CN114094162A - Battery cell, battery, electric device, and method and device for manufacturing battery cell - Google Patents

Abstract

The embodiment of the application provides a single battery, a battery, electric equipment, a manufacturing method of the single battery and manufacturing equipment of the single battery, and belongs to the technical field of batteries. The battery cell comprises a shell, an electrode assembly, an end cover and a current collecting component. The housing has an opening. The electrode assembly is accommodated in the case. The end cover covers the opening and is connected with the shell in a sealing mode. The current collecting member is received in the case on a side of the electrode assembly facing the end cap, and is configured to connect the case and the electrode assembly such that the electrode assembly is electrically connected with the case. In the process of assembling the single battery, the current collecting component can be connected with the shell in the shell, the firmness of the connected current collecting component and the shell can be ensured, the current collecting component is connected with the electrode assembly and the shell, and then the end cover is covered on the opening of the shell and is hermetically connected with the shell, so that the electrode assembly is more conveniently electrically connected with the shell.

Description

Battery cell, battery, electric device, and method and device for manufacturing battery cell

The present application is a divisional application based on the invention having the application number of 202110759560.5, application date of 2021, 07/06, entitled "battery cell, battery, power-consuming device, and method and device for manufacturing battery cell".

Technical Field

The application relates to the technical field of batteries, in particular to a battery cell, a battery, electric equipment, and a manufacturing method and equipment of the battery cell.

Background

The lithium ion battery is a rechargeable battery and has the advantages of small volume, high energy density, high power density, multiple recycling times, long storage time and the like.

The battery cell generally includes a case for accommodating an electrode assembly, which generally includes a positive electrode tab and a negative electrode tab, and an electrolyte, and generates electric energy by movement of metal ions (e.g., lithium ions) between the positive electrode tab and the negative electrode tab.

For a general battery cell, the electrode assembly needs to be electrically connected to the case so that the case serves as a positive output electrode or a negative output electrode of the battery cell.

Disclosure of Invention

The embodiment of the application provides a battery cell, a battery, electric equipment, a manufacturing method of the battery cell and manufacturing equipment of the battery cell, and electric connection between an electrode assembly and a shell can be achieved more conveniently.

In a first aspect, an embodiment of the present application provides a battery cell, including: a housing having an opening; an electrode assembly housed within the case; the end cover covers the opening and is connected with the shell in a sealing mode; and a current collecting member received in the case on a side of the electrode assembly facing the end cap, the current collecting member being configured to connect the case and the electrode assembly so as to electrically connect the electrode assembly with the case.

Among the above-mentioned technical scheme, the mass flow component is located the one side of electrode subassembly facing the end cover, electrode subassembly and casing pass through the mass flow component and are connected, the opening of casing is covered to the end cover lid, end cover and casing sealing connection, this kind of structure makes at the free in-process of equipment battery, the mass flow component can be connected with the casing in the inside of casing, can guarantee the fastness after mass flow component and casing are connected, with mass flow component connection behind electrode subassembly and casing, again cover the opening of casing and with casing sealing connection with the end cover, make the electric connection of electrode subassembly and casing more convenient.

In some embodiments, the current collecting member is connected to an inner side of the case.

Among the above-mentioned technical scheme, the mass flow component is connected in the medial surface of casing for mass flow component and casing have great area of contact, can effectively improve the fastness that the mass flow component connected in the casing.

In some embodiments, the outer side of the end cap is disposed opposite the inner side of the housing; at least a portion of the current collecting member is positioned between an outer side of the end cap and an inner side of the housing, and the end cap is configured to press a portion of the current collecting member against the inner side of the housing.

Among the above-mentioned technical scheme, the current-collecting component is partly located between the medial surface of the lateral surface of end cover and casing at least, and the end cover supports partial pressure in the medial surface of casing with the current-collecting component for current-collecting component and casing in close contact with, improved the fastness that current-collecting component connects in the casing.

In some embodiments, the current collecting member includes a first connection portion and a second connection portion; at least a part of the first connection part is located between the end cap and the electrode assembly in a thickness direction of the end cap, the first connection part being configured to be connected with the electrode assembly; the second connection portion is connected to the first connection portion and extends from the first connection portion away from the electrode assembly in a thickness direction of the end cap, the second connection portion being configured to be connected to the case.

In the above technical solution, the current collecting member includes a first connecting portion and a second connecting portion that are connected to each other, and in a thickness direction of the end cover, at least a portion of the first connecting portion is located between the end cover and the electrode assembly, so that the first connecting portion is connected to the electrode assembly. The second connecting portion extends from the first connecting portion in a direction away from the electrode assembly along the thickness of the end cap, so that the second connecting portion is connected with the case. The current collecting component has simple integral structure and is easy to form and manufacture.

In some embodiments, the second connection portion is a ring-shaped structure connected to an outer edge of the first connection portion.

Among the above-mentioned technical scheme, the second connecting portion are the annular structure of connecting in the outward flange of first connecting portion, easily make by moulding for second connecting portion and casing have great area of contact.

In some embodiments, the housing is provided with a stopper at one end of the opening; the stopper is configured to restrict the end cap from coming off the case in a direction away from the electrode assembly.

Among the above-mentioned technical scheme, the open-ended one end of casing is provided with spacing portion, and spacing portion plays the restriction effect to the end cover to the restriction end cover breaks away from the casing along the direction that deviates from electrode subassembly.

In some embodiments, at least a portion of the end cap is located between the stopper portion and the current collecting member in a thickness direction of the end cap, and the stopper portion and the current collecting member cooperate to restrict movement of the end cap in the thickness direction of the end cap.

In the technical scheme, in the thickness direction of the end cover, at least one part of the end cover is positioned between the limiting part and the current collecting component, and the limiting part and the current collecting component can both play a role in limiting the end cover so as to limit the movement of the end cover in the thickness direction.

In some embodiments, the inner surface of the housing comprises a stepped surface; in the thickness direction of the end cover, at least one part of the end cover is positioned between the limiting part and the step surface, and the limiting part and the step surface limit the movement of the end cover in the thickness direction of the end cover together.

In the technical scheme, in the thickness direction of the end cover, at least one part of the end cover is positioned between the limiting part and the step surface of the shell, and the limiting part and the step surface can both play a role in limiting the end cover so as to limit the movement of the end cover in the thickness direction.

In some embodiments, the stop portion is an annular structure.

Among the above-mentioned technical scheme, spacing portion is the loop configuration, easily make by shaping, and spacing portion whole week all can play the restriction effect to the end cover, has guaranteed the spacing ability of spacing portion to the end cover.

In some embodiments, the limiting portion is a flanged structure that is partially folded inwards.

In the technical scheme, the limiting part is a flanging structure which is formed by partially turning the shell inwards, namely, the limiting part can be formed at the opening position of the shell in a mode of turning the shell, and the forming is simple. In the process of assembling the single battery, the current collecting component can be accommodated in the shell and connected with the electrode assembly and the shell, the end cover is covered on the opening of the shell, and finally the limiting part is formed by turning over the shell so as to limit the end cover.

In some embodiments, the inner surface of the housing comprises a stepped surface; the current collecting member abuts against the step face in a direction facing the electrode assembly.

In the above technical solution, the current collecting member abuts against a step surface of the case in a direction facing the electrode assembly, and the step surface acts as a restriction function against the current collecting member to restrict the current collecting member from moving in the direction facing the electrode assembly. After the current collecting member is abutted against the step surface, the current collecting member can be connected to the shell, and the installation of the current collecting member can be conveniently realized.

In some embodiments, the battery cell further comprises a seal; the end cap is connected with the shell in a sealing mode through the sealing piece.

Among the above-mentioned technical scheme, end cover and casing pass through sealing member sealing connection to guarantee the sealing performance of end cover and casing.

In some embodiments, the seal is configured to insulate the housing from the end cap.

Among the above-mentioned technical scheme, the sealing member keeps apart casing and end cover insulation, that is to say, the sealing member both plays sealed effect between casing and end cover, plays insulating effect again, when guaranteeing the sealing performance of end cover and casing, has reduced the electrified risk of end cover.

