Patent Description:
Patent application number <CIT> discloses a closed type battery having no electrolyte leakage and improved airtightness, which comprises a battery header in which an electrode-drawing sheet of polarity opposite to that of a battery can is fixed by caulking to an insulating member fitted into a through-hole in a metal sheet while an electrode-leading pin remains inserted into the through-hole. An internal insulating sheet mounted on the surface of the metal sheet of the battery header located inside the battery can come into contact at two or more surfaces with an external insulating sheet mounted on a surface of the metal sheet of the battery header located outside the battery can.

Patent application number <CIT> discloses an insulation insertion part and/or an insulating contact part is compressed with a compression force, a first insulating member, a second insulating member, a case lid, and/or an insert-through part create a receiving space which allows the insulation insertion part to deform in a shape that reduces a compression stress acting on the insulation insertion part when the insulation insertion part is compressed and receive a deformed portion thereof, and/or a receiving space which allows an insulating member having the insulating contact part to deform in a shape that reduces a compression stress acting on the insulating contact part when the insulating contact part is compressed and receives the deformed portion thereof.

Utility application <CIT> relates to a battery that commprises an insulating substrate provided with a post hole. The circumference of the pole column perforation extends outwards to form a protrusion with an annular groove formed between projections.

Utility application <CIT> describes a battery top cover assembly, comprising a top cover sheet, a pole, an elastic seal and an insulating pressing ring, the top cover sheet is provided with an electrode hole; the pole passes through the elastic seal, the electrode hole and the insulating pressing ring. The insulating pressing ring is attached to the side surface of the top cover sheet away from the battery core, and the elastic sealing member is located on the side of the insulating pressing ring facing the battery core. An insulating sleeve is also provided, the insulating sleeve is located between the pole and the electrode hole, and its two ends are respectively attached to the insulating pressing ring and the elastic sealing member.

Owing to such advantages as high energy density, high power density, multiple cycles and long storage time, secondary batteries such as lithium-ion batteries are widely used in electric vehicles. During the actual use of the secondary batteries, it is found that a cell has such safety risks as fire and explosion.

One technical problem to be solved in the present application is to reduce such risks as fire or explosion of secondary batteries when the secondary batteries are subjected to high voltage.

To solve the above technical problem, the present application provides a top cover assembly of a secondary battery, as defined in independent claim <NUM>, as well as a secondary battery as defined in claim <NUM>; a battery module as defined in claim <NUM> and an electric equipment as defined in claim <NUM>.

In some embodiments, a side surface of the first matching part, which is far away from a central axis of the electrode extraction hole, is configured to be a first inclined surface, and the first inclined surface is gradually close to the central axis of the electrode lead-out hole along a direction from bottom to top.

In some embodiments, at least part of an inner wall of the electrode lead-out hole is configured to be a second inclined surface, and the second inclined surface is gradually close to the central axis of the electrode lead-out hole along the direction from bottom to top.

In some embodiments, the first matching part is sealed with a side wall of the groove which is adjacent to a central axis of the electrode extraction hole.

In some embodiments, the sealing member includes a second sealing part, and the second sealing part extends downwards from the first sealing part and at least part of the second sealing part is located in the electrode extraction hole.

In some embodiments, the second insulating part includes a second matching part, the second matching part is connected to a side surface of the first matching part which is adjacent to a central axis of the electrode extraction hole, and the second matching part is sealed with a lower end of the second sealing part.

In some embodiments, a top end of the second matching part is sealed with the lower end of the second sealing part.

In some embodiments, the top end of the second matching part is lower than a top end of the first matching part.

By embedding and sealing the sealing member and the lower insulating member, the present application can effectively extend the creepage distance, thereby reducing such risks as fire or explosion when the secondary battery is subjected to high voltage.

Other characteristics and advantages of the present application will become clear through a detailed description of the exemplary embodiments of the present application with reference to the accompanying drawings below.

