KR101886719B1 - Holder for holding button type elecric cell - Google Patents

Abstract

The present invention relates to a button cell holder for mounting a button cell. The present invention relates to a mobile communication terminal comprising: a cell mounting portion to which a button cell is mounted; And a terminal portion electrically connected to the button cell. According to a preferred embodiment, the present invention relates to a lower body comprising: a lower body; An upper body coupled to an upper portion of the lower body; A cell mounting portion formed between the lower body and the upper body and having a button cell mounted thereon; A terminal portion electrically connected to the button cell; And a rotational coupling means for rotationally coupling the lower body and the upper body. INDUSTRIAL APPLICABILITY According to the present invention, it is possible to easily and stably mount a button cell, and to perform performance measurement and charge / discharge of a button cell easily.

Description

Button cell holder {HOLDER FOR HOLDING BUTTON TYPE ELECRIC CELL}

The present invention relates to a button cell holder for mounting a button cell, more specifically, a button cell can be easily and stably mounted, and a performance of a button cell can be easily measured and charged / discharged. And more particularly to a button cell holder capable of injecting air or the like.

In general, the performance of a battery cell such as a primary battery or a secondary battery is measured after the completion of manufacture. For example, electrochemical devices such as lithium ion batteries, capacitors, and the like, which are widely used as power sources for various electronic products such as portable electronic devices, are known.

Performance measurement is also important for evaluating battery cells by performance (grade) by evaluating electrical characteristics such as voltage, current, and capacity of manufactured battery cells, but it is very important for reliability with consumers. If the battery cell does not meet the required characteristics or is poor enough to be driven, it may damage the associated electric / electronic product or cause a risk of explosion.

Thus, most of the battery cells are subjected to performance measurement as a part of reliability before being supplied to the consumer. For example, in the case of a battery cell such as a lithium ion battery or a super capacitor, a self-discharge (SD), a leakage current (L / C), a capacitance (CAP) And electrical characteristics such as ESR (Equivalent Series Resistance) are measured.

Also, most of the battery cells are preceded by aging before the performance is measured. Generally, aging is carried out by injecting a battery cell into a chamber, and then aging by applying a temperature and a voltage. The actual performance of the battery cell is measured after the aging process is performed, and after the quality is verified by the aging process and the performance measurement, the battery cell is supplied to the consumer. That is, the reliability of the product can be verified by confirming in advance whether the battery cell is properly driven by the ambient temperature change or the like through aging and performance measurement as described above.

Generally, the battery cell is classified into a cylindrical shape, a square shape (plate shape), and a button shape depending on its shape. 1 and 2 illustrate battery cells. Fig. 1 shows a cylindrical battery cell 1, and Fig. 2 shows a button-shaped battery cell 10. Fig. 1, the cylindrical battery cell 1 includes a cylindrical main body 2 and two terminals 4 of a positive (+) and a negative (-) protruding from both sides of the main body 2 do.

2, a button-type battery cell 10 (hereinafter referred to as a "button cell") includes a cathode can 12, a cathode can 14 coupled to the anode can 12, And an insulating gasket 13 for insulation between the can 12 and the anode can 14. The button cell 10 has a button shape by pressing and assembling the anode can 12 and the anode can 14. Such a button cell 10 is mainly used for small electronic appliances, and is commonly referred to as a coin type electric cell in view of its shape.

As shown in Fig. 2, the button cell 10 is provided with a product in the form of an air cell in which a gas injection hole 15 is formed. In this air cell product, when air is injected through the gas injection hole 15, oxygen in the air oxidizes the metal (such as lithium or zinc) contained in the two cans 12 and 14 to generate chemical energy Electrical energy.

Generally, a cell holder is used for measuring the aging performance of the battery cell. That is, the battery cell is mounted (fixed) on the holder, and the aging process, the performance measurement, and the like proceed. The cell holder is also used for charging / discharging the battery cell. Such a cell holder has a structure capable of stably mounting the battery cell and electrically connecting the terminal (+) (-) of the battery cell and the performance measuring device.

For example, Korean Patent No. 10-0987942, Korean Patent No. 10-1180760, Korean Patent No. 10-1432523, Korean Patent Laid-Open No. 10-2012-0032742, Japanese Patent Application Laid-Open No. 2013-058348, Japanese Laid-Open Patent Publication No. JP-A-2016-046040 discloses a technique related to the above.

