阅读说明：本技术 纽扣电池导线座、纽扣电池组件和纽扣电池组件组装工艺 (Button battery lead seat, button battery assembly and button battery assembly assembling process ) 是由 张丰学 夏祖见 黄亦农 于 2021-08-06 设计创作，主要内容包括：本发明公开一种纽扣电池导线座、纽扣电池组件和纽扣电池组件的组装工艺,本发明纽扣电池导线座在金属底壳主体、金属制成板与绝缘本体之间形成安装空间,以供纽扣电池安装,纽扣电池装入安装空间后,其中一电极可与第一金属弹性结构电导通,从而使外接面的第一电极金属连接区可与纽扣电池的一电极导通；第一电极金属连接区用以供用电设备的电极线焊接,用电设备的电极线与第一电极金属连接区焊接后,可与纽扣电池的电极导通,从而实现用电设备与纽扣电池的电导通；由于用电设备的电极线是焊接于绝缘本体上,焊接固定的难度更小,因此焊接效率更高,从而可提高纽扣电池与用电设备的安装连接效率。(The invention discloses a button battery lead seat, a button battery assembly and an assembly process of the button battery assembly, wherein the button battery lead seat forms an installation space among a metal bottom shell main body, a metal made plate and an insulating body for installing a button battery; the first electrode metal connecting area is used for welding an electrode wire of the electric equipment, and the electrode wire of the electric equipment can be conducted with the electrode of the button battery after being welded with the first electrode metal connecting area, so that the electric conduction of the electric equipment and the button battery is realized; because the electrode wire of the electric equipment is welded on the insulating body, the difficulty of welding and fixing is smaller, so that the welding efficiency is higher, and the installation and connection efficiency of the button cell and the electric equipment can be improved.)

1. A button cell wire base is characterized in that the button cell wire base comprises an external component and a bottom shell component,

the external connection assembly comprises an insulation body, a first metal elastic structure, at least one first electrode metal connection area and at least one second electrode metal connection area;

the insulating body is provided with a battery conducting surface and an external connecting surface which are arranged oppositely;

the battery conducting surface is provided with the first metal elastic structure and is used for electrically contacting an electrode of a button battery when elastic compression occurs;

the external junction is provided with at least one first electrode metal connecting region and at least one second electrode metal connecting region;

said first electrode connecting region being in electrical communication with said first metal spring structure;

the bottom shell assembly comprises a metal bottom shell main body and at least two metal supporting plates;

the metal bottom shell main body is provided with a second metal elastic structure which is used for electrically contacting an electrode of another button cell when elastic compression occurs;

the external joint surface is also provided with at least two metal connecting structures;

said second electrode metal connection region being in electrical communication with at least one of said metal connection structures;

the edge of the metal bottom shell main body is provided with at least two metal supporting plates which are respectively and fixedly connected with the metal connecting structure, and an installation space is formed among the metal bottom shell main body, the metal supporting plates and the insulating body so as to install the button cell.

2. The button battery lead seat according to claim 1, wherein the bottom shell assembly comprises two limiting plates, the two limiting plates are oppositely arranged at the edge of the bottom shell main body, and limiting surfaces of the two limiting plates face the installation space.

3. The button battery lead holder according to claim 2, wherein the two limiting plates are a first limiting plate and a second limiting plate, and the height h1 of the first limiting plate is greater than the height h2 of the second limiting plate.

4. The button cell lead holder according to claim 3, wherein the first metal elastic structure has a first inclination angle, and the second metal elastic structure has a second inclination angle, and the inclination direction of the first inclination angle is identical to the inclination direction of the second inclination angle.

5. The button cell lead holder according to claim 4, wherein the inclination direction of the first inclination angle and the inclination direction of the second inclination angle are the same as the inclination direction formed by the height difference between the first stopper plate and the second stopper plate.

6. The button cell lead holder according to any one of claims 1 to 5, wherein the first electrode metal connection area and the second electrode metal connection area are made of copper, nickel, tin or an alloy of these elements.

7. The button cell lead holder according to any one of claims 1 to 5, wherein the metal support plate and the metal connecting structure are connected by welding.

8. A button cell assembly, comprising a button cell and the button cell lead holder according to any one of claims 1 to 7, wherein the button cell is mounted in the mounting space of the button cell lead holder, one pole of the button cell is electrically connected with the first metal elastic structure, and the other pole of the button cell is electrically connected with the second metal elastic structure.

