Patent Description:
A chemical battery, electrochemical battery, or electrochemical cell refers to a type of apparatus that converts chemical energy of positive and negative electrode active materials into electric energy through a redox reaction. Unlike an ordinary redox reaction, oxidation and reduction reactions are carried out separately, with the oxidation reaction taking place at a negative electrode and the reduction reaction taking place at a positive electrode, and gain and loss of electrons are carried out through an external circuit, and thus a current is formed. This is an essential characteristic of all batteries. After long-term research and development, the chemical battery has ushered in a situation of great varieties and wide applications, for example, it may be a huge device that can fit in a building, or a small device in millimeter. With the development of modern electronic technology, high requirements are put forward for the chemical battery. Every breakthrough in chemical battery technology brings revolutionary development of an electronic device. Many electrochemical scientists in the world have focused their research and development interests in the field of chemical batteries that power electric automobiles.

As a kind of chemical battery, a lithium-ion battery has advantages of small size, high energy density, high power density, multiple recycle times, long storage time, and the like, and has been widely applied in some electronic devices, electric vehicles, electronic toys and electric devices. For example, currently, the lithium-ion battery is widely applied in mobile phones, notebook computers, electromobiles, electric automobiles, electric airplanes, electric ships, electric toy cars, electric toy ships, electric toy aircrafts, electric tools, or the like.

With the continuous development of lithium-ion battery technology, higher requirements are put forward for performance of lithium-ion battery. It is hoped that design factors in multiple aspects can be simultaneously considered for the lithium-ion battery.

<CIT> provides a power source device, which is composed of a plurality of batteries <NUM> having a safety valve <NUM> housed in a case <NUM>. The case <NUM> is divided into a battery chamber <NUM> housing the plurality of batteries <NUM> and an exhaustion chamber <NUM> exhausting the gas exhausted from the safety valve <NUM> of the batteries <NUM> housed in the battery chamber <NUM>, by a separation wall <NUM>. An opening part <NUM> of the safety valve of the batteries <NUM> housed in the battery chamber <NUM> are arranged to communicate with the exhaustion chamber <NUM>. On the power source device, the safety valve <NUM> is opened, and the gas exhausted from the safety valve <NUM> flows into the exhaustion chamber <NUM> without flowing into the battery chamber <NUM>, and exhausted to the outside of the case <NUM> from the exhaustion chamber <NUM>. The safety of the power source device can be improved by reducing influence affected by an over-heated battery to the utmost even when the battery gets into abnormal state, effectively jetting fire extinguishing agent in the battery case from a fire extinguisher by exactly and quickly detecting the abnormality of the battery and by making the fire extinguisher operate with a simple structure.

<CIT> provides various embodiments of energy storage devices. The apparatus comprises a sealed container configured to house a plurality of energy storage devices and enable electrical communication across the container; a vent device configured along a portion of the container, the vent device comprises a circular countersink extending perimetrically adjacent to an edge of a substrate to define a central panel, the countersink, and an outer edge, and a score configured on an outer surface of the substrate and positioned within the countersink, such that the container is configured to vent via a snap-through buckling event triggered by the countersink, where the countersink is configured to fracture the score along the score region when the pressure in the container exceeds a predetermined value.

<CIT> relates to a high-density battery pack. The battery packs include a plurality of cell blocks, each cell block comprising a plurality of battery cells. The battery pack also includes a plenum chamber configured to fluidly couple each of the cell blocks to an exterior of the battery pack in response to a thermal event in the battery cell in a separate cell block. In some embodiments, at least one of the cell blocks is configured to be fluidly coupled to the plenum structure via a cell block vent. <CIT> and <CIT> also disclose busbar arrangements for battery packs.

The accompanying drawings described herein are used to provide further understanding of the present application and constitute part of the present application, and the exemplary embodiments of the present application and the description thereof are used to illustrate the present application and do not constitute an undue limitation to the present application. In the drawings:.

To make the objectives, technical solutions and advantages of the present application clearer, the technical solutions in embodiments of the present application will be clearly and completely described below with reference to the accompanying drawings for a plurality of embodiments according to the present application.

Unless otherwise defined, all technical and scientific terms used in the present application have the same meanings as those commonly understood by those skilled in the technical art to which the present application belongs. The terms used in the specification of the present application are merely for the purpose of describing specific embodiments, but are not intended to limit the present application. The terms "comprising", "including", "having", "possessing", "containing", "involving" and the like in the specification, claims and the foregoing description of the accompanying drawings of the present application are open words. Therefore, a method or apparatus "comprising", "including" or "having" one or more steps or elements for example has one or more steps or elements, but is not limited to merely having the one or more elements. The terms "first", "second" and the like in the specification and the claims or the foregoing accompanying drawings of the present application are intended to distinguish between different objects, rather than to describe a specific order or primary-secondary relationship. In addition, the terms "first" and "second" are only intended for a purpose of description, and shall not be understood as an indication or implication of relative importance or implicit indication of the quantity of indicated technical features. Therefore, a feature limited by "first" or "second" may explicitly or implicitly include one or more features. In the description of the present application, unless otherwise provided, "a plurality of" means two or more than two.

In the description of the present application, it should be understood that orientations or positional relationships indicated by terms such as "center", "crosswise", "length", "width", "up", "down", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inside", "outside", "axial direction", "radial direction" and "circumferential direction" are orientations or positional relationships shown based on the drawings, and the terms are merely for convenience of describing the present application and for simplifying the description, rather than for indicating or implying that an apparatus or element referred to must have a specific orientation, and must be constructed and operated in a specific orientation, which thus may not be understood as a limitation to the present application.

In the description of the present application, it should be noted that, unless explicitly specified and defined otherwise, terms "installation", "interconnection", "connection" and "attachment" should be understood broadly, for example, they may either be a fixed connection, or a detachable connection, or an integrated connection; and they may either be a direct connection, or an indirect connection through an intermediary, and may be an connection between interiors of two elements. Those of ordinary skill in the art may understand specific meanings of the foregoing terms in the present application according to specific conditions.

The phrase "embodiments" referred to in the present application means that the specific features, structures, and characteristics described with reference to the embodiments may be included in at least one embodiment of the present application. The phrase at various locations in the specification does not necessarily refer to the same embodiment, or an independent or alternative embodiment exclusive of another embodiment. Those skilled in the art understand, in explicit and implicit manners, that the embodiments described in the present application may be combined with another embodiment.