In order to more clearly illustrate technical solutions in embodiments of the present application or in the prior art, a brief introduction will be given below on accompanying drawings which need to be used in the description of the embodiments or the prior art. Apparently, the accompanying drawings described below are merely some embodiments of the present application. Those skilled in the art can obtain other accompanying drawings according to these drawings without any creative effort.

A clear and complete description will be given below on the technical solutions in the embodiments of the present application in combination with the accompanying drawings in the embodiments of the present application below, and apparently the embodiments described below are only a part but not all of the embodiments of the present application. The description of at least one exemplary embodiment below is merely illustration, rather than serving as any limitation to the present application and applications or uses thereof. Based upon the embodiments of the present application, all the other embodiments which can occur to those skilled in the art without any inventive effort shall fall into the protection scope of the present application.

The techniques, methods and devices known to those of ordinary skills in the art may not be discussed in detail, however, under appropriate conditions, the techniques, methods and devices should be deemed as a part of the authorized description.

In the description of the present application, it should be understood that, the orientation or positional relationship indicated by such nouns of locality as "front, rear, up, down, left, right", "transverse, longitudinal, vertical, horizontal" and "top, bottom" is generally based on the orientation or positional relationship shown in the drawings, and is merely for facilitating description of the present application and for simplifying the description. In the absence of an opposite statement, these nouns of locality do not indicate or imply that the device or element referred to must be located in a certain orientation or must be configured or operated in a certain orientation, therefore, these nouns of locality cannot be understood as a limitation to the protection scope of the present application; and such nouns of locality as "inside, outside" refer to the inside or outside of the outline of each part itself.

In the description of the present application, it should be understood that, the defining of components and parts by such terms as "first" and "second" is merely for the convenience of distinguishing corresponding components and parts, unless otherwise stated, the above terms have no special meanings, therefore, such terms cannot be understood as a limitation to the protection scope of the present application.

In addition, the technical features involved in different embodiments of the present application described below can be combined mutually as long as they do not conflict with each other.

At present, the voltage of a complete vehicle system is about 300V to 900V When a cell is abnormal, an internal circuit or a fuse (a fusing structure) will be disconnected, at this time, the cell will be subjected to a reverse high voltage of the system, however, the safety distance inside the existing secondary battery is not sufficient, therefore, the cell which is subjected to a reverse high voltage will have such safety risks as fire or explosion.

<FIG> show an embodiment of a secondary battery <NUM> and a top cover assembly thereof provided in the present application.

As shown in <FIG>, the secondary battery <NUM> includes a top cover assembly, a connecting plate <NUM>, an electrode assembly <NUM> and a case <NUM>, etc..

The case <NUM>, for accommodating the electrode assembly <NUM> and the like, is provided with a cavity inside and a top opening. The case <NUM> may be made of metal materials including aluminium, aluminum alloy or nickel-plated steel.

The electrode assembly <NUM>, as a core part of the secondary battery <NUM>, is accommodated in the cavity inside the case <NUM>, and is formed by stacking or winding of a first electrode plate, a second electrode plate and an insulating spacer arranged between the first electrode plate and the second electrode plate. One of the first electrode plate and the second electrode plate is served as a positive electrode plate, while the other one is served as a negative electrode plate, and the first electrode plate and the second electrode plate both have a coating part coated with an active substance and tabs <NUM> which extend outwards from the coating part and are not coated with the active substance. The electric energy produced by the electrode assembly <NUM> is transmitted outwards through the tabs <NUM>. The tab <NUM> corresponding to the positive electrode plate is called a positive tab (the tab <NUM> arranged on the right side in the figure), while the tab <NUM> corresponding to the negative electrode plate is called a negative tab (the tab <NUM> arranged on the left side in the figure).

The top cover assembly covers on the top opening of the case <NUM>, and is configured to provide a sealed space for the electrode assembly <NUM> and electrolyte in the cavity inside the case <NUM>, and is configured to guide the electric energy produced by the electrode assembly <NUM> out of the case <NUM>. As shown in <FIG>, the top cover assembly includes a top cover plate <NUM>, a terminal assembly <NUM>, a sealing member <NUM> and a lower insulating member <NUM>.