In some embodiments, the seal is configured to wrap around the end cap around the opening.

Among the above-mentioned technical scheme, the sealing member has improved the sealing performance of sealing member to end cover and casing on the one hand in the cladding of the open-ended circumference in the casing, and on the other hand has improved the wholeness of sealing member and casing. In the process of assembling the battery cell, the sealing element can be wrapped on the end cover, and then the end cover and the sealing element are installed on the shell as a whole.

In some embodiments, the housing is provided with a limiting part at one end of the opening, and at least a part of the sealing element is located between the end cover and the limiting part in the thickness direction of the end cover so as to realize the sealing connection between the end cover and the housing.

In the technical scheme, the limiting part limits the end cover so as to limit the end cover to be separated from the shell along the direction departing from the electrode assembly. At least one part of the sealing element is positioned between the end cover and the limiting part, so that the end cover is in sealing connection with the shell, and good sealing performance between the end cover and the shell is guaranteed.

In some embodiments, the seal comprises an enclosure and a third connecting portion connected to the enclosure; at least one part of the end cover is positioned in the enclosure, and the third connecting part is positioned between the end cover and the limiting part in the thickness direction of the end cover so as to realize the sealing connection of the end cover and the shell.

Among the above-mentioned technical scheme, the sealing member includes interconnect's the body and third connecting portion of enclosing, and the end cover is partly located the body at least, and the third connecting portion are located between end cover and the spacing portion, and sealing member simple structure when realizing the good sealed of end cover and casing for sealing member and end cover have fine wholeness.

In some embodiments, the electrode assembly includes a first tab configured to be connected with the current collecting member; the battery cell further comprises an insulating piece, the insulating piece is located between the first pole lug and the end cover in the thickness direction of the end cover, and the projection of the insulating piece in the thickness direction of the end cover covers the first pole lug.

Among the above-mentioned technical scheme, in the thickness direction of end cover, insulating part is located between first utmost point ear and the end cover, and the projection of insulating part along the thickness direction of end cover covers first utmost point ear, and insulating part plays the effect of keeping apart end cover and first utmost point ear, reduces the electrified risk of end cover.

In some embodiments, the electrode assembly includes a main body and a first tab having a cylindrical structure, one end of the first tab is connected to the main body, and the other end of the first tab is welded to the current collecting member.

In the technical scheme, the first tab of the electrode assembly is of a cylindrical structure, and one end, far away from the main body, of the first tab is welded to the current collecting member.

In some embodiments, the current collecting member is welded to the housing.

In the technical scheme, the current collecting member is welded on the shell, the connection mode of the current collecting member and the shell is simple, and the firmness of connection of the current collecting member and the shell can be ensured.

In some embodiments, the melting point of the current collecting member is lower than the melting point of the shell.

Among the above-mentioned technical scheme, the melting point of collection flow component is less than the melting point of casing, and when welding the collection flow component in the casing from the inside of casing, the phenomenon by the puncture is difficult to appear in the casing, effectively reduces the risk of casing weeping.

In some embodiments, the battery cell further comprises a pressure relief mechanism; the pressure relief mechanism is arranged on the end cover and is configured to be actuated to relieve the internal pressure when the internal pressure or temperature of the battery cell reaches a threshold value.

Among the above-mentioned technical scheme, be equipped with pressure relief mechanism on the end cover, pressure relief mechanism can actuate when battery monomer internal pressure or temperature reach the threshold value in order to release inside pressure to improve battery monomer's security.

In a second aspect, an embodiment of the present application provides a battery, which includes a plurality of battery cells provided in any one of the embodiments of the first aspect.

In a third aspect, an embodiment of the present application provides an electric device, which includes a plurality of battery cells provided in any one of the embodiments of the first aspect.

In a fourth aspect, an embodiment of the present application provides a method for manufacturing a battery cell, including: providing a housing having an opening; providing an electrode assembly; providing an end cap; providing a current collecting member; connecting a current collecting member to the electrode assembly; receiving the electrode assembly and the current collecting member in the case; connecting the current collecting member to the case to electrically connect the electrode assembly with the case; and covering the end cover on the opening, and hermetically connecting the end cover with the shell, so that the current collecting member is positioned on one side of the electrode assembly facing the end cover.

In some embodiments, said connecting said current collecting member to said housing comprises: welding the current collecting member to the case from the inside of the case; wherein a melting point of the current collecting member is lower than a melting point of the case.

Among the above-mentioned technical scheme, the melting point of collecting the flow component is less than the melting point of casing, welds the collecting flow component in the casing from the inside of casing for the difficult phenomenon of being punctured that appears of casing reduces the risk of casing weeping effectively.

In some embodiments, the method of manufacturing further comprises: after the end cover is covered on the opening, the shell is subjected to flanging treatment, so that a limiting part is formed at one end, provided with the opening, of the shell, and the limiting part limits the end cover to be separated from the shell along the direction departing from the electrode assembly.

In the technical scheme, after the end cover is covered on the opening of the shell, the shell is flanged, so that a limiting part is formed at one end of the shell with the opening to limit the end cover to be separated from the shell along the direction departing from the electrode assembly. The limiting part is formed in a flanging mode, the implementation mode is simple, and the manufacturing cost can be effectively reduced.

In a fifth aspect, embodiments of the present application further provide a manufacturing apparatus of a battery cell, including: a first providing device for providing a housing having an opening; second providing means for providing an electrode assembly; third providing means for providing an end cap; fourth providing means for providing a current collecting member; an assembly device for connecting a current collecting member to the electrode assembly; receiving the electrode assembly and the current collecting member in the case; connecting the current collecting member to the case to electrically connect the electrode assembly with the case; and covering the end cover on the opening, and hermetically connecting the end cover with the shell, so that the current collecting member is positioned on one side of the electrode assembly facing the end cover.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained from the drawings without inventive effort.

FIG. 1 is a schematic illustration of a vehicle according to some embodiments of the present application;

fig. 2 is a schematic structural diagram of a battery provided in some embodiments of the present application;

fig. 3 is an exploded view of a battery cell provided in some embodiments of the present application;

fig. 4 is a cross-sectional view of the battery cell shown in fig. 3;

fig. 5 is a partially enlarged view of a battery cell shown in fig. 4 at a;

fig. 6 is a partial enlarged view of a battery cell provided in accordance with further embodiments of the present application;

fig. 7 is a partial enlarged view of a battery cell provided in accordance with still other embodiments of the present application;

fig. 8 is a partial view of the battery cell shown in fig. 4;

fig. 9 provides a partial view of a battery cell for other embodiments of the present application;

fig. 10 is a flow chart of a method of manufacturing a battery cell according to some embodiments of the present disclosure;

fig. 11 is a flow chart of a method of manufacturing a battery cell according to further embodiments of the present disclosure;

fig. 12 is a schematic block diagram of a manufacturing apparatus of a battery cell provided in some embodiments of the present application.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs; the terminology used in the description of the application in the present application is for the purpose of describing particular embodiments only and is not intended to be limiting of the application; the terms "including" and "having," and any variations thereof, in the description and claims of this application and the description of the above figures are intended to cover non-exclusive inclusions. The terms "first," "second," and the like in the description and claims of this application or in the above-described drawings are used for distinguishing between different elements and not for describing a particular sequential or chronological order.

Reference in the specification to "an embodiment" means that a particular feature, structure, or characteristic described in connection with the embodiment can be included in at least one embodiment of the specification. The appearances of the phrase in various places in the specification are not necessarily all referring to the same embodiment, nor are separate or alternative embodiments mutually exclusive of other embodiments.

In the description of the present application, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "attached" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present application can be understood by those of ordinary skill in the art as appropriate.

The term "and/or" in this application is only one kind of association relationship describing the associated object, and means that there may be three kinds of relationships, for example, a and/or B, which may mean: a exists alone, A and B exist simultaneously, and B exists alone. In addition, the character "/" in this application generally indicates that the preceding and following associated objects are in an "or" relationship.