As described above, it should be emphasized that the term "comprising/including", when used in this specification, is used to clearly specify the presence of stated features, integers, steps or components, but do not preclude the presence or addition of one or more other features, integers, steps, or components or groups of features, integers, steps or components. As used in the present application, the singular form "a", "an" and "the" include plural forms unless the context clearly dictates otherwise.

The terms "a" and "an" in this specification can mean one, but may have the same meaning as "at least one" or "one or more". The term "about" generally means plus or minus <NUM>%, or more specifically plus or minus <NUM>%, of the mentioned value. The term "or" used in the claims means "and/or" unless it is clearly stated that it only refers to an alternative solution.

The term "and/or" in the present application merely describes an association relationship between associated objects and indicates that here may be three relationships. For example, A and/or B may indicate the following three cases: only A exists, both A and B exist, and only B exists. In addition, the character "/" in the present application generally indicates that the associated previous and next objects are in the relationship of "or".

A battery mentioned in the art can be divided into a primary battery and a rechargeable battery according to whether it is rechargeable. The primary battery is also called a "disposable" battery and a galvanic battery, because after its power is exhausted, it cannot be recharged and can only be discarded. The rechargeable battery is also called a secondary battery, a second-level battery, or a storage battery. The rechargeable battery is different from the primary battery in manufacturing material and process, and has an advantage that it can be recycled multiple times after being charged, and output current load capacity of the rechargeable battery is higher than that of most primary batteries. At present, common types of rechargeable batteries are: a lead-acid battery, a nickel-metal hydride battery (Ni-MH battery) and a lithium-ion battery. The lithium-ion battery has advantages such as light weight, large capacity (<NUM> to <NUM> times that of Ni-MH of the same weight), and no memory effect, and has a very low self-discharge rate, so even if its price is relatively high, it still gets widely used. At present, the lithium-ion battery is also widely used in battery electric vehicles and hybrid vehicles. The lithium-ion battery for this purpose has a relatively low capacity, but has a larger output and charging current, and a longer service life, but a higher cost.

A battery described in embodiments of the present application refers to a rechargeable battery. Hereinafter, a lithium-ion battery will be mainly used as an example to describe the embodiments disclosed in the present application. It should be understood that the embodiments disclosed in the present application are applicable to any other suitable type of rechargeable battery. The battery mentioned in the embodiments disclosed in the present application can be directly or indirectly applied to an appropriate apparatus to power the apparatus.

The battery mentioned in the embodiments disclosed in the present application refers to a single physical module that includes one or more battery cells to provide a predetermined voltage and capacity. A battery cell is a basic unit in a battery, and can be generally divided into a cylindrical battery cell, a prismatic battery cell and a pouch battery cell according to the way of packaging. The following will mainly focus on a prismatic battery cell. It should be understood that the embodiments described below are also applicable to a cylindrical battery cell or a pouch battery cell in certain aspects.

The battery cell includes a positive electrode sheet, a negative electrode sheet, an electrolytic solution and an isolation film. The operation of a lithium-ion battery cell mainly relies on movement of lithium ions between the positive electrode sheet and the negative electrode sheet. For example, the lithium-ion battery cell uses one embedded lithium compound as one electrode material. Currently, main common cathode materials used as a lithium-ion battery are: lithium cobalt oxide (LiCoO<NUM>), lithium manganese oxide (LiMn<NUM>O<NUM>), lithium nickel oxide (LiNiO<NUM>) and lithium iron phosphate (LiFePO<NUM>). The isolation film is disposed between the positive electrode sheet and the negative electrode sheet to form a thin film structure with three layers of materials. The thin film structure is generally made into an electrode assembly with a desired shape by winding or stacking. For example, a thin film structure of three layers of materials in a cylindrical battery cell is wound into an electrode assembly in a cylindrical shape, while in a prismatic battery cell the thin film structure is wound or stacked into an electrode assembly in a substantially cuboid shape.

In a typical battery cell structure, a battery cell includes a box, an electrode assembly and an electrolytic solution. The electrode assembly is accommodated in the box of the battery cell, and the electrode assembly includes a positive electrode sheet, a negative electrode sheet and an isolation film. The material of the isolation film may be PP or PE, etc. The electrode assembly may be a coiled structure or a laminated structure. The box includes a housing and a cover plate. The housing includes an accommodation chamber formed by a plurality of walls and an opening. The cover plate is arranged at the opening to close the accommodation chamber. In addition to the electrode assembly, the accommodation chamber also accommodates the electrolytic solution. The positive electrode sheet and the negative electrode sheet in the electrode assembly include electrode tabs. Specifically, the positive electrode sheet includes a positive electrode current collector and a positive electrode active material layer. The positive electrode active material layer is coated on a surface of the positive electrode current collector, and the positive electrode current collector not coated with the positive electrode active material layer protrudes from the positive electrode current collector coated with the positive electrode active material layer and serves as a positive electrode tab. A material of the positive electrode current collector may be aluminum, and the positive electrode active material may be lithium cobalt oxides, lithium iron phosphate, ternary lithium or lithium manganate, etc. The negative electrode sheet includes a negative electrode current collector and a negative electrode active material layer. The negative electrode active material layer is coated on a surface of the negative electrode current collector, and the negative electrode current collector not coated with the negative electrode active material layer protrudes from the negative electrode current collector coated with the negative electrode active material layer and serves as a negative electrode tab. The material of the negative electrode current collector may be copper, and the negative electrode active material may be carbon or silicon, etc. In order to ensure that no fusing occurs when a large current passes, there are a plurality of positive electrode tabs which are stacked together, and there are a plurality of negative electrode tabs which are stacked together. The electrode tabs are electrically connected with a positive electrode terminal and a negative electrode terminal located outside the battery cell through a connecting member. For a prismatic battery cell, the electrode terminal is generally provided on a portion of a cover plate. A plurality of battery cells are connected in series and/or in parallel via electrode terminals for various applications.

In some high-power applications such as electric vehicles, application of a battery includes three levels: a battery cell, a battery module, and a battery pack. The battery module is formed by electrically connecting a certain number of battery cells together and putting them in a frame in order to protect the battery cells from external impact, heat, vibration, etc. The battery pack is the final state of a battery system installed in an electric automobile. The battery pack generally includes a case configured to package one or more battery cells. The case can prevent liquid or other foreign objects from affecting the charging or discharging of battery cells. The case is generally composed of a cover body and a case shell. Most of current battery packs are made by assembling various control and protection systems such as a battery management system (BMS) and a thermal management component on one or more battery modules. With the development of technology, the level of battery module can be omitted, that is, a battery pack can be directly formed from battery cells. This improvement allows the battery system to significantly reduce the number of components while increasing weight energy density and volume energy density. The battery mentioned in the present application includes a battery module or a battery pack.

