincides with a part of the third side 42143; a part of the orthographic projection of the third subsection 4315 on the third side 42143 coincides with the third side 42143; The entire orthographic projection of the third subsection 4315 on the third side 42143 coincides with a part of the third side 42143; or, the orthographic projection of the third subsection 4315 on the third side 42143 completely coincides with the third side 42143, that is The surface of the third subsection 4315 facing the third side 42143 has the same thickness as the third side 42143 , and the outer circumference of the surface of the third subsection 4315 facing the third side 42143 is flush with the outer circumference of the third side 42143 . In this way, the second bare cell portion 43 can be used to protect
- the first sub-section 4313, the second sub-section 4314 and the third sub-section 4315 may be independent of each other and physically separated. That is, the three are independent bare cells.
- the present application is not limited thereto, and in other embodiments, the first sub-section 4313 , the second sub-section 4314 and the third sub-section 4315 may also have an integrated structure.
- any two of the first sub-section 4313 , the second sub-section 4314 , and the third sub-section 4315 are of an integrated structure, and the other one is an independent bare cell.
- an accommodating cavity is formed in the housing 41 , and the first bare cell part 42 and the second bare cell part 43 can be located in the accommodating cavity, so that the first bare cell part 42 Sharing the accommodating cavity with the second bare cell part 43 not only helps to reduce the overall volume of the battery 40 but also reduces the cost.
- FIG. 15 is a three-dimensional cross-sectional view of a battery according to other embodiments of the present application.
- the first bare cell part 42 and the second bare cell part 43 may also be located in different accommodating cavities of the housing 41 .
- FIG. 15 is a three-dimensional cross-sectional view of a battery according to other embodiments of the present application.
- the first bare cell part 42 and the second bare cell part 43 may also be located in different accommodating cavities of the housing 41 .
- FIG. 15 is a three-dimensional cross-sectional view of a battery according to other embodiments of the present application.
- the first bare cell part 42 and the second bare cell part 43 may also be located in different accommodating cavities of the
- the housing 41 includes a first housing unit 41a and a second housing unit 41b.
- a part of the second case unit 41b is located on the side of the first case unit 41a facing the opening of the battery compartment 13 and the other part of the second case unit 41b is located on the inner side of the first case unit 41a facing the battery compartment 13 side.
- a first accommodating cavity is formed in the first housing unit 41a
- a second accommodating cavity is formed in the second housing unit 41b
- the first bare cell part 42 is accommodated in the first accommodating cavity
- the first bare cell part 42 The shape of the second bare cell part 43 can be matched with the shape of the first housing unit 41a
- the second bare cell part 43 is accommodated in the second accommodating cavity
- the shape of the second bare cell part 43 can be matched with the shape of the second housing unit 41b. fit.
- FIG. 16 is an exploded view of a battery according to still other embodiments of the present application.
- the second bare cell portion 43 includes a first sub-section 4313, a second sub-section 4314, and a fourth sub-section 4316.
- the first sub-section 4313 is located on the side to which the first surface 4213 faces, and the orthographic projection of the first sub-section 4313 on the first surface 4213 overlaps the first surface 4213 . That is to say, a part of the orthographic projection of the first subsection 4313 on the first surface 4213 coincides with a part of the first surface 4213 , and a part of the orthographic projection of the first subsection 4313 on the first surface 4213 completely coincides with the first surface 4213 , the entire orthographic projection of the first subsection 4313 on the first surface 4213 coincides with a part of the first surface 4213 , or the orthographic projection of the first subsection 4313 on the first surface 4213 completely coincides with the first surface 4213 .
- the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the first surface 4213 side, thereby improving the safety of the battery 40 .
- the side surface 4214 includes a first side surface 42141, a second side surface 42142 and a fourth side surface 42144, the first side surface 42141 and the second side surface 42142 are arranged and connected in the circumferential direction of the first surface 4213, and the fourth side surface 42144 is opposite to the first side surface 42141. Opposite to each other, the tabs of the first bare cell portion 42 are disposed on the first side surface 42141 .
- the second sub-section 4314 is located on the side to which the second side surface 42142 faces, and the orthographic projection of the second sub-section 4314 on the second side surface 42142 overlaps the second side surface 42142 . That is, a part of the orthographic projection of the second subsection 4314 on the second side 42142 coincides with a part of the second side 42142; a part of the orthographic projection of the second subsection 4314 on the second side 42142 coincides with the second side 42142; The entire orthographic projection of the second subsection 4314 on the second side surface 42142 coincides with a part of the second side surface 42142; In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the second side 42142 side, thereby improving the safety of the battery 40 .
- the fourth sub-section 4316 is located on the side to which the fourth side surface 42144 faces, and the orthographic projection of the fourth sub-section 4316 on the fourth side surface 42144 overlaps the fourth side surface 42144 . That is, a part of the orthographic projection of the fourth subsection 4316 on the fourth side 42144 coincides with a part of the fourth side 42144, and a part of the orthographic projection of the fourth subsection 4316 on the fourth side 42144 coincides with the fourth side 42144, The entire orthographic projection of the fourth sub-section 4316 on the fourth side 42144 coincides with a part of the fourth side 42144 , or the orthographic projection of the fourth sub-section 4316 on the fourth side 42144 completely coincides with the fourth side 42144 . In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the fourth side 42144 side, thereby improving the safety of the battery 40 .
- the first sub-section 4313 , the second sub-section 4314 and the fourth sub-section 4316 may be independent of each other and physically separated, that is, the three are independent bare cells.
- the present application is not limited thereto, and in other embodiments, at least two of the first sub-section 4313 , the second sub-section 4314 , and the fourth sub-section 4316 have an integrated structure.
- the first sub-section 4313, the second sub-section 4314, and the fourth sub-section 4316 have an integrated structure.
- FIG. 17 is a partial structural schematic diagram of a battery provided by other embodiments of the present application, and the casing is not shown in FIG. 17 .
- the second bare cell portion 43 includes a first sub-portion 4313 and a fourth sub-portion 4316 .
- the first sub-section 4313 is located on the side to which the first surface 4213 faces, and the orthographic projection of the first sub-section 4313 on the first surface 4213 overlaps the first surface 4213 . That is, a part of the orthographic projection of the first subsection 4313 on the first surface 4213 coincides with a part of the first surface 4213; a part of the orthographic projection of the first subsection 4313 on the first surface 4213 coincides with the first surface 4213; The entire orthographic projection of the first subsection 4313 on the first surface 4213 coincides with a part of the first surface 4213 ; or, the orthographic projection of the first subsection 4313 on the first surface 4213 completely coincides with the first surface 4213 . In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the first surface 4213 side, thereby improving the safety of the battery 40.
- the side surfaces 4214 include a first side surface 42141 and a fourth side surface 42144 .
- the first side 42141 is opposite to the fourth side 42144.
- the tabs of the first bare cell portion 42 are disposed on the first side surface 42141 .
- the fourth sub-section 4316 is located on the side to which the fourth side surface 42144 faces, and the orthographic projection of the fourth sub-section 4316 on the fourth side surface 42144 overlaps the fourth side surface 42144 . That is, a part of the orthographic projection of the fourth subsection 4316 on the fourth side 42144 coincides with a part of the fourth side 42144; a part of the orthographic projection of the fourth subsection 4316 on the fourth side 42144 coincides with the fourth side 42144; The entire orthographic projection of the fourth subsection 4316 on the fourth side 42144 coincides with a part of the fourth side 42144; or, the orthographic projection of the fourth subsection 4316 on the fourth side 42144 completely coincides with the fourth side 42144. In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the fourth side 42144 side, thereby improving the safety of the battery 40 .
- first sub-section 4313 and the fourth sub-section 4316 may be independent of each other and physically separated, that is, the two are independent bare cells.
- present application is not limited thereto, and in other embodiments, the diaphragms of the first sub-section 4313 and the fourth sub-section 4316 are connected into one piece.
- an accommodating cavity is formed in the casing 41 , and the first bare cell part 42 and the second bare cell part 43 can be placed in the accommodating cavity, so that the first bare cell part 42 and The second bare cell part 43 shares the accommodating cavity, which not only helps to reduce the overall volume of the battery 40 but also reduces the cost.
- the example is not limited to this, and the first bare cell portion 42 and the second bare cell portion 43 may also be located in different accommodating cavities of the housing 41 .
- the second bare cell part 43 may also include the first sub-part 4313 , the second sub-part 4314 , the third sub-part 4315 and the fourth sub-part 4316 at the same time.
- the first surface 4213 side, the second side surface 42142 side, the third side surface 42143 side and the fourth side surface 42144 side of the first bare cell part 42 are simultaneously protected to improve the safety of the battery 40 .
- the protection of the second bare cell portion 43 to the side surface 4214 of the first bare cell portion 42 may be for any side surface 4214 of the plurality of side surfaces 4214 arranged along the circumferential direction of the first surface 4213 , or any of several sides 4214, or all sides 4214.
- the side surface 4214 includes a first side surface 42141 and a second side surface 42142, the second side surface 42142 and the first side surface 42141 are arranged and connected in the circumferential direction of the first surface 4213, and the tabs of the first bare cell part 42 Disposed on the first side 42141, the second bare cell portion 43 is located on the side facing the second side 42142, and the orthographic projection of the second bare cell portion 43 on the second side 42142 overlaps the second side 42142.
- a part of the orthographic projection of the second bare cell part 43 on the second side 42142 coincides with a part of the second side 42142;
- the side surfaces 42142 overlap; the entire orthographic projection of the second bare cell portion 43 on the second side 42142 overlaps with a part of the second side 42142; or, the orthographic projection of the second bare cell portion 43 on the second side 42142 is the same as the second The sides 42142 are completely coincident.
- the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the second side 42142 side, thereby improving the safety of the battery 40 .
- a housing cavity is formed in the housing 41, and the first bare cell part 42 and the second bare cell part 43 are located in the accommodating cavity, so that the first bare cell part 42 and the second bare cell part 43 are located in the accommodating cavity.
- the second bare cell part 43 can accommodate a cavity, which not only helps to reduce the overall volume of the battery 40 but also reduces the cost.
- FIG. 19 is a three-dimensional cross-sectional view of a battery provided by other embodiments of the present application.
- the first bare cell part 42 and the second bare cell part 43 may also be located in different accommodating cavities of the casing 41 .
- the housing 41 includes a first housing unit 41a and a second housing unit 41b, and the second housing unit 41b is located on a side of the first housing unit 41a adjacent to the second side surface 42142, and is connected with the first housing unit 41a.
- the body unit 41a is relatively fixed, the first housing unit 41a is formed with a first accommodating cavity, the second housing unit 41b is formed with a second accommodating cavity, the first bare cell part 42 is accommodated in the first accommodating cavity, and the second accommodating cavity is formed in the second housing unit 41b.
- the shape of a bare cell portion 42 can be adapted to the shape of the first housing unit 41a, the second bare cell portion 43 is accommodated in the second accommodating cavity, and the shape of the second bare cell portion 43 can be matched with the shape of the second bare cell portion 43.
- the shape of the housing unit 41b is adapted. In this way, the first bare cell portion 42 and the second bare cell portion 43 can be independent of each other, thereby improving the safety of the first bare cell portion 42 and the second bare cell portion 43 in operation.
- the side surface 4214 includes a first side surface 42141, a second side surface 42142 and a fourth side surface 42144.
- the second side surface 42142 and the first side surface 42141 are arranged and connected in the circumferential direction of the first surface 4213.
- the first bare cell The tabs of the part 42 are disposed on the first side 42141 , the fourth side 42144 is opposite to the first side 42141 , and the second bare cell part 43 includes a second sub-section 4314 and a fourth sub-section 4316 .
- the second sub-section 4314 is located on the side to which the second side surface 42142 faces, and the orthographic projection of the second sub-section 4314 on the second side surface 42142 overlaps the second side surface 42142 . That is, a part of the orthographic projection of the second subsection 4314 on the second side 42142 coincides with a part of the second side 42142; a part of the orthographic projection of the second subsection 4314 on the second side 42142 coincides with the second side 42142; The entire orthographic projection of the second subsection 4314 on the second side surface 42142 coincides with a part of the second side surface 42142; In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the second side 42142 side, thereby improving the safety of the battery 40 .
- the fourth sub-section 4316 is located on the side to which the fourth side surface 42144 faces, and the orthographic projection of the fourth sub-section 4316 on the fourth side surface 42144 overlaps the fourth side surface 42144 . That is, a part of the orthographic projection of the fourth subsection 4316 on the fourth side 42144 coincides with a part of the fourth side 42144; a part of the orthographic projection of the fourth subsection 4316 on the fourth side 42144 coincides with the fourth side 42144; The entire orthographic projection of the fourth subsection 4316 on the fourth side 42144 coincides with a part of the fourth side 42144; or, the orthographic projection of the fourth subsection 4316 on the fourth side 42144 completely coincides with the fourth side 42144. In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the fourth side 42144 side, thereby improving the safety of the battery 40 .
- the second sub-section 4314 and the fourth sub-section 4316 may be independent of each other and physically separated, that is, they are independent bare cells.
- the present application is not limited thereto, and in other embodiments, the second sub-section 4314 and the fourth sub-section 4316 may be a structural whole.
- FIG. 21 is a partial structural schematic diagram of a battery provided by other embodiments of the present application, and the case is not shown in FIG. 21 .
- the side surfaces 4214 include a first side surface 42141 , a second side surface 42142 , a third side surface 42143 and a fourth side surface 42144 .
- the second side 42142 and the first side 42141 are arranged and connected in the circumferential direction of the first surface 4213, the tabs of the first bare cell part 42 are arranged on the first side 42141, and the third side 42143 is opposite to the second side 42142 Yes, the fourth side 42144 is opposite the first side 42141.
- the second bare cell portion 43 includes a second sub-portion 4314 , a third sub-portion 4315 and a fourth sub-portion 4316 .
- the second sub-section 4314 is located on the side to which the second side surface 42142 faces, and the orthographic projection of the second sub-section 4314 on the second side surface 42142 overlaps the second side surface 42142 . That is, a part of the orthographic projection of the second sub-section 4314 on the second side 42142 coincides with a part of the second side 42142, and a part of the orthographic projection of the second sub-section 4314 on the second side 42142 coincides with the second side 42142, The entire orthographic projection of the second subsection 4314 on the second side 42142 coincides with a part of the second side 42142 , or the orthographic projection of the second subsection 4314 on the second side 42142 completely coincides with the second side 42142 . In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the second side 42142 side, thereby improving the safety of the battery 40 .
- the third sub-section 4315 is located on the side to which the third side surface 42143 faces, and the orthographic projection of the third sub-section 4315 on the third side surface 42143 overlaps the third side surface 42143 . That is, a part of the orthographic projection of the third subsection 4315 on the third side 42143 coincides with a part of the third side 42143; a part of the orthographic projection of the third subsection 4315 on the third side 42143 coincides with the third side 42143; The entire orthographic projection of the third sub-section 4315 on the third side surface 42143 coincides with a part of the third side surface 42143; In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the third side 42143 side, thereby improving the safety of the battery 40 .