In the embodiments of the present application, like reference numerals denote like parts, and a detailed description of the same parts is omitted in different embodiments for the sake of brevity. It should be understood that the thickness, length, width and other dimensions of the various components in the embodiments of the present application and the overall thickness, length, width and other dimensions of the integrated device shown in the drawings are only exemplary and should not constitute any limitation to the present application.

The appearances of "a plurality" in this application are intended to mean more than two (including two).

In the present application, the battery cell may include a lithium ion secondary battery, a lithium ion primary battery, a lithium sulfur battery, a sodium lithium ion battery, a sodium ion battery, a magnesium ion battery, or the like, which is not limited in the embodiments of the present application. The battery cell may be a cylinder, a flat body, a rectangular parallelepiped, or other shapes, which is not limited in the embodiments of the present application. The battery cells are generally divided into three types in an encapsulation manner: the cylindrical battery monomer, the square battery monomer and the soft package battery monomer are also not limited in the embodiment of the application.

Reference to a battery in embodiments of the present application refers to a single physical module that includes one or more battery cells to provide higher voltage and capacity. For example, the battery referred to in the present application may include a battery module or a battery pack, etc. Batteries generally include a case for enclosing one or more battery cells. The box can avoid liquid or other foreign matters to influence the charging or discharging of battery monomer.

The battery monomer comprises an electrode assembly and electrolyte, wherein the electrode assembly comprises a positive plate, a negative plate and an isolating membrane. The battery cell mainly depends on metal ions moving between the positive plate and the negative plate to work. The positive plate comprises a positive current collector and a positive active substance layer, wherein the positive active substance layer is coated on the surface of the positive current collector, the positive current collector which is not coated with the positive active substance layer protrudes out of the positive current collector which is coated with the positive active substance layer, and the positive current collector which is not coated with the positive active substance layer is used as a positive electrode lug. Taking a lithium ion battery as an example, the material of the positive electrode current collector may be aluminum, and the positive electrode active material may be lithium cobaltate, lithium iron phosphate, ternary lithium, lithium manganate, or the like. The negative plate comprises a negative current collector and a negative active substance layer, the negative active substance layer is coated on the surface of the negative current collector, the negative current collector which is not coated with the negative active substance layer protrudes out of the negative current collector which is coated with the negative active substance layer, and the negative current collector which is not coated with the negative active substance layer is used as a negative pole tab. The material of the negative electrode current collector may be copper, and the negative electrode active material may be carbon, silicon, or the like. In order to ensure that the fuse is not fused when a large current is passed, the number of the positive electrode tabs is multiple and the positive electrode tabs are stacked together, and the number of the negative electrode tabs is multiple and the negative electrode tabs are stacked together. The material of the isolation film may be PP (polypropylene) or PE (polyethylene). In addition, the electrode assembly may have a winding structure or a lamination structure, and the embodiment of the present application is not limited thereto.

The development of battery technology needs to consider various design factors, such as energy density, cycle life, discharge capacity, charge and discharge rate, and other performance parameters, and also needs to consider the safety of the battery.

For cells, the main safety hazard comes from the charging and discharging processes, and at the same time, with a suitable ambient temperature design, there are generally at least three protective measures for the cells in order to effectively avoid unnecessary losses. In particular, the protective measures comprise at least a switching element, selection of a suitable isolating membrane material and a pressure relief mechanism. The switching element is an element that can stop charging or discharging the battery when the temperature or resistance in the battery cell reaches a certain threshold value. The isolating membrane is used for isolating the positive plate and the negative plate, and can automatically dissolve the micron-scale (even nano-scale) micropores attached to the isolating membrane when the temperature rises to a certain value, so that metal ions cannot pass through the isolating membrane, and the internal reaction of the battery monomer is stopped.

The pressure relief mechanism refers to an element or a component that is actuated to relieve the internal pressure or temperature of the battery cell when the internal pressure or temperature reaches a predetermined threshold. The threshold design varies according to design requirements. The threshold may depend on the material of one or more of the positive electrode sheet, the negative electrode sheet, the electrolyte and the separator in the battery cell. The pressure relief mechanism may take the form of, for example, an explosion-proof valve, an explosion-proof sheet, a gas valve, a pressure relief valve, or a safety valve, and may specifically employ a pressure-sensitive or temperature-sensitive element or configuration, that is, when the internal pressure or temperature of the battery cell reaches a predetermined threshold value, the pressure relief mechanism performs an action or a weak structure provided in the pressure relief mechanism is broken, thereby forming an opening or a passage through which the internal pressure or temperature can be relieved.

As used herein, "activate" means that the pressure relief mechanism is activated or activated to a certain state, such that the internal pressure and temperature of the battery cell are relieved. The actions generated by the pressure relief mechanism may include, but are not limited to: at least a portion of the pressure relief mechanism ruptures, fractures, is torn or opened, or the like. When the pressure relief mechanism is actuated, high-temperature and high-pressure substances in the battery cells are discharged outwards from the actuated part as emissions. In this way, the battery cell can be subjected to pressure relief and temperature relief under the condition of controllable pressure or temperature, so that the potential more serious accident is avoided.

Reference herein to emissions from the battery cell includes, but is not limited to: electrolyte, dissolved or split anode and cathode pole pieces, fragments of a separation film, high-temperature and high-pressure gas generated by reaction, flame and the like.

The pressure relief mechanism on the battery cell has an important influence on the safety of the battery. For example, when a short circuit or overcharge occurs, thermal runaway may occur inside the battery cell, and the pressure or temperature may suddenly rise. In this case, the internal pressure and temperature can be released outwards by the actuation of the pressure relief mechanism, so as to prevent the explosion and the fire of the battery cells.

For a general battery cell, the electrode assembly needs to be electrically connected to the case so that the case serves as a positive output electrode or a negative output electrode of the battery cell.

The inventors have found that, in a single battery cell, since the case has a hollow structure with an open top end, the electrode assembly is electrically connected to the case, and generally, the bottom wall of the case and the tabs of the electrode assembly are welded together from the outside of the case to electrically connect the electrode assembly to the case.

In view of this, the embodiments of the present application provide a solution, in which the current collecting member is disposed on a side of the electrode assembly facing the end cap, the electrode assembly is electrically connected to the case through the current collecting member, the end cap covers the opening of the case, and the end cap is hermetically connected to the case. In the process of assembling the single battery, the current collecting component can be connected with the shell in the shell, the firmness of the connected current collecting component and the shell can be ensured, the current collecting component is connected with the electrode assembly and the shell, and then the end cover is covered on the opening of the shell and is hermetically connected with the shell, so that the electrode assembly is more conveniently electrically connected with the shell.

The technical scheme described in the embodiment of the application is suitable for the battery and the electric equipment using the battery.

The electric equipment can be vehicles, mobile phones, portable equipment, notebook computers, ships, spacecrafts, electric toys, electric tools and the like. The vehicle can be a fuel oil vehicle, a gas vehicle or a new energy vehicle, and the new energy vehicle can be a pure electric vehicle, a hybrid electric vehicle or a range-extended vehicle and the like; spacecraft include aircraft, rockets, space shuttles, and spacecraft, among others; electric toys include stationary or mobile electric toys, such as game machines, electric car toys, electric ship toys, electric airplane toys, and the like; the electric power tools include metal cutting electric power tools, grinding electric power tools, assembly electric power tools, and electric power tools for railways, such as electric drills, electric grinders, electric wrenches, electric screwdrivers, electric hammers, electric impact drills, concrete vibrators, and electric planers. The embodiment of the present application does not specifically limit the above-mentioned electric devices.

For convenience of explanation, the following embodiments will be described by taking an electric device as an example of a vehicle.