Generally, in addition to battery cells, a battery also includes a cover body, an insulating part, and a battery management unit. A bus component configured to electrically connect the battery cells is usually arranged between the cover body and the battery cells. This arrangement makes the overall volume of the battery larger. Moreover, the bus component is usually enclosed in the case, and thus the battery management unit electrically connected with the bus component also needs to be installed in the case of the battery (the cover body is, for example, a portion of the case), so that the volume of the case of the battery is large, and the battery management unit is sealed in the case, which is not convenient for subsequent maintenance and replacement.

For researchers and those skilled in the art, to change the design concept of the bus component installed between the cover body and the battery cells, it is necessary to solve various technical problems and overcome technical prejudices, and it is not achieved overnight.

In order to solve this problem, it is easy for many researchers to think of increasing the degree of detachability of the case, so as to facilitate subsequent opening of the case to maintain the battery management unit to solve this technical problem. That is, due to technical prejudice caused by the existence of the above-mentioned various problems or other various problems, those skilled in the art will not easily think of embedding the bus component in the cover body to solve this problem. This is also because such a modification of the design is too risky and too difficult, and this risk and difficulty hinder researchers from changing the installation method of the bus component.

In order to solve or at least partially solve the above-mentioned problems and other potential problems of the battery in the prior art, the inventor of the present application goes the other way and proposes a novel battery after conducting a lot of research and experiments. Applicable apparatuses for the battery described in the embodiments of the present application include, but are not limited to: mobile phones, portable devices, notebook computers, electromobiles, electric vehicles, ships, spacecrafts, electronic toys, electric tools, and the like. For example, the spacecrafts include airplanes, rockets, space shuttles, spaceships, and the like; the electronic toys include fixed or mobile electronic toys, such as game consoles, electric car toys, electric ship toys, electric aircraft toys, and the like; and the electric tools include electric metal cutting tools, electric grinding tools, electric assembling tools and electric railway tools, such as electric drills, electric grinders, electric spanners, electric screwdrivers, electric hammers, electric impact drills, concrete vibrators, and electric planers.

For example, as shown in <FIG>, the figure is a simplified schematic diagram of a vehicle <NUM> according to an embodiment of the present application. The vehicle <NUM> may be a fuel-powered vehicle, a gas-powered vehicle or a new-energy vehicle. The new-energy vehicle may be a battery electric vehicle, a hybrid vehicle or an extended-range vehicle, or the like. A battery <NUM> may be provided inside the vehicle <NUM>, for example, the battery <NUM> may be provided at the bottom, head or tail of the vehicle <NUM>. The battery <NUM> may be used for power supply to the vehicle <NUM>. For example, the battery <NUM> may serve as an operation power supply of the vehicle <NUM>. In addition, the vehicle <NUM> may further include a controller <NUM> and a motor <NUM>. The controller <NUM> is configured to control the battery <NUM> to supply power to the motor <NUM>, for example, for a working power demand of the vehicle <NUM> during startup, navigation, and running. In another embodiment of the present application, the battery <NUM> can be serve not only as an operation power supply of the vehicle <NUM>, but also as a driving power supply of the vehicle <NUM>, replacing or partially replacing fuel or natural gas to provide driving power for the vehicle <NUM>.

<FIG> and <FIG> respectively show exploded views of a battery according to embodiments of the present application, respectively. As shown in <FIG> and <FIG>, the battery <NUM> includes a plurality of battery cells <NUM> and a bus component <NUM> configured to electrically connect the plurality of battery cells <NUM>. In order to protect the battery cells <NUM> from invasion or corrosion of external liquid or foreign objects, the battery <NUM> includes a case <NUM> for packaging the plurality of battery cells and other necessary components, as shown in <FIG> and <FIG>. In some embodiments, the case <NUM> may include a cover body <NUM> and a case shell <NUM>. The cover body <NUM> and the case shell <NUM> are combined together in a sealing manner to collectively enclose and form an electrical chamber configured to accommodate the plurality of battery cells <NUM>.

The bus component <NUM> may also be embedded in the cover body <NUM>, and <FIG> show schematic diagrams of the bus component <NUM> embedded in the cover body <NUM>. As shown in the figures, the cover body <NUM> may include an accommodation space 111a, and the accommodation space 111a is capable of accommodating the bus component <NUM>. In some embodiments, the accommodation space 111a may be a through hole formed on the cover body <NUM>. The bus component <NUM> may be fixed in the through hole in an appropriate manner. For example, the bus component <NUM> may be loaded into a mold before the cover body <NUM> is molded, so that the bus component <NUM> can be embedded in the cover body <NUM> after the cover body <NUM> is formed.

It should be understood that the bus component <NUM> is arranged at a position of the cover body <NUM> that is corresponding to an electrode terminal <NUM> (including a positive electrode terminal 214a and a negative electrode terminal 214b) of the battery cells <NUM>. After the battery cells <NUM> in the case <NUM> are put in place, the cover body <NUM> may be directly assembled to the case shell <NUM>, and then the bus component <NUM> is electrically connected with the electrode terminal <NUM> of the battery cells <NUM> in a fixing manner such as welding, such as laser welding or ultrasonic welding. Then, an insulating part <NUM> attached to the cover body <NUM> is used to cover at least the bus component <NUM>, thereby forming the packaged case <NUM>.

In some embodiments, the insulating part <NUM> may be a sheet or thin plate-shaped structure, and the material of the insulating part <NUM> may be PP, PE or PET, etc.; in some other embodiments, the insulating part <NUM> may also be insulating glue or insulating paint, etc..

In some embodiments, the insulating part <NUM> may be applied or assembled to the cover body <NUM>. For example, after the bus component <NUM> is electrically connected to the electrode terminal <NUM> of the battery cells <NUM>, the insulating part <NUM> may be formed by coating an insulating layer on a position of the cover body <NUM> having the bus component <NUM>. In some alternative embodiments, the insulating part <NUM> may also be a component that is assembled to the cover body <NUM> to cover at least the insulating part <NUM>. The insulating part <NUM> and the cover body <NUM> may be assembled in a sealing manner to ensure the sealing of the case <NUM>. In some embodiments, the coated insulating layer or the assembled insulating part <NUM> may also cover the entire outer surface of the cover body <NUM>.