The top cover plate <NUM> covers on the top opening of the case <NUM>, and provides an installation foundation for the terminal assembly <NUM>, the sealing member <NUM> and the lower insulating member <NUM>. As can be seen from <FIG>, the top cover plate <NUM> of the present embodiment is in a shape of thin plate, and has a shape and size which are matched with those of the top opening of the case <NUM>, thereby facilitating the top cover plate <NUM> to connect with the top opening of the case <NUM> to close the top opening of the case <NUM>. Meanwhile, the top cover plate <NUM> is provided with an electrode lead-out hole <NUM>, and the electrode lead-out hole <NUM> is a through hole, to facilitate electric connection between the terminal assembly <NUM> and the tab <NUM>, and guide out the electric energy from inside to outside. Corresponding to the two tabs <NUM>, the number of the electrode extraction holes <NUM> is also two, and the two electrode extraction holes <NUM> are respectively corresponding to the positive tab and the negative tab.

The terminal assembly <NUM>, the sealing member <NUM> and the lower insulating member <NUM> are all arranged on the top cover plate <NUM>, and corresponding to the two tabs <NUM>, the number of the terminal assemblies <NUM>, the sealing members <NUM> and the lower insulating members <NUM> is also two, wherein the terminal assembly <NUM>, the sealing member <NUM> and the lower insulating member <NUM> corresponding to the positive tab form one group, while the terminal assembly <NUM>, the sealing member <NUM> and the lower insulating member <NUM> corresponding to the negative tab form the other group, and the structures of the two groups are generally set to be the same, to simplify the structures. Therefore, one of the groups is mainly described below. If two groups need to be mentioned, then the groups are respectively named as "positive" and "negative", to facilitate distinguishing.

The terminal assembly <NUM> is arranged above the top cover plate <NUM> and is configured to be electrically connected with the tab <NUM>. The terminal assembly <NUM> includes an electrode terminal and a terminal fixed member, the electrode terminal is electrically connected with the tab <NUM>, and the electrode terminal is connected with the top cover plate <NUM> through the terminal fixed member.

The electrode terminal may be implemented as a pole extending into the case <NUM>, or a terminal plate outside the case <NUM>. As shown in <FIG>, in the present embodiment, the electrode terminal is implemented as a terminal plate <NUM>, and the terminal plate <NUM> is arranged above the top cover plate <NUM>, covers the electrode lead-out hole <NUM>, and is electrically connected with the tab <NUM>. Compared with the pole which extends into the case <NUM> via the electrode lead-out hole <NUM>, the terminal plate <NUM> being arranged outside the electrode lead-out hole <NUM> doesn't need to occupy internal space of the case <NUM>, therefore, the energy density of the secondary battery <NUM> can be effectively improved. The terminal plate <NUM> may be of a circular or square slice or a thin plate structure. The terminal plate <NUM> corresponding to the positive tab is called a positive terminal plate, and the terminal plate <NUM> corresponding to the negative tab is called a negative terminal plate.

In the present embodiment, the terminal plate <NUM> is electrically connected with the tab <NUM> through a connecting plate <NUM>. The connecting plate <NUM> is arranged between the electrode assembly <NUM> and the top cover assembly, and is configured to electrically connect the tab <NUM> with the terminal plate <NUM>, so as to transmit the electric energy produced by the electrode assembly <NUM> to the terminal plate <NUM>, thereby facilitating the terminal plate <NUM> to draw the electric energy out of the secondary battery <NUM>. It can be seen from <FIG> that, in the present embodiment, the number of the connecting plates <NUM> is two, one of the connecting plates <NUM> electrically connects the positive tab with the positive terminal plate, and the other connecting plate <NUM> electrically connects the negative tab with the negative terminal plate.