Referring to fig. 1, fig. 1 is a schematic structural diagram of avehicle 1000 according to some embodiments of the present disclosure, abattery 100 is disposed inside thevehicle 1000, and thebattery 100 may be disposed at a bottom portion, a head portion, or a tail portion of thevehicle 1000. Thebattery 100 may be used for power supply of thevehicle 1000, for example, thebattery 100 may serve as an operation power source of thevehicle 1000.

Thevehicle 1000 may further include acontroller 200 and amotor 300, thecontroller 200 being configured to control thebattery 100 to supply power to themotor 300, for example, for starting, navigation, and operational power requirements while thevehicle 1000 is traveling.

In some embodiments of the present application, thebattery 100 may be used not only as an operating power source of thevehicle 1000, but also as a driving power source of thevehicle 1000, instead of or in part of fuel or natural gas, to provide driving power for thevehicle 1000.

In some embodiments, referring to fig. 2, fig. 2 is a schematic structural diagram of abattery 100 according to some embodiments of the present disclosure, where thebattery 100 includes a plurality ofbattery cells 10. The plurality ofbattery cells 10 may be connected in series or in parallel or in series-parallel. The series-parallel connection means that a plurality ofbattery cells 10 are connected in series or in parallel.

In some embodiments, thebattery 100 may further include a bus member (not shown), and the plurality ofbattery cells 10 may be electrically connected to each other through the bus member, so as to connect the plurality ofbattery cells 10 in series or in parallel or in series-parallel.

The bus members may be metallic conductors such as copper, iron, aluminum, steel, aluminum alloys, and the like.

In some embodiments, thebattery cell 10 may further include acase 20, and thecase 20 is used to accommodate thebattery cell 10. Thecase 20 may include a first portion 21 and asecond portion 22, and the first portion 21 and thesecond portion 22 cover each other to define a receivingspace 23 for receiving thebattery cell 10. Of course, the connection between the first portion 21 and thesecond portion 22 can be sealed by a sealing element (not shown), which can be a sealing ring, a sealant, etc.

Wherein the first portion 21 and thesecond portion 22 may be various shapes, such as a rectangular parallelepiped, a cylinder, etc. The first portion 21 may be a hollow structure with one side open, thesecond portion 22 may also be a hollow structure with one side open, and the open side of thesecond portion 22 is closed to the open side of the first portion 21, thereby forming thebox body 20 having the receivingspace 23. Of course, the first portion 21 may have a hollow structure with one side open, thesecond portion 22 may have a plate-like structure, and thesecond portion 22 may cover the open side of the first portion 21 to form thecase 20 having theaccommodating space 23.

Referring to fig. 3, fig. 3 is an exploded view of abattery cell 10 according to some embodiments of the present disclosure, thebattery cell 10 may include acase 11, anelectrode assembly 12, anend cap 13, and a current collectingmember 14, thecase 11 has anopening 111, theelectrode assembly 12 is accommodated in thecase 11, theend cap 13 covers theopening 111, theend cap 13 is hermetically connected to thecase 11, the current collectingmember 14 is accommodated in thecase 11, the current collectingmember 14 is located on a side of theelectrode assembly 12 facing theend cap 13, and the current collectingmember 14 is configured to connect thecase 11 and theelectrode assembly 12, so that theelectrode assembly 12 is electrically connected to thecase 11.

In which theend cap 13 covers theopening 111 of thecase 11 to form a sealed space 112 (not shown in fig. 3) for accommodating theelectrode assembly 12 and an electrolyte, which may be an electrolyte.

Because the current collectingmember 14 is located on one side of theelectrode assembly 12 facing theend cover 13, theelectrode assembly 12 is electrically connected with thecase 11 through the current collectingmember 14, theend cover 13 covers theopening 111 of thecase 11, and theend cover 13 is hermetically connected with thecase 11, the structure enables the current collectingmember 14 to be connected with thecase 11 inside thecase 11 during the process of assembling thebattery cell 10, the firmness of the connection of the current collectingmember 14 with thecase 11 can be ensured, and after the current collectingmember 14 is connected with theelectrode assembly 12 and thecase 11, theend cover 13 covers theopening 111 of thecase 11 and is hermetically connected with thecase 11, so that the electrical connection of theelectrode assembly 12 and thecase 11 is more convenient.

For ageneral battery cell 10, since the bottom wall of thecase 11 and the tab are welded together, in the process of welding the bottom wall of thecase 11 and the tab, the bottom wall of thecase 11 is easily broken down, which causes liquid leakage and affects the performance of thebattery cell 10. In the embodiment of the present application, theelectrode assembly 12 and thecase 11 are electrically connected through the current collectingmember 14, theend cap 13 and thecase 11 are hermetically connected, theelectrode assembly 12 is not directly connected to theend cap 13, and thebattery cell 10 is not prone to leakage from theend cap 13.

In some embodiments, thebattery cell 10 may further include a sealingmember 15, and theend cap 13 and thehousing 11 are hermetically connected by the sealingmember 15, so as to ensure the sealing performance of theend cap 13 and thehousing 11.

Optionally, the sealingmember 15 is configured to insulate and isolate thehousing 11 from theend cap 13, that is, the sealingmember 15 serves as both a sealing function and an insulating function between thehousing 11 and theend cap 13, and reduces the risk of theend cap 13 being electrified while ensuring the sealing performance between theend cap 13 and thehousing 11.

The sealingmember 15 may be made of rubber, plastic, etc., and theend cap 13 may be made of metal, such as copper, iron, aluminum, steel, aluminum alloy, etc.

In other embodiments, theend cap 13 and thehousing 11 may be sealed by a tight fit, for example, an interference fit is formed between theend cap 13 and thehousing 11 to achieve a sealed connection between theend cap 13 and thehousing 11. In this embodiment, theend cap 13 may be made of an insulating material to reduce the risk of theend cap 13 being electrified.

In some embodiments, thebattery cell 10 may further include apressure relief mechanism 16, thepressure relief mechanism 16 is disposed on theend cap 13, and thepressure relief mechanism 16 is configured to be actuated to relieve internal pressure when the internal pressure or temperature of thebattery cell 10 reaches a threshold value, so as to improve the safety of thebattery cell 10.

Thepressure relief mechanism 16 may be a component such as an explosion-proof valve, an explosion-proof plate, a gas valve, or a pressure relief valve. In fig. 3, thepressure relief mechanism 16 is shown by way of example as a rupture disc, which may be bonded to theend cap 13.

When thebattery cell 10 is thermally runaway and the exhaust is discharged through thepressure relief mechanism 16, theend cap 13 may be charged, and if one of theend cap 13 and thecase 11 is positively charged and the other is negatively charged, thebattery cell 10 may be short-circuited. And theseal 15 insulating thehousing 11 from theend cap 13 effectively reduces the risk of short circuits.

In the present embodiment, thehousing 11 may have various shapes, such as a cylinder, a rectangular parallelepiped, and the like. The shape of thecase 11 may be determined according to the specific shape of theelectrode assembly 12. For example, if theelectrode assembly 12 has a cylindrical structure, thecase 11 may alternatively have a cylindrical structure; if theelectrode assembly 12 has a rectangular parallelepiped structure, thecase 11 may have a rectangular parallelepiped structure.

Illustratively, in fig. 3, thecase 11 has a hollow cylindrical structure and theelectrode assembly 12 has a cylindrical structure.

Thehousing 11 may be made of various materials, such as copper, iron, aluminum, steel, aluminum alloy, etc.

In some embodiments, the melting point of thehousing 11 may be higher than the melting point of theend cap 13. For example, thehousing 11 is made of steel and theend cap 13 is made of aluminum.

When thebattery cell 10 is in thermal runaway, since the melting point of theend cap 13 is lower than that of thehousing 11, theend cap 13 is easier to melt, the possibility that thebattery cell 10 bursts to impactother battery cells 10 is reduced, and the risk that thewhole battery 100 is deformed or even fails under high pressure is reduced.