9. The utility model provides an assembly process of button cell subassembly which characterized in that, includes button cell wire holder and button cell, button cell wire holder is including external subassembly and drain pan subassembly: the external connection assembly comprises an insulation body, a first metal elastic structure, at least one first electrode metal connection area and at least one second electrode metal connection area; the insulating body is provided with a battery conducting surface and an external connecting surface which are arranged oppositely; the conductive surface is provided with a first metal elastic structure which is used for electrically contacting an electrode of a button cell when elastic compression occurs; the external junction surface is provided with at least one first electrode metal connecting region and at least one second electrode metal connecting region; said first electrode connecting region being in electrical communication with said first metal spring structure; the bottom shell assembly comprises a metal bottom shell main body and at least two metal supporting plates; the metal bottom shell main body is provided with a second metal elastic structure which is used for electrically contacting an electrode of another button cell when elastic compression occurs; the external joint surface is also provided with at least two metal connecting structures; said second electrode metal connection region being in electrical communication with at least one of said metal connection structures; at least two metal supporting plates are arranged at the edge of the bottom shell main body and are respectively and fixedly connected to the metal connecting structures, and an installation space is formed among the metal bottom shell main body, the metal supporting plates and the insulating body so as to be used for installing a button cell;

the assembly process comprises the following steps:

placing a button battery on the bottom shell main body, and enabling the bottom of the button battery to be in contact with the second metal elastic structure for electrical conduction;

placing an insulating body on the top of the button battery, and enabling the top of the button battery to be in contact with the first metal elastic structure to be electrically conducted;

extruding the insulating body to elastically compress the first metal elastic structure and the second metal elastic structure;

and fixing the metal support plates with the metal connecting structures respectively to enable the first metal elastic structure and the second metal elastic structure to keep an elastic compression state.

10. The utility model provides an assembly process of button cell subassembly which characterized in that, includes button cell wire holder and button cell, button cell wire holder is including external subassembly and drain pan subassembly: the external connection assembly comprises an insulation body, a first metal elastic structure, at least one first electrode metal connection area and at least one second electrode metal connection area; the insulating body is provided with a battery conducting surface and an external connecting surface which are arranged oppositely; the conductive surface is provided with a first metal elastic structure which is used for electrically contacting an electrode of a button cell when elastic compression occurs; the external junction surface is provided with at least one first electrode metal connecting region and at least one second electrode metal connecting region; said first electrode connecting region being in electrical communication with said first metal spring structure; the bottom shell assembly comprises a metal bottom shell main body and at least two metal supporting plates; the metal bottom shell main body is provided with a second metal elastic structure which is used for electrically contacting an electrode of another button cell when elastic compression occurs; the external joint surface is also provided with at least two metal connecting structures; said second electrode metal connection region being in electrical communication with at least one of said metal connection structures; at least two metal supporting plates are arranged at the edge of the bottom shell main body and are respectively and fixedly connected to the metal connecting structures, and an installation space is formed among the metal bottom shell main body, the metal supporting plates and the insulating body so as to be used for installing a button cell;

the assembly process comprises the following steps:

fixing the metal supporting plates with the metal connecting structures respectively to form mounting spaces among the metal bottom shell main body, the metal supporting plates and the insulating body;

extruding the button battery to the installation space by a certain inclination angle formed between the bottom surface of the button battery and the plane of the metal bottom shell main body, so that the first metal elastic structure and the second metal elastic structure are elastically compressed;

and extruding the button battery, and stopping extruding when the bottom surface of the button battery is relatively parallel to the plane of the metal bottom shell main body, so that the first metal elastic structure and the second metal elastic structure keep an elastic compression state.

Technical Field

The invention relates to the technical field of batteries, in particular to a button battery wire seat, a button battery assembly and an assembly process of the button battery assembly.

Background

In addition, the portable electronic devices are increasingly more complex and light, and therefore have higher endurance requirements. Especially, in recent years, a wearable 3C consumer electronics market has scraped a lot of sales cyclones (such as TWS earphones), and has become an indispensable electronic product in modern life.

In the related art, the button cell is usually welded to an electrode line of the power utilization circuit in an application scenario to keep the button cell and the power utilization circuit connected. Currently, manufacturers have used the circuit to connect the button cell by welding (such as spot welding, impedance welding, ultrasonic welding, laser spot welding, and electric welding of conduction medium value welding type). And button cell's shell is made by stainless steel material, and the welded fastening degree of difficulty of stainless steel material and electrode line is great, leads to welding efficiency lower, has reduced button cell and consumer's installation effectiveness, simultaneously, in welding process, leads to button cell's shell to damage easily, and then reduces button cell's life, leads to button cell to scrap even.

Disclosure of Invention

The invention mainly aims to provide a button battery wire seat and aims to solve the technical problem of how to improve the installation efficiency of a button battery and electric equipment.