The conventional cell holder including the above-mentioned patent documents is limited to a cylindrical or square battery cell. In other words, the conventional cell holder is limited to the battery cell 1 having a cylindrical shape as shown in FIG. 1 in most cases, and the button cell 10 (= coin cell) shown in FIG. 2 is mounted There is no dedicated holder for this. Thus, in the case of the button cell 10 shown in Fig. 2, a clamping type connection fixture (usually a serrated crocodile clip) is used.

However, there is a problem that the jig-type connection fixture can not be stably mounted (fixed) on the button cell 10 and is easily detached. Also, good electrical connection with the can 12 (14) is difficult. For example, in the case of a serrated clip (alligator clip), the area of contact with the can 12 (14) is small due to point-connecting. As described above, when the contact area with the can 12 (14) is small, overheating or high temperature is generated at the contact point at the time of application of a high current, which may adversely affect the electrical characteristics of the button cell 10, An error may occur in measurement or the like.

Also, when the air cell is used as the target, the performance measurement process is troublesome and time consuming. Specifically, when measuring the performance of the air cell type button cell 10 as shown in FIG. 2, air (oxygen) is first injected into the gas injection hole 15 using an air injector. Then, air cells injected with air are fixed to the jig-type connecting fixture by a separate process, and then the performance is measured. Accordingly, since the injection of air and the performance measurement are separately performed, the performance measurement process is troublesome and takes a long time, and the button cell 10 is easily separated from the connection fixture.

Korean Patent No. 10-0987942 Korean Patent No. 10-1180760 Korean Patent No. 10-1432523 Korean Patent Publication No. 10-2012-0032742 Japanese Patent Application Laid-Open No. 2013-058348 Japanese Laid-Open Patent Application No. JP2016-046040

Accordingly, it is an object of the present invention to provide an improved button cell holder. Specifically, it is an object of the present invention to provide a button cell holder that can easily and stably mount a button cell (= coin cell) through storage and rotation operations.

It is another object of the present invention to provide a button cell holder capable of injecting gas such as air and capable of easily performing air injection and performance measurement on an air cell product.

According to an aspect of the present invention,

A cell mounting portion on which the button cell is mounted; And

And a terminal portion electrically connected to the button cell.

According to a preferred embodiment,

A lower body;

An upper body coupled to an upper portion of the lower body;

A cell mounting portion formed between the lower body and the upper body and having a button cell mounted thereon;

A terminal portion electrically connected to the button cell; And

And a rotational coupling means for rotationally coupling the lower body and the upper body.

In this case,

A coupling protrusion formed on the lower body and having a first thread formed on the outer periphery; And

And a coupling groove portion formed in the upper body and having a second screw thread formed on an inner peripheral edge thereof.

Further, the button cell holder according to the present invention may further include a stopper for preventing further rotation when the lower body and the upper body are rotationally coupled. At this time, the stopper includes a protrusion formed on the lower body and a guide groove formed on the upper body, wherein when the lower body and the upper body are rotationally coupled, the protrusion is attached to the other end of the guide groove It is caught by the formed locking jaws so that further rotation can be prevented.

In addition, the button cell holder according to the present invention may further include a gas injection unit into which gas such as air or oxygen is injected. According to an exemplary embodiment of the present invention, the gas injecting unit includes an injection unit body, a fixing member elastically fixing the gas injector inserted into the injection unit body, a detent pin preventing the detachment of the fixing member, And an elastic member for applying an elastic force to the fixing member.

According to the present invention, it is possible to easily and stably mount the button cell through the receiving and rotating operation.

Further, according to the present invention, it is possible to inject air, oxygen, and the like, so that the injection of air and oxygen, performance measurement, and the like can be simultaneously and easily carried out while the button cell of the air cell product or the like is attached to the cell holder .

1 is a perspective view showing a cylindrical battery cell.
2 is a partially cut perspective view showing a button cell (a button cell).
3 is an assembled perspective view of a button cell holder according to an embodiment of the present invention.
4 is an exploded perspective view of a button cell holder according to an embodiment of the present invention.
FIG. 5 is an exploded perspective view of a button cell holder according to an embodiment of the present invention, showing a bottom surface of an upper body. FIG.
6 is a detailed exploded perspective view of a button cell holder according to an embodiment of the present invention.
7 is a perspective view for explaining the operation of the gas injecting unit and the gas discharging unit constituting the button cell holder according to the embodiment of the present invention.
8 is an exploded cross-sectional view of a button cell holder according to an embodiment of the present invention.