In some embodiments, referring to fig. 4, fig. 4 is a cross-sectional view of thebattery cell 10 shown in fig. 3, thecase 11 may include acan 113 and anoutput part 114, theopening 111 is formed at one end of thecan 113, the other end of thecan 113 is connected to theoutput part 114, thecan 113 is connected to the current collectingmember 14, and theoutput part 114 is electrically connected to theelectrode assembly 12. One of thecylindrical body 113 and theoutput portion 114 is a positive output electrode of thebattery cell 10, and the other is a negative output electrode of thebattery cell 10.

Under the condition that thepressure relief mechanism 16 is arranged on theend cover 13, it can be understood that thepressure relief mechanism 16 and theoutput part 114 are located at two opposite sides of thehousing 11, thepressure relief mechanism 16 does not occupy the space of theoutput part 114, and the structure can ensure that theoutput part 114 has a larger contact area with a confluence part, so that the overcurrent capacity is improved. Taking the case where the bus member is welded to theoutput portion 114 as an example, theoutput portion 114 and the bus member have a large welding area.

Illustratively, thebarrel 113 is of cylindrical configuration and theoutput 114 is of plate-like configuration. Theend cap 13 is used for covering theopening 111 at one end of thecylinder 113 far away from theoutput part 114, and theend cap 13 may be a circular plate-shaped structure matched with thecylinder 113.

Optionally, thebarrel 113 is formed with aflange portion 1131 at an end away from theopening 111, thebarrel 113 is partially recessed to form a first limitingprotrusion 1132, and thebarrel 113 forms a necking structure at the position of the first limitingprotrusion 1132. In the thickness direction Z of theend cover 13, theflange portion 1131 and thefirst limit protrusion 1132 are respectively located at two sides of theoutput portion 114, and theflange portion 1131 and thefirst limit protrusion 1132 jointly limit the movement of theoutput portion 114 in the thickness direction of the end cover.

Illustratively, thecuff 1131 and thefirst limit protrusion 1132 are both annular structures.

In thesingle battery 10, theoutput portion 114 may be a positive output electrode, and thecylindrical body 113 may be a negative output electrode; thecylindrical body 113 may be a negative output electrode, and theoutput unit 114 may be a positive output electrode. The positive output electrode and the negative output electrode are portions of thebattery cell 10 for connecting with other components and outputting the electric energy of thebattery cell 10. Taking the twosingle batteries 10 electrically connected through the bus bar, for example, to realize the series connection of the twosingle batteries 10, both the positive output electrode of onesingle battery 10 and the negative output electrode of the othersingle battery 10 can be welded to the bus bar.

It can be understood that the positive output electrode and the negative output electrode of thebattery cell 10 are in an insulated state, and therefore, thecylindrical body 113 and theoutput part 114 are both connected in an insulated manner. In some embodiments,barrel 113 andoutput 114 may be insulated and isolated by insulating unit 17. The insulating unit 17 may be made of rubber, plastic, or the like.

In some embodiments, theelectrode assembly 12 may include amain body 121 and tabs extending from themain body 121. Thebody 121 may include a positive electrode tab, a negative electrode tab, and a separator. Thebody 121 may have a winding structure formed by winding a positive electrode tab, a separator, and a negative electrode tab. Themain body 121 may have a stacked structure in which a positive electrode tab, a separator, and a negative electrode tab are stacked.

The positive pole piece comprises a positive current collector and positive active material layers coated on two opposite sides of the positive current collector. The negative pole piece comprises a negative current collector and negative active material layers coated on two opposite sides of the negative current collector. Themain body 121 is the portion of theelectrode assembly 12 corresponding to the area of the pole piece coated with the active material layer, and the tab is the area of the pole piece not coated with the active material layer.

The tabs may be divided into afirst tab 122 and asecond tab 123, and thefirst tab 122 may be connected with the current collectingmember 14 to electrically connect theelectrode assembly 12 with thecan 113 of thecase 11; thesecond tab 123 may be connected to theoutput part 114, enabling electrical connection of theelectrode assembly 12 to theoutput part 114.

Illustratively, thefirst tab 122 may have a cylindrical structure, one end of thefirst tab 122 is connected to themain body 121, and the other end of thefirst tab 122 is welded to the current collectingmember 14. This configuration ensures the connection of thefirst tab 122 to the current collectingmember 14 with good reliability and simplifies the connection process of thefirst tab 122 to the current collectingmember 14.

For example, thesecond tab 123 may have a cylindrical structure, one end of thesecond tab 123 is connected to thebody 121, and the other end of thesecond tab 123 is welded to theoutput unit 114. This structure can ensure the firmness of the connection between thesecond tab 123 and theoutput portion 114, and simplify the connection process between thesecond tab 123 and theoutput portion 114.

One of thefirst tab 122 and thesecond tab 123 is a positive tab, and the other is a negative tab. The positive electrode tab is a region on the positive electrode sheet which is not coated with the positive electrode active material layer. The negative electrode tab is a region of the negative electrode tab not coated with the negative electrode active material layer.

If thefirst tab 122 is a positive tab, thesecond tab 123 is a negative tab, thecylinder 113 is a positive output electrode, and theoutput unit 114 is a negative output electrode; if thefirst tab 122 is a negative tab, the second tab is a positive tab, thecylinder 113 is a negative output electrode, and theoutput part 114 is a positive output electrode.

In the present embodiment, the current collectingmember 14 may be a metal conductor, such as copper, iron, aluminum, steel, aluminum alloy, or the like. The current collectingmember 14 may be connected with thecase 11 in various ways. For example, the current collectingmember 14 is welded to thecase 11, and for example, the current collectingmember 14 is bonded to thecase 11 by a conductive paste.

In some embodiments, the current collectingmember 14 is welded to thecase 11, and the melting point of the current collectingmember 14 is lower than the melting point of thecase 11.

When the current collectingmember 14 is welded in theshell 11 from the inside of theshell 11, theshell 11 is not easy to break down due to the fact that the melting point of the current collectingmember 14 is lower than that of theshell 11, and the risk of liquid leakage of theshell 11 is effectively reduced.

Taking thecase 11 as a steel material and the current collectingmember 14 as an aluminum material as an example, the melting point of thecase 11 is 1500 ℃, the melting point of the current collectingmember 14 is 660 ℃, and during welding, the welding temperature can be 660-1500 ℃, for example, the welding temperature is 800 ℃, which does not reach the melting point of thecase 11, and thecase 11 is not easy to break down during welding.

Specifically, the current collectingmember 14 has a melting point lower than that of thebarrel 113 of thecase 11.

In some embodiments, referring to fig. 5, fig. 5 is an enlarged view of a portion a of thebattery cell 10 shown in fig. 4, the current collectingmember 14 is connected to theinner side 115 of thecase 11, such that the current collectingmember 14 and thecase 11 have a larger contact area, which can effectively improve the firmness of the connection of the current collectingmember 14 to thecase 11 and improve the overcurrent capability.

Theinner side surface 115 of thehousing 11 is a surface formed by the movement of a bus line along the circumferential direction of theopening 111 of thehousing 11, where the bus line is a line arranged in the thickness direction Z of theend cover 13. Taking thecase 11 as a cylindrical structure, theinner side surface 115 of thecase 11 is an inner circumferential surface of thecase 11.

Illustratively, the current collectingmember 14 is welded to theinner side 115 of thehousing 11.

Optionally,outer side 131 ofend cap 13 is disposed oppositeinner side 115 ofhousing 11. At least a part of the current collectingmember 14 is located between theouter side 131 of theend cap 13 and theinner side 115 of thehousing 11, and theend cap 13 is configured to press a part of the current collectingmember 14 against theinner side 115 of thehousing 11, so that the current collectingmember 14 is in close contact with thehousing 11, and the firmness of connecting the current collectingmember 14 to thehousing 11 is improved.