In order to achieve the purpose, the invention provides a wire holder of a button cell, which comprises an external connection component and a bottom shell component,

the external connection assembly comprises an insulation body, a first metal elastic structure, at least one first electrode metal connection area and at least one second electrode metal connection area;

the insulating body is provided with a battery conducting surface and an external connecting surface which are arranged oppositely;

the battery conducting surface is provided with the first metal elastic structure and is used for electrically contacting an electrode of a button battery when elastic compression occurs;

the external junction is provided with at least one first electrode metal connecting region and at least one second electrode metal connecting region;

said first electrode connecting region being in electrical communication with said first metal spring structure;

the bottom shell assembly comprises a metal bottom shell main body and at least two metal supporting plates;

the metal bottom shell main body is provided with a second metal elastic structure which is used for electrically contacting an electrode of another button cell when elastic compression occurs;

the external joint surface is also provided with at least two metal connecting structures;

said second electrode metal connection region being in electrical communication with at least one of said metal connection structures;

the edge of the metal bottom shell main body is provided with at least two metal supporting plates which are respectively and fixedly connected with the metal connecting structure, and an installation space is formed among the metal bottom shell main body, the metal supporting plates and the insulating body so as to install the button cell.

Optionally, the bottom shell assembly includes two limiting plates, the two limiting plates are disposed at the edge of the bottom shell main body, and the limiting surfaces of the two limiting plates face the installation space.

Optionally, the two limiting plates are respectively a first limiting plate and a second limiting plate, and the height h1 of the first limiting plate is greater than the height h2 of the second limiting plate.

Optionally, the first metal elastic structure has a first inclination angle, the second metal elastic structure has a second inclination angle, and an inclination direction of the first inclination angle is consistent with an inclination direction of the second inclination angle.

Optionally, the inclination direction of the first inclination angle and the inclination direction of the second inclination angle are consistent with the formed inclination direction of the height difference between the first limiting plate and the second limiting plate.

Optionally, the first electrode metal connection region and the second electrode metal connection region are made of copper, nickel, tin or an alloy of these elements.

Optionally, the metal support plate and the metal connecting structure are connected by welding.

The invention further provides a button battery assembly, which comprises a button battery and the button battery lead seat, wherein the button battery is arranged in the installation space of the button battery lead seat, one pole of the button battery is electrically communicated with the first metal elastic structure, and the other pole of the button battery is electrically communicated with the second metal elastic structure.

The invention also provides an assembly process of the button battery, which comprises the button battery and the button battery lead seat, and the assembly process comprises the following steps:

placing a button battery on the bottom shell main body, and enabling the bottom of the button battery to be in contact with the second metal elastic structure for electrical conduction;

placing an insulating body on the top of the button battery, and enabling the top of the button battery to be in contact with the first metal elastic structure to be electrically conducted;

extruding the insulating body to elastically compress the first metal elastic structure and the second metal elastic structure;

and fixing the metal support plates with the metal connecting structures respectively to enable the first metal elastic structure and the second metal elastic structure to keep an elastic compression state.

The invention also provides an assembly process of the button battery, which comprises the button battery and the button battery lead seat, and the assembly process comprises the following steps:

fixing the metal supporting plates with the metal connecting structures respectively to form mounting spaces among the metal bottom shell main body, the metal supporting plates and the insulating body;

extruding the button battery to the installation space by a certain inclination angle formed between the bottom surface of the button battery and the plane of the metal bottom shell main body, so that the first metal elastic structure and the second metal elastic structure are elastically compressed;

and extruding the button battery, and stopping extruding when the bottom surface of the button battery is relatively parallel to the plane of the metal bottom shell main body, so that the first metal elastic structure and the second metal elastic structure keep an elastic compression state.

According to the button battery lead seat, an installation space is formed among the metal bottom shell main body, the metal plate and the insulating body, so that a button battery can be installed, after the button battery is installed in the installation space, one electrode can be electrically conducted with the first metal elastic structure, and therefore the first electrode metal connection area of the external connection surface can be conducted with one electrode of the button battery; the other electrode is electrically communicated with the second metal elastic structure, so that the second electrode metal connecting area of the external connecting surface can be communicated with the other electrode of the button cell; the first electrode metal connecting area and the second electrode metal connecting area are used for welding or abutting contact of positive and negative electrode wires of the electric equipment, and electrode wires of the electric equipment can be conducted with the electrode of the button cell after being welded with the first electrode metal connecting area and the second electrode metal connecting area, so that the electric conduction of the electric equipment and the button cell is realized; because the electrode line of consumer welds on insulator, the welded fastening or the degree of difficulty of contradicting the contact is littleer, consequently welding efficiency is higher to can improve button cell and consumer's erection joint efficiency.