- the fourth sub-section 4316 is located on the side to which the fourth side surface 42144 faces, and the orthographic projection of the fourth sub-section 4316 on the fourth side surface 42144 overlaps the fourth side surface 42144 . That is to say, a part of the orthographic projection of the fourth subsection 4316 on the fourth side 42144 coincides with a part of the fourth side 42144; and a part of the orthographic projection of the fourth subsection 4316 on the fourth side 42144 coincides with the fourth side 42144 ; the entire orthographic projection of the fourth subsection 4316 on the fourth side 42144 coincides with a part of the fourth side 42144; In this way, the second bare cell portion 43 can be used to protect the first bare cell portion 43 from the fourth side 42144 side, thereby improving the safety of the battery 40 .
- the first bare cell part 42 and the second bare cell part 43 can be used for capacity division without reducing the total capacity of the battery 40, so that the first bare cell part 42 and the capacity of the second bare cell portion 43 are both smaller than the capacity of the battery 40 having one bare cell in the related art, so that the first bare cell portion 42 and the second bare cell portion 43 can be reduced at least to a certain extent.
- the risk of burning due to the internal short circuit of the battery 40 due to the large capacity improves the safety of the battery 40; on the other hand, since the orthographic projection of the second bare cell portion 43 on the first surface 4213 overlaps the first surface 4213 , and/or the orthographic projection of the second bare cell portion 43 on the side 4214 overlaps with the side 4214, so that during the use of the battery 40, the second bare cell portion 43 can be used for the first bare cell portion 42 For protection, the overall damage of the battery 40 will not be caused to be scrapped.
- the second bare cell part 43 is a fast-charging bare cell part.
- the part of the fast-charging bare cells specifically refers to the bare cells that can realize the charging and discharging process with a rate (C rate) not lower than the third preset threshold.
- the third preset threshold includes, but is not limited to, 1C, 2C, 2.5C, 3C, 4C, 4.5C, and the like.
- the second bare cell portion 43 is set as a fast-charging bare cell under the premise that the volume of the second bare cell portion 43 in the battery is constant. part, the capacity of the second bare cell part 43 can be reduced, and less power is released when a short circuit occurs, which can improve the safety of the battery to a certain extent and reduce the possibility of the battery flaring up and exploding.
- the first bare cell portion 42 is a high-energy bare cell portion.
- the high-energy bare cell portion specifically refers to the portion of the bare cell whose volume energy density is not lower than the first preset threshold.
- the first preset threshold includes but is not limited to 500Wh/L, 510Wh/L, 520Wh/L, 540Wh/L, 550Wh/L, 580Wh/L, 600Wh/L, and the like.
- the charging and discharging speed of the high-energy bare cell part does not exceed a second preset threshold, the second preset threshold includes but is not limited to 1c, 1.5c, 2c, 2.2c, 2.5c, 3c and so on.
- the battery life Due to the high volume energy density of the high-energy bare cell part, the battery life can be guaranteed.
- the first bare cell part 42 is a high-energy bare cell part and the second bare cell part 43 is a fast charging bare cell part
- the volume ratio of the bare cell part 43 can make the battery more fast-charging characteristics or more high-energy characteristics. Specifically, if the volume ratio of the first bare cell portion 42 in the battery 40 is larger, the volume energy density of the battery 40 is higher, and the battery life is longer. If the volume ratio of the second bare cell part 43 in the battery 40 is larger, the charging speed of the battery 40 is faster, which can meet the requirements in the scenario where the allowable charging time is short. Specifically, reasonable designs can be made for different application scenarios.
- first bare cell portion 42 and the second bare cell portion 43 may also be bare cell portions that do not have fast charging characteristics and high-energy characteristics, and may also be bare cells that have fast charging characteristics or both have high-energy characteristics. core part.
- the second bare cell part 43 can be used to protect the first bare cell part 42 to improve the safety of the battery.
- the following description is only made on the basis that the first bare cell portion 42 is a high-energy bare cell portion, and the second bare cell portion 43 is a fast-charging bare cell portion.
- the size structure and material system of the two bare cells can be designed respectively.
- the thickness of the positive electrode sheet of the second bare cell portion 43 is smaller than the thickness of the positive electrode sheet of the first bare cell portion 42 , while the thickness of the negative electrode sheet of the second bare cell portion 43 is smaller than that of the first bare cell portion 43 The thickness of the negative electrode sheet of the core portion 42 . Since the thickness of the pole piece is smaller, the separator in the same volume of the bare cell part is larger, the transmission path of lithium ions in the electrolyte is shorter, the charging and discharging speed is faster, and the fast charging performance is better.
- the thicknesses of the pole pieces of the first bare cell portion 42 and the second bare cell portion 43 are designed to be inconsistent, that is, the structures of the two are different, so that the first bare cell portion 42 exhibits high-energy characteristics , the second bare cell part 43 reflects the fast charging characteristic.
- the thickness of the positive electrode sheet of the first bare cell portion 42 ranges from 80 ⁇ m to 120 ⁇ m.
- the thickness of the positive electrode sheet of the first bare cell part 42 is 85 ⁇ m, 90 ⁇ m, 95 ⁇ m, 100 ⁇ m or 105 ⁇ m.
- the value range of the thickness of the negative electrode sheet of the first bare cell part 42 is 110-160 ⁇ m.
- the thickness of the negative electrode sheet of the first bare cell portion 42 is 110 ⁇ m, 115 ⁇ m, 120 ⁇ m, 125 ⁇ m, 130 ⁇ m, 135 ⁇ m, 140 ⁇ m, 145 ⁇ m, 150 ⁇ m or 155 ⁇ m.
- the thickness of the positive electrode sheet of the second bare cell portion 43 ranges from 40 ⁇ m to 80 ⁇ m. Further, the value range of the thickness of the positive electrode sheet of the second bare cell portion 43 is 50-70 ⁇ m. For example, the thickness of the positive electrode sheet of the second bare cell portion 43 can be 55 ⁇ m, 60 ⁇ m, 65 ⁇ m or 68 ⁇ m. The thickness of the negative electrode sheet of the second bare cell portion 43 ranges from 70 ⁇ m to 110 ⁇ m. For example, the thickness of the negative electrode sheet of the second bare cell portion 43 is 75 ⁇ m, 80 ⁇ m, 85 ⁇ m, 88 ⁇ m or 100 ⁇ m.
- the battery 40 may further include a third bare cell portion in addition to the first bare cell portion 42 and the second bare cell portion 43 . .
- the third bare cell portion is located on the side to which the second surface 4215 of the first bare cell portion 42 faces. In this way, the first bare cell portion 42 can be protected from the side of the second surface 4215 to prevent debris generated by the bottom wall of the battery compartment from penetrating into the first bare cell portion 42, thereby further improving the safety of the battery.
- FIG. 22 is a three-dimensional cross-sectional view of the battery shown in FIG. 9 after adding a third bare cell
- FIG. 23 is a schematic diagram of a partial structure of the battery shown in FIG. 22. , the housing is not shown in Figure 23.
- the third bare cell portion 46 is located on the side toward which the second surface 4215 of the first bare cell portion 42 faces.
- the orthographic projection of the third bare cell portion 46 on the second surface 4215 overlaps the second surface 4215 . That is to say, a part of the orthographic projection of the third bare cell part 46 on the second surface 4215 coincides with a part of the second surface 4215; The surface 4215 coincides; the entire orthographic projection of the third bare cell portion 46 on the second surface 4215 coincides with a part of the second surface 4215 ; or, the orthographic projection of the third bare cell portion 46 on the second surface 4215 coincides with the second Surface 4215 is completely coincident.
- the orthographic projection of the third bare cell portion 46 on the second surface 4215 coincides with the second surface 4215 means that the outer periphery of the surface of the third bare cell portion 46 facing the second surface 4215 is the same as the second surface 4215 .
- the perimeter of surface 4215 is flush.
- the third bare cell portion 46 , the second bare cell portion 43 and the first bare cell portion 42 may be located in the same accommodating cavity of the housing 41 , and the first bare cell portion 42 is on the first surface
- the orthographic projection of 4213 completely coincides with the first surface 4213
- the orthographic projection of the third bare cell portion 46 on the second surface 4215 completely coincides with the second surface 4215 .
- the third bare cell portion 46 , the second bare cell portion 43 and the first bare cell portion 42 may also be located in different accommodating cavities of the housing 41 respectively. Or any two of the third bare cell portion 46 , the second bare cell portion 43 and the first bare cell portion 42 are located in the same accommodating cavity, and the other is located in the accommodating cavity of other separate housings.
- the structure and material of the third bare cell portion 46 may be the same as those of the second bare cell portion 43 described above.
- the shape of the third bare cell portion body of the third bare cell portion 46 may include, but is not limited to, a rectangular parallelepiped shape, a cylindrical shape, and a frustum shape.
- the third bare cell portion 46 and the second bare cell portion 43 and the third bare cell portion 46 and the first bare cell portion 42 may be independent and physically separated from each other.
- the present application is not limited to this. In other embodiments, between the third bare cell portion 46 and the second bare cell portion 43 , and/or the third bare cell 46 and the first bare cell portion 42 A whole structure can be formed between them.
- the third bare cell portion 46 is a fast-charging bare cell portion. In this way, under the premise that the volume ratio of the third bare cell part 46 in the battery is constant, since the volume energy density of the fast charging bare cell part is low, the capacity of the third bare cell part 46 is small, and the battery compartment When the debris on the inner wall penetrates the third bare cell part 46, the released energy is small, which can further reduce the risk of fire and explosion.
- the third bare cell portion 46 may also be a high-energy bare cell portion, or neither a fast-charging bare cell portion nor a high-energy bare cell portion.
- the volume of all the fast-charging bare cell parts, the volume of all the fast-charging bare cell parts and the volume of the high-energy bare cell part is 5% to 95%.
- the ratio of the volume of all the fast-charging bare cell parts to the sum of the volume of all the fast-charging bare cell parts and the volume of the high-energy bare cell part is 10% to 50%. In this way, the fast charging characteristics and high-energy characteristics of the battery can be taken into account at the same time.
- the third bare cell part 46 has at least two tabs (not shown in the figure), the at least two tabs include a positive tab and a negative tab, the positive tab and the negative tab form a fifth charge discharge port.
- the protection plate 45 has a first charge-discharge circuit and a second charge and discharge circuit.
- the first charge-discharge circuit and the second charge-discharge circuit are integrated on the protection plate 45, which is not shown in the figure.
- the first charging and discharging circuit is electrically connected to the first bare cell part 42 through the first charging and discharging port B.
- the protection plate 45 also has a third charging and discharging port D.
- the third charging and discharging port D is located on the first charging and discharging circuit.
- the protection board 45 is used for being electrically connected with the power management module 52 , the charging management module 51 , and the charger in FIG. 2 by means of the third charging and discharging port D, so as to form a charging and discharging link.
- the second charging and discharging circuit is electrically connected to the second bare cell part 43 via the second charging and discharging port C.
- the protection board 45 also has a fourth charging and discharging port E, and the fourth charging and discharging port E is located on the second charging and discharging circuit.
- the protection board 45 is used for being electrically connected with the power management module 52 , the charging management module 51 , and the charger in FIG. 2 by means of the fourth charging and discharging port E, so as to form another charging and discharging link.
- the protection board 45 may also have a third charge-discharge circuit, and the third charge-discharge circuit uses the fifth charge-discharge port to communicate with the third charge-discharge port.
- the three bare cell portions 46 are electrically connected.
- the protection plate 45 also has a sixth charging and discharging port F.
- the sixth charging and discharging port F is located on the third charging and discharging circuit.
- the protection board 45 is used to electrically connect with the power management module 52 , the charging management module 51 , and the charger in FIG. 2 by means of the sixth charging and discharging port F, so as to form another charging and discharging link.
- the battery forms at least two independent charging and discharging links.
- the first bare cell part will not be affected.
- the normal use of 42 can prevent the first bare cell part 42 and the second bare cell part 43 from being short-circuited at the same time, resulting in a large amount of energy released at the same time, thereby reducing the possibility of causing safety problems such as burning and explosion.
- charging and discharging the battery simultaneously through the two charging and discharging links can improve the charging and discharging speed of the battery 20 .
- one of the first bare cell part 42 and the second bare cell part 43 can be charged and discharged, and parameters such as capacity, cycle times, and state of health can be detected.
- Both the first bare cell part 42 and the second bare cell part 43 can be charged and discharged simultaneously, and parameters such as capacity, cycle times, and state of health can be detected.
- the power management module 52 is configured to discharge the power of the second bare cell portion 43 of the battery 40 to the first preset threshold, to discharge.
- the second bare cell portion 43 has a preferential discharge performance, which can reduce the power in the second bare cell portion 43 even if the second bare cell portion 43 is closed due to its proximity to the opening of the battery compartment 13 and the inner side of the battery compartment 13 . If it is damaged, the second bare cell part 43 has less power, which reduces the risk of burning and improves the safety of the battery 40 .
- the power management module 52 discharges the power of the second bare cell portion 43 of the battery 40 to the first preset threshold, and then discharges the first bare cell portion 42 . It means: when the power management module 52 discharges the power of the second bare cell part 43 of the battery 40 to the first preset threshold, then simultaneously discharges the first bare cell part 42 and the second bare cell part 43 , or only the first bare cell portion 42 is discharged. That is to say, during the process of discharging the first bare cell portion 42 , the power management module 52 is still discharging the second bare cell portion 43 of the battery 40 , or discharging the first bare cell portion 42 . , the power management module 52 can also control the second bare cell part 43 of the battery 40 to stop discharging.
- the value interval range of the first preset threshold is [0, 80% SOC].
- the second preset threshold is 10% SOC, 20% SOC, 30% SOC, 40% SOC, 50% SOC, 60% SOC or 70% SOC.
- SOC State of charge, state of charge
- SOC state of charge, state of charge
- 60% SOC means that the remaining capacity of the battery 40 accounts for 60% of the battery capacity.
- the charging management module 51 is configured to charge the first bare cell portion 42 of the battery 40 at the same time when the power of the second bare cell portion 43 of the battery 40 is charged to the second preset threshold. Charge. That is to say, the charging management module 51 is configured to start charging the first bare cell portion 42 of the battery 40 when the power of the second bare cell portion 43 of the battery 40 is charged to the second preset threshold, and when charging the first bare cell portion 42 of the battery 40 During the charging process of the first bare cell part 42 of the battery 40 , the charging management module 51 is still charging the second bare cell part 43 of the battery 40 .
- the first stage is: the second bare cell part 43 is charged, and the first bare cell part 42 is not charged before the power of the second bare cell part 43 reaches the second preset threshold, so that the thickness of the pole piece is relatively high.
- the charging speed of the second bare cell part 43 is faster.
- the second bare cell part 43 is charged first, which is beneficial to the battery
- the timely replenishment of 40 power is convenient for users to use, and the management of the battery 40 is more intelligent.
- the second stage is: when the power of the second bare cell part 43 of the battery 40 is charged to the second preset threshold, the first bare cell part 42 and the second bare cell part 43 are charged at the same time, so that more It is beneficial to improve the charging speed of the battery, facilitate the timely replenishment of the power of the battery 40, facilitate the use of the user, and the management of the battery 40 is more intelligent.