It should be noted that theend cover 13 may press a part of the current collectingmember 14 against theinner side surface 115 of thehousing 11, or theend cover 13 may directly press a part of the current collectingmember 14 against theinner side surface 115 of thehousing 11, that is, theend cover 13 directly presses against the current collectingmember 14; theend cap 13 may indirectly press a part of the current collectingmember 14 against theinner side surface 115 of thehousing 11, that is, theend cap 13 may indirectly press against the current collectingmember 14, for example, in a case where theend cap 13 is hermetically connected to thehousing 11 by the sealingmember 15, theend cap 13 may indirectly press against the current collectingmember 14 by the sealingmember 15.

In some embodiments, the current collectingmember 14 includes afirst connection portion 141 and asecond connection portion 142, thefirst connection portion 141 being at least partially located between theend cap 13 and theelectrode assembly 12 in the thickness direction Z of theend cap 13, thefirst connection portion 141 being configured to be connected with theelectrode assembly 12 to achieve electrical connection of the current collectingmember 14 with theelectrode assembly 12. Thesecond connection portion 142 is connected to thefirst connection portion 141 and extends from thefirst connection portion 141 in the thickness direction Z of theend cap 13 away from theelectrode assembly 12, and thesecond connection portion 142 is configured to be connected to thecase 11. Such a current collectingmember 14 has a simple structure, is easy to mold and manufacture, and can be easily connected to both theelectrode assembly 12 and thecase 11.

Wherein thefirst connection portion 141 is used to be connected to thefirst tab 122 of theelectrode assembly 12, for example, thefirst connection portion 141 is welded to thefirst tab 122. The second connectingportion 142 may be connected to theinner side surface 115 of theshell 11, for example, the second connectingportion 142 is welded to theinner side surface 115 of theshell 11.

For example, as shown in fig. 5, theend cap 13 presses the second connectingportion 142 of the current collectingmember 14 against theinner side surface 115 of thehousing 11 through the sealingmember 15, so as to improve the firmness of the connection of the current collectingmember 14 to thehousing 11.

Alternatively, thesecond connection portion 142 is a ring-shaped structure connected to the outer edge of thefirst connection portion 141, and this structure allows the current collectingmember 14 to be formed by stamping, which is simple and convenient to form. In addition, the annular second connectingportion 142 has a larger contact area with thehousing 11, which is beneficial to improving the overcurrent capacity.

In some embodiments, the inner surface of thecase 11 includes a steppedsurface 116 against which the current collectingmember 14 abuts in a direction facing theelectrode assembly 12, the steppedsurface 116 acting as a restriction on the current collectingmember 14 to restrict the current collectingmember 14 from moving in a direction facing theelectrode assembly 12.

After the current collectingmember 14 is abutted against the steppedsurface 116 during assembly of thebattery cell 10, the current collectingmember 14 may be connected to thecase 11, and the mounting of the current collectingmember 14 may be conveniently accomplished.

Wherein the steppedsurface 116 is connected to theinner side surface 115 of thecase 11, it may be that thefirst connection portion 141 of the current collectingmember 14 abuts against the steppedsurface 116 in a direction facing theelectrode assembly 12.

In this embodiment, as shown in fig. 5, the current collectingmember 14 may be connected to theinner side surface 115 of thecase 11. In other embodiments, the current collectingmember 14 may not be connected to theinner side surface 115 of thecase 11, but may be abutted against and connected to the steppedsurface 116, for example, the first connectingportion 141 of the current collectingmember 14 is welded to the steppedsurface 116, and the second connectingportion 142 of the current collecting member is in contact with theinner side surface 115 of thecase 11, but is not connected together.

In some embodiments, with continued reference to fig. 5, thecase 11 is provided with a limitingportion 117 at one end of theopening 111, and the limitingportion 117 is configured to limit theend cap 13 from being separated from thecase 11 in a direction away from theelectrode assembly 12, that is, the limitingportion 117 limits theend cap 13 from being separated from thecase 11 in a direction away from theelectrode assembly 12.

It can be understood that the limitingportion 117 is located at one end of thecylinder 113 of thehousing 11 away from theoutput portion 114.

The limitingportion 117 may be a flanged structure that thehousing 11 is partially folded inward, that is, the limitingportion 117 may be formed at the position of theopening 111 of thehousing 11 by folding thehousing 11, and the forming is simple.

In the process of assembling thesingle battery 10, the current collectingmember 14 may be accommodated in thecase 11 and connected to theelectrode assembly 12 and thecase 11, theend cap 13 may be covered on theopening 111 of thecase 11, and the limitingportion 117 may be formed by folding thecase 11 to limit theend cap 13.

In order to enable the limitingportion 117 to have a better limiting capability for theend cap 13, the limitingportion 117 may be configured as an annular structure. Of course, theannular stopper 117 is more easily sealed with theend cap 13.

In some embodiments, at least a portion of theend cap 13 is located between the limitingportion 117 and the current collectingmember 14 in the thickness direction Z of theend cap 13, and the limitingportion 117 and the current collectingmember 14 together limit the movement of theend cap 13 in the thickness direction Z, so that theend cap 13 is not easily moved in the thickness direction Z of thehousing 11 in thehousing 11.

Illustratively, in fig. 5, a portion of theend cover 13 is located between thestopper portion 117 and thefirst connection portion 141 of the current collectingmember 14 in the thickness direction Z of theend cover 13.

Thestopper 117 and the current collectingmember 14 both restrict theend cap 13. The current collectingmember 14 may directly or indirectly abut against theend cover 13, and thestopper 117 may directly or indirectly abut against theend cover 13 to restrict the movement of theend cover 13 in the thickness direction Z. Illustratively, in fig. 5, theend cap 13 abuts against thestopper 117 via theseal 15.

In other embodiments, in the thickness direction Z of theend cover 13, at least a part of theend cover 13 is located between the limitingportion 117 and thestep surface 116, and the limitingportion 117 and thestep surface 116 together limit the movement of theend cover 13 in the thickness direction Z, so that theend cover 13 is not easy to move in the thickness direction Z of thehousing 11 in thehousing 11.

The limitingportion 117 and thestep surface 116 both limit theend cap 13. Thestopper 117 may directly or indirectly abut against theend cap 13, and the steppedsurface 116 may directly or indirectly abut against theend cap 13 to restrict the movement of theend cap 13 in the thickness direction Z.

In some embodiments, with continued reference to fig. 5, in the case that theend cap 13 is connected to thehousing 11 by the sealingmember 15, the sealingmember 15 may be wrapped around theend cap 13 along the circumference of theopening 111 of thehousing 11. This configuration improves, on the one hand, the sealing of theend cap 13 with thehousing 11 by theseal 15 and, on the other hand, the integrity of theseal 15 with thehousing 11. In the process of assembling thebattery cell 10, theend cap 13 may be covered with theseal 15, and theend cap 13 and theseal 15 may be mounted to thecase 11 as a whole.

In some embodiments, in the case that the limitingportion 117 is disposed at one end of theopening 111 of thehousing 11, at least a part of the sealingmember 15 is located between theend cover 13 and the limitingportion 117 in the thickness direction Z of theend cover 13, so as to achieve the sealing connection between theend cover 13 and thehousing 11, and ensure good sealing performance between theend cover 13 and thehousing 11.

In some embodiments, the sealingmember 15 may include anenclosure 151 and a third connectingportion 152, the third connectingportion 152 being connected to theenclosure 151. At least a part of theend cover 13 is located in theenclosure 151, and in the thickness direction Z of theend cover 13, the third connectingportion 152 is located between theend cover 13 and the limitingportion 117, so as to realize the sealing connection between theend cover 13 and thehousing 11.

Since theend cap 13 is at least partially located within theenclosure 151, it is achieved that theseal 15 is wrapped around theend cap 13 in the circumferential direction of theopening 111 of thehousing 11. Since the third connectingportion 152 is located between theend cover 13 and the limitingportion 117, theend cover 13 and thehousing 11 are hermetically connected, and even if theend cover 13 and the collectingmember 14 are not hermetically sealed, liquid leakage does not occur between theend cover 13 and thehousing 11. The sealingmember 15 has a simple structure, and the sealingmember 15 and theend cover 13 have good integrity while achieving good sealing between theend cover 13 and thehousing 11.