In addition, because the electrode wire of the power consumption equipment is not directly welded on the button cell, the button cell can be prevented from being damaged in the welding process. If the electric energy of the button battery is exhausted or fails, the button battery can be replaced by dismounting the button battery from the button battery lead seat, thereby reducing the replacement difficulty of the button battery, improving the replacement efficiency of the button battery,

furthermore, the external component is fixedly connected with the bottom shell component, the button battery is accommodated in the installation space, and the shell of the button battery is extruded, so that the service life of the button battery can be prolonged; can also avoid button cell to bring danger in breaking down, for example the short circuit, inside produces gas fast, flushes button cell casing, causes the explosion, owing to have stopping of external subassembly and drain pan subassembly, leads to button cell's shell to be difficult to flush, forms the space and investigates gas, and then can't cause the explosion and cause the damage.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

Fig. 1 is a schematic structural view of a button battery lead base according to an embodiment of the invention;

FIG. 2 is a schematic structural view of another embodiment of a button cell lead holder according to the present invention;

FIG. 3 is a schematic cross-sectional view of a button cell lead base according to an embodiment of the invention;

FIG. 4 is a schematic cross-sectional view of another embodiment of a button cell lead base according to the present invention;

FIG. 5 is a schematic structural view of an embodiment of a button cell assembly according to the present invention;

FIG. 6 is a schematic flow chart illustrating an assembly process of a button cell assembly according to an embodiment of the present invention;

fig. 7 is a schematic flow chart of an assembly process of a button cell assembly according to another embodiment of the invention.

The reference numbers illustrate:

the implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that, if directional indications (such as up, down, left, right, front, and back … …) are involved in the embodiment of the present invention, the directional indications are only used to explain the relative positional relationship between the components, the movement situation, and the like in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indications are changed accordingly.

In addition, if there is a description of "first", "second", etc. in an embodiment of the present invention, the description of "first", "second", etc. is for descriptive purposes only and is not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the meaning of "and/or" appearing throughout is to include three juxtapositions, exemplified by "A and/or B," including either the A or B arrangement, or both A and B satisfied arrangement. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

The invention provides a button cell wire holder which is used as an intermediate connecting piece between a button cell 40 and electric equipment, wherein the button cell 40 can be arranged on the button cell wire holder and electrically conducted, and an electrode wire of the electric equipment can be welded on the button cell wire holder, so that the electric equipment and the button cell 40 are electrically conducted.

In the embodiment of the invention, as shown in fig. 1 to 5 to fig. 5, the button cell wire holder comprises an external connection component and a bottom shell component,

the external connection component comprises an insulating body 10, a first metal elastic structure 50, at least one first electrode metal connection area 13 and at least one second electrode metal connection area 14;

the insulating body 10 is provided with a battery conducting surface 11 and an external connection surface 12 which are arranged oppositely;

the battery conducting surface 11 is provided with the first metal elastic structure 50, and is used for electrically contacting an electrode of a button battery 40 when elastic compression occurs;

said external junction 12 is provided with at least one said first electrode metal connection region 13 and at least one said second electrode metal connection region 14;

said first electrode connection region being in electrical communication with said first metallic elastic structure 50;

the bottom shell assembly comprises a metal bottom shell body 20 and at least two metal support plates 22;

the metal bottom shell main body 20 is provided with a second metal elastic structure 24 for electrically contacting an electrode of another button cell 40 when the elastic compression occurs;

the outer joint surface 12 is further provided with at least two metal connecting structures;

said second electrode metal connection region 14 is in electrical communication with at least one of said metal connection structures;

at least two metal supporting plates 22 are arranged at the edge of the metal bottom shell main body 20 and are respectively and fixedly connected to the metal connecting structure, and an installation space 30 is formed among the metal bottom shell main body 20, the metal supporting plates 22 and the insulating body 10 so as to install the button cell 40.

The insulating body 10 may be a circular plate or a square plate, and is not particularly limited. The first electrode metal connection area 13 is used for welding or abutting contact electric conduction of an electrode wire of an electric device, the electrode wire of the electric device may be a positive electrode wire or a negative electrode wire, and no limitation is imposed on the electrode wire, specifically for example, when the first electrode metal connection area 13 is electrically conducted with the positive electrode of the button cell 40, the positive electrode wire of the electric device is welded or abutting contact electric conduction with the button cell; when the first electrode metal connecting region 13 is electrically connected with the negative electrode of the button cell 40, the negative electrode wire of the electric device is welded or in contact with the button cell.

The shape of the metal bottom case main body 20 may correspond to that of the insulating body 10, so that the installation space 30 formed by the metal bottom case main body 20 and the insulating body 10 is more regular, for example, the metal bottom case main body 20 and the insulating body 10 are both configured as circular plates, so that the installation space 30 is adapted to the button cell 40 in a circular button shape. After the button cell 40 is installed in the installation space 30, one end surface of the button cell 40 abuts against the cell conduction surface 11, and one electrode of the button cell 40 is formed on the end surface, and the electrode may be a positive electrode or a negative electrode, which is not limited specifically. The purpose of the contact between the battery conducting surface 11 and the button cell 40 is to better fix the button cell 40, and therefore, the battery conducting surface 11 and the button cell 40 may be in direct contact or indirect contact, or only needs to be stably fixed in the installation space 30 when the button cell 40 is determined to be able to be good without contact. Preferably, the battery conducting surface 11 is insulated, and after the first metal elastic structure 50 is electrically connected with one electrode of the button battery 40, the first metal elastic structure is electrically connected with the first electrode metal connection region 13 through an internal trace of the insulating body 10.