- the value interval range of the second preset threshold is [60% SOC, 100% SOC].
- the second preset threshold is 65% SOC, 66% SOC, 70% SOC, 75% SOC, 80% SOC, 85% SOC or 90% SOC.
- the relationship among the safety characteristics, high-energy characteristics and fast charging characteristics of the battery 40 is described below by taking the electronic device as a mobile phone as an example.
- FIG. 24 is a schematic diagram of a front structure of the electronic device 100 provided by some embodiments of the present application
- FIG. 25 is a schematic diagram of a cross-sectional structure of the electronic device 100 shown in FIG. 24 at the line A-A.
- the battery 40 includes only one bare cell 44 .
- FIG. 26 is another schematic cross-sectional structure diagram of the electronic device 100 shown in FIG. 24 at the line A-A.
- the battery 40 includes a first bare cell portion 42 and a second bare cell portion 43 .
- the second bare cell portion 43 is located on the side of the first bare cell portion 42 close to the back cover 12 of the mobile phone, and the second bare cell portion 43 and the first bare cell portion 42 are stacked.
- the second bare cell portion 43 is a fast-charging bare cell portion
- the first bare cell portion 42 is a high-energy bare cell portion.
- the parameters of the battery 40 in the electronic device shown in FIG. 25 and the parameters of the battery 40 in the electronic device shown in FIG. 26 may include the following first and second embodiments.
- the size, charging rate, capacity, and charging speed (ie, charging capacity per 10 minutes) of the bare cell portion of the two types of batteries 40 are reported in Table 1 below, respectively. Specifically, the parameters of the battery 40 shown in Fig. 25 are described in the "Battery before improvement” section in Table 1, and the parameters of the battery 40 shown in Fig. 26 are described in the “Battery after improvement” section in Table 1.
- the volume of the second bare cell portion 43 in the improved battery of the present application accounts for 60% of the total volume of the battery (ie, the volume ratio).
- the improved charging speed is about 18% faster than that of the battery 40 before the improvement, and the total capacity of the battery 40 after the improvement is slightly lower than that of the battery 40 before the improvement. Therefore, the improved battery 40 exhibits fast charging characteristics.
- the steel nail 00 is used to pierce the battery 40 before the improvement and the battery 40 after the improvement through the back cover 12 of the mobile phone, so as to compare and test the battery 40 after the improvement. safety performance. Specifically, the test results are shown in Table 2 below.
- the improved battery in this embodiment allows a depth of 3.0 mm to be penetrated by foreign objects, and the improved battery has higher safety performance.
- the size, charging rate, capacity, and charging speed (charging capacity per 10 minutes) of the bare cell portion of the two types of batteries 40 are reported in Table 3 below, respectively. Specifically, the parameters of the battery 40 shown in FIG. 25 are described in the “Battery before improvement” section in Table 3, and the parameters of the battery 40 shown in FIG. 26 are described in the “Battery after improvement” section in Table 3.
- the volume ratio of the second bare cell portion 43 in the improved battery in this embodiment is smaller than the volume ratio of the second bare cell portion 43 in the improved battery in Embodiment 1.
- the volume ratio of the second bare cell portion 43 is 10%.
- the charging speed of the improved battery 40 in this embodiment is increased by about 4%, which is smaller than that of the improved battery in the first embodiment.
- the battery 40 still embodies the fast charging feature.
- the capacity of the improved battery 40 is basically the same as that of the battery before the improvement, and the capacity of the improved battery 40 in this embodiment is higher than that of the improved battery 40 in the first embodiment.
- the steel nail 00 is used to pierce the battery 40 before the improvement and the battery 40 after the improvement through the back cover 12 of the mobile phone, so as to compare and test the battery 40 after the improvement. safety performance. Specifically, the test results are shown in Table 4 below.
- the improved battery in this embodiment allows the penetration depth of foreign objects to be only 0.5 mm, and the improved battery has certain safety performance. However, the safety performance is lower than that of the improved battery in Example 1.
- the capacity of the battery 40 will be greater than that of the battery before the improvement. In this way, the battery 40 exhibits high-energy characteristics.
- the volume ratio of the improved second bare cell portion 43 is reduced, the thickness of the second bare cell portion 43 is also reduced. Under the premise of ensuring safety performance, the depth to allow foreign objects to penetrate is also correspondingly Reduced, that is, the safety performance is lower.
- the relationship among the high-energy characteristics, fast charging characteristics and safety characteristics of the improved battery of the present application is as follows: with the enhancement of the fast charging characteristics, the larger the volume ratio of the second bare cell portion 43, the greater the thickness. The larger it is, the deeper the foreign body is allowed to penetrate, and the higher the safety performance.
- the volume ratio of the first bare cell portion 42 is reduced, and the high-energy performance of the battery is small.
- the enhancement of high-energy performance the larger the volume ratio of the first bare cell portion 42 is, the smaller the volume ratio of the second bare cell portion 43 is, the lower the fast charging characteristic is, and the lower the volume ratio of the second bare cell portion 43 is.
- the smaller the thickness of the core portion 43 the smaller the depth to which the foreign matter is allowed to penetrate, and the lower the safety performance.
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Abstract
一种电池和电子设备。该电池包括:第一裸电芯部分和第二裸电芯部分。第一裸电芯部分具有第一表面以及与第一表面相接的侧面,第一表面用于在电池安装于电子设备的电池仓内时与电池仓的开口朝向相同,侧面用于在电池安装于电子设备的电池仓内时朝向电池仓的内侧面;第二裸电芯部分位于第一表面所朝向的一侧,且第二裸电芯部分在第一表面的正投影与第一表面有交叠,和/或,第二裸电芯部分位于侧面所朝向的一侧,且第二裸电芯部分在侧面的正投影与侧面有交叠。在本申请实施例提供的电池中,可以至少在一定程度上降低第一裸电芯部分和第二裸电芯部分因容量大而导致的电池内部短路而燃烧的风险,提高电池的安全性。
Description
本申请要求于2021年02月09日提交国家知识产权局、申请号为202110182367.X、发明名称为“一种安全电池及其结构”的优先权,其全部内容通过引用结合在本申请中。
本申请要求于2021年07月30日提交国家知识产权局、申请号为202110873479.X、发明名称为“电池和电子设备”的优先权,其全部内容通过引用结合在本申请中。
本申请涉及电子设备技术领域,尤其涉及一种电池和电子设备。
目前,电池广泛应用于各种电子设备中,为电子设备提供电能。随着电子设备的功能越来越强大,为了满足电子设备的电量需求,电子设备所需的电池的容量就越大。然而,容量大的电池在跌落、维修等场景下因碎裂后盖、螺丝刀等异物刺入而引起电池内部短路并产生燃烧的风险越高。由此,导致电池的安全性能较低。