In the case where the sealingmember 15 has an insulating property, both theenclosure 151 and the third connectingportion 152 of the sealingmember 15 may serve as an insulator between theend cap 13 and thehousing 11.

Illustratively, theend cap 13 presses the second connectingportion 142 of the current collectingmember 14 against theinner side 115 of thehousing 11 through theenclosure 151 of theseal 15. The third connectingportion 152 and the limitingportion 117 are both annular structures, and the inner diameter of the third connectingportion 152 is smaller than that of the limitingportion 117.

In some embodiments, referring to fig. 6, fig. 6 is a partially enlarged view of abattery cell 10 provided in some embodiments of the present application, and the sealingmember 15 may further include afourth connection portion 153, and theenclosure 151, thethird connection portion 152 and thefourth connection portion 153 are sequentially connected. Theend cap 13 includes abody portion 132 and anextension portion 133, theextension portion 133 extends from thebody portion 132 in a direction away from theelectrode assembly 12, theenclosure 151 is located outside theextension portion 133, thefourth connection portion 153 is located inside theextension portion 133, and thethird connection portion 152 is located between theextension portion 133 and thestopper portion 117 in the thickness direction Z of theend cap 13. Thestopper 117 is provided with abent portion 118, thebent portion 118 is bent toward theelectrode assembly 12 relative to thestopper 117, and the fourth connectingportion 153 is located between the extendingportion 133 and thebent portion 118. Thestopper 117 presses the third connectingportion 152 against the extendingportion 133, and thebent portion 118 presses the fourth connectingportion 153 against the extendingportion 133. This structure can further improve the sealing property between theend cap 13 and thehousing 11.

Illustratively, the third connectingportion 152, the limitingportion 117 and the fourth connectingportion 153 are all annular structures.

In this embodiment, thehousing 11 may be provided with thestep surface 116, or may not be provided with thestep surface 116. Illustratively, in fig. 6, thehousing 11 is not provided with thestep surface 116.

It should be noted that, in the embodiment of the present application, the sealingmember 15 is not limited to the above-described structure, and the sealingmember 15 may have another structure. For example, the sealingmember 15 includes only theenclosure 151, theenclosure 151 has an open structure at both ends, theenclosure 151 covers the outer periphery of theend cap 13, theenclosure 151 abuts against theouter side surface 131 of theend cap 13 and theinner side surface 115 of thecase 11, or theenclosure 151 abuts against theouter side surface 131 of theend cap 13 and thesecond connection portion 142 of the current collectingmember 14, thereby sealing thecase 11 and theend cap 13. For another example, the sealingmember 15 includes only the third connectingportion 152, and the third connectingportion 152 is located between the limitingportion 117 and theend cover 13 in the thickness direction Z of theend cover 13, so as to achieve the sealing between thehousing 11 and theend cover 13.

It should be noted that, in the embodiment of the present application, the steppedsurface 116 of thehousing 11 may have various forms. For example, as shown in fig. 5, a portion of thehousing 11 near theopening 111 protrudes laterally, so that the inner diameter of the protruding portion of thehousing 11 is larger than the inner diameter of the portion of thehousing 11 that does not protrude, thereby forming astep surface 116; for another example, referring to fig. 7, fig. 7 is a partial enlarged view of abattery cell 10 according to still another embodiment of the present disclosure, in which a second limitingprotrusion 119 is formed in a partial concave of acase 11, a necking structure is formed at a position of the second limitingprotrusion 119 of thecase 11, the second limitingprotrusion 119 is used for limiting amain body 121 of anelectrode assembly 12 to move towards a direction close to anend cap 13, and astep surface 116 is formed at a side of the second limitingprotrusion 119 away from theelectrode assembly 12. Illustratively, thesecond limit projection 119 is an annular structure.

In some embodiments, referring to fig. 8, fig. 8 is a partial view of thebattery cell 10 shown in fig. 4, thebattery cell 10 may further include an insulatingmember 18, in a thickness direction Z of theend cover 13, the insulatingmember 18 is located between thefirst tab 122 and theend cover 13, and a projection of the insulatingmember 18 along the thickness direction Z of theend cover 13 covers thefirst tab 122. Theinsulator 18 serves to isolate theend cap 13 from thefirst tab 122, reducing the risk of charging theend cap 13.

The projection of theinsulator 18 in the thickness direction Z of theend cover 13 covers thefirst tab 122, i.e., the projection of theinsulator 18 in the thickness direction Z of theend cover 13 covers the end face of thefirst tab 122 remote from the main body 121 (the end face of thefirst tab 122 connected to the current collecting member 14). Taking thefirst tab 122 as an example of a cylindrical structure, a projection of theinsulator 18 in the thickness direction Z of theend cover 13 covers an annular end surface of thefirst tab 122 away from themain body 121.

Theinsulator 18 may be rubber, plastic, or the like.

In some embodiments, aninsulator 18 is located at least partially between the current collectingmember 14 and theend cap 13 in the thickness direction Z of theend cap 13 to insulate the current collectingmember 14 from theend cap 13.

Illustratively, theinsulator 18 is partially positioned between thefirst connection portion 141 of the current collectingmember 14 and theend cover 13 in the thickness direction Z of theend cover 13 to insulate and isolate the current collectingmember 14 from theend cover 13. The insulatingmember 18 is provided with a first throughhole 181, the first connectingportion 141 is provided with a second throughhole 143, the first throughhole 181 and the second throughhole 143 are both opened to thecentral hole 124 of themain body 121 of theelectrode assembly 12, and the first throughhole 181 and the second throughhole 143 are both disposed opposite to thepressure relief mechanism 16, so that the pressure inside thebattery cell 10 is relieved through thepressure relief mechanism 16 when the internal pressure or temperature of thebattery cell 10 reaches a threshold value.

As shown in fig. 8, both theinsulator 18 and theseal 15 may be independent of each other, i.e. theinsulator 18 and theseal 15 are two separate parts. In another embodiment, referring to fig. 9, fig. 9 is a partial view of thebattery cell 10 according to another embodiment of the present disclosure, and the insulatingmember 18 and the sealingmember 15 may also be integrally formed, that is, the insulatingmember 18 and the sealingmember 15 are integrally formed. Illustratively, in the thickness direction Z of theend cap 13, the insulatingmember 18 and the third connectingportion 152 are respectively located at two ends of theenclosure 151, and the insulatingmember 18 and the third connectingportion 152 jointly limit theend cap 13 from being separated from the sealingmember 15.

Referring to fig. 10, fig. 10 is a flowchart of a method for manufacturing abattery cell 10 according to some embodiments of the present disclosure, where the method includes:

s100: providing ahousing 11, thehousing 11 having anopening 111;

s200: providing anelectrode assembly 12;

s300: providing anend cap 13;

s400: providing a current collectingmember 14;

s500: connecting the current collectingmember 14 to theelectrode assembly 12;

s600: theelectrode assembly 12 and the current collectingmember 14 are accommodated in thecase 11;

s700: connecting the current collectingmember 14 to thecase 11 to electrically connect theelectrode assembly 12 with thecase 11;

s800: theend cap 13 is fitted to theopening 111 of thecase 11 and theend cap 13 is sealingly connected to thecase 11 such that the current collectingmember 14 is located on the side of theelectrode assembly 12 facing theend cap 13.

In the above method, the order of step S100, step S200, step S300, and step S400 is not limited, for example, step S400, step S300, step S200, and step S100 may be executed first, then step S300, and then step S200 may be executed.

In some embodiments, step S700 may include: welding the current collectingmember 14 to thecase 11 from the inside of thecase 11; wherein the melting point of the current collectingmember 14 is lower than that of thecase 11.

Since the melting point of the current collectingmember 14 is lower than that of thecase 11, the current collectingmember 14 is welded to thecase 11 from the inside of thecase 11, so that thecase 11 is less prone to be broken down, and the risk of liquid leakage from thecase 11 is effectively reduced.