The second electrode metal connection region 14 is used for welding or abutting contact electrical conduction of an electrode wire of an electrical device, and may be a positive electrode wire or a negative electrode wire, which is not limited herein, specifically for example, when the second electrode metal connection region 14 is electrically conducted with a positive electrode of the button cell 40, the positive electrode wire of the electrical device is welded or abutting contact electrical conduction therewith; when the second electrode metal connecting region 14 is electrically connected to the negative electrode of the button cell 40, the negative electrode wire of the electric device is welded or in contact therewith.

The metal bottom case body 20 is made of a conductive material such as stainless steel, and copper, nickel, tin or an alloy of these elements to maintain sufficient structural strength while being conductive.

After the button cell 40 is installed in the installation space 30, the positive electrode abuts against the first metal elastic structure 50 on the insulating body 10, the negative electrode abuts against the second metal elastic structure 24 on the metal bottom case main body 20, namely, the positive electrode of the button cell 40 can be electrically conducted with the first electrode metal connection area 13 on the insulating body 10, so that the positive electrode wire welded on the first electrode metal connection area 13 can be electrically conducted with the negative electrode of the button cell 40, the negative electrode of the button cell 40 can be electrically conducted with the second electrode metal connection area 14 on the insulating body 10, so that the negative electrode wire welded on the second electrode metal connection area 14 can be electrically conducted with the negative electrode of the button cell 40, and the button cell 40 and the electric equipment can form a current loop through the button cell wire seat.

Because the positive pole line and the negative pole line of the electric equipment can be welded on the insulating body 10, the connection difficulty of the electric equipment and the button cell 40 can be further reduced, and the connection efficiency and the connection strength can be improved. Compared with the traditional method for welding two end faces of a button cell, the method can be used for directly welding one face, can be completed in one step particularly in the automatic welding process, improves the welding efficiency, and further, the first electrode metal connecting area 13 and the second electrode metal connecting area 14 on the insulating body 10 can be made of any conductive metal or non-metal material, preferably, the material is selected from copper, nickel, tin or alloy of the elements. The first electrode metal connection region 13 and the second electrode metal connection region 14 are used for electrode wire welding and conducting electricity, and copper, nickel and tin can reduce the connection difficulty during welding so as to further improve the welding efficiency.

In addition, when the button cell 40 is replaced, the electrode wire does not need to be operated, and only the button cell 40 needs to be disassembled and assembled, so that the replacement efficiency of the button cell 40 is further improved.

Further, in order to facilitate welding, the first electrode metal connection region 13 and the second electrode metal connection region 14 are disposed at adjacent positions on the same side, so that automatic welding is facilitated, that is, welding of a positive electrode wire and a negative electrode wire of an electric device can be completed at the same time. Of course, in order to better adapt to various devices, a plurality of first electrode metal connecting areas 13 and second electrode metal connecting areas 14 may be provided, and preferably, one first electrode metal connecting area 13 and two second electrode metal connecting areas 14 are provided, wherein one first electrode metal connecting area 13 and one second electrode metal connecting area 14 are provided at adjacent positions on the same side, so that welding can be facilitated; the other second electrode metal connection region 14 is disposed at the other side opposite to the first electrode metal connection region 13, which facilitates the interference contact, so that the force applied during the interference contact is uniform.

The method can be understood as setting one positive metal connection area and two negative metal connection areas, or two positive metal connection areas and one negative metal connection area, wherein one positive metal connection area and one negative metal connection area are set at adjacent positions on the same side, and the other positive metal connection area or negative metal connection area is set at an opposite position on the other side, and in a specific use process, if an external electric device adopts a welding mode, the positive metal connection area and the negative metal connection area adjacent on the same side can be preferably selected for use, so that the welding can be facilitated; if the mode of conflict electric conduction is carried out, the positive pole metal connecting area and the negative pole metal connecting area which are opposite to each other at two sides can be selected and used preferably, so that the uniformity of conflict electric conduction stress can be facilitated, and the stability is further improved.

The metal supporting plate 22 is used to fixedly connect the metal bottom case main body 20 and the insulating body 10, and the metal supporting plate 22 and the metal bottom case main body 20 can be integrally injection-molded to improve the structural strength and reduce the processing difficulty. It should be understood that the metal supporting plate 22 not only serves to support the fixed connection, but also serves to transmit electric conduction from the second metal elastic structure 24 on the metal bottom case body 20 to the metal connection structure by making interference contact with the bottom of the button cell 40. The two metal support plates 22 are opposite to each other, and can limit the button cell 40 in the installation space 30 from two opposite directions. The end of the metal supporting plate 22 is away from the end of the metal bottom case main body 20, and after the end of the metal supporting plate 22 is fastened to the external connection surface 12 of the insulating body 10, the metal bottom case main body 20 can be electrically connected to the external connection surface 12.