发明内容
本申请的实施例提供一种电池和电子设备,有利于提高电池的使用安全。
为达到上述目的,本申请的实施例采用如下技术方案:
第一方面,本申请一些实施例提供一种电池,该电池包括:第一裸电芯部分和第二裸电芯部分。第一裸电芯部分具有第一表面以及与第一表面相接的侧面,第一表面用于在电池安装于电子设备的电池仓内时与电池仓的开口朝向相同,侧面用于在电池安装于电子设备的电池仓内时朝向电池仓的内侧面;第二裸电芯部分位于第一表面所朝向的一侧,且第二裸电芯部分在第一表面的正投影与第一表面有交叠,和/或,第二裸电芯部分位于侧面所朝向的一侧,且第二裸电芯部分在侧面的正投影与侧面有交叠。
在本申请实施例提供的电池中,由于同时设置了第一裸电芯部分和第二裸电芯部分,与相关技术中设置一个裸电芯部分的电池相比,一方面在不降低电池总容量的前提下,可以利用第一裸电芯部分和第二裸电芯部分进行容量分割,这样可以使得第一裸电芯部分和第二裸电芯部分的容量均小于相关技术中的具有一个裸电芯部分的电池的容量,从而可以至少在一定程度上降低第一裸电芯部分和第二裸电芯部分因容量大而导致的电池内部短路而燃烧的风险,提高电池的安全性;另一方面,有利于实现第一裸电芯部分和第二裸电芯部分工作的相互独立,这样在电池的使用过程中,可以利用第二裸电芯部分对第一裸电芯部分进行防护,不会导致电池的整体损坏报废。
在第一方面的一种可能的实现方式中,第一裸电芯部分为高能裸电芯部分,第二裸电芯部分为快充裸电芯部分。由于快充裸电芯部分的体积能量密度通常较低,因此第二裸电芯部分在电池内的体积占比一定的前提下,将第二裸电芯部分设置为快充裸电芯部分,可以降低第二裸电芯部分的容量,在产生短路时释放的电量较少,能够在一定程度上提高电池的安全性,降低电池出现起、爆炸的可能性。由于高能裸电芯部 分的体积能量密度较高,因此,可以保证电池的续航能力。由此电池可以同时兼顾快充特性和高能特性。
在第一方面的一种可能的实现方式中,第二裸电芯部分的负极片的厚度小于第一裸电芯部分的负极片的厚度。这样在利用多个裸电芯部分来储存电能,保证电池的容量的基础上,不但有利于提高电池的整体的充放电速度,而且由于第二裸电芯部分的较快的放电速度,储存在第二裸电芯部分内的电量就会在短时间内耗尽,有利于降低电池在跌落、维修等场景下因碎裂后盖、螺丝刀等异物刺入而引起电池内部短路并产生燃烧的风险。
在上述两种实现方式中任一实现方式的基础上,第二裸电芯部分包括第一子部分,第一子部分位于第一表面所朝向的一侧,且第一子部分在第一表面的正投影与第一表面有交叠。
进一步地,第一子部分在第一表面的正投影与第一表面重合。
在上述多种实现方式中任一实现方式的基础上,侧面包括第一侧面和第二侧面,第二侧面与第一侧面在第一表面的周向上排布且相连;第一裸电芯部分的极耳设置于第一侧面;第二裸电芯部分包括第二子部分,第二子部分位于第二侧面朝向的一侧,且第二子部分在第二侧面的正投影与第二侧面有交叠。
进一步地,第二子部分在第二侧面的正投影与第二侧面重合。
在第一方面的一种可能的实现方式中,侧面还包括第三侧面,第三侧面与第二侧面相背对;第二裸电芯部分还包括第三子部分,第三子部分位于第三侧面所朝向的一侧,第三子部分在第三侧面的正投影与第三侧面有交叠。
进一步地,第三子部分在第三侧面的正投影与第三侧面重合。
在上述多种实现方式中任一实现方式的基础上,侧面还包括第四侧面,第四侧面与第一侧面相背对;第二裸电芯部分还包括第四子部分,第四子部分位于第四侧面所朝向的一侧,且第四子部分在第四侧面的正投影与第四侧面有交叠。
进一步地,第四子部分在第四侧面的正投影与第四侧面重合。
在第一方面的一种可能的实现方式中,侧面包括第一侧面和第四侧面,第一侧面与第四侧面相背对;第一裸电芯部分的极耳设置于第一侧面,第二裸电芯部分还包括第四子部分,第四子部分位于第四侧面所朝向的一侧,且第四子部分在第四侧面的正投影与第四侧面有交叠。
进一步地,第四子部分在第四侧面的正投影与第四侧面重合。
在第一方面的一种可能的实现方式中,第一裸电芯部分还具有第二表面,第二表面与第一表面相背对;电池还包括:第三裸电芯部分,第三裸电芯部分位于第二表面所朝向的一侧,且第三裸电芯部分在第二表面的正投影与第二表面交叠。
进一步地,第三裸电芯部分在第二表面的正投影与第二表面重合。
在第一方面的一种可能的实现方式中,第一裸电芯部分的正极片的厚度的取值范围为:80μm~120μm;第一裸电芯部分的负极片的厚度的取值范围为110μm~160μm。这样,不但可以避免因极片的厚度过厚而导致的第一裸电芯部分的厚度较厚以至于第一裸电芯部分体积较大的问题,而且还可以保证第一裸电芯部分的容量。
在第一方面的一种可能的实现方式中,第二裸电芯部分的正极片的厚度的取值范 围为:40μm~80μm;第二裸电芯部分的负极片的厚度的取值范围为70μm~110μm。这样,不但可以保证第二裸电芯部分的充电速度,也可以避免因极片的厚度过小而导致的第二裸电芯部分的结构强度弱的问题。
在第一方面的一种可能的实现方式中,电池还包括:壳体,第一裸电芯部分和第二裸电芯部分位于壳体内。
在第一方面的一种可能的实现方式中,壳体内形成容纳腔,第一裸电芯部分和第二裸电芯部分均位于容纳腔内。这样设置,有利于减小电池的体积。
在第一方面的一种可能的实现方式中,壳体包括第一壳体单元和第二壳体单元;第一壳体单元内形成第一容纳腔,第一裸电芯部分容纳于第一容纳腔内;第二壳体单元位于第一壳体单元的外部并与第一壳体单元相对固定,第二壳体单元内形成第二容纳腔,第二裸电芯部分容纳于第二容纳腔内。
在第一方面的一种可能的实现方式中,第一裸电芯部分的极耳和第二裸电芯部分的极耳穿过壳体伸出至壳体的外侧,第一裸电芯部分的极耳形成第一充放电端口,第二裸电芯部分的极耳形成第二充放电端口。电池还包括保护板,该保护板具有第一充放电电路、第二充放电电路、第三充放电端口和第四充放电端口。第一充放电电路借助第一充放电端口与第一裸电芯部分电连接,第三充放电端口位于第一充放电电路上,保护板用于借助第三充放电端口与电源管理模块、充电管理模块和充电器电连接,以形成一条充放电链路。第二充放电电路借助第二充放电端口与第二裸电芯部分电连接,第四充放电端口位于第二充放电电路上,保护板用于借助第四充放电端口与电源管理模块、充电管理模块和充电器电连接,以形成另一条充放电链路。这样一来,电池形成至少两条相互独立的充放电链路,当第二裸电芯部分因碎裂后盖、螺丝刀等物品刺入而出现短路时,不会影响第一裸电芯部分的正常使用,以避免第一裸电芯部分和第二裸电芯部分同时短路而导致同一时间释放的能量较大,从而降低引起燃烧、爆炸等安全问题的可能性。此外,在电池的体积一定的前提下,通过该两条充放电链路同时对电池进行充放电,可以提高电池的充放电速度。同时借助该至少两条充放电链路,可以分别对第一裸电芯部分和第二裸电芯部分中的一个进行充放电管理以及容量、循环次数、健康状态等参数的检测,也可以同时对第一裸电芯部分和第二裸电芯部分两个进行充放电管理以及容量、循环次数、健康状态等参数的检测。完成电池性能和健康状态的最大化利用,还可以实现对一个裸电芯充电的同时,对另一个裸电芯进行放电。
第二方面,本申请的一些实施例中提供一种电子设备,包括:外壳和电池。外壳内设有电池仓,电池仓具有开口,上述任一技术方案中的电池,电池安装于电池仓内,且电池中第一裸电芯部分的第一表面的朝向与电池仓的开口的朝向相同,第一裸电芯部分的侧面朝向电池仓的内侧面。
由于本申请实施例提供的电子设备包括如上任一技术方案所述的电池,因此二者能够解决相同的技术问题,并达到相同的效果。
在第二方面的一种可能的实现方式中,电子设备还包括:电源管理模块,电源管理模块与电池电连接,电源管理模块用于在将电池的第二裸电芯部分的电量释放至第一预设阈值时,再对第一裸电芯部分进行放电。通过使得第二裸电芯部分优先放电, 可以降低第二裸电芯部分内的电量,即使第二裸电芯部分因靠近电池仓的开口和电池仓的内侧面而被损坏,也会因第二裸电芯部分的电量少,降低燃烧的风险,提高电池的安全性。
具体地,第一预设阈值的取值区间范围为[0,80%SOC]。
进一步地,第一预设阈值的取值区间范围为[0,70%SOC]。
在第二方面的一种可能的实现方式中,电子设备还包括:充电管理模块,充电管理模块与电池电连接,充电管理模块用于在将电池的第二裸电芯部分的电量充至第二预设阈值时,再同时对电池的第一裸电芯部分进行充电。对于极片厚度较薄的第二裸电芯部分来说,第二裸电芯部分的充电速度较快,当电池的电量耗尽时,优先对第二裸电芯部分进行充电,有利于对电池电量的及时补充,方便用户的使用,并且电池的管理更加智能化。
具体地,第二预设阈值的取值区间范围为:[60%SOC,100%SOC]。
图1为本申请一些实施例提供的电子设备的立体图;
图2为图1所示的电子设备的爆炸图;
图3为本申请一些实施例提供的电池的立体图;
图4为图3所示的电池的爆炸图;
图5为本申请另一些实施例提供的电池的立体图;
图6为图5所示的电池的爆炸图;
图7a为本申请一些实施例提供的第一裸电芯部分的膜片的示意图;
图7b为图7a所示第一裸电芯部分本体与第一极耳的一种连接结构示意图;
图7c为图7a所示第一裸电芯部分本体与第一极耳的又一种连接结构示意图;
图7d为图7a所示第一裸电芯部分本体中第一极片在展开状态时与第一极耳的一种连接结构示意图;
图7e为图7d所示第一极片与第一隔膜、第二极片、第二隔膜卷绕形成裸电芯后的结构示意图;
图7f为图7a所示第一裸电芯部分本体中第一极片在展开状态时与第一极耳的又一种连接结构示意图;
图7g为图7f所示第一极片与第一隔膜、第二极片、第二隔膜卷绕形成裸电芯后的结构示意图;
图8为本申请一些实施例提供的第二裸电芯部分的膜片的示意图;
图9为图5所示的电池的立体剖视图;
图10为图5所示的电池的部分结构示意图,图10中壳体未示出;
图11为本申请又一些实施例提供的电池的立体剖视图;
图12为本申请再一些实施例提供的电池的爆炸图;
图13为本申请其它一些实施例提供的电池的立体剖视图;
图14为本申请其它另一些实施例提供的电池的爆炸图;
图15为本申请其它又一些实施例提供的电池的立体剖视图;
图16为本申请其它再一些实施例提供的电池的爆炸图;
图17为本申请其它再一些实施例提供的电池的部分结构示意图,图17中壳体未示出;
图18为本申请其它再一些实施例提供的电池的爆炸图;
图19为本申请其它再一些实施例提供的电池的立体剖视图;
图20为本申请其它再一些实施例提供的电池的爆炸图;
图21为本申请其它再一些实施例提供的电池的部分结构示意图,图21中壳体未示出;
图22为在图9所示电池的基础上增加第三裸电芯部分后的立体剖视图;
图23为图22所示的电池的部分结构示意图,图23中壳体未示出;
图24为本申请一些实施例提供的电子设备的正面结构示意图;
图25为图24所示电子设备在A-A线处的一种截面结构示意图;
图26为图24所示电子设备在A-A线处的另一种截面结构示意图。
在本申请实施例中,术语“第一”、“第二”、“第三”、“第四”仅用于描述目的,而不能理解为指示或暗示相对重要性或者隐含指明所指示的技术特征的数量。由此,限定有“第一”、“第二”、“第三”、“第四”的特征可以明示或者隐含地包括一个或者更多个该特征。
在本申请实施例中,术语“包括”、“包含”或者其任何其他变体意在涵盖非排他性的包含,从而使得包括一系列要素的过程、方法、物品或者装置不仅包括那些要素,而且还包括没有明确列出的其他要素,或者是还包括为这种过程、方法、物品或者装置所固有的要素。在没有更多限制的情况下,由语句“包括一个……”限定的要素,并不排除在包括该要素的过程、方法、物品或者装置中还存在另外的相同要素。
本申请提供一种电子设备。具体地,本申请实施方式涉及的电子设备可以是包括电池40的任何设备,该电子设备包括但不限于手机、平板电脑(tablet personal computer)、膝上型电脑(laptop computer)、个人数码助理(personal digital assistant,PDA)、个人计算机、笔记本电脑、车载设备和可穿戴设备等电子设备。
在本申请实施例中,“和/或”,仅仅是一种描述关联对象的关联关系,表示可以存在三种关系,例如,A和/或B,可以表示:单独存在A,同时存在A和B,单独存在B这三种情况。另外,本文中字符“/”,一般表示前后关联对象是一种“或”的关系。
请参阅图1和图2,图1为本申请一些实施例提供的电子设备的立体图,图2为图1所示的电子设备的爆炸图。该电子设备可以包括外壳10、用电器件20、电路板30、充电管理模块51、电源管理模块52和电池40。
用电器件20用于实现电子设备的某一项或者多项功能。用电器件20包括但不限于处理器、摄像头模组和显示屏。
请继续参阅图2,外壳10为由前盖板15、中板14、边框11和后盖12拼接成的结构。
具体地,前盖板15为透光件,用电器件20包括显示屏,显示屏用于显示图像、视频等。前盖板15与显示屏层叠设置并固定连接。前盖板15主要用于对显示屏起到保护以及防尘作用。
前盖板15的材质包括但不限于玻璃、塑料或陶瓷。显示屏可以采用柔性显示屏,也可以采用刚性显示屏。例如,显示屏可以为有机发光二极管(organic light-emitting diode,OLED)显示屏,有源矩阵有机发光二极体或主动矩阵有机发光二极体(active-matrix organic light-emitting diode,AMOLED)显示屏,迷你发光二极管(mini organic light-emitting diode)显示屏,微型发光二极管(micro organic light-emitting diode)显示屏,微型有机发光二极管(micro organic light-emitting diode)显示屏,量子点发光二极管(quantum dot light emitting diodes,QLED)显示屏,液晶显示屏(liquid crystal display,LCD)。
中板14位于显示屏的远离前盖板15的一侧。后盖12设在中板14的远离显示屏的一侧。边框11位于后盖12与前盖板15之间,且环绕在中板14的外周。示例性地,边框11可以通过粘胶或焊接固定连接于后盖12上。边框11也可以与后盖12为一体成型结构,即边框11与后盖12为一个整体结构。边框11还可以通过胶粘或焊接固定于中板14上。或者,边框11也可以与中板14为一体成型结构,即边框11与中板14为一个整体结构。
具体地,外壳10内设有电池仓13。电池仓13具有开口。示例性地,中板14和边框11拼接后可限定出具有开口的电池仓13,电池仓13的开口邻近后盖12设置,电池仓13的开口可以由后盖12封盖。或者,电池仓13可以由中板14的远离显示屏的一侧表面朝向靠近显示屏的一侧表面凹入而形成,电池仓13的开口邻近后盖12设置,电池仓13的开口可以由后盖12封盖。
电路板30设于外壳10且位于电池仓13的周向的一侧。具体地,电路板30位于中板14和后盖12之间,且电路板30位于电池仓13的上侧。
电源管理模块52可以设在电路板30上。电源管理模块52与电池40电连接。电源管理模块52用于接收电池40的输入,并且对用电器件20进行放电,以为用电器件20供电。电源管理模块52还可以用于监测电池40的容量,电池40循环次数,电池40健康状态(漏电,阻抗)等参数。
充电管理模块51可以设在电路板30上。充电管理模块51与电池40电连接。具体地,请参阅图2所示,充电管理模块51用于从充电器接收充电输入。充电器可以是无线充电器,也可以是有线充电器。在一些有线充电的实施例中,充电管理模块51可以通过USB接口接收有线充电器的充电输入。在一些无线充电的实施例中,充电管理模块51可以通过电子设备的无线充电线圈接收无线充电输入。在一些实施例中,电源管理模块52和充电管理模块51可以集成为一体,也可以分体设置。
电池40设置于电池仓13内,并且电池40与电路板30电连接。电池40可以包括但不限于镍镉电池、镍氢电池、锂电池或其他类型的包含裸电芯的电池。并且,本申请实施例中的电池40的数量可以为多个,也可以为一个,本申请实施例中电池40的具体数量以及排布方式可以根据实际需要进行设置。在下面的描述中,以电池40为锂电池例进行说明。