To simplify the structure, in the present embodiment, the two connecting plates <NUM> adopt the same structure. As shown in <FIG>, the connecting plate <NUM> of the present embodiment includes a tab connecting part <NUM> and a terminal connecting part <NUM>, the tab connecting part <NUM> is electrically connected with the tab <NUM>, and the terminal connecting part <NUM> is electrically connected with the terminal plate <NUM>. The electrical connection herein may be realized for example through a welding manner.

Moreover, in combination with <FIG>, it can be known that, in the present embodiment, the tab connecting part <NUM> is plate-shaped, and is roughly parallel to the top cover plate <NUM>; and the terminal connecting part <NUM> is connected with the tab connecting part <NUM> and protrudes upwards relative to the tab connecting part <NUM>, and the terminal connecting part <NUM> extends into the electrode lead-out hole <NUM> and is in contact with the terminal plate <NUM>, thereby facilitating welding between the terminal connecting part <NUM> and the terminal plate <NUM> outside the electrode lead-out hole <NUM>, and realizing electrical connection between the connecting part <NUM> and the terminal plate <NUM>. The terminal connecting part <NUM> may be of a cylindrical convex hull structure, and may be formed by stamping the connecting plate <NUM>.

The sealing member <NUM> is arranged between the top cover plate <NUM> and the terminal plate <NUM>, and is configured to seal the electrolyte and the like, to prevent leakage of the electrolyte, thus improving operational reliability of the secondary battery <NUM>. The lower insulating member <NUM> is configured to realize insulation between the top cover plate <NUM> and the electrode assembly <NUM> and the connecting plate <NUM>, and the lower insulating member <NUM> is generally made of insulating materials including plastics.

In the process of practicing the present application, the inventor found that, when being matched, the sealing member <NUM> and the lower insulating member <NUM> generally do not contact or connect, or only contact but do not connect. Under such a condition, the creepage distance between the top cover plate <NUM> and the terminal plate <NUM> is short, meanwhile, the sealing effect of the sealing member <NUM> is poor, much electrolyte exists on the creepage distance, and the resistance is small, and these are important reasons that cause high-pressure discharge of the secondary battery <NUM> fire and even explosion under high voltage). The creepage distance refers to the shortest distance between two conducting parts along the surface of solid insulating materials. The longer the creepage distance is, the lower the risk of high-pressure discharge between conductors is.

In addition, the sealing member <NUM> arranged between the top cover plate <NUM> and the terminal plate <NUM> will be squeezed by the top cover plate <NUM> and the terminal plate <NUM>, and thus be deformed (including deformation along a radial direction of the electrode lead-out hole <NUM>), therefore, in the case that the sealing member <NUM> and the lower insulating member <NUM> only contact but do not connect, even if the two are expected to be sealed through contact, however, since the two are not connected with each other, after the sealing member <NUM> is deformed, the contact area between the sealing member <NUM> and the lower insulating member <NUM> will become small, even the two will be separated from each other and cannot contact, such that an expected sealing effect cannot be achieved, and even sealing failure may occur.

In view of the above situation, in the present application, the structure of the top cover assembly is improved, and the sealing member <NUM> of the top cover assembly is embedded with and sealed with the lower insulating member <NUM>, thereby achieving at least one effect of extending the creepage distance and improving tightness, and further lowering the risk of high-pressure discharge of the secondary battery <NUM>.

As shown in <FIG>, the sealing member <NUM> of the top cover assembly in the present application includes a first sealing part <NUM>, the first sealing part <NUM> is arranged on an upper surface of the top cover plate <NUM>. The lower insulating member <NUM> is provided with a first insulating part <NUM> and a second insulating part <NUM> which are connected with each other, the first insulating part <NUM> is arranged below the top cover plate <NUM>, the second insulating part <NUM> extends upwards from the first insulating part <NUM> and at least part of the second insulating part <NUM> is arranged in the electrode lead-out hole <NUM>, one of the second insulating part <NUM> and the sealing member <NUM> is provided with a groove 121a, while the other includes a first matching part 142a, and the first matching part 142a is embedded into the groove 121a and is sealed with a bottom wall of the groove 121a.