According to the button cell lead seat, an installation space 30 is formed among the metal bottom shell main body 20, the metal support plate and the insulating body 10 so as to be used for installing the button cell 40, after the button cell 40 is installed in the installation space 30, one electrode of the button cell 40 can be electrically conducted with the first metal elastic structure 50, and therefore the first electrode metal connection area 13 of the external connection surface 12 can be conducted with one electrode of the button cell 40; the other electrode is electrically connected with the second metal elastic structure 24, so that the second electrode metal connection region 14 of the external connection surface 12 can be electrically connected with the other electrode of the button cell 40; the first electrode metal connecting area 13 and the second electrode metal connecting area 14 are used for welding or abutting against and electrically conducting positive and negative electrode wires of the electric equipment, and electrode wires of the electric equipment can be conducted with the electrodes of the button cell 40 after being welded or abutting against and contacted with the first electrode metal connecting area 13 and the second electrode metal connecting area 14, so that the electric equipment is electrically conducted with the button cell 40; because the electrode wire of the electric equipment is welded on the insulating body 10, the difficulty of welding fixation or contact conflict is smaller, so that the welding efficiency is higher, and the installation and connection efficiency of the button cell 40 and the electric equipment can be improved.

In addition, since the electrode wires of the electric equipment are not directly welded to the button cell 40, the button cell 40 can be prevented from being damaged by the welding process. If the electric energy of the button cell 40 is exhausted or fails, the button cell 40 can be disassembled and assembled from the button cell wire seat to realize replacement, so that the replacement difficulty of the button cell 40 is reduced, and the replacement efficiency of the button cell 40 is improved.

Further, the external connection assembly is fixedly connected with the bottom shell assembly, the button cell 40 is accommodated in the installation space 30, the shell of the button cell 40 is extruded, the service life of the button cell 40 can be prolonged, gas can be generated when an electric core of the button cell 40 works, the shell of the button cell 40 can be extruded when the gas is too much, and if the shell is extruded all the time, the positive and negative shells of the button cell 40 can be loosened and then contacted with air, so that the service life of the button cell 40 is shortened; the button cell 40 can also be avoided bringing danger in breaking down, for example the short circuit, and inside quick production is gaseous, breaks away button cell 40 casing, causes the explosion, owing to have stopping of external subassembly and drain pan subassembly, leads to button cell 40's shell to be difficult to break away, forms the space and inspects gas, and then can't cause the explosion to cause the damage.

The first metal elastic structure 50 may be a conductive elastic sheet additionally connected to the insulating body 10, and the specific form of the first metal elastic structure 50 is not limited, and only needs to have elasticity and tilt to the installation space 30. The first metal elastic structure 50 can ensure the abutting with the button cell 40, thereby improving the electrical conduction stability of the insulating body 10 and the button cell 40.

The second metal elastic structure 24 can be integrally formed on the metal bottom case body 20, so as to reduce the cost of the second metal elastic structure 24. The second metal elastic structure 24 can ensure the abutting with the button cell 40, thereby improving the stability of the electrical conduction between the metal bottom case main body 20 and the button cell 40, or stably clamping the electrode wire to the button cell 40. Because two end faces of the button cell 40 are respectively contacted with the first metal elastic structure 50 and the second metal elastic structure 24 in an abutting mode, the shock absorption effect can be achieved, and the damage of the cell caused by the vibration of electronic equipment in fading can be avoided.

In an embodiment, as shown in fig. 1 to 5, the bottom shell assembly includes two position limiting plates, the two position limiting plates are oppositely disposed at the edge of the bottom shell main body, and the position limiting surfaces of the two position limiting plates face the installation space 30. The limiting plate is used for limiting and abutting against the peripheral wall of the button cell 40 so as to prevent the button cell 40 from separating from the mounting space 30. In combination with the above-mentioned embodiment of the metal support plate 22, the two metal support plates 22 and the two limiting plates can be distributed at intervals along the circumferential direction of the installation space 30, so as to limit the button cell 40 from four directions, thereby further improving the installation stability of the button cell 40.

Specifically, the two limiting plates are a first limiting plate 231 and a second limiting plate 232, respectively, and the height h1 of the first limiting plate 231 is greater than the height h2 of the second limiting plate 232. An installation opening can be formed between the end of the second limiting plate 232 and the insulating body 10, so that the button cell 40 enters the installation space 30 from the installation opening, or is detached from the installation space 30 from the installation opening, thereby reducing the difficulty in detaching the button cell 40. And first limiting plate 231 can increase the spacing butt area with button cell 40 to improve spacing stability, and avoid button cell 40 to extrude away on one side in addition when the installation.