请参阅图3和图4,图3为本申请一些实施例提供的电池40的立体图,图4为图3所示的电池40的爆炸图。具体地,电池40包括壳体41、电解液(图未示出)、裸电芯44和保护板45。
壳体41用于封装并保护裸电芯44和电解液,壳体41的形状包括但不限于长方体、圆柱体或圆台等。
壳体41的材质可以为钢壳,也可以为复合膜。在图4所示的示例中,壳体41的材质为复合膜。具体地,复合膜至少分为三层,中间层为金属镀膜层,起到隔绝水分的作用,外层为塑料镀膜层,起阻止空气尤其是氧的渗透作用;内层为密封层,起密封并防止电解液腐蚀金属镀膜层的作用。密封层的材质选自聚乙烯、聚丙烯、聚乙烯或聚丙烯的酯化物、聚乙烯或聚丙烯的离子交联物中的至少一种,聚乙烯选自低密度聚乙烯、中密度聚乙烯或高密度聚乙烯;聚丙烯选自均聚聚丙烯、嵌段聚丙烯或无规聚丙烯。金属镀膜层的材质选自金属、金属合金、金属氧化物或陶瓷中的至少一种,金属选自铝、铁、银、铜、镍、锰、锡、钛、锆或钒;塑料镀膜层的材质选自聚酰胺树脂、聚烯烃、聚碳酸酯或氟树脂中的至少一种。该复合膜具体可以为铝塑膜,铝塑膜的中间层为铝层,起隔绝水分作用,铝塑膜的外层为聚酰胺,起阻止空气尤其是氧的渗透作用;铝塑膜的内层为聚丙烯层,起密封并防止电解液腐蚀铝层的作用。
电解液为电池40内传输锂离子的载体,电解液一般由高纯度的有机溶剂、电解质锂盐、必要的添加剂等原料在一定条件下并按一定比例配制而成。
保护板45可以为对电池40起保护作用的集成电路板,例如,该保护板45为BTB连接器,保护板45用于实现电池40与电路板30的电连接。
请继续参阅图4,裸电芯44包括裸电芯本体441和极耳。具体地,极耳与裸电芯本体441相连,极耳包括第一极耳442a和第二极耳442b,第一极耳442a和第二极耳442b中的其中一个为正极耳且另一个为负极耳,裸电芯本体441位于壳体41内,并且两个极耳穿过壳体41与保护板45相连。
一般地,随着电子设备的功能越来越强大,为了满足电子设备的电量需求,电子设备所需的电池的容量就越大。然而,容量大的电池内部短路而燃烧的风险也较高,例如电池在日常生活中因外力撞击、碎裂的后盖刺入电池内部或维修电子设备时、螺丝刀刺入电池内等外力滥用引起的电池内部短路。
现有技术中,为提升电池安全,目前的改善方案都集中在对极片、电解液和隔膜等材料进行优化。例如,在正极片铝箔上增加功能涂层或提升隔膜强度等,防止出现最危险的铝箔与负极片或者铜箔短路,引发电池起火燃烧。又如,降低隔膜的闭孔温度,或者隔膜增加耐热涂层,防止热量在电池内部进一步蔓延而出现热失控等。这些措施虽然有效,但使电池的能量密度降低,充放电速度也下降。
因此,为了提高电池40的安全性,本申请从分割电芯容量的角度出发对电池40进行了改进。具体地,请参阅图5-图6,图5为本申请另一些实施例提供的电池40的立体图,图6为图5所示的电池40的爆炸图。在该实施例中,电池40包括第一裸电芯部分42和第二裸电芯部分43。
其中,第一裸电芯部分42和第二裸电芯部分43位于壳体41内。该壳体41的材质与上述实施例中的壳体41的可以相同。
请继续参阅图6所示,第一裸电芯部分42包括第一裸电芯部分本体421和极耳。
第一裸电芯部分本体421的形状可以包括但不限于长方体状、圆柱体状和圆台状。
在一些实施例中,第一裸电芯部分本体421可以为卷绕式。请参阅图7a,图7a 为图6所示电池40中第一裸电芯部分本体421的截面结构示意图。在本实施例中,第一裸电芯部分本体421为卷绕式裸电芯部分。第一裸电芯部分本体421由膜片M卷绕形成。具体地,膜片M包括依次层叠设置的第一极片4211a、第一隔膜4212a、第二极片4211b、第二隔膜4212b。第一极片4211a和第二极片4211b中的其中一个为正极片且另一个为负极片。相邻的两个极片之间布置的隔膜可以将正极片和负极片间隔开,起到绝缘隔离的作用,防止两极发生短路。
其中,极片包括集流片以及设置于该集流片表面的极性材料,极性材料为参与充放电反应的材料,集流片用于汇集电流。对于正极片来说,集流片的形成材料为铝(化学式:Al)。对于负极片来说,集流片的形成材料为铜(化学式:Cu)。
另外,隔膜的形成材料为聚烯烃多孔膜。沿膜片的卷绕轴线的延伸方向,隔膜的两端均超出极片的两端边缘,由此能够对极片沿膜片的卷绕轴线的延伸方向的两端边缘进行绝缘保护。
在其他一些实施例中,第一裸电芯部分本体421也可以为叠片式。具体地,第一裸电芯部分本体421由第一极片、第二极片依次交替并堆叠而成,且相邻的第一极片与第二极片之间设有隔膜。其中,第一极片和第二极片中的其中一个为正极片且另一个为负极片,该实施例中的第一极片和第二极片可以分别与上述卷绕式第一裸电芯部分本体421中极片的结构相同。隔膜起到绝缘隔离的作用。隔膜可以为隔膜袋,也可以为沿Z字型折叠的隔膜,还可以为多个单片的隔膜,本申请不限定叠片式裸电芯部分中隔膜的具体结构形式,只要能够绝缘隔离第一极片和第二极片即可。隔膜的材料也可以为聚烯烃多孔膜。
需要说明的是,为了方便下文说明,以下仅以第一裸电芯部分本体421为卷绕式裸电芯部分为例进行说明,这并不能认为是对本申请构成的特殊限制。
请继续参阅图6所示,具体地,第一裸电芯部分42的极耳包括第一极耳422a和第二极耳422b,第一极耳422a和第二极耳422b中的其中一个为正极耳且另一个为负极耳,第一极耳422a和第二极耳422b穿过壳体41伸出至壳体41的外侧与保护板45相连。第一极耳422a和第二极耳422b形成第一充放电端口B。
具体地,第一极耳422a的一端与第一极片4211a电连接,第一极耳422a的另一端穿过壳体41伸出至壳体41的外侧与保护板45相连。第二极耳422b的一端与第二极片4211b电连接,第二极耳422b的另一端穿过壳体41伸出至壳体41的外侧与保护板45相连。
第一极耳422a可以通过焊接、压合等方式连接于第一极片4211a的集流片上,也可以由第一极片4211a的集流片直接延伸形成。
示例地,请参阅图7b,图7b为图7a所示第一裸电芯部分本体421与第一极耳422a的一种连接结构示意图。在本实施例中,第一极片4211a包括集流片4211aa和设置于该集流片4211aa上的极性材料4211ab。第一极耳422a通过焊接、压合等方式连接于第一极片4211a的集流片4211aa上。
又示例地,请参阅图7c,图7c为图7a所示第一裸电芯部分本体421与第一极耳422a的又一种连接结构示意图。在本实施例中,第一极片4211a包括集流片4211aa和设置于该集流片4211aa上的极性材料4211ab。第一极耳422a由第一极片4211a的 集流片4211aa直接延伸形成。
同理的,请参阅图7b和图7c,第二极片4211b包括集流片4211ba以及设置于该集流片4211ba上的极性材料4211bb。第二极耳422b可以通过焊接、压合等方式连接于第二极片4211b的集流片4211ba上,也可以由第二极片4211b的集流片4211ba直接延伸形成。具体地,第二极耳422b与第二极片4211b的集流片4211ba的连接形式,可以参考图7b或图7c所示第一极耳422a与第一极片4211a的集流片4211aa的连接形式实施,在此不做赘述。
需要说明的是,图7b和图7c仅给出了第一极耳422a为单个极耳单元的示例,第一极耳422a的结构并不限于此,在其他一些实施例中,第一极耳422a还可以由多个极耳单元通过焊接、压合等方式固定形成。该多个极耳单元间隔设置于第一极片4211a的集流片4211aa上。当第一极片4211a与第一隔膜4212a、第二极片4211b、第二隔膜4212b卷绕成裸电芯时,该多个极耳单元层叠设置,以方便固定。该多个极耳单元可以通过焊接、压合等方式固定于第一极片4211a的集流片4211aa上,也可以由集流片4211aa直接延伸形成,在此不做具体限定。
示例地,请参阅图7d,图7d为图7a所示第一裸电芯部分本体421中第一极片4211a在展开状态时与第一极耳422a的一种连接结构示意图。第一极耳422a包括多个极耳单元422a1。多个极耳单元422a1通过焊接、压合等工艺间隔固定于第一极片4211a的集流片4211aa上。当第一极片4211a与第一隔膜4212a、第二极片4211b、第二隔膜4212b卷绕成裸电芯时,请参阅图7e,图7e为图7d所示第一极片4211a与第一隔膜4212a、第二极片4211b、第二隔膜4212b卷绕形成裸电芯后的结构示意图。在本实施例中,多个极耳单元422a1层叠设置,以便采用焊接、压合等工艺固定在一起,以形成第一极耳422a。
又示例地,请参阅图7f,图7f为图7a所示第一裸电芯部分本体421中第一极片4211a在展开状态时与第一极耳422a的又一种连接结构示意图。第一极耳422a包括多个极耳单元422a1。多个极耳单元422a1由第一极片4211a的集流片4211aa直接延伸形成。当第一极片4211a与第一隔膜4212a、第二极片4211b、第二隔膜4212b卷绕成裸电芯时,请参阅图7g,图7g为图7f所示第一极片4211a与第一隔膜4212a、第二极片4211b、第二隔膜4212b卷绕形成裸电芯后的结构示意图。在本实施例中,多个极耳单元422a1层叠设置,以便采用焊接、压合等工艺固定在一起,以形成第一极耳422a。
同理的,第二极片4211b包括集流片4211ba以及设置于该集流片4211ba上的极性材料4211bb。第二极耳422b也可以由多个极耳单元通过焊接、压合等方式固定形成。该多个极耳单元间隔设置于第二极片4211b的集流片4211ba上。当第二极片4211b与第一隔膜4212a、第一极片4211a、第二隔膜4212b卷绕成裸电芯时,该多个极耳单元层叠设置,以方便固定。该多个极耳单元可以通过焊接、压合等方式固定于第二极片4211b的集流片4211ba上,也可以由该集流片4211ba直接延伸形成,在此不做具体限定。
结合上述任一实施例所述的第一裸电芯部分42的极耳(包括第一极耳422a和第二极耳422b),第一裸电芯部分42的极耳穿设于壳体41的部分包裹有极耳胶,极耳 胶起到绝缘隔离的作用,以避免极耳与壳体41内的金属等导电层接触。
具体地,极耳胶由单面胶带缠绕而成,该单面胶带包括基材以及设置于基材表面的胶材,基材的形成材料包括但不限于聚丙烯(polypropylene,PP)、聚乙烯(polyethylene,PE)、聚酰胺(polyamide,PA)、聚碳酸酯(polycarbonate,PC)、聚甲醛(polyformaldehyde,POM)、聚对苯二甲酸乙二酯(polyethylene glycol terephthalate,PET)、聚对苯二酸丁二醇酯(polybutylene terephthalate,PBT)、聚苯醚(polyphenylene oxide,PPO)等塑料,胶材具有一定粘度,且该胶材耐化学溶剂腐蚀且耐高温(典型的如200℃),胶材包括但不限于丁苯胶、聚氨酯、硝酸纤维素、聚醋酸乙烯等溶剂型粘合剂,乙烯-醋酸乙烯共聚物、乙烯-丙烯酸共聚物等水溶型粘合剂,醋酸乙烯树脂、丙烯酸树脂等乳液型粘合剂,聚苯乙烯、聚氨酯、聚丙烯酸酯等热塑性树脂组成的热熔型粘合剂等的一种或几种上述材料的叠加或混合。该单面胶带的形状包括但不限于长方形、圆形、正方形、菱形、梯形和六边形。可以理解的是,极耳胶也可以为滴注于极耳上的点胶或者套设于极耳上的橡胶、塑胶等绝缘材料形成的绝缘套管。
请继续参阅图6,第一裸电芯部分42具有第一表面4213、第二表面4215和侧面4214。其中,第一表面4213和第二表面4215相背设置。侧面4214连接在第一表面4213和第二表面4215之间。当电池40应用于电子设备时,第一表面4213用于在电池40安装至电子设备的电池仓13内时与电池仓13的开口朝向相同。也就是说,该第一表面4213更靠近上述的后盖12。当电池40应用于电子设备时,第二表面4215用于在电池40安装于电子设备的电池仓13内时朝向电池仓13的底面。也就是说,该第二表面4215背离后盖12、朝向电池仓13的仓底。当电池40应用于电子设备时,侧面4214用于在电池40安装于电子设备的电池仓13内时朝向电池仓13的内侧面。
请继续参阅图6,第二裸电芯部分43包括第二裸电芯部分本体431和极耳。
第二裸电芯部分本体431的形状可以包括但不限于长方体状、圆柱体状和圆台状。
在一些实施例中,第二裸电芯部分本体431可以为卷绕式。请参阅图8所示,图8为图6所示电池40中第二裸电芯部分本体431的截面结构示意图。在本实施例中,第二裸电芯部分本体431为卷绕式裸电芯部分。第二裸电芯部分本体431由膜片N卷绕形成。具体地,膜片N包括依次层叠设置的第一极片4311a、第一隔膜4312a、第二极片4311b、第二隔膜4312b。第一极片4311a和第二极片4311b中的其中一个为正极片且另一个为负极片,并且相邻的两个极片之间布置的隔膜可以将正极片和负极片间隔开,起到绝缘隔离的作用,防止两极发生短路。
其中,第二裸电芯部分本体431的极片的结构和材质可与上述的第一裸电芯部分本体421的极片的相同,第二裸电芯部分本体431的隔膜的材质可与上述第一裸电芯部分本体421的相同。
在其他一些实施例中,第二裸电芯部分本体431也可以为叠片式。具体地,第二裸电芯部分本体431由第一极片、第二极片依次交替并堆叠而成,且相邻的第一极片与第二极片之间设有隔膜。其中,第一极片和第二极片中的其中一个为正极片且另一个为负极片。该叠片式第二裸电芯部分43的第一极片和第二极片可以分别与上述卷绕式第二裸电芯部分本体431中极片的结构和材质相同。本实施例中,隔膜可以为隔膜 袋,也可以为沿Z字型折叠的隔膜,还可以为多个单片的隔膜,本申请不限定叠片式裸电芯部分中隔膜的具体结构形式,只要能够绝缘隔离第一极片和第二极片即可。隔膜的材料也可以为聚烯烃多孔膜。
需要说明的是,第二裸电芯部分43和第一裸电芯部分42可以是相互独立,且物理分开的,即该二者分别为独立的裸电芯。当然,本申请不限于此,在另一些实施方式中,第二裸电芯部分43的隔膜和第一裸电芯部分42的隔膜还可以是连接成一体的,在此实施例中,第二裸电芯部分43与第一裸电芯部分42连接成一体。
请继续参阅图6,第二裸电芯部分43的极耳包括第一极耳433a和第二极耳433b。第一极耳433a和第二极耳433b中的其中一个为正极耳且另一个为负极耳,第一极耳433a和第二极耳433b穿过壳体41伸出至壳体41的外侧与保护板45相连。第一极耳433a和第二极耳433b形成第二充放电端口C。
具体地,第一极耳433a的一端与第一极片4311a电连接,第一极耳433a的另一端穿过壳体41伸出至壳体41的外侧与保护板45相连,第二极耳433b的一端与第二极片4311b电连接,第二极耳433b的另一端穿过壳体41伸出至壳体41的外侧与保护板45相连。
示例性地,第一极耳433a的一端连接至第一极片4311a的集流片,第二极耳433b的一端连接至第二极片4311b的集流片。具体地,第一极耳433a和第二极耳433b可以分别通过焊接、压合等方式连接于第一极片4311a的集流片和第二极片4311b的集流片上,也可以分别由第一极片4311a的集流片和第二极片4311b的集流片直接延伸形成,在此不做具体限定。
结合上述任一实施例所述的第二裸电芯部分43的极耳(包括第一极耳433a和第二极耳433b),第二裸电芯部分43的极耳穿设于壳体41的部分包裹有极耳胶,极耳胶起到绝缘隔离的作用,以避免极耳与壳体41内的金属等导电层接触。该极耳胶的材质以及形状与上述用于包裹第一裸电芯部分42的极耳胶的材质以及形状相同,在此不做赘述。
本申请借助第二裸电芯部分43抵抗碎裂后盖、螺丝刀等物品刺入,同时防止这些物品在刺入第二裸电芯部分43的同时还刺入第一裸电芯部分42,由此来避免第一裸电芯部分42和第二裸电芯部分43同时短路而导致同一时间释放的能量较大,从而降低产生起火、爆炸等安全问题的可能性。为了达到此目的,需合理布局第一裸电芯部分42与第二裸电芯部分43之间的方位关系,以采用第二裸电芯部分43对第一裸电芯部分42进行防护,降低第一裸电芯部分42和第二裸电芯部分43被同时刺入以引起短路的可能性。具体地,第一裸电芯部分42与第二裸电芯部分43之间的方位关系可以包括下述示例一至示例三。