In some embodiments, the insulating part <NUM> may also be integrally formed with the cover body <NUM>. For example, the insulating part <NUM> may be formed as a portion of the cover body <NUM> protruding from the outer surface, and an accommodation space 111a is formed inside the portion to accommodate the bus component <NUM>. In these embodiments, the bus component <NUM> may also be embedded in the cover body <NUM> by means such as molding or later assembled into the cover body <NUM> after the cover body <NUM> is formed. In the latter case mentioned, the bus component <NUM> may be electrically connected to the electrode terminal <NUM> of the battery cells <NUM> by means of resistance welding or the like.

According to the arrangement of embedding the bus component <NUM> into the cover body <NUM> described in the above embodiment, it is possible to greatly reduce the volume of the battery <NUM> without affecting safety of the battery <NUM> or even improving the safety of the battery, thereby improving volume energy density of the battery <NUM>. In addition, this manner can also reduce the difficulty of assembling the battery <NUM>, thereby reducing assembly costs. In addition, embedding the bus component <NUM> into the cover body <NUM> can also realize that the battery management unit mentioned above is at least partially arranged outside an electrical chamber 11a.

Specifically, for a conventional battery, components in the electrical chamber 11a all need to be properly connected before the cover body <NUM> and the case shell <NUM> are sealed. The connection includes connection between the bus component <NUM> and the electrode terminal <NUM> and connection between the battery management unit and the bus component <NUM>. That is, in the conventional battery, the battery management unit is packaged in the sealed case <NUM>. However, the battery management unit is a vulnerable component compared to other components. After the battery management unit is damaged or malfunctions, the sealed case <NUM> needs to be opened for replacement. The operation is time-consuming and laborious, and the sealing of the case <NUM> is also affected.

Unlike the conventional battery, in the case where the bus component <NUM> is embedded in the cover body <NUM>, the battery management unit may be at least partially arranged outside the electrical chamber 11a. For example, at least one of electrical connection component <NUM> between a control module (not shown) of the battery management unit and the bus component <NUM> may also be embedded in the cover body <NUM>, as shown in <FIG>. The control module may be accommodated in an accommodation portion integrally formed with the cover body <NUM>. In this case, after the control module or the electrical connection component <NUM> of the battery management unit malfunctions, maintenance can be carried out without opening the case <NUM>, which reduces maintenance costs while ensuring sealing of the case <NUM> is not affected, and furthermore, improves battery safety performance and user experience. In some embodiments, the electrical connection component <NUM> may include, but is not limited to, at least one of the following: a circuit board (such as a printed circuit board or a flexible circuit board), a cable, a wire, a conducting strip or a conducting bar. The electrical connection component <NUM> is configured to be electrically connected with the plurality of battery cells <NUM> to capture temperature or voltage signals of the plurality of battery cells <NUM>.

<FIG> shows a partial enlarged view of a part B in <FIG>. As can be seen from <FIG>, a thermal management component <NUM> is provided under a battery cell <NUM>, and there are two chambers under the battery cell <NUM>-a collection chamber 11b and an avoidance chamber 134a. The avoidance chamber 134a provides a space for the actuation of a pressure relief mechanism <NUM> of the battery cell. The collection chamber 11b is configured to collect emissions, and may be sealed or unsealed. In some embodiments, the collection chamber 11b may contain air or another gas. Optionally, the collection chamber 11b may also contain liquid, such as a cooling medium, or a component configured to accommodate the liquid may be provided to further lower the temperature of the emissions entering the collection chamber 11b. Further, optionally, the gas or the liquid in the collection chamber 11b flows in a circulating manner. In order to understand functions and structures of the thermal management component <NUM> and the double-chamber structure, it is first necessary to describe the structure of the battery cell <NUM> with reference to <FIG>.

<FIG> show three-dimensional views of a battery cell <NUM> observed from different angles, respectively. As shown in the figures, in the battery cell <NUM> according to the present application, an electrode assembly is accommodated in a box of the battery cell <NUM>. The box includes a housing <NUM> and a cover plate <NUM>. The housing <NUM> includes an accommodation chamber formed by a plurality of walls and an opening. The cover plate <NUM> is arranged at the opening to close the accommodation chamber. In addition to the electrode assembly, the accommodation chamber also accommodates an electrolytic solution. A positive electrode sheet and a negative electrode sheet in the electrode assembly are generally provided with electrode tabs. The electrode tabs generally include a positive electrode tab and a negative electrode tab. The electrode tab is electrically connected to an electrode terminal <NUM> located outside the battery cell <NUM> through a connecting member. The electrode terminal <NUM> generally includes a positive electrode terminal 214a and a negative electrode terminal 214b. At least one battery cell <NUM> of the battery cells <NUM> in the battery <NUM> of the present application includes a pressure relief mechanism <NUM>. In some embodiments, a pressure relief mechanism <NUM> may be provided on a battery cell <NUM> of the plurality of battery cells <NUM> that may be more likely to suffer thermal runaway due to a position of the battery cell <NUM> in the battery <NUM>. Certainly, it is also possible that each battery cell <NUM> in the battery <NUM> is provided with a pressure relief mechanism <NUM>.

The pressure relief mechanism <NUM> refers to an element or component that is actuated when an internal pressure or temperature of the battery cell <NUM> reaches a predetermined threshold, to relieve the internal pressure and/or internal substance. The threshold referred to in the present application may be a pressure threshold or a temperature threshold. The threshold design is different according to different design requirements. For example, the threshold may be designed or determined according to an internal pressure or internal temperature value of the battery cell <NUM> that is considered to have danger and a risk of being out of control. In addition, the threshold may depend on the material of one or more of the positive electrode sheet, the negative electrode sheet, the electrolytic solution and the isolation film in the battery cell <NUM>. That is, the pressure relief mechanism <NUM> is configured to be actuated when the internal pressure or temperature of the at least one battery cell <NUM> in which it is located reaches a threshold, to relieve the pressure inside the battery, thereby avoiding more dangerous accidents. As mentioned above, the pressure relief mechanism <NUM> may also be called an anti-explosion valve, an air valve, a pressure relief valve or a safety valve, etc., and may specifically adopt a pressure-sensitive or temperature-sensitive element or structure. That is, when the internal pressure or temperature of the battery cell <NUM> reaches a predetermined threshold, the pressure relief mechanism <NUM> executes an action or a weakened structure provided in the pressure relief mechanism is damaged, so as to form an opening or channel for relieving the internal pressure. The bus component <NUM> is also called a bus bar or a bus, etc., which is a component that electrically connects the plurality of battery cells <NUM> in series and/or in parallel. The plurality of battery cells <NUM> have a higher voltage after being connected in series and/or parallel by the bus component <NUM>. Therefore, a side having the bus component <NUM> is sometimes referred to as a high-voltage side.