The term "and / or" used in the present invention is used to mean at least one of the constituents listed before and after. The term "one or more" as used in the present invention means one or more than two. In the present invention, terms such as " first ", "second "," one side ", and "other side" are used to distinguish one element from another, It is not.

Hereinafter, the present invention will be described with reference to the accompanying drawings. BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention. In addition, in the accompanying drawings, the thickness may be enlarged to clearly show the area of each component, and the technical scope of the present invention is not limited by the thickness, size and ratio shown in the drawings.

FIG. 3 is an exploded perspective view of a button cell holder according to an embodiment of the present invention, and FIG. 4 is an exploded perspective view of a button cell holder according to an embodiment of the present invention. FIG. 5 is an exploded perspective view of a button cell holder according to an embodiment of the present invention. FIG. 5 is a bottom perspective view of an upper body. FIG. 6 is a detailed exploded perspective view of a button cell holder according to an embodiment of the present invention, and FIG. 7 is a perspective view illustrating an operation of a gas injection unit and a gas discharge unit constituting the button cell holder according to the embodiment of the present invention. And FIG. 8 is an exploded cross-sectional view of a button cell holder according to an embodiment of the present invention.

The present invention provides a button cell holder capable of mounting a button cell (10). The button cell holder according to the present invention is an exclusive holder of the button cell 10, which includes a cell mount 300 to which the button cell 10 is mounted; And a terminal portion 400 electrically connected to the button cell 10.

The button cell holder (hereinafter, abbreviated as "cell holder") according to the present invention is not particularly limited as long as it is used for mounting the button cell 10. In a specific application, the cell holder according to the present invention can be usefully used for performance measurement, aging, and / or charging and discharging of the button cell 10.

Also, in the present invention, the button cell 10 is a battery cell having a button shape (= coin shape), which can be selected from a primary battery and a secondary battery, and the specific kind thereof is not particularly limited. The button cell 10 may be an electrochemical device such as a lithium ion battery, a lithium polymer battery and a capacitor (electric double layer capacitor, pseudo capacitor, hybrid capacitor, etc.), a nickel-cadmium battery and a nickel- An air cell product such as an air lithium battery and an air zinc battery operated by an air cell, and the like.

As mentioned above, FIG. 2 shows a button cell 10, which shows an exemplary form of a button cell 10 that can be mounted to a cell holder according to the present invention. 2, the button cell 10 includes a cathode can 12, a cathode can 14 coupled to one side (lower side in the figure) of the anode can 12, And has an insulated gasket 13 for insulation of the anode can 14 and can have a button shape (coin shape) by the combination (assembly) of the anode can 12 and the anode can 14. The button cell 10 may have a structure in which a gas injection hole 15 is formed in at least one of the anode can 12 and the anode can 14. At this time, for example, gas such as air and / or oxygen may be injected into the button cell 10 through the gas injection hole 15. The button cell 10 may be an air cell product in which air (or oxygen) is injected through the gas injection hole 15 in one example.

The cell holder according to the present invention is useful as a dedicated holder for easily and stably mounting the button cell 10 as described above. The cell mounting part 300 provides a space for accommodating and mounting the button cell 10. The terminal unit 400 electrically connects the button cell 10 stored in the cell mounting unit 300 to an arbitrary device (not shown). The arbitrary device may be selected from a performance meter for measuring the performance of the button cell 10, for example. The performance meter may include, for example, a voltage meter, a current meter, a capacitance meter, and / or a resistance meter. For example, the arbitrary device may include an aging device (for example, a high voltage generator) for aging the button cell 10, a charge / discharge device for charge / discharge of the button cell 10, / RTI > device as an < / RTI >

According to a preferred embodiment of the present invention, a cell holder according to the present invention includes a lower body 100, an upper body 200 coupled to an upper portion of the lower body 100, A terminal part 400 electrically connected to the button cell 10 mounted on the cell mounting part 300 and a terminal part 400 electrically connected to the lower body 100 And a rotational coupling means 500 for rotational coupling of the upper body 200 and the upper body 200.

The lower body 100 forms a base body of the cell holder according to the present invention and may be formed of an insulator such as a plastic material. The lower body 100 may have a shape such as a polygonal or circular shape in cross section, and a figure having a substantially square cross section is illustrated in the figure.