示例一
本示例是以第二裸电芯部分43仅从第一表面4213侧对第一裸电芯部分42防护的角度出发进行的改进。
请继续参阅图6,并且结合图9和图10,图9为图5所示的电池的立体剖视图,图10为图5所示的电池的部分结构示意图,图10中壳体未示出。在该示例中,第二裸电芯部分43位于第一表面4213所朝向的一侧,且第二裸电芯部分43在第一表面 4213的正投影与第一表面4213有交叠。也就是说,第二裸电芯部分43在第一表面4213的正投影的一部分与第一表面4213的一部分重合;第二裸电芯部分43在第一表面4213的正投影的一部分与第一表面4213重合;第二裸电芯部分43在第一表面4213的正投影的全部与第一表面4213的一部分重合;或者,第二裸电芯部分43在第一表面4213的正投影与第一表面4213完全重合,也就是说,第二裸电芯部分43朝向第一表面4213的表面的外周与第一表面4213的外周是平齐的。这样,可以利用第二裸电芯部分43从第一表面4213侧对第一裸电芯部分43进行防护,提高电池40的安全性。
请继续参阅图9-图10,在该示例中,壳体41内形成有容纳腔,第一裸电芯部分42和第二裸电芯部分43可以位于壳体41的该容纳腔内,即第一裸电芯部分42和第二裸电芯部分43共用容纳腔,有利于提高电池40的空间利用率。当然,该示例不限于此,请参阅图11所示,图11为本申请又一些实施例提供的电池的立体剖视图。在图11所示的示例中,第一裸电芯部分42和第二裸电芯部分43位于壳体41的不同的容纳腔内。
具体地,请继续参阅图11,壳体41包括第一壳体单元41a和第二壳体单元41b。
第一壳体单元41a和第二壳体单元41b的材质可与上述的壳体41的材质相同。第一壳体单元41a的形状包括但不限于长方体状、圆柱体体、或圆台状等,第二壳体单元41b的形状包括但不限于长方体状、圆柱体状、或圆台状。
第二壳体单元41b与第一壳体单元41a层叠设置,且第二壳体单元41b位于第一壳体单元41a的朝向电池仓13的开口的一侧并与第一壳体单元41a相对固定,例如第二壳体单元41b通过胶粘、卡接、螺纹连接、焊接等方式与第一壳体单元41a固定。
第一壳体单元41a内形成有第一容纳腔,第二壳体单元41b内形成有第二容纳腔。第一裸电芯部分42容纳于第一容纳腔内,第一裸电芯部分42的外形可与第一壳体单元41a的形状相适配。第二裸电芯部分43容纳于第二容纳腔内,第二裸电芯部分43的外形可与第二壳体单元41b的形状相适配。这样设置,可以实现第一裸电芯部分42和第二裸电芯部分43的相互独立,从而提高第一裸电芯部分42和第二裸电芯部分43工作的安全性。
示例二
本示例是以第二裸电芯部分43从第一表面4213侧和侧面4214侧对第一裸电芯部分42防护的角度出发进行的改进。在该实施方式中,第二裸电芯部分43对第一裸电芯部分42的侧面4214的防护可以是针对沿第一表面4213的周向排布的多个侧面4214中的任意一个侧面4214的,或者任意几个侧面4214的,或者所有的侧面4214的。
在本示例的一些具体示例中,请参阅图12,图12为本申请再一些实施例提供的电池的爆炸图。在该示例中,第二裸电芯部分43包括第一子部分4313和第二子部分4314。
第一子部分4313位于第一表面4213所朝向的一侧,且第一子部分4313在第一表面4213的正投影与第一表面4213有交叠。也就是说,第一子部分4313在第一表面4213的正投影的一部分与第一表面4213的一部分重合;第一子部分4313在第一表面4213的正投影的一部分与第一表面4213重合;第一子部分4313在第一表面4213的正投影的全部与第一表面4213的一部分重合;或者,第一子部分4313在第一表面4213 的正投影与第一表面4213完全重合,也即第一子部分4313朝向第一表面4213的表面的外周与第一表面4213的外周是平齐的。这样,可以利用第二裸电芯部分43从第一表面4213侧对第一裸电芯部分43进行防护,提高电池40的安全性。
侧面4214包括第一侧面42141和第二侧面42142。第一侧面42141和第二侧面42142在第一表面4213的周向上排布且相连。第一裸电芯部分42的极耳设置于第一侧面42141。第二子部分4314位于第二侧面42142所朝向的一侧,且第二子部分4314在第二侧面42142的正投影与第二侧面42142有交叠。也就是说,第二子部分4314在第二侧面42142的正投影的一部分与第二侧面42142的一部分重合;第二子部分4314在第二侧面42142的正投影的一部分与第二侧面42142重合;第二子部分4314在第二侧面42142的正投影的全部与第二侧面42142的一部分重合;或者,第二子部分4314在第二侧面42142的正投影与第二侧面42142完全重合,也即第二子部分4314的朝向第二侧面42142的表面与第二侧面42142的厚度相等,且第二子部分4314的朝向第二侧面42142的表面的外周与第二侧面42142的外周是平齐的。这样,可以利用第二裸电芯部分43从第二侧面42142侧对第一裸电芯部分43进行防护,提高电池40的安全性。
可选地,第一子部分4313和第二子部分4314可以是相互独立,且物理分开的,即该二者分别为独立的裸电芯。当然,本申请不限于此,在另一些实施方式中,第一子部分4313和第二子部分4314可以为一体结构。
在该示例中,请继续参阅图12,壳体41内形成有容纳腔,第一裸电芯部分42和第二裸电芯部分43可以位于该容纳腔内,这样第一裸电芯部分42和第二裸电芯部分43共用容纳腔,不但有利于减小电池40的整体体积,而且还可以降低成本。当然,本申请不限于此,请参阅图13所示,图13为本申请其它一些实施例提供的电池的立体剖视图。在该示例中,第一裸电芯部分42和第二裸电芯部分43也可以位于壳体41的不同的容纳腔内。具体地,请继续参阅图13,壳体41包括第一壳体单元41a和第二壳体单元41b。第二壳体单元41b的一部分位于第一壳体单元41a的朝向电池仓13的开口的一侧且第二壳体单元41b的另一部分位于第一壳体单元41a的朝向电池仓13的内侧面的一侧。第一壳体单元41a内形成有第一容纳腔,第二壳体单元41b内形成有第二容纳腔。第一裸电芯部分42容纳于第一容纳腔内,第一裸电芯部分42的外形可与第一壳体单元41a的形状相适配。第二裸电芯部分43容纳于第二容纳腔内,第二裸电芯部分43的外形可与第二壳体单元41b的形状相适配。
在示例的另一些具体示例中,请参阅图14所示,图14为本申请其它另一些实施例提供的电池的爆炸图。第二裸电芯部分43包括第一子部分4313、第二子部分4314和第三子部分4315。
第一子部分4313位于第一表面4213所朝向的一侧,且第一子部分4313在第一表面4213的正投影与第一表面4213有交叠。也就是说,第一子部分4313在第一表面4213的正投影的一部分与第一表面4213的一部分重合;第一子部分4313在第一表面4213的正投影的一部分与第一表面4213重合;第一子部分4313在第一表面4213的正投影的全部与第一表面4213的一部分重合;或者,第一子部分4313在第一表面4213的正投影与第一表面4213完全重合。这样,可以利用第二裸电芯部分43从第一表面 4213侧对第一裸电芯部分43进行防护,提高电池40的安全性。
侧面4214包括第一侧面42141、第二侧面42142和第三侧面42143。第一侧面42141和第二侧面42142在第一表面4213的周向上排布且相连。第三侧面42143与第二侧面42142相背对。第一裸电芯部分42的极耳设置于第一侧面42141。
第二子部分4314位于第二侧面42142所朝向的一侧,且第二子部分4314在第二侧面42142的正投影与第二侧面42142有交叠。也就是说,第二子部分4314在第二侧面42142的正投影的一部分与第二侧面42142的一部分重合;第二子部分4314在第二侧面42142的正投影的一部分与第二侧面42142重合;第二子部分4314在第二侧面42142的正投影的全部与第二侧面42142的一部分重合;或者,第二子部分4314在第二侧面42142的正投影与第二侧面42142完全重合。这样,可以利用第二裸电芯部分43从第二侧面42142侧对第一裸电芯部分43进行防护,提高电池40的安全性。
第三子部分4315位于第三侧面42143所朝向的一侧,第三子部分4315在第三侧面42143的正投影与第三侧面42143有交叠。也就是说,第三子部分4315在第三侧面42143的正投影的一部分与第三侧面42143的一部分重合;第三子部分4315在第三侧面42143的正投影的一部分与第三侧面42143重合;第三子部分4315在第三侧面42143的正投影的全部与第三侧面42143的一部分重合;或者,第三子部分4315在第三侧面42143的正投影与第三侧面42143完全重合,也即第三子部分4315的朝向第三侧面42143的表面与第三侧面42143的厚度相等,且第三子部分4315的朝向第三侧面42143的表面的外周与第三侧面42143的外周是平齐的。这样,可以利用第二裸电芯部分43从第三侧面42143侧对第一裸电芯部分43进行防护,提高电池40的安全性。
可选地,第一子部分4313、第二子部分4314和第三子部分4315可以分别是相互独立,且物理分开的。即该三者分别为独立的裸电芯。当然,本申请不限于此,在另一些实施方式中,第一子部分4313、第二子部分4314和第三子部分4315也可以为一体结构。或者,第一子部分4313、第二子部分4314、第三子部分4315中的任意两个为一体结构,其余一个是独立的裸电芯。
在该示例中,请继续参阅图14,壳体41内形成有容纳腔,第一裸电芯部分42和第二裸电芯部分43可以位于该容纳腔内,这样第一裸电芯部分42和第二裸电芯部分43共用容纳腔,不但有利于减小电池40的整体体积,而且还可以降低成本。当然,该示例不限于此,请参阅图15所示,图15为本申请其它又一些实施例提供的电池的立体剖视图。在该示例中,第一裸电芯部分42和第二裸电芯部分43也可以位于壳体41的不同的容纳腔内。具体地,请继续参阅图15,壳体41包括第一壳体单元41a和第二壳体单元41b。第二壳体单元41b的一部分位于第一壳体单元41a的朝向电池仓13的开口的一侧且第二壳体单元41b的另一部分位于第一壳体单元41a的朝向电池仓13的内侧面的一侧。第一壳体单元41a内形成有第一容纳腔,第二壳体单元41b内形成有第二容纳腔,第一裸电芯部分42容纳于第一容纳腔内,第一裸电芯部分42的外形可与第一壳体单元41a的形状相适配,第二裸电芯部分43容纳于第二容纳腔内,第二裸电芯部分43的外形可与第二壳体单元41b的形状相适配。
在本示例的又一示例中,请参阅图16所示,图16为本申请其它再一些实施例提供的电池的爆炸图。在该示例中,第二裸电芯部分43包括第一子部分4313、第二子 部分4314和第四子部分4316。
第一子部分4313位于第一表面4213所朝向的一侧,且第一子部分4313在第一表面4213的正投影与第一表面4213有交叠。也就是说,第一子部分4313在第一表面4213的正投影的一部分与第一表面4213的一部分重合,第一子部分4313在第一表面4213的正投影的一部分与第一表面4213完全重合,第一子部分4313在第一表面4213的正投影的全部与第一表面4213的一部分重合,或者,第一子部分4313在第一表面4213的正投影与第一表面4213完全重合。这样,可以利用第二裸电芯部分43从第一表面4213侧对第一裸电芯部分43进行防护,提高电池40的安全性。
侧面4214包括第一侧面42141、第二侧面42142和第四侧面42144,第一侧面42141和第二侧面42142在第一表面4213的周向上排布且相连,第四侧面42144与第一侧面42141相背对,第一裸电芯部分42的极耳设置于第一侧面42141。
第二子部分4314位于第二侧面42142所朝向的一侧,且第二子部分4314在第二侧面42142的正投影与第二侧面42142有交叠。也就是说,第二子部分4314在第二侧面42142的正投影的一部分与第二侧面42142的一部分重合;第二子部分4314在第二侧面42142的正投影的一部分与第二侧面42142重合;第二子部分4314在第二侧面42142的正投影的全部与第二侧面42142的一部分重合;或者,第二子部分4314在第二侧面42142的正投影与第二侧面42142完全重合。这样,可以利用第二裸电芯部分43从第二侧面42142侧对第一裸电芯部分43进行防护,提高电池40的安全性。
第四子部分4316位于第四侧面42144所朝向的一侧,且第四子部分4316在第四侧面42144的正投影与第四侧面42144有交叠。也就是说,第四子部分4316在第四侧面42144的正投影的一部分与第四侧面42144的一部分重合,第四子部分4316在第四侧面42144的正投影的一部分与第四侧面42144重合,第四子部分4316在第四侧面42144的正投影的全部与第四侧面42144的一部分重合,或者,第四子部分4316在第四侧面42144的正投影与第四侧面42144完全重合。这样,可以利用第二裸电芯部分43从第四侧面42144侧对第一裸电芯部分43进行防护,提高电池40的安全性。
可选地,第一子部分4313、第二子部分4314和第四子部分4316可以分别是相互独立,且物理分开的,即这三者分别为独立的裸电芯。当然,本申请不限于此,在另一些实施方式中,第一子部分4313、第二子部分4314、第四子部分4316中的至少两个为一体结构。具体地,第一子部分4313、第二子部分4314、第四子部分4316三者为一体结构。
在本示例的再一些具体示例中,请参阅图17,图17为本申请其它再一些实施例提供的电池的部分结构示意图,图17中壳体未示出。在该示例中,第二裸电芯部分43包括第一子部分4313和第四子部分4316。
第一子部分4313位于第一表面4213所朝向的一侧,且第一子部分4313在第一表面4213的正投影与第一表面4213有交叠。也就是说,第一子部分4313在第一表面4213的正投影的一部分与第一表面4213的一部分重合;第一子部分4313在第一表面4213的正投影的一部分与第一表面4213重合;第一子部分4313在第一表面4213的正投影的全部与第一表面4213的一部分重合;或者,第一子部分4313在第一表面4213的正投影与第一表面4213完全重合。这样,可以利用第二裸电芯部分43从第一表面 4213侧对第一裸电芯部分43进行防护,提高电池40的安全性。
侧面4214包括第一侧面42141和第四侧面42144。第一侧面42141与第四侧面42144相背对。第一裸电芯部分42的极耳设置于第一侧面42141。
第四子部分4316位于第四侧面42144所朝向的一侧,且第四子部分4316在第四侧面42144的正投影与第四侧面42144有交叠。也就是说,第四子部分4316在第四侧面42144的正投影的一部分与第四侧面42144的一部分重合;第四子部分4316在第四侧面42144的正投影的一部分与第四侧面42144重合;第四子部分4316在第四侧面42144的正投影的全部与第四侧面42144的一部分重合;或者,第四子部分4316在第四侧面42144的正投影与第四侧面42144完全重合。这样,可以利用第二裸电芯部分43从第四侧面42144侧对第一裸电芯部分43进行防护,提高电池40的安全性。
可选地,第一子部分4313和第四子部分4316可以分别是相互独立,且物理分开的,即这二者分别为独立的裸电芯。当然,本申请不限于此,在另一些实施方式中,第一子部分4313与第四子部分4316的隔膜是连接成一体的。
在该示例中,请继续参阅图17,壳体41内形成有容纳腔,第一裸电芯部分42和第二裸电芯部分43可以该容纳腔内,这样第一裸电芯部分42和第二裸电芯部分43共用容纳腔,不但有利于减小电池40的整体体积,而且还可以降低成本。当然,该示例不限于此,第一裸电芯部分42和第二裸电芯部分43也可以位于壳体41的不同的容纳腔内。