The "actuation" mentioned in the present application means that the pressure relief mechanism <NUM> acts or is activated to a certain state, such that the internal pressure of the battery cell <NUM> can be relieved. The action generated by the pressure relief mechanism <NUM> may include but is not limited to: at least a portion of the pressure relief mechanism <NUM> being fractured, broken, torn or opened, etc. When the pressure relief mechanism <NUM> is actuated, high-temperature and high-pressure substances inside the battery cell <NUM> are discharged outwards from an actuated position as emissions. In this way, the pressure in the battery cell <NUM> can be relieved at a controllable pressure or temperature, thereby avoiding potentially, more serious accidents. The emissions from the battery cell <NUM> mentioned in the present application include but are not limited to: an electrolytic solution, dissolved or split positive and negative electrode sheets, fragments of an isolation film, high-temperature and high-pressure gas generated by reaction, flame, etc. The high-temperature and high-pressure emissions are discharged toward a direction in which the pressure relief mechanism <NUM> of the battery cell <NUM> is provided, and more specifically, may be discharged toward a direction of a region in which the pressure relief mechanism <NUM> is actuated. The strength and destructive power of such emissions may be huge, or may even be large enough to break through one or more structures such as the cover body <NUM> provided in this direction.

Unlike a conventional battery, the pressure relief mechanism <NUM> and the bus component <NUM> in the battery <NUM> according to the embodiments of the present application are respectively arranged on different sides of the battery cell <NUM>. That is, generally, the bus component <NUM> is arranged on a top side where the cover plate <NUM> is located, and the pressure relief mechanism <NUM> of the battery cell <NUM> according to the embodiments of the present application may be arranged on any appropriate side different from the top side. For example, <FIG> show that the pressure relief mechanism <NUM> is arranged on a side opposite to the bus component <NUM>. In fact, the pressure relief mechanism <NUM> may be arranged on any one or more walls of the housing <NUM> of the battery cell <NUM>, which will be further explained below.

On the one hand, for example, when the battery <NUM> is applied to an electric vehicle or the like, the high-voltage side where the bus component <NUM> is provided is generally arranged on a side adjacent to a driver's cabin due to wiring, etc., and the pressure relief mechanism <NUM> is arranged on a different side so that when the pressure relief mechanism <NUM> is actuated, the emissions from the battery cell <NUM> are discharged in a direction away from the bus component <NUM>, as shown by arrows in the avoidance chamber 134a shown in <FIG>, and the emissions are discharged in a substantially fan direction toward the direction away from the bus component <NUM>. In this way, a hazard endangering safety of occupants when emissions are discharged toward a driver's cabin is eliminated, thereby significantly improving a use safety factor of the battery <NUM>.

On the other hand, since the emissions include various conductive liquid or solid, arranging the bus component <NUM> and the pressure relief mechanism <NUM> on the same side has a great risk in that the emissions may directly conduct high-voltage positive and negative electrodes and cause a short circuit. A series of chain reactions caused by the short circuit may cause thermal runaway or explosion of all battery cells <NUM> in the battery <NUM>. By arranging the bus component <NUM> and the pressure relief mechanism <NUM> on different sides so that the emissions are discharged in the direction away from the bus component <NUM>, the above-mentioned problems can be avoided, thereby further improving safety performance of the battery <NUM>.

<FIG> show views at different angles and a sectional view of a thermal management component <NUM> according to some embodiments. The thermal management component <NUM> will be described below in conjunction with <FIG>.

The thermal management component <NUM> in the present application refers to a component that can manage and adjust the temperature of the battery cells <NUM>. The thermal management component <NUM> can accommodate a fluid to manage and adjust the temperature of the battery cells <NUM>. The fluid here may be liquid or gas. The management and adjustment of the temperature may include heating or cooling the plurality of battery cells <NUM>. For example, in the case of cooling or lowering the temperature of the battery cells <NUM>, the thermal management component <NUM> is configured to accommodate a cooling fluid to lower the temperature of the plurality of battery cells <NUM>. In this case, the thermal management component <NUM> may also be called a cooling component, a cooling system or a cooling plate, etc. The fluid accommodated in it may also be called a cooling medium or a cooling fluid, and more specifically, may be called a cooling liquid or a cooling gas. The cooling medium may be designed to flow in a circulating manner to achieve a better temperature adjustment effect. The cooling medium may specifically use water, a mixture of water and ethylene glycol, or air, etc. In order to achieve the effectiveness of cooling, the thermal management component <NUM> is generally attached to the battery cells <NUM> by means of thermally conductive silica gel for example. In addition, the thermal management component <NUM> may also be used for heating to raise the temperature of the plurality of battery cells <NUM>. For example, heating the battery <NUM> before starting an electric vehicle in some regions with colder temperature in winter can improve battery performance.

In some embodiments, the thermal management component <NUM> may include a pair of thermally conductive plates and a flow channel <NUM> formed between the pair of thermally conductive plates. For the convenience of the description below, the pair of thermally conductive plates will be referred to as a first thermally conductive plate <NUM> attached to the plurality of battery cells <NUM> and a second thermally conductive plate <NUM> arranged on a side of the first thermally conductive plate <NUM> away from the battery cell <NUM>. The flow channel <NUM> is configured to accommodate a fluid and allow the fluid to flow therein. In some embodiments, the thermal management component <NUM> including the first thermally conductive plate <NUM>, the second thermally conductive plate <NUM> and the flow channel <NUM> may be integrally formed by an appropriate process such as blow molding, or the first thermally conductive plate <NUM> and the second thermally conductive plate <NUM> are assembled together by welding (such as brazing). In some alternative embodiments, the first thermally conductive plate <NUM>, the second thermally conductive plate <NUM> and the flow channel <NUM> may also be formed separately and assembled together to form the thermal management component <NUM>.

In some embodiments, the thermal management component <NUM> may constitute a portion of the case <NUM> configured to accommodate the plurality of battery cells. For example, the thermal management component <NUM> may be a bottom portion (not shown in the figures) of the case shell <NUM> of the case <NUM>. In addition to the bottom portion, the case shell <NUM> also includes side portions 112b. In some embodiments, the side portions 112b are formed as a frame structure, and can be assembled together with the thermal management component <NUM> to form the case shell <NUM>. In this way, the structure of the battery <NUM> can be made more compact, effective utilization of space can be improved, and energy density can be improved.