In some embodiments, referring to fig. 11, fig. 11 is a flowchart of a method for manufacturing abattery cell 10 according to still other embodiments of the present disclosure, after theend cap 13 is covered on theopening 111, the method may further include:

s900: thecase 11 is subjected to a burring process such that thecase 11 forms astopper 117 at an end where theopening 111 is provided, so that thestopper 117 restricts theend cap 13 from being detached from thecase 11 in a direction away from theelectrode assembly 12.

The limitingpart 117 is formed in a flanging mode to limit theend cover 13 to be separated from theshell 11 along the direction departing from theelectrode assembly 12, the implementation mode is simple, and the manufacturing cost can be effectively reduced.

It should be noted that, for the structure of thesingle battery 10 manufactured by the manufacturing method provided in the foregoing embodiments, reference may be made to thesingle battery 10 provided in the foregoing embodiments, and details are not repeated herein.

In addition, amanufacturing apparatus 2000 of abattery cell 10 is further provided in embodiments of the present application, please refer to fig. 12, where fig. 12 is a schematic block diagram of themanufacturing apparatus 2000 of thebattery cell 10 provided in some embodiments of the present application, and themanufacturing apparatus 2000 includes a first providingdevice 1100, asecond providing device 1200, a third providingdevice 1300, a fourth providingdevice 1400, and anassembling device 1500.

The first providingdevice 1100 is used to provide thehousing 11, and thehousing 11 has anopening 111. A second providingdevice 1200 for providing theelectrode assembly 12. Third providing means 1300 for providing theend cap 13. A fourth providingdevice 1400 for providing a current collectingmember 14. Anassembly device 1500 for connecting the current collectingmember 14 to theelectrode assembly 12; theelectrode assembly 12 and the current collectingmember 14 are accommodated in thecase 11; connecting the current collectingmember 14 to thecase 11 to electrically connect theelectrode assembly 12 to thecase 11; theend cap 13 is fitted to theopening 111 and theend cap 13 is hermetically connected to thecase 11 such that the current collectingmember 14 is located at a side of theelectrode assembly 12 facing theend cap 13.

It should be noted that, with regard to the structure of thebattery cell 10 manufactured by themanufacturing apparatus 2000 provided in the foregoing embodiments, reference may be made to thebattery cell 10 provided in each of the foregoing embodiments, and details are not repeated herein.

It should be noted that the embodiments and features of the embodiments in the present application may be combined with each other without conflict.

The above embodiments are merely for illustrating the technical solutions of the present application and are not intended to limit the present application, and those skilled in the art can make various modifications and variations of the present application. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (24)

1. A battery cell, comprising:

a housing having an opening;

an electrode assembly housed within the case;

the end cover is covered on the opening and is connected with the shell in a sealing way; and

a current collecting member received in the case on a side of the electrode assembly facing the end cap, the current collecting member being configured to connect the case and the electrode assembly to electrically connect the electrode assembly with the case;

the end cover is connected with the shell in a sealing mode through the sealing piece.

2. The battery cell as recited in claim 1 wherein the current collecting member is connected to an inside face of the case.

3. The battery cell of claim 2, wherein an outer side of the end cap is disposed opposite an inner side of the housing;

at least a portion of the current collecting member is positioned between an outer side of the end cap and an inner side of the housing, and the end cap is configured to press a portion of the current collecting member against the inner side of the housing.

4. The battery cell according to claim 1, wherein the current collecting member includes a first connecting portion and a second connecting portion;

in a thickness direction of the end cap, the first connection portion is at least partially located between the end cap and the electrode assembly, the first connection portion being configured to be connected to the electrode assembly;

the second connection portion is connected to the first connection portion and extends from the first connection portion away from the electrode assembly in a thickness direction of the end cap, the second connection portion being configured to be connected to the case.

5. The battery cell according to claim 4, wherein the second connection portion is a ring-shaped structure connected to an outer edge of the first connection portion.

6. The battery cell as recited in claim 1, wherein the housing is provided with a stopper at one end of the opening;

the stopper is configured to restrict the end cap from coming off the case in a direction away from the electrode assembly.

7. The battery cell as recited in claim 6 wherein the end cap is at least partially positioned between the stopper and the current collecting member in a thickness direction of the end cap, the stopper and the current collecting member cooperating to restrict movement of the end cap in the thickness direction of the end cap.

8. The battery cell as recited in claim 6 wherein the limiting portion is an annular structure.

9. The battery cell as recited in claim 6, wherein the limiting portion is a flanging structure that is partially folded inwards.

10. The battery cell of any of claims 1-9, wherein the inner surface of the housing comprises a step surface;

the current collecting member abuts against the step face in a direction facing the electrode assembly.

11. The battery cell of any of claims 1-9, wherein the seal is configured to insulate the housing from the end cap.

12. The battery cell as recited in any of claims 1-9, wherein the seal member is configured to wrap around the end cap along a circumference of the opening.

13. The battery cell according to any one of claims 1 to 9, wherein the housing is provided with a stopper portion at one end of the opening, and the sealing member is located at least partially between the end cap and the stopper portion in a thickness direction of the end cap to achieve the sealed connection between the end cap and the housing.

14. The battery cell as recited in claim 13 wherein the seal member comprises a surrounding body and a third connecting portion, the third connecting portion being connected to the surrounding body;

at least one part of the end cover is positioned in the enclosure, and the third connecting part is positioned between the end cover and the limiting part in the thickness direction of the end cover so as to realize the sealing connection of the end cover and the shell.

15. The battery cell of any of claims 1-9, wherein the electrode assembly includes a first tab configured to connect with the current collecting member;

the single battery also comprises an insulating piece, wherein in the thickness direction of the end cover, the insulating piece is positioned between the first pole lug and the end cover, and the projection of the insulating piece along the thickness direction of the end cover covers the first pole lug.

16. The battery cell according to any of claims 1-9, wherein the current collecting member is welded to the case.

17. The battery cell as recited in claim 16 wherein the current collecting member has a melting point lower than the melting point of the housing.

18. The battery cell of any of claims 1-9, further comprising a pressure relief mechanism;

the pressure relief mechanism is arranged on the end cover and is configured to be actuated to relieve the internal pressure when the internal pressure or temperature of the battery cell reaches a threshold value.

19. A battery comprising a plurality of cells according to any one of claims 1 to 18.

20. An electric device comprising a battery cell according to any one of claims 1-18.

21. A method of manufacturing a battery cell, comprising:

providing a housing having an opening;

providing an electrode assembly;

providing an end cap;

providing a current collecting member;

connecting a current collecting member to the electrode assembly;

receiving the electrode assembly and the current collecting member in the case;

connecting the current collecting member to the case to electrically connect the electrode assembly with the case;

covering the end cap with the opening and hermetically connecting the end cap with the case such that the current collecting member is located at a side of the electrode assembly facing the end cap;

wherein the end cap is connected with the shell in a sealing manner through a sealing element.

22. The method of manufacturing of claim 21, wherein the connecting the current collecting member to the housing comprises:

welding the current collecting member to the case from the inside of the case;

wherein a melting point of the current collecting member is lower than a melting point of the case.

23. The manufacturing method according to claim 21 or 22, characterized by further comprising:

after the end cover is covered on the opening, the shell is subjected to flanging treatment, so that a limiting part is formed at one end, provided with the opening, of the shell, and the limiting part limits the end cover to be separated from the shell along the direction departing from the electrode assembly.

24. An apparatus for manufacturing a battery cell, comprising:

a first providing device for providing a housing having an opening;

second providing means for providing an electrode assembly;

third providing means for providing an end cap;

fourth providing means for providing a current collecting member;

an assembly device for connecting a current collecting member to the electrode assembly; receiving the electrode assembly and the current collecting member in the case; connecting the current collecting member to the case to electrically connect the electrode assembly with the case; covering the end cap with the opening and hermetically connecting the end cap with the case such that the current collecting member is located at a side of the electrode assembly facing the end cap;

wherein the end cap is connected with the shell in a sealing manner through a sealing element.

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