在本示例的其他一些具体示例中,第二裸电芯部分43还可以同时包括上述第一子部分4313、第二子部分4314、第三子部分4315和第四子部分4316。以对第一裸电芯部分42的第一表面4213侧、第二侧面42142侧、第三侧面42143侧和第四侧面42144侧同时进行防护,提高电池40的安全性。
示例三
本示例是以第二裸电芯部分43仅从侧面4214侧对第一裸电芯部分42防护的角度出发,进行的改进。在该实施方式中,第二裸电芯部分43对第一裸电芯部分42的侧面4214的防护可以是针对沿第一表面4213的周向排布的多个侧面4214中的任意一个侧面4214的,或者任意几个侧面4214的,或者所有的侧面4214的。
在示例的一些具体示例中,请参阅图18,图18为本申请其它再一些实施例提供的电池的爆炸图。在该示例中,侧面4214包括第一侧面42141和第二侧面42142,第二侧面42142与第一侧面42141在第一表面4213的周向上排布且相连,第一裸电芯部分42的极耳设置于第一侧面42141,第二裸电芯部分43位于第二侧面42142所朝向的一侧,且第二裸电芯部分43在第二侧面42142的正投影与第二侧面42142有交叠。也就是说,第二裸电芯部分43在第二侧面42142的正投影的一部分与第二侧面42142的一部分重合;第二裸电芯部分43在第二侧面42142的正投影的一部分与第二侧面42142重合;第二裸电芯部分43在第二侧面42142的正投影的全部与第二侧面42142的一部分重合;或者,第二裸电芯部分43在第二侧面42142的正投影与第二侧面42142完全重合。这样,可以利用第二裸电芯部分43从第二侧面42142侧对第一裸电芯部分43进行防护,提高电池40的安全性。
请继续参阅图18,在该示例中,壳体41内形成有容纳腔,第一裸电芯部分42和 第二裸电芯部分43位于该容纳腔内,这样第一裸电芯部分42和第二裸电芯部分43可以容纳腔,不但有利于减小电池40的整体体积,而且还可以降低成本。当然,本示例不限于此,请参阅图19所示,图19为本申请其它再一些实施例提供的电池的立体剖视图。在该实施例中,第一裸电芯部分42和第二裸电芯部分43也可以位于壳体41的不同的容纳腔内。具体而言,壳体41包括第一壳体单元41a和第二壳体单元41b,第二壳体单元41b位于第一壳体单元41a的邻近第二侧面42142的一侧,并与第一壳体单元41a相对固定,第一壳体单元41a内形成有第一容纳腔,第二壳体单元41b内形成有第二容纳腔,第一裸电芯部分42容纳于第一容纳腔内,第一裸电芯部分42的外形可与第一壳体单元41a的形状相适配,第二裸电芯部分43容纳于第二容纳腔内,第二裸电芯部分43的外形可与第二壳体单元41b的形状相适配。这样设置,可以实现第一裸电芯部分42和第二裸电芯部分43的相互独立,从而提高第一裸电芯部分42和第二裸电芯部分43工作的安全性。
在本示例的另一种具体示例中,请参阅图20,图20为本申请其它再一些实施例提供的电池的爆炸图。在该示例中,侧面4214包括第一侧面42141、第二侧面42142和第四侧面42144,第二侧面42142与第一侧面42141在第一表面4213的周向上排布且相连,第一裸电芯部分42的极耳设置于第一侧面42141,第四侧面42144与第一侧面42141相背对,第二裸电芯部分43包括第二子部分4314和第四子部分4316。
第二子部分4314位于第二侧面42142所朝向的一侧,且第二子部分4314在第二侧面42142的正投影与第二侧面42142有交叠。也就是说,第二子部分4314在第二侧面42142的正投影的一部分与第二侧面42142的一部分重合;第二子部分4314在第二侧面42142的正投影的一部分与第二侧面42142重合;第二子部分4314在第二侧面42142的正投影的全部与第二侧面42142的一部分重合;或者,第二子部分4314在第二侧面42142的正投影与第二侧面42142完全重合。这样,可以利用第二裸电芯部分43从第二侧面42142侧对第一裸电芯部分43进行防护,提高电池40的安全性。
第四子部分4316位于第四侧面42144所朝向的一侧,且第四子部分4316在第四侧面42144的正投影与第四侧面42144有交叠。也就是说,第四子部分4316在第四侧面42144的正投影的一部分与第四侧面42144的一部分重合;第四子部分4316在第四侧面42144的正投影的一部分与第四侧面42144重合;第四子部分4316在第四侧面42144的正投影的全部与第四侧面42144的一部分重合;或者,第四子部分4316在第四侧面42144的正投影与第四侧面42144完全重合。这样,可以利用第二裸电芯部分43从第四侧面42144侧对第一裸电芯部分43进行防护,提高电池40的安全性。
可选地,第二子部分4314和第四子部分4316可以分别是相互独立,且物理分开的,即二者为独立的裸电芯。当然,本申请不限于此,在另一些实施方式中,第二子部分4314和第四子部分4316可以为一个结构整体。
在本示例的再一种具体示例中,请参阅图21,图21为本申请其它再一些实施例提供的电池的部分结构示意图,图21中壳体未示出。侧面4214包括第一侧面42141、第二侧面42142、第三侧面42143和第四侧面42144。第二侧面42142与第一侧面42141在第一表面4213的周向上排布且相连,第一裸电芯部分42的极耳设置于第一侧面42141,第三侧面42143与第二侧面42142相背对,第四侧面42144与第一侧面42141 相背对。第二裸电芯部分43包括第二子部分4314、第三子部分4315和第四子部分4316。
第二子部分4314位于第二侧面42142所朝向的一侧,且第二子部分4314在第二侧面42142的正投影与第二侧面42142有交叠。也就是说,第二子部分4314在第二侧面42142的正投影的一部分与第二侧面42142的一部分重合,第二子部分4314在第二侧面42142的正投影的一部分与第二侧面42142重合,第二子部分4314在第二侧面42142的正投影的全部与第二侧面42142的一部分重合,或者,第二子部分4314在第二侧面42142的正投影与第二侧面42142完全重合。这样,可以利用第二裸电芯部分43从第二侧面42142侧对第一裸电芯部分43进行防护,提高电池40的安全性。
第三子部分4315位于第三侧面42143所朝向的一侧,第三子部分4315在第三侧面42143的正投影与第三侧面42143有交叠。也就是说,第三子部分4315在第三侧面42143的正投影的一部分与第三侧面42143的一部分重合;第三子部分4315在第三侧面42143的正投影的一部分与第三侧面42143重合;第三子部分4315在第三侧面42143的正投影的全部与第三侧面42143的一部分重合;或者,第三子部分4315在第三侧面42143的正投影与第三侧面42143完全重合。这样,可以利用第二裸电芯部分43从第三侧面42143侧对第一裸电芯部分43进行防护,提高电池40的安全性。
第四子部分4316位于第四侧面42144所朝向的一侧,且第四子部分4316在第四侧面42144的正投影与第四侧面42144有交叠。也就是说,第四子部分4316在第四侧面42144的正投影的一部分与第四侧面42144的一部分重合;,第四子部分4316在第四侧面42144的正投影的一部分与第四侧面42144重合;第四子部分4316在第四侧面42144的正投影的全部与第四侧面42144的一部分重合;或者,第四子部分4316在第四侧面42144的正投影与第四侧面42144完全重合。这样,可以利用第二裸电芯部分43从第四侧面42144侧对第一裸电芯部分43进行防护,提高电池40的安全性。
由上述示例一至示例三的描述可知,在本申请实施例提供的电池40中,由于同时设置了第一裸电芯部分42和第二裸电芯部分43,与相关技术中设置一个裸电芯的电池40相比,一方面在不降低电池40总容量的前提下,可以利用第一裸电芯部分42和第二裸电芯部分43进行容量分割,这样可以使得第一裸电芯部分42和第二裸电芯部分43的容量均小于相关技术中的具有一个裸电芯的电池40的容量,从而可以至少在一定程度上降低第一裸电芯部分42和第二裸电芯部分43因容量大而导致的电池40内部短路而燃烧的风险,提高电池40的安全性;另一方面,由于第二裸电芯部分43在第一表面4213的正投影与第一表面4213有交叠,和/或第二裸电芯部分43在侧面4214的正投影与侧面4214有交叠,这样在电池40的使用过程中,可以利用第二裸电芯部分43对第一裸电芯部分42进行防护,不会导致电池40的整体损坏报废。
在上述示例一至示例三中任一具体示例中,可选地,第二裸电芯部分43为快充裸电芯部分。其中,快充裸电芯部分特指可以实现倍率(C率)不低于第三预设阈值的充放电过程的裸电芯。第三预设阈值包括但不限于1C、2C、2.5C、3C、4C、4.5C等等。
由于快充裸电芯部分的体积能量密度通常较低,因此第二裸电芯部分43在电池内的体积占比一定的前提下,将第二裸电芯部分43设置为快充裸电芯部分,可以降低第二裸电芯部分43的容量,在产生短路时释放的电量较少,能够在一定程度上提高电池的安全性,降低电池出现起、爆炸的可能性。
在此基础上,可选地,第一裸电芯部分42为高能裸电芯部分。其中,高能裸电芯部分特指体积能量密度不低于第一预设阈值的裸电芯部分。其中,第一预设阈值包括但不限于500Wh/L、510Wh/L、520Wh/L、540Wh/L、550Wh/L、580Wh/L、600Wh/L等等。且高能裸电芯部分的充放电速度不超过第二预设阈值,该第二预设阈值包括但不限于1c、1.5c、2c、2.2c、2.5c、3c等等。
由于高能裸电芯部分的体积能量密度较高,因此,可以保证电池的续航能力。
根据上述实施例的描述,当第一裸电芯部分42为高能裸电芯部分,第二裸电芯部分43为快充裸电芯部分时,通过设计第一裸电芯部分42和第二裸电芯部分43的体积占比,可以使得电池更具有快充特性或者更具有高能特性。具体地,若第一裸电芯部分42在电池40内的体积占比越大,电池40的体积能量密度则越高,续航时间越长。若第二裸电芯部分43在电池40内的体积占比越大,电池40的充电速度则越快,能够满足允许充电时间短场景下的需求。具体地,可以针对不同的应用场景,进行合理设计。
当然,第一裸电芯部分42和第二裸电芯部分43也可以为不具有快充特性和高能特性的裸电芯部分,还可以均为具有快充特性或者均具有高能特性的裸电芯部分。在此不做具体限定。只要能够采用第二裸电芯部分43对第一裸电芯部分42进行防护,以提高电池的安全性即可。为了方便描述,下文仅是在第一裸电芯部分42为高能裸电芯部分,第二裸电芯部分43为快充裸电芯部分的基础上进行的说明。
为了将第一裸电芯部分42设计为高能裸电芯部分,将第二裸电芯部分43设计为快充裸电芯部分,可以从两个裸电芯的尺寸结构以及材料体系进行分别设计。
在一些实施例中,第二裸电芯部分43的正极片的厚度小于第一裸电芯部分42的正极片的厚度,同时第二裸电芯部分43的负极片的厚度小于第一裸电芯部分42的负极片的厚度。由于极片的厚度越小,相同体积的裸电芯部分中的隔膜占比较大,电解液中锂离子的传输路径越短,充放电速度越快,快充性能越优。与之相反的,极片的厚度越大,相同体积的裸电芯部分中的隔膜占比通常较小,因此体积能量密度越大,高能性能越优。因此本实施例通过将第一裸电芯部分42和第二裸电芯部分43的极片厚度设计得不一致,也即是二者的结构不同,来使得第一裸电芯部分42体现高能特性,第二裸电芯部分43体现快充特性。
在上述实施例的基础上,可选地,第一裸电芯部分42的正极片的厚度的取值范围为:80μm~120μm。例如,该第一裸电芯部分42的正极片的厚度为85μm、90μm、95μm、100μm或105μm。第一裸电芯部分42的负极片的厚度的取值范围为:110~160μm。例如,第一裸电芯部分42的负极片的厚度的取值为110μm、115μm、120μm、125μm、130μm、135μm、140μm、145μm、150μm或155μm。第二裸电芯部分43的正极片的厚度的取值范围为40μm~80μm。进一步地,第二裸电芯部分43的正极片的厚度的取值范围为50~70μm。例如,第二裸电芯部分43的正极片的厚度的取值为55μm、60μm、65μm或68μm。第二裸电芯部分43的负极片的厚度取值范围为70μm~110μm。例如,第二裸电芯部分43的负极片的厚度为75μm、80μm、85μm、88μm或100μm。
在上述示例一至示例三中任一具体示例的基础上,可选地,电池40除了包括第一 裸电芯部分42和第二裸电芯部分43之外,还可以包括第三裸电芯部分。该第三裸电芯部分位于第一裸电芯部分42的第二表面4215所朝向的一侧。这样,可以由第二表面4215侧对第一裸电芯部分42进行防护,防止电池仓底壁产生的碎屑刺入第一裸电芯部分42,从而进一步提升电池的安全性。
示例地,请参阅图22和图23所示,图22为在图9所示电池的基础上增加第三裸电芯部分后的立体剖视图,图23为图22所示的电池的部分结构示意图,图23中壳体未示出。本实施例中,第三裸电芯部分46位于第一裸电芯部分42的第二表面4215所朝向的一侧。
在此基础上,第三裸电芯部分46在第二表面4215的正投影与第二表面4215交叠。也就是说,第三裸电芯部分46在第二表面4215的正投影的一部分与第二表面4215的一部分重合;第三裸电芯部分46在第二表面4215的正投影的一部分与第二表面4215重合;第三裸电芯部分46在第二表面4215的正投影的全部与第二表面4215的一部分重合;或者,第三裸电芯部分46在第二表面4215的正投影与第二表面4215完全重合。
这里,可以理解的是,第三裸电芯部分46在第二表面4215的正投影与第二表面4215重合是指第三裸电芯部分46的朝向第二表面4215的表面的外周与第二表面4215的外周是平齐的。
在此基础上,第三裸电芯部分46、第二裸电芯部分43和第一裸电芯部分42可以位于壳体41的同一容纳腔内,第一裸电芯部分42在第一表面4213的正投影与第一表面4213完全重合,第三裸电芯部分46在第二表面4215的正投影与第二表面4215完全重合。可以理解的是,第三裸电芯部分46、第二裸电芯部分43和第一裸电芯部分42还可以分别位于壳体41的不同的容纳腔内。或者第三裸电芯部分46、第二裸电芯部分43和第一裸电芯部分42中的任意两个位于同一容纳腔,而另一个则位于其它单独壳体的容纳腔内。
第三裸电芯部分46的结构和材质可以上述的第二裸电芯部分43的相同。第三裸电芯部分46的第三裸电芯部分本体的形状可以包括但不限于长方体状、圆柱体状和圆台状。
第三裸电芯部分46与第二裸电芯部分43之间,以及第三裸电芯部分46与第一裸电芯部分42之间可以是相互独立,且物理分开的。当然,本申请不限于此,在另一些实施方式中,第三裸电芯部分46与第二裸电芯部分43之间,和/或第三裸电芯46与第一裸电芯部分42之间可以形成一个结构件整体。
在一些实施例中,第三裸电芯部分46为快充裸电芯部分。这样,第三裸电芯部分46在电池内的体积占比一定的前提下,由于快充裸电芯部分的体积能量密度较低,因此第三裸电芯部分46的容量较小,电池仓内壁的碎屑刺入第三裸电芯部分46时,所释放的能量较小,能够进一步降低出现起火、爆炸的风险。在其他一些实施例中,第三裸电芯部分46也可以为高能裸电芯部分,或者既不属于快充裸电芯部分又不属于高能裸电芯部分。
结合上述任一实施例所述的电池40,可选地,在电池40中,所有的快充裸电芯部分的体积与所有的快充裸电芯部分的体积和高能裸电芯部分的体积之和的比值的取 值范围为5%~95%。例如,所有的快充裸电芯部分的体积与所有的快充裸电芯部分的体积和高能裸电芯部分的体积之和的比值为10%~50%。这样,可以同时兼顾电池的快充特性和高能特性。
第三裸电芯部分46具有至少两个极耳(图中未示出),该至少两个极耳包括一个正极极耳和一个负极极耳,该正极极耳和负极极耳形成第五充放电端口。