By utilizing the match between the first matching part 142a and the groove 121a, the sealing member <NUM> and the lower insulating member <NUM> are embedded and sealed with each other, and in the present application, the creepage distance between the top cover plate <NUM> or the connecting plate <NUM> and the terminal plate <NUM> can be extended, thereby effectively lowering the risk of high-pressure discharge of the secondary battery <NUM>.

Meanwhile, the sealing member <NUM> is in interface seal with the lower insulating member <NUM>, thereby reducing electrolyte on the creepage distance, increasing the resistance, reducing current at a constant voltage, and further lowering the risk of high-pressure discharge.

Moreover, different from the structural form in which the sealing member <NUM> and the lower insulating member <NUM> are not connected with each other, in the present application, one of the sealing member <NUM> and the lower insulating member <NUM> is embedded into the other , such that the two are connected in an embedding manner (or called a clamping manner), since this can restrict the relative positional relationship of the two to a certain extent, the positional relationship and sealing interface of the two will not be influenced too much by the deformation of the sealing member <NUM>, thus such problems as poor sealing or even failed sealing between the sealing member <NUM> and the lower insulating member <NUM> caused by the deformation of the sealing member <NUM> can be effectively prevented, thereby the sealing effect of the two being improved, and the risk of high-pressure discharge being lowered.

A further description will be given below on the top cover assembly of the present application with the structures shown in <FIG> as an example below.

As shown in <FIG>, in the present embodiment, the sealing member <NUM> not only includes a first sealing part <NUM>, but also includes a second sealing part <NUM> connected with the first sealing part <NUM>. The first sealing part <NUM> is located between the upper surface of the top cover plate <NUM> and the lower surface of the terminal plate <NUM>, in this way, the terminal plate <NUM> can tightly press the first sealing part <NUM> on the upper surface of the top cover plate <NUM>, such that a sealing line is formed between the terminal plate <NUM> and the top cover plate <NUM>; while the second sealing part <NUM> extends downwards from the first sealing part <NUM>, and at least part of the second sealing part <NUM> is arranged in the electrode lead-out hole <NUM>. The overall sealing member <NUM> may adopt an annular structure, at this time, the first sealing part <NUM> and the second sealing part <NUM> are both annular and are concentric with each other, moreover, the second sealing part <NUM> is arranged below the first sealing part <NUM> and has an outer diameter dimension which is smaller than that of the first sealing part <NUM>.

As can be seen from <FIG> the groove 121a is arranged on the sealing member <NUM>, and is specifically arranged on the lower surface of the first sealing part <NUM>. Moreover, the groove 121a, in the present embodiment, is located at a position at which the first sealing part <NUM> is connected with the second sealing part <NUM>, that is, the groove 121a is formed at a part, abutted against the second sealing part <NUM>, of the lower surface of the first sealing part <NUM>, such a setting has advantages of not only facilitating the sealing member <NUM> to be matched with the second insulating part <NUM> through the groove 121a, but also facilitating the sealing member <NUM> to be matched with the top cover plate <NUM> through the groove 121a.

As shown in <FIG> the first sealing part <NUM> is embedded with the top cover plate <NUM> through the groove 121a. Specifically, in the present embodiment, a bulge which protrudes upwards is arranged on an upper surface, in contact with the first sealing part <NUM>, of the top cover plate <NUM>, and the bulge is embedded into the groove 121a, such that the top cover plate <NUM> is clamped with the first sealing part <NUM>. Based on this, the top cover plate <NUM> can be utilized to limit the first sealing part <NUM>, such that the sealing member <NUM> is more stably arranged on the upper surface of the top cover plate <NUM>, and is not easily displaced on the radial direction of the electrode lead-out hole <NUM>. Moreover, based on this, the influence of the deformation of the sealing member <NUM> on the sealing effect can be effectively reduced by utilizing the match between the groove 121a and the first matching part 142a, which will be further illustrated below in combination with the description of the lower insulating member <NUM>.