In one embodiment, as shown in fig. 1 and 3, the peripheral wall of the insulating housing 10 is provided with a positioning groove 15, and the end of the metal supporting plate 22 is positioned and matched with the positioning groove 15. The end of the metal supporting plate 22 passes through the positioning slot 15 and then is fastened to the external surface 12 of the insulating body 10. The positioning groove 15 can prevent the metal supporting plate 22 from moving along the circumferential direction of the insulating housing 10, so as to improve the connection stability between the metal bottom housing main body 20 and the insulating housing 10. In addition, the side of the metal supporting plate 22 can be protruded with a limiting rib, and the limiting rib abuts against the battery conducting surface 11 of the insulating body 10 to cooperate with the end of the metal supporting plate 22 to limit and fix the metal bottom case main body 20 and the insulating body 10 in the axial direction, so that the connection stability between the insulating body 10 and the metal bottom case main body 20 is further improved. Preferably, the insulating body 10 of the present application is a PCBA board and a PCB board, which facilitates direct integration of other electronic devices thereon, and improves the utilization rate of air.

In one embodiment, as shown in fig. 1 to 5, the button cell wire holder further includes a circuit protection chip 60 mounted on the external connection surface 12 for protecting the current stability between the electrical device and the button cell 40, and preventing one of the button cell 40 or the electrical device from being damaged when the other one fails, so as to improve the current transmission stability of the button cell wire holder.

In practical application, the first electrode metal connection area 13 and the second electrode metal connection area 14 can be respectively provided with a positive mark and a negative mark for distinguishing by welding personnel, so that the welding difficulty is further reduced.

In one embodiment, the first metal elastic structure 50 has a first inclination angle, and the second metal elastic structure 24 has a second inclination angle, and the inclination direction of the first inclination angle is the same as the inclination direction of the second inclination angle. Under the condition of consistent inclination directions, the button cell 40 can be conveniently extruded into the installation space 30, that is, when the button cell 40 is placed into the installation space 30, the button cell can be conveniently installed by extruding along the inclination directions of the first metal elastic structure 50 and the second metal elastic structure 24.

The first inclination angle and the second inclination angle are inclined relative to the height direction of the limiting plate, and the first metal elastic structure 50 and the second metal elastic structure 24 are both inclined towards the direction away from the second limiting plate 232, namely towards the direction away from the loading port, so that when the button cell 40 enters the installation space 30 from the loading port, the first metal elastic structure 50 and the second metal elastic structure 24 can play a role in guiding the button cell 40, and the process that the button cell 40 enters the installation space 30 is simpler and more convenient; and after the button cell 40 is mounted in place, the first metal elastic structure 50 and the second metal elastic structure 24 can play a role in clamping and fixing the button cell 40, so as to improve the mounting stability of the button cell 40.

Specifically, the inclination direction of the first inclination angle and the inclination direction of the second inclination angle are the same as the inclination direction formed by the height difference of the first restriction plate 231 and the second restriction plate 232; therefore, the guiding direction of the first metal elastic structure 50 and the second metal elastic structure 24 to the button cell 40 is consistent with the loading direction of the button cell 40, so as to further improve the loading efficiency of the button cell 40.

In an embodiment, the material of the first electrode metal connection region 13 and the second electrode metal connection region 14 is copper, nickel, tin, or an alloy of these elements. The first electrode metal connection region 13 and the second electrode metal connection region 14 are used for electrode wire welding and conducting electricity, and copper, nickel and tin can reduce the connection difficulty during welding so as to further improve the welding efficiency.

Specifically, the metal support plate 22 and the metal connection structure are connected by welding, so that the connection difficulty is reduced, the contact resistance can be effectively reduced, and the connection strength is improved.

As shown in fig. 5, the present invention further provides a button battery assembly, which includes a button battery 40 and a button battery wire holder, and the specific structure of the button battery wire holder refers to the above embodiments, and since the button battery assembly adopts all the technical solutions of all the above embodiments, the button battery assembly at least has all the beneficial effects brought by the technical solutions of the above embodiments, and details are not repeated herein.

The button cell 40 is mounted in the mounting space 30 of the button cell wire holder, one pole of the button cell 40 is electrically connected to the first metal elastic structure 50, and the other pole of the button cell 40 is electrically connected to the second metal elastic structure 24.