结合上述任一实施例所述的电池40,请返回参阅图6、图12、图14、图16、图17、图18、图20、图21和图23,保护板45具有第一充放电电路和第二充放电电路。该第一充放电电路和第二充放电电路集成在保护板45上,在图中未示出。第一充放电电路借助第一充放电端口B与第一裸电芯部分42电连接。在此基础上,保护板45还具有第三充放电端口D。该第三充放电端口D位于第一充放电电路上。保护板45用于借助第三充放电端口D与图2中电源管理模块52、充电管理模块51、充电器电连接,以形成一条充放电链路。同理的,第二充放电电路借助第二充放电端口C与第二裸电芯部分43电连接。在此基础上,保护板45还具有第四充放电端口E,该第四充放电端口E位于第二充放电电路上。保护板45用于借助第四充放电端口E与图2中电源管理模块52、充电管理模块51、充电器电连接,以形成另一条充放电链路。
需要说明的是,当电池还包括上述第三裸电芯部分46时,请参阅图23,保护板45还可以具有第三充放电电路,第三充放电电路借助前述第五充放电端口与第三裸电芯部分46电连接。在此基础上,保护板45还具有第六充放电端口F。该第六充放电端口F位于第三充放电电路上。保护板45用于借助第六充放电端口F与图2中电源管理模块52、充电管理模块51、充电器电连接,以形成再一条充放电链路。
这样一来,电池形成至少两条相互独立的充放电链路,当第二裸电芯部分43因碎裂后盖、螺丝刀等物品刺入而出现短路时,不会影响第一裸电芯部分42的正常使用,以避免第一裸电芯部分42和第二裸电芯部分43同时短路而导致同一时间释放的能量较大,从而降低引起燃烧、爆炸等安全问题的可能性。此外,在电池的体积一定的前提下,通过该两条充放电链路同时对电池进行充放电,可以提高电池20的充放电速度。同时借助该至少两条充放电链路,可以分别对第一裸电芯部分42和第二裸电芯部分43中的一个进行充放电管理以及容量、循环次数、健康状态等参数的检测,也可以同时对第一裸电芯部分42和第二裸电芯部分43两个进行充放电管理以及容量、循环次数、健康状态等参数的检测。完成电池性能和健康状态的最大化利用,还可以实现对一个裸电芯充电的同时,对另一个裸电芯进行放电。
在上述实施例的基础上,可选地,电源管理模块52用于在将电池40的第二裸电芯部分43的电量释放至第一预设阈值时,再对第一裸电芯部分42进行放电。这样第二裸电芯部分43具有优先放电性能,可以降低第二裸电芯部分43内的电量,即使第二裸电芯部分43因靠近电池仓13的开口和电池仓13的内侧面而被损坏,也会因第二裸电芯部分43的电量少,降低燃烧的风险,提高电池40的安全性。
这里,需要解释的是,电源管理模块52在将电池40的第二裸电芯部分43的电量释放至第一预设阈值时,再对第一裸电芯部分42进行放电。是指:电源管理模块52在将电池40的第二裸电芯部分43的电量释放至第一预设阈值时,再对第一裸电芯部分42和第二裸电芯部分43同时进行放电,或者仅对第一裸电芯部分42进行放电。也 就是说,在对第一裸电芯部分42进行放电过程中,电源管理模块52仍在对电池40的第二裸电芯部分43进行放电,或者在对第一裸电芯部分42进行放电时,电源管理模块52也可以控制所述电池40的第二裸电芯部分43停止放电。
具体地,第一预设阈值的取值区间范围为[0,80%SOC]。例如,该第二预设阈值为10%SOC、20%SOC、30%SOC、40%SOC、50%SOC、60%SOC或70%SOC。这里,SOC(State of charge,荷电状态)用来反映电池的剩余容量,其数值上定义为剩余容量占电池容量的比值。示例性地,60%SOC是指该电池40的剩余容量占电池容量的60%。
在上述实施例的基础上,充电管理模块51用于在将电池40的第二裸电芯部分43的电量充至第二预设阈值时,再同时对电池40的第一裸电芯部分42充电。也就是说,充电管理模块51用于在将电池40的第二裸电芯部分43的电量充至第二预设阈值时,开始对电池40的第一裸电芯部分42充电,且在对电池40的第一裸电芯部分42进行充电的过程中,充电管理模块51仍在对电池40的第二裸电芯部分43进行充电。
因此,电池40的整个充电过程中,分为两个阶段:
第一阶段为:第二裸电芯部分43充电,且在第二裸电芯部分43的电量未达到第二预设阈值之前,第一裸电芯部分42不充电,这样对于极片厚度较薄的第二裸电芯部分43来说,第二裸电芯部分43的充电速度较快,当电池40的电量耗尽时,优先对第二裸电芯部分43进行充电,有利于对电池40电量的及时补充,方便用户的使用,并且电池40的管理更加智能化。
第二阶段为:在将电池40的第二裸电芯部分43的电量充至第二预设阈值时,第一裸电芯部分42和第二裸电芯部分43同时进行充电,这样,更加有利于提高电池的充电速度,便于对电池40电量的及时补充,方便用户的使用,并且电池40的管理更加智能化。
具体地,第二预设阈值的取值区间范围为[60%SOC,100%SOC]。例如,该第二预设阈值为65%SOC、66%SOC、70%SOC、75%SOC、80%SOC、85%SOC或90%SOC。
根据以上各实施例的描述,下面以电子设备是手机为例,说明电池40的安全特性、高能特性和快充特性三者之间的关系。
具体地,请参阅图24,图24为本申请一些实施例提供的电子设备100的正面结构示意图,图25为图24所示电子设备100在A-A线处的一种截面结构示意图。在本实施例中,电池40仅包括一个裸电芯44。
请参阅图26,图26为图24所示电子设备100在A-A线处的另一种截面结构示意图。在本实施例中,电池40包括第一裸电芯部分42和第二裸电芯部分43。第二裸电芯部分43位于第一裸电芯部分42的靠近手机后盖12的一侧,且第二裸电芯部分43与第一裸电芯部分42层叠设置。第二裸电芯部分43为快充裸电芯部分,第一裸电芯部分42为高能裸电芯部分。
图25所示电子设备中电池40的参数和图26所示电子设备中电池40的参数,可以包括以下实施例一和实施例二。
实施例一
两种电池40的裸电芯部分的尺寸、充电倍率、容量和充电速度(也即是每10分钟的充电容量)分别记载在下表1中。具体地,图25所示电池40的各参数记载在表 1中的“改进前的电池”部分,图26所示电池40的各参数记载在表1中的“改进后的电池”部分。
表1
根据表1可知,本申请改进后的电池内第二裸电芯部分43的体积占电池总体积的比例(也即是体积占比)为60%。改进后的充电速度比改进前的电池40的充电速度提升约18%,而改进后的电池40的总容量比改进前的电池40的容量略低。因此改进后的电池40体现快充特性。
在实施例一的基础上,请继续参阅图25和图26,采用钢钉00由手机后盖12刺入上述改进前的电池40以及改进后的电池40内,以对比测试改进后的电池40的安全性能。具体地,测试结果参见下表2。
表2
根据表2可知,本实施例改进后的电池允许异物刺入的深度为3.0mm,改进后的电池的安全性能较高。
实施例二
两种电池40的裸电芯部分的尺寸、充电倍率、容量和充电速度(每10分钟的充电容量)分别记载在下表3中。具体地,图25所示电池40的各参数记载在表3中的“改进前的电池”部分,图26所示电池40的各参数记载在表3中的“改进后的电池”部分。
表3
根据表3可知,本实施例改进后的电池内第二裸电芯部分43的体积占比小于实施例一中改进后的电池内第二裸电芯部分43的体积占,具体地,本实施例的第二裸电芯部分43的体积占比为10%。在此基础上,本实施例改进后的电池40的充电速度提升约4%,该充电速度提升幅度小于实施一中改进后的电池的充电速度提升幅度。电池40仍然体现快充特性。但是,改进后的电池40的容量与改进前的电池的容量基本相同,本实施例中改进后的电池40的容量比实施例一中改进后的电池40的容量增加。
在实施例二的基础上,请继续参阅图25和图26,采用钢钉00由手机后盖12刺入上述改进前的电池40以及改进后的电池40内,以对比测试改进后的电池40的安全性能。具体地,测试结果参见下表4。
表4
根据表4可知,本实施例改进后的电池允许异物刺入的深度仅为0.5mm,改进后的电池具有一定的安全性能。但是该安全性能比实施例一中改进后的电池的安全性能低。
在上述实施例二的基础上,若进一步降低本申请改进后的电池内第二裸电芯部分43的体积占电池总体积的比例,则会使得电池40的容量大于改进前的电池的容量。这样电池40即体现高能特性。但是,随着改进后的第二裸电芯部分43的体积占比的缩小,第二裸电芯部分43的厚度也减小,在保证安全性能的前提下,允许异物刺入的深度也相应减小,也就是安全性能较低。由此可知本申请改进后的电池的高能特性、 快充特性和安全特性三者之间的关系为:随着快充特性的加强,第二裸电芯部分43的体积占比越大,厚度越大,允许异物刺入的深度越大,安全性能越高。但是随着快充特性的加强,第一裸电芯部分42的体积占比减小,电池的高能性能较小。与之相反的,随着高能性能的加强,第一裸电芯部分42的体积占比越大,第二裸电芯部分43的体积占比越小,快充特性越低,第二裸电芯部分43的厚度越小,允许异物刺入的深度越小,安全性能越低。
在本说明书的描述中,具体特征、结构、材料或者特点可以在任何的一个或多个实施例或示例中以合适的方式结合。
最后应说明的是:以上实施例仅用以说明本申请的技术方案,而非对其限制;尽管参照前述实施例对本申请进行了详细的说明,本领域的普通技术人员应当理解:其依然可以对前述各实施例所记载的技术方案进行修改,或者对其中部分技术特征进行等同替换;而这些修改或者替换,并不使相应技术方案的本质脱离本申请各实施例技术方案的精神和范围。
Claims (20)
- 一种电池,其特征在于,包括:第一裸电芯部分,所述第一裸电芯部分具有第一表面以及与所述第一表面相接的侧面,所述第一表面用于在所述电池安装于电子设备的电池仓内时与所述电池仓的开口朝向相同,所述侧面用于在所述电池安装于所述电子设备的电池仓内时朝向所述电池仓的内侧面;第二裸电芯部分,所述第二裸电芯部分位于所述第一表面所朝向的一侧,且所述第二裸电芯部分在所述第一表面的正投影与所述第一表面有交叠,和/或,所述第二裸电芯部分位于所述侧面所朝向的一侧,且所述第二裸电芯部分在所述侧面的正投影与所述侧面有交叠。
- 根据权利要求1所述的电池,其特征在于,所述第一裸电芯部分为高能裸电芯部分,所述第二裸电芯部分为快充裸电芯部分。
- 根据权利要求1或2所述的电池,其特征在于,所述第二裸电芯部分的负极片的厚度小于所述第一裸电芯部分的负极片的厚度。
- 根据权利要求1-3任一项所述的电池,其特征在于,所述第二裸电芯部分包括第一子部分,所述第一子部分位于所述第一表面所朝向的一侧,且所述第一子部分在所述第一表面的正投影与所述第一表面有交叠。
- 根据权利要求1-4任一项所述的电池,其特征在于,所述侧面包括第一侧面和第二侧面,所述第二侧面与所述第一侧面在所述第一表面的周向上排布且相连;所述第一裸电芯部分的极耳设置于所述第一侧面;所述第二裸电芯部分包括第二子部分,所述第二子部分位于所述第二侧面朝向的一侧,且所述第二子部分在所述第二侧面的正投影与所述第二侧面有交叠。
- 根据权利要求5所述的电池,其特征在于,所述侧面还包括第三侧面,所述第三侧面与所述第二侧面相背对;所述第二裸电芯部分还包括第三子部分,所述第三子部分位于所述第三侧面所朝向的一侧,所述第三子部分在所述第三侧面的正投影与所述第三侧面有交叠。
- 根据权利要求5或6所述的电池,其特征在于,所述侧面还包括第四侧面,所述第四侧面与所述第一侧面相背对;所述第二裸电芯部分还包括第四子部分,所述第四子部分位于所述第四侧面所朝向的一侧,且所述第四子部分在所述第四侧面的正投影与所述第四侧面有交叠。
- 根据权利要求4所述的电池,其特征在于,所述侧面包括第一侧面和第四侧面,所述第一侧面与所述第四侧面相背对;所述第一裸电芯部分的极耳设置于所述第一侧面,所述第二裸电芯部分还包括第四子部分,所述第四子部分位于所述第四侧面所朝向的一侧,且所述第四子部分在所述第四侧面的正投影与所述第四侧面有交叠。
- 根据权利要求1-8任一项所述的电池,其特征在于,所述第一裸电芯部分还具有第二表面,所述第二表面与所述第一表面相背对;所述电池还包括:第三裸电芯部分,所述第三裸电芯部分位于所述第二表面所朝向的一侧,且所述 第三裸电芯部分在所述第二表面的正投影与所述第二表面交叠。
- 根据权利要求1-9任一项所述的电池,其特征在于,所述第一裸电芯部分的正极片的厚度的取值范围为:80μm~120μm;所述第一裸电芯部分的负极片的厚度的取值范围为110μm~160μm。
- 根据权利要求1-10任一项所述的电池,其特征在于,所述第二裸电芯部分的正极片的厚度的取值范围为:40μm~80μm;所述第二裸电芯部分的负极片的厚度的取值范围为70μm~110μm。
- 根据权利要求1-11任一项所述的电池,其特征在于,还包括:壳体,所述第一裸电芯部分和所述第二裸电芯部分位于所述壳体内。
- 根据权利要求12所述的电池,其特征在于,所述壳体内形成容纳腔,所述第一裸电芯部分和所述第二裸电芯部分均位于所述容纳腔内。
- 根据权利要求12所述的电池,其特征在于,所述壳体包括第一壳体单元和第二壳体单元;所述第一壳体单元内形成第一容纳腔,所述第一裸电芯部分容纳于所述第一容纳腔内;所述第二壳体单元位于所述第一壳体单元的外部并与所述第一壳体单元相对固定,所述第二壳体单元内形成第二容纳腔,所述第二裸电芯部分容纳于所述第二容纳腔内。
- 根据权利要求12-14任一项所述的电池,其特征在于,所述第一裸电芯部分的极耳和所述第二裸电芯部分的极耳穿过所述壳体伸出至所述壳体的外侧,所述第一裸电芯部分的极耳形成第一充放电端口,第二裸电芯部分的极耳形成第二充放电端口;所述电池还包括保护板,所述保护板具有第一充放电电路、第二充放电电路、第三充放电端口和第四充放电端口;所述第一充放电电路借助所述第一充放电端口与所述第一裸电芯部分电连接,所述第三充放电端口位于所述第一充放电电路上,所述保护板用于借助所述第三充放电端口与电源管理模块、充电管理模块和充电器电连接,以形成一条充放电链路;所述第二充放电电路借助所述第二充放电端口与所述第二裸电芯部分电连接,所述第四充放电端口位于所述第二充放电电路上,所述保护板用于借助所述第四充放电端口与电源管理模块、充电管理模块和充电器电连接,以形成另一条充放电链路。
- 一种电子设备,其特征在于,包括:外壳,所述外壳内设有电池仓,所述电池仓具有开口;权利要求1-15任一项所述的电池,所述电池安装于所述电池仓内,且所述电池中第一裸电芯部分的第一表面的朝向与所述电池仓的开口的朝向相同,所述第一裸电芯部分的侧面朝向所述电池仓的内侧面。
- 根据权利要求16所述的电子设备,其特征在于,还包括:电源管理模块,所述电源管理模块与所述电池电连接,所述电源管理模块用于在将所述电池的第二裸电芯部分的电量释放至第一预设阈值时,再对所述第一裸电芯部分进行放电。
- 根据权利要求17所述的电子设备,其特征在于,所述第一预设阈值的取值区间范围为[0,80%SOC]。
- 根据权利要求16-18任一项所述的电子设备,其特征在于,还包括:充电管理模块,所述充电管理模块与所述电池电连接,所述充电管理模块用于在将所述电池的第二裸电芯部分的电量充至第二预设阈值时,再同时对所述电池的第一裸电芯部分进行充电。
- 根据权利要求19所述的电子设备,其特征在于,所述第二预设阈值的取值区间范围为[60%SOC,100%SOC]。
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CN114914618B (zh) | 2023-11-07 |
US20230261337A1 (en) | 2023-08-17 |
CN114914618A (zh) | 2022-08-16 |
CN117594855A (zh) | 2024-02-23 |
EP4156393A4 (en) | 2024-03-27 |
EP4156393A1 (en) | 2023-03-29 |
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