As shown in <FIG>, <FIG>, in the present embodiment, the whole lower insulating member <NUM> is roughly plate-shaped, and includes a first insulating part <NUM> and a second insulating part <NUM>, wherein the first insulating part <NUM> is arranged below the top cover plate <NUM>, to realize electric insulation between the top cover plate <NUM> and the electrode assembly <NUM> and the connecting plate <NUM>; and the second insulating part <NUM> is connected with the first insulating part <NUM> and extends upwards from the first insulating part <NUM> into the electrode lead-out hole <NUM>. The second insulating part <NUM> may be a hollow cylindrical protruding part arranged on the upper surface of the first insulating part <NUM>.

Moreover, as shown in <FIG>, in the present embodiment, the second insulating part <NUM> not only includes a first matching part 142a, but also includes a second matching part 142b, and the second matching part 142b is connected to a surface on a side of the first matching part 142a which is, adjacent to the central axis of the electrode lead-out hole <NUM> (that is, the surface on the right side in <FIG>), wherein the first matching part 142a and the groove 121a are clamped and are in sealed match, while the second matching part 142b is in sealed match with a lower end of the second sealing part <NUM>.

Specifically, it can be known from <FIG> that, in the present embodiment, the first matching part 142a is embedded into the groove 121a, such that the second insulating part <NUM> is clamped with the first sealing part <NUM> in an embedding manner, moreover, the first matching part 142a embedded into the groove 121a is not only in sealed match with the bottom wall of the groove 121a, but also in sealed match with a side wall on a side (that is, the right side wall in <FIG>), adjacent to the central axis of the electrode lead-out hole <NUM>, of the groove 121a.

The first matching part 142a is sealed with the groove 121a, such that the environmental medium between the top cover plate <NUM> and the terminal plate <NUM> and the connecting plate <NUM> is changed from air or electrolyte into the lower insulating member <NUM>, therefore, the creepage distance is increased, and the electrolyte on the creepage distance is reduced, thus helping to lower the risk of safety accidents of the secondary battery <NUM> due to bearing reverse high voltage. Moreover, the first matching part 142a is simultaneously in sealed match with the bottom wall and the side wall of the groove 121a, such that more than one sealing interface is formed between the first matching part 142a and the first sealing part <NUM>, the overall seal between the first matching part 142a and the first sealing part <NUM> will not fail due to the failure of one of the sealing interfaces, therefore, the sealing reliability is higher.

Meanwhile, the sealing member <NUM> is clamped with the lower insulating member <NUM> through the embedding between the first matching part 142a and the groove 121a, relative to the condition in which the sealing member <NUM> is not connected with the lower insulating member <NUM>, the relative positions of the two are not restricted, and the sealing interface between the two is not easily damaged due to the extrusion deformation of the sealing member <NUM>, therefore, the problem of failed sealing caused by the deformation of the sealing member <NUM> can be effectively prevented. The sealing interface between the first matching part 142a and the bottom wall of the groove 121a is especially not influenced by the extrusion deformation of the sealing member <NUM>. When the sealing member <NUM> is deformed towards the electrode lead-out hole and down due to extrusion, a good contact sealing relationship between the first matching part 142a with the bottom wall of the groove 121a can be maintained, therefore, the sealing effect is good, and the sealing reliability is high. Moreover, as mentioned above, the groove 121a in the present embodiment is also embedded with the top cover plate <NUM> simultaneously, and under such a condition, the top cover plate <NUM> can further restrict the deformation of the sealing member <NUM> when the sealing member <NUM> is squeezed, and reduce changes in shape and position of the groove 121a in the deformation process of the sealing member <NUM>, such that the embedding and sealed matching relationship between the groove 121a and the first matching part 142a is more stable, thereby being beneficial for realizing a more effective and reliable sealing effect.

In addition, as mentioned above, in the present embodiment, the lower insulating member <NUM> is not only in sealed match with the sealing member <NUM> through the first matching part 142a, but also in sealed match with the sealing member <NUM> through the second matching part 142b, based on this, the sealing interfaces between the lower insulating member <NUM> and the sealing member <NUM> are further increased, and the sealing area are enlarged, thereby being beneficial for further improving the sealing effect, and improving the operating safety of the secondary battery <NUM>.