As shown in fig. 6, the present invention further provides an assembly process of a button cell assembly, including a button cell 40 and a button cell wire holder, where the button cell wire holder includes an external connection assembly and a bottom shell assembly: the external connection component comprises an insulating body 10, a first metal elastic structure 50, at least one first electrode metal connection area 13 and at least one second electrode metal connection area 14; the insulating body 10 is provided with a battery conducting surface 11 and an external connection surface 12 which are arranged oppositely; the conductive surface is provided with a first metal elastic structure 50 for electrically contacting an electrode of a button cell 40 when elastic compression occurs; said external junction 12 is provided with at least one first electrode metal connection region 13 and at least one second electrode metal connection region 14; said first electrode connection region being in electrical communication with said first metallic elastic structure 50; the bottom shell assembly comprises a metal bottom shell body 20 and at least two metal support plates 22; the metal bottom shell main body 20 is provided with a second metal elastic structure 24 for electrically contacting an electrode of another button cell 40 when the elastic compression occurs; the outer joint surface 12 is further provided with at least two metal connecting structures; said second electrode metal connection region 14 is in electrical communication with at least one of said metal connection structures; at least two metal supporting plates 22 are arranged at the edge of the bottom shell main body and are respectively fixedly connected to the metal connecting structures, and an installation space 30 is formed among the metal bottom shell main body 20, the metal supporting plates 22 and the insulating body 10 so as to be used for installing a button battery 40;

the assembly process comprises the following steps:

s1, placing the button cell 40 on the bottom case main body, so that the bottom of the button cell 40 is in contact with the second metal elastic structure 24 for electrical conduction;

s2, placing the insulating body 10 on top of the button cell 40, so that the top of the button cell 40 is in contact with the first metal elastic structure 50 for electrical conduction;

s3, pressing the insulating body 10 to elastically compress the first metal elastic structure 50 and the second metal elastic structure 24;

s4, fixing the metal supporting plates 22 to the metal connecting structures respectively, so that the first metal elastic structure 50 and the second metal elastic structure 24 are kept in an elastic compression state.

The assembly process can reduce the assembly difficulty of the button battery 40 and the button battery lead seat, improve the assembly efficiency and simultaneously avoid overlarge stress of the button battery 40 and the button battery lead seat in the assembly process. It should be understood that the button cell assembly in the present application includes the button cell 40 and the button cell wire holder, and the button cell 40 is firstly placed on the bottom case assembly of the button cell wire holder, and then the external connection assembly and the bottom case assembly are fixedly connected together, so that the structural design requirements on the first metal elastic structure 50 and the second metal elastic structure 24 of the button cell wire holder are relatively simple.

As shown in fig. 7, the present invention further provides an assembly process of a button cell assembly, including a button cell 40 and a button cell wire holder, where the button cell wire holder includes an external connection assembly and a bottom shell assembly: the external connection component comprises an insulating body 10, a first metal elastic structure 50, at least one first electrode metal connection area 13 and at least one second electrode metal connection area 14; the insulating body 10 is provided with a battery conducting surface 11 and an external connection surface 12 which are arranged oppositely; the conductive surface is provided with a first metal elastic structure 50 for electrically contacting an electrode of a button cell 40 when elastic compression occurs; said external junction 12 is provided with at least one first electrode metal connection region 13 and at least one second electrode metal connection region 14; said first electrode connection region being in electrical communication with said first metallic elastic structure 50; the bottom shell assembly comprises a metal bottom shell body 20 and at least two metal support plates 22; the metal bottom shell main body 20 is provided with a second metal elastic structure 24 for electrically contacting an electrode of another button cell 40 when the elastic compression occurs; the outer joint surface 12 is further provided with at least two metal connecting structures; said second electrode metal connection region 14 is in electrical communication with at least one of said metal connection structures; at least two metal supporting plates 22 are arranged at the edge of the bottom shell main body and are respectively fixedly connected to the metal connecting structures, and an installation space 30 is formed among the metal bottom shell main body 20, the metal supporting plates 22 and the insulating body 10 so as to be used for installing a button battery 40;

the assembly process comprises the following steps:

s10, fixing the metal supporting plates 22 to the metal connecting structures respectively, so that an installation space 30 is formed between the metal bottom case main body 20, the metal supporting plates 22 and the insulating body 10;

s20, pressing the button cell 40 toward the installation space 30 by a certain inclination angle between the bottom surface of the button cell 40 and the plane of the metal bottom case main body 20, so that the first metal elastic structure 50 and the second metal elastic structure 24 are elastically compressed;

s30, pressing the button cell 40, and stopping pressing when the bottom surface of the button cell 40 is relatively parallel to the plane of the metal bottom case main body 20, so that the first metal elastic structure 50 and the second metal elastic structure 24 maintain an elastic compression state.

The assembly process can reduce the assembly difficulty of the button battery 40 and the button battery lead seat, improve the assembly efficiency and simultaneously avoid overlarge stress of the button battery 40 and the button battery lead seat in the assembly process. It should be understood that the button cell assembly in the present application includes the button cell 40 and the button cell wire holder, and the button cell 40 is placed in the mounting space 30 after the external component and the bottom case component are fixedly connected to each other, so that the button cell can be rapidly mounted.

The above description is only an alternative embodiment of the present invention, and not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.