The thermal management component <NUM> and the side portions 112b may be assembled together by a sealing member such as a sealing ring and a fastener in a sealing manner. In order to improve the sealing effect, the fastener may use a flow drill screw (FDS). Certainly, it should be understood that this sealing assembly manner is only illustrative, and is not intended to limit the protection scope of the content of the present application. Any other suitable assembly manner is also possible. For example, in some alternative embodiments, the thermal management component <NUM> and the side portions 112b may be assembled together in an appropriate manner such as bonding.

In some alternative embodiments, the thermal management component <NUM> and the side portions 112b may also be integrally formed. That is, the case shell <NUM> of the case <NUM> may be integrally formed. This forming manner can increase the strength of the case shell <NUM> and is less prone to leakage. In some alternative embodiments, the side portions 112b of the case shell <NUM> may also be integrally formed with the cover body <NUM>. That is, in this case, the cover body <NUM> constitutes a structure with a lower opening, and the lower opening can be closed by the thermal management component <NUM>.

In other words, the thermal management component <NUM> and the case <NUM> may have various relationships. For example, in some alternative embodiments, the thermal management component <NUM> may not be a portion of the case shell <NUM> of the case <NUM>, but a component assembled on a side of the case shell <NUM> facing the cover body <NUM>. This manner is more conducive to keeping the case <NUM> closed. In some other alternative embodiments, the thermal management component <NUM> may also be integrated on an inner side of the case shell <NUM> in a suitable manner.

As mentioned above, some pressure relief mechanism <NUM> needs to be provided with an avoidance structure <NUM> at a position outside the battery cell <NUM> corresponding to the pressure relief mechanism <NUM> when actuated, so that the pressure relief mechanism <NUM> can be smoothly actuated to perform its intended function. In some embodiments, the avoidance structure <NUM> may be arranged on the thermal management component <NUM>, so that when the thermal management component <NUM> is attached to the plurality of battery cells <NUM>, an avoidance chamber 134a can be formed between the avoidance structure <NUM> and the pressure relief mechanism <NUM>. That is, the avoidance chamber 134a mentioned in the present application refers to a closed hollow chamber formed by collective surrounding of the avoidance structure <NUM> and the pressure relief mechanism <NUM>. In this solution, for the discharge of the emissions from the battery cell <NUM>, an inlet side surface of the avoidance chamber 134a may be opened due to actuation of the pressure relief mechanism <NUM>, and an outlet side surface opposite to the inlet side surface may be partially damaged and opened due to high-temperature and high-pressure emissions, thereby forming a relief channel for the emissions. According to some other embodiments, the avoidance chamber 134a may be, for example, a non-closed hollow chamber formed by collective surrounding of the avoidance structure <NUM> and the pressure relief mechanism <NUM>. An outlet side surface of the non-closed hollow chamber may originally have a channel for the emissions to flow out.

With continuing reference to <FIG>, as shown in the figures, in some embodiments, the first thermally conductive plate <NUM> and the second thermally conductive plate <NUM> may be respectively provided with a half-recess structure corresponding to the flow channel <NUM>, and half-recess structures of the first thermally conductive plate <NUM> and the second thermally conductive plate <NUM> are aligned with each other. By assembling the first thermally conductive plate <NUM> and the second thermally conductive plate <NUM> together, the half-recess structures of the first thermally conductive plate <NUM> and the second thermally conductive plate <NUM> are combined into the flow channel <NUM>, and finally the thermal management component <NUM> is formed.

Certainly, it should be understood that the specific structure of the thermal management component <NUM> described above is only schematic and is not intended to limit the protection scope of the present application. Any other suitable structure or arrangement is also possible. For example, in some alternative embodiments, at least one of the first thermally conductive plate <NUM>, the second thermally conductive plate <NUM> and the flow channel <NUM> may be omitted. For example, the second thermally conductive plate <NUM> may be omitted. That is, in some embodiments, the thermal management component <NUM> may only include the first thermally conductive plate <NUM> and the flow channel <NUM> arranged on one side or embedded therein.

As can be seen from the above description, in some embodiments, when the pressure relief mechanism <NUM> is arranged on a different side with respect to the bus component <NUM> of the battery cell <NUM>, a double-chamber structure can be formed after structural adjustment. The double chambers refer to the avoidance chamber 134a between the pressure relief mechanism <NUM> of the battery cell <NUM> and the avoidance structure <NUM> and the collection chamber 11b mentioned above. The double-chamber structure can effectively ensure that the emissions from the battery cell <NUM> can be discharged in a controllable, orderly and timely manner when the pressure relief mechanism <NUM> is actuated. In addition, in some embodiments, the avoidance chamber 134a may also be damaged to allow the fluid in the thermal management component <NUM> to flow out for cooling and extinguishing the emissions from the battery cell <NUM>, so that the temperature of the emissions from the battery cell <NUM> can be quickly lowered, thereby improving safety performance of the battery <NUM>.

Hereinafter, referring to <FIG>, it can be seen that, in some embodiments, the avoidance structure <NUM> formed on the thermal management component <NUM> may include an avoidance bottom wall 134b and an avoidance side wall 134c surrounding the avoidance chamber 134a. The avoidance bottom wall 134b and the avoidance side wall 134c in the present application are relative to the avoidance chamber 134a. Specifically, the avoidance bottom wall 134b refers to a wall of the avoidance chamber 134a opposite to the pressure relief mechanism <NUM>, and the avoidance side wall 134c is a wall adjacent to and at a predetermined angle with respect to the avoidance bottom wall 134b to surround the avoidance chamber 134a. In some embodiments, the avoidance bottom wall 134b may be a portion of the second thermally conductive plate <NUM>, and the avoidance side wall 134c may be a portion of the first thermally conductive plate <NUM>.

For example, in some embodiments, the avoidance structure <NUM> may be formed by recessing a portion of the first thermally conductive plate <NUM> toward the second thermally conductive plate <NUM> and forming an opening, and fixing an edge of the opening and the second thermally conductive plate <NUM> together in a suitable fixing manner. When the pressure relief mechanism <NUM> is actuated, the emissions from the battery cell <NUM> will first enter the avoidance chamber 134a. As shown by arrows in the avoidance chamber 134a of <FIG>, the emissions will be discharged outward in a substantially fan-shaped direction.

Unlike a conventional thermal management component, the thermal management component <NUM> according to the embodiment of the present application can be damaged when the pressure relief mechanism <NUM> is actuated, so that the emissions from the battery cell <NUM> can pass through the thermal management component <NUM>. An advantage of this arrangement is that high-temperature and high-pressure emissions from the battery cell <NUM> can pass through the thermal management component <NUM> smoothly, so as to avoid secondary accidents caused by the emissions not being discharged in time, thereby improving safety performance of the battery <NUM>.