Specifically, as shown in <FIG>, a top end of the second matching part 142b is sealed with the lower end of the second sealing member <NUM>, forming another sealing interface, such that between the lower insulating member <NUM> and the sealing member <NUM>, not only a sealing interface between the bottom wall and the side wall of the first matching part 142a and the groove 121a is included, but also a sealing interface between the second matching part 142b and the second sealing part <NUM> is simultaneously included, forming a multi-interface seal, therefore, the sealing reliability between the lower insulating member <NUM> and the sealing member <NUM> can be further improved.

The top end of the second matching part 142b may abut against the lower end of the second sealing part <NUM>, and the two interfere with each other to form an interference fit, such that a tighter and more reliable sealed matching relationship can be realized between the second matching part 142b and the second sealing part <NUM>.

Moreover, as can be seen from <FIG>, in the present embodiment, the top end of the second matching part 142b is lower than the top end of the first matching part 142a, such that a step part is formed between the top end of the first matching part 142a and the top end of the second matching part 142b, and the lower end of the second sealing part <NUM> extends downwards below the top end of the first matching part 142a and contacts a lower step surface of the step part for sealing, meanwhile, the first matching part 142a is not only sealed with a side wall on a side, adjacent to the central axis of the electrode lead-out hole <NUM>, of the groove 121a, but also sealed with a surface on a side, far away from the central axis of the electrode lead-out hole <NUM>, of the second sealing part <NUM>, in this way, the sealing area between the first matching part 141a and the sealing member <NUM> in the vertical direction is increased, thereby being beneficial for further improving the sealing effect.

In addition, it can be known from <FIG> that, in the present embodiment, a surface on a side (the surface on the left side in <FIG>), far away from the central axis of the electrode lead-out hole <NUM>, of the first matching part 142a is configured to be a first inclined surface 14a, and the first inclined surface 14a is gradually close to the central axis of the electrode lead-out hole <NUM> along a direction from bottom to top. Based on this, relative to the condition in which the surface on the side, far away from the central axis of the electrode lead-out hole <NUM>, of the first matching part 142a is set vertically or set to be inclined in a reverse direction, a size of the first matching part 142a along the radial direction of the electrode lead-out hole <NUM> (which can be called width for short) is reduced, since this is beneficial for reducing the internal space of the electrode lead-out hole <NUM> occupied by the second insulating part <NUM>, more space is reserved for the terminal connecting part <NUM> on the upper part of the electrode lead-out hole <NUM>, such that the terminal connecting part <NUM> may be set with a greater surface area to facilitate welding of the terminal connecting part <NUM> and the terminal plate <NUM> at a larger area, it's beneficial for increasing the welding area between the connecting plate <NUM> and the terminal plate <NUM>, which can enhance a discharge capacity, and reduce heat.

To facilitate assembly of the second insulating part <NUM> and the sealing member <NUM>, at least part of an inner wall of the electrode lead-out hole <NUM> may be configured to be a second inclined surface 131a, and the second inclined surface 131a is gradually close to the central axis of the electrode lead-out hole <NUM> along the direction from bottom to top. Specifically, as shown in <FIG>, in the present embodiment, the part arranged at the lower part of the inner wall of the electrode lead-out hole <NUM> is configured to be the second inclined surface <NUM>1a. In this way, the second inclined surface 131a can play a role of guiding assembly, and guide the first matching part 142a to be embedded into the groove 121a, such that the assembly process of the second insulating part <NUM> and the sealing member <NUM> can be finished more accurately and more rapidly.

It can be known in combination with the above that, as to the top cover assembly in the embodiments shown in <FIG>, the structure is simple, the assembly is convenient, meanwhile, the creepage distance is longer, and the electrolyte on the creepage distance is less, therefore, when the secondary battery <NUM> including such a top cover assembly is subjected to a reverse high voltage, such problems as fire and even explosion do not easily occur, and the use safety is higher. Moreover, the sealing effect of the top cover assembly is less influenced by the extrusion deformation of the sealing member <NUM> and the sealing reliability is higher.

However, to improve use safety and operating reliability of the secondary battery <NUM>, the structure of the top cover assembly is not limited to what is shown in the above <FIG>. Although not shown in figures, several feasible variant examples will be enumerated below. Moreover, to simplify description, the part which is the same as <FIG> will not be described repeatedly, and only differences of each embodiment are described as an emphasis.

As a variant of the top cover assembly shown in <FIG>, the groove 121a arranged on the lower surface of the first sealing part <NUM> and matched with the first matching part 142a may be not simultaneously embedded with the top cover plate <NUM>. In order to realize a more stable arrangement of the sealing member on the top cover plate <NUM>, the top cover plate <NUM> and the first sealing part <NUM> may adopt other matching manners in addition to embedding, or the top cover plate <NUM> and the first sealing part <NUM> may still adopt an embedding manner, but the two are embedded through a slot other than the groove 121a, in other words, a slot may further be arranged on the lower surface of the first sealing part <NUM>, and the first sealing part <NUM> is embedded with the top cover plate <NUM> through the slot. In this case, the lower surface of the first sealing part <NUM> is provided with more than one slot, and includes the groove 121a and the slot.

As another variant of the top cover assembly shown in <FIG>, the groove 121a may be no longer arranged on the first sealing part <NUM>, but arranged on the second sealing part <NUM> instead, for example, the groove 121a may be arranged at the lower end of the second sealing part <NUM>, at this time, the second insulating part <NUM> may be inserted into the groove 121a, to realize the clamping and sealed match between the sealing member <NUM> and the second insulating part <NUM>.

As still another variant of the top cover assembly shown in <FIG>, the groove 121a may be no longer arranged on the sealing member <NUM>, but arranged on the second insulating part <NUM> instead, at this time, the second sealing part <NUM> may be inserted into the groove 121a, to realize the clamping and sealed match between the sealing member <NUM> and the second insulating part <NUM>.

As still another variant of the top cover assembly shown in <FIG>, the sealing member <NUM> may only include the first sealing part <NUM>, but not include the second sealing part <NUM>, in this case, the clamping and sealed match between the sealing member <NUM> and the second insulating part <NUM> may also be realized through the match between the groove 121a on the first sealing part <NUM> and the first matching part 142a.

The present application further provides a battery module which includes the secondary battery <NUM> of the present application.

The present application further provides an electric equipment which includes the secondary battery <NUM> of the present application, and the secondary battery <NUM> is configured to provide electric energy.

Claim 1:
A top cover assembly of a secondary battery (<NUM>), characterized in that, comprising:
a top cover plate (<NUM>), provided with an electrode lead-out hole (<NUM>);
a sealing member (<NUM>), comprising a first sealing part (<NUM>), wherein the first sealing part (<NUM>) is arranged on an upper surface of the top cover plate (<NUM>), and a groove (121a) is arranged on a lower surface of the first sealing part (<NUM>); and
a lower insulating member (<NUM>), provided with a first insulating part (<NUM>) and a second insulating part (<NUM>) which are connected with each other, wherein the first insulating part (<NUM>) is arranged below the top cover plate (<NUM>), the second insulating part (<NUM>) extends upwards from the first insulating part (<NUM>) and at least part of the second insulating part (<NUM>) is located in the electrode lead-out hole (<NUM>), the second insulating part (<NUM>) is provided with a first matching part (142a), and the first matching part (142a) is embedded into the groove (121a) and is sealed with a bottom wall of the groove (121a);
characterized in that, the first sealing part (<NUM>) is embedded with the top cover plate (<NUM>) through the groove (121a); or the lower surface of the first sealing part (<NUM>) is provided with a slot, and the first sealing part (<NUM>) is embedded with the top cover plate (<NUM>) through the slot.