In order to allow the emissions to pass through the thermal management component <NUM> smoothly, a through hole or a relief mechanism may be provided at a position of the thermal management component <NUM> opposite to the pressure relief mechanism <NUM>. For example, in some embodiments, a relief mechanism may be provided on the avoidance bottom wall 134b, that is, on the second thermally conductive plate <NUM>. The relief mechanism in the present application refers to a mechanism that can be actuated when the pressure relief mechanism <NUM> is actuated, to allow at least the emissions from the battery cell <NUM> to pass through the thermal management component <NUM> to be discharged. In some embodiments, the relief mechanism may also adopt the same structure as the pressure relief mechanism <NUM> on the battery cell <NUM>. That is, in some embodiments, the relief mechanism may be a mechanism arranged on the second thermally conductive plate <NUM> and having the same structure as the pressure relief mechanism <NUM>. In some alternative embodiments, the relief mechanism may also adopt a structure different from that of the pressure relief mechanism <NUM>, and is only a weakened structure provided at the avoidance bottom wall 134b. The weakened structure may include, but is not limited to, for example: a thinned part integral with the avoidance bottom wall 134b, an indentation (for example, a cross-shaped indentation 134d as shown in <FIG>), or a vulnerable part made of a vulnerable material such as plastic installed at the avoidance bottom wall 134b. Alternatively, the relief mechanism may be a temperature-sensitive or pressure-sensitive relief mechanism that is actuated when a temperature or pressure sensed by the relief mechanism exceeds a threshold.

In some embodiments, in order to allow the emissions to pass through the thermal management component <NUM> smoothly, the avoidance structure <NUM> may also be a through hole penetrating the thermal management component <NUM>. That is, the avoidance structure <NUM> may only have the avoidance side wall 134c, and the avoidance side wall 134c is thus a hole wall of the through hole. In this case, when the pressure relief mechanism <NUM> is actuated, the emissions from the battery cell <NUM> can directly pass through the avoidance structure <NUM> to be discharged. In this way, formation of secondary high pressure can be avoided more effectively, thereby improving safety performance of the battery <NUM>.

In some embodiments, the thermal management component <NUM> may also be configured to be damaged when the pressure relief mechanism <NUM> is actuated, to allow a fluid to flow out. The fluid outflow could quickly lower the temperature of the high-temperature and high-pressure emissions from the battery cell <NUM> and extinguish them, thereby avoiding further damage to other battery cells <NUM> and the battery <NUM> so as not to cause more serious accidents. For example, in some embodiments, the avoidance side wall 134c may also be formed to be easily damaged by the emissions from the battery cell <NUM>. Since internal pressure of the battery cell <NUM> is relatively great, the emissions from the battery cell <NUM> will be discharged outward in a substantially conical shape. In this case, if a contact area between the avoidance side wall 134c and the emissions can be increased, possibility of damage to the avoidance side wall 134c can be increased.

For example, in some embodiments, the avoidance side wall 134c is configured to form a predetermined included angle relative to a direction of the pressure relief mechanism <NUM> toward the thermal management component <NUM>, and the included angle is greater than or equal to <NUM>° and less than or equal to <NUM>°. For example, a predetermined included angle shown in <FIG> is about <NUM>°. By properly setting the included angle, the avoidance side wall 134c can be more easily damaged when the pressure relief mechanism <NUM> is actuated, so as to further allow the fluid to flow out to contact the emissions, and achieve the effect of cooling the emissions in time. In addition, the predetermined included angle can also enable the avoidance side wall 134c to be formed more easily. For example, the predetermined included angle can provide a certain draft angle, thereby being conducive to the manufacture of the avoidance side wall 134c and even the entire first thermally conductive plate <NUM>.

In addition, this arrangement manner of the avoidance side wall 134c can be applied to the above-mentioned case with the avoidance chamber 134a and the case where the avoidance structure <NUM> is a through hole. For example, in the case where the avoidance structure <NUM> is the through hole, an aperture of the through hole may gradually decrease along a direction of the pressure relief mechanism <NUM> toward the thermal management component <NUM>, and an included angle formed by a hole wall of the through hole relative to the direction of the pressure relief mechanism <NUM> toward the thermal management component <NUM> is greater than or equal to <NUM>° and less than or equal to <NUM>°.

Certainly, it should be understood that the aforementioned configuration that the avoidance side wall 134c is at a predetermined included angle with respect to the direction of the pressure relief mechanism <NUM> toward the thermal management component <NUM> is only illustrative, and is not intended to limit the protection scope of the content of the present application. Any other suitable structure that can help the avoidance side wall 134c be damaged when the pressure relief mechanism <NUM> is actuated is feasible. For example, in some embodiments, any type of weakened structure may also be provided on the avoidance side wall 134c.

The above embodiment describes the case where the thermal management component <NUM> has the avoidance structure <NUM>. That is, the avoidance chamber 134a mentioned in the above embodiment is formed by the avoidance structure <NUM> on the thermal management component <NUM> and the pressure relief mechanism <NUM>. It should be understood that the above embodiments of the avoidance chamber 134a are only illustrative and are not intended to limit the scope of protection of the content of the present application, and any other appropriate structure or arrangement is also possible. For example, in some alternative embodiments, the thermal management component <NUM> may not include the avoidance structure <NUM>. In this case, the avoidance chamber 134a may be formed from a protruding portion formed around the pressure relief mechanism <NUM> and the thermal management member <NUM>, for example. In addition, a position of the thermal management component <NUM> opposite to the pressure relief mechanism <NUM> may be provided with a relief mechanism or a weakened structure, so that the emissions from the battery cell <NUM> can pass through the thermal management component <NUM> and/or break through the thermal management component <NUM> to allow the fluid to flow out.

Certainly, in some embodiments, the avoidance chamber 134a may not be used. For example, for some pressure relief mechanisms <NUM> that can be actuated without an avoidance space, the pressure relief mechanism <NUM> may be arranged in close contact with the thermal management component <NUM>. Such pressure relief mechanism <NUM> may include, but is not limited to, a temperature-sensitive pressure relief mechanism <NUM>, for example. The temperature-sensitive pressure relief mechanism <NUM> is a mechanism that is actuated when a temperature of the battery cell <NUM> reaches a threshold, to relieve internal pressure of the battery cell <NUM>. Corresponding to this is a pressure-sensitive pressure relief mechanism <NUM>. The pressure-sensitive pressure relief mechanism <NUM> is the pressure relief mechanism <NUM> mentioned above. The pressure-sensitive pressure relief mechanism is a mechanism that is actuated when an internal pressure of the battery cell <NUM> reaches a threshold, to relieve the internal pressure of the battery cell <NUM>.

Hereinafter, the collection chamber 11b will be described in conjunction with <FIG> again. The collection chamber 11b in the present application refers to a hollow chamber that collects emissions from the battery cell <NUM> and the thermal management component <NUM> when the pressure relief mechanism <NUM> is actuated. In the case where the avoidance chamber 134a exists as described above, the avoidance chamber 134a can be isolated from the collection chamber 11b by the thermal management component <NUM>. The so-called "isolation" here refers to separation, which may refer to unsealing. This situation can be more advantageous for the emissions to break through the avoidance side wall 134c to allow a fluid to flow out, so as to further lower the temperature of the emissions and extinguish them, thereby improving safety performance of the battery <NUM>. In addition, in the case where the avoidance structure <NUM> described above is a through hole, the avoidance chamber 134a and the collection chamber 11b may be in communication with each other. This manner is more conducive to discharge of emissions, thereby avoiding safety hazards caused by secondary high pressure.

In some embodiments, the collection chamber 11b may also be an open cavity outside the thermal management component <NUM>. For example, in an embodiment in which the thermal management component <NUM> serves as a bottom portion of the case shell <NUM> of the case <NUM>, the emissions from the battery cell <NUM> may be directly discharged to an outer space of the thermal management component <NUM> after passing through the thermal management component <NUM>, that is, the outside of the case <NUM>, thereby avoiding generation of secondary high pressure. In some alternative embodiments, the battery <NUM> may further include a protective member <NUM>. The protective member <NUM> in the present application refers to a component arranged on a side of the thermal management component <NUM> away from the battery cell <NUM> to provide protection for the thermal management component <NUM> and the battery cell <NUM>. In these embodiments, the collection chamber 11b may be arranged between the protective member <NUM> and the thermal management component <NUM>.

In some embodiments, the protective member <NUM> may be a portion installed at the bottom of the case <NUM> to play a protective role. This manner helps to promote more diversified design of an application position or space for the battery <NUM> of an apparatus such as an electric vehicle. For example, for some electric vehicles, in order to reduce manufacturing costs and further reduce the price of a final product, the protective member <NUM> may not be provided without affecting the usage. A user can choose whether to install a protective member according to needs. In this case, the collection chamber 11b constitutes an open cavity mentioned above, and the emissions from the battery cell <NUM> can be directly discharged to the outside of the battery <NUM>.

In some embodiments, the protective member <NUM> may be a bottom portion of the case shell <NUM> of the case <NUM>. For example, the heat management component <NUM> may be assembled to the protective member <NUM> that serves as the bottom portion of the case shell <NUM>, and the heat management component <NUM> is assembled to the protective member <NUM> with a gap therebetween to form the collection chamber 11b. In this case, the collection chamber 11b can serve as a buffer chamber for the emissions from the battery cell <NUM>. When at least one of the temperature, volume, or pressure of the emissions in the collection chamber 11b reaches a predetermined level or threshold, the protective member <NUM> may be partially damaged to relieve the pressure in the collection chamber 11b in time. In some alternative embodiments, alternatively or additionally, a sealing member (such as a sealing ring, a sealant, or the like) may be provided between the protective member <NUM> and the thermal management component <NUM> to seal the collection chamber 11b, where the sealing member may also be at least partially damaged when at least one of the temperature, volume, or pressure of the emissions in the collection chamber 11b reaches a predetermined level or threshold, to relieve the pressure in the collection chamber 11b in time to avoid secondary damage.

In some alternative embodiments, the protective member <NUM> may also be integrally formed with the thermal management component <NUM>. For example, on the outside of the thermal management component <NUM>, a protective member <NUM> is also integrally formed, and there is a space between the protective member <NUM> and the thermal management component <NUM> to form the collection chamber 11b. The protective member <NUM> may be provided with a weakened structure, so that when the temperature, volume or pressure of the emissions in the collection chamber 11b reaches a predetermined level or threshold, the protective member <NUM> can be partially damaged to relieve the pressure of the collection chamber 11b in time. This manner can further reduce the number of components, and therefore reduce assembly time and assembly costs.

The battery of the embodiment of the present application is described above in conjunction with <FIG>, and a method and device for producing a battery of an embodiment of the present application will be described below in conjunction with <FIG>, and for parts that are not described in detail, reference can be made to the foregoing embodiments.

Referring to <FIG>, in an embodiment given in the present application, there is further provided a method <NUM> for producing a battery, including the following steps: a step <NUM> of providing a plurality of battery cells configured to be electrically connected to each other through a bus component; a step <NUM> of providing a cover body including an accommodation space configured to install the bus component; and a step <NUM> of providing an insulating part attached to the cover body and provided to cover at least the bus component.

Referring to <FIG>, in an embodiment given in the present application, there is further provided a device <NUM> for producing a battery, including: a battery cell production module <NUM> configured to produce a plurality of battery cells configured to be electrically connected to each other through a bus component; a cover body production module <NUM> configured to produce a cover body including an accommodation space configured to install the bus component; and an insulating part production module <NUM> configured to produce an insulating part attached to the cover body and provided to cover at least the bus component.

Claim 1:
A battery (<NUM>), comprising:
a plurality of battery cells (<NUM>) configured to be electrically connected to each other through a bus component (<NUM>);
a cover body (<NUM>) comprising an accommodation space (111a) configured to install the bus component (<NUM>); and
an insulating part (<NUM>) attached to the cover body (<NUM>) and provided to cover at least the bus component (<NUM>);
wherein at least one battery cell (<NUM>) of the plurality of battery cells (<NUM>) comprises a pressure relief mechanism (<NUM>), and the pressure relief mechanism (<NUM>) is configured to be actuated when an internal pressure or temperature of the at least one battery cell (<NUM>) reaches a threshold, to relieve the internal pressure,
wherein the pressure relief mechanism (<NUM>) and the bus component (<NUM>) are respectively arranged on different sides of the at least one battery cell (<NUM>), so that when the pressure relief mechanism (<NUM>) is actuated, emissions from the at least one battery cell (<NUM>) are discharged in a direction away from the bus component (<NUM>);
wherein the accommodation space (111a) is a blind hole formed on the cover body (<NUM>), the bus component (<NUM>) is capable of entering the accommodation space (111a) through an opening of the accommodation space (111a), and at least a portion of the bus component (<NUM>) is accommodated in the accommodation space (111a), and the insulating part (<NUM>) is integrally formed with the cover body (<NUM>).