Referring to FIG. 5, the lower body 100 may include a coupling protrusion 110 for attaching / detaching (coupling and separating) the upper body 200. The coupling protrusion 110 may protrude from the upper center of the lower body 100, and may have, for example, a circular cross-section. The first thread S1 is formed on the outer circumference of the coupling protrusion 110 and can be freely attached and detached (engaged and disengaged) with the upper body 200 through screw rotation.

The upper body 200 is coupled to an upper portion of the lower body 100 and may be formed of an insulator such as a plastic material. The upper body 200 may have a shape such as a polygonal or circular shape in its cross section, and a figure having a substantially square cross section is illustrated in the figure. In addition, as shown in the figure, the upper portion of the upper body 200 may have a slant surface 201 inclined in both directions.

Referring to FIG. 5, the upper body 200 may include an engagement groove 210 for attaching / detaching (joining and separating) the upper body 200 to the lower body 100. The engaging groove 210 may be formed at a lower center of the lower portion of the upper body 200, and may have a circular cross section, for example. The second thread S2 is formed on the inner circumference of the coupling groove 210 so that the second thread S2 can be freely attached to and detached from the lower body 100 through screw rotation. That is, by the screw connection between the upper body 200 and the lower body 100 by screwing the second thread S2 formed on the coupling groove 210 and the first thread S1 formed on the coupling protrusion 110, And separation can be achieved.

The cell mounting portion 300 is formed between the lower body 100 and the upper body 200, and the button cell 10 is accommodated therein. The cell mounting portion 300 may be made of an insulator such as plastic material. The cell mounting portion 300 may be formed at the center of the lower body 100 as shown in the figure and may be formed in the coupling protrusion 110 of the lower body 100 have. More specifically, for example, an attachment groove 113 may be formed at an upper center of the coupling protrusion 110, and a cell mounting portion 300 may be installed in the attachment groove 113.

6 shows a state in which the cell mounting portion 300 is separated from the coupling protrusion 110. As shown in FIG. 6, the cell mounting part 300 includes a cell receiving part 310 coupled to the mounting recess 113 of the coupling protrusion 110, and the cell receiving part 310 And a plurality of cell supporting portions 320 protruding from an edge of the cell supporting portion 320. At this time, the button cell 10 is seated on the cell housing part 310. The cell supporting part 320 presses and supports the side surface of the button cell 10 placed on the cell housing part 310, .

Accordingly, the cell mounting part 300 forms a storage space through the cell housing part 310 and the cell supporting part 320 protruding from the cell housing part 310 to stably store and mount the button cell 10. The cell mounting portion 300 may be coupled to the coupling protrusion 110 through a fastener 330 such as a screw. A concave hole 313 is formed at the center of the cell accommodating portion 310. The concave hole 330 penetrates the concave hole 313 and then passes through the concave hole 313 of the concave portion 110 So that the coupling force of the cell mounting portion 300 and the coupling protrusion 110 can be achieved.

The cell mounting portion 300 may include a plurality of terminal supporting portions 340 extending from the cell supporting portion 320. The terminal supporting portion 340 closely contacts the side surface of the terminal portion 400 to prevent the terminal portion 400 from being separated. For example, as shown in the figure, four cell supporting portions 320 are protruded from the edge of the cell accommodating portion 310, and terminals (not shown) extending from the cell supporting portion 320 are formed on both sides of the cell accommodating portion 310. [ Two support portions 340 may be formed. The side surface of the terminal part 400 is closely fitted between the two terminal supporting parts 340 so that the terminal part 400 can be prevented from being separated. In other words, the fitting portion 344 is formed between the two terminal supporting portions 340, and the fitting portions 424 and 444 of the terminal portion 400 are fitted into the fitting portion 344, (400) may be coupled.

The terminal unit 400 is electrically connected to the button cell 10 mounted on the cell mounting unit 300. The terminal portion 400 is electrically conductive, and is made of, for example, an electrically conductive metal material having a predetermined elasticity. The terminal portion 400 is provided on both sides of the cell mounting portion 300. Specifically, the terminal portion 400 includes a negative terminal portion 420 provided on one side (left side in FIG. 6) of the cell mounting portion 300, 6 to the right). The anode terminal part 420 is connected to the cathode can 12 of the button cell 10 and the anode terminal part 440 is connected to the anode can 14 of the button cell 10.

6, the cathode terminal portion 420 includes an anode ground portion 422 connected to the anode can 12, and a cathode extension portion 422 integrally extended from the anode ground portion 422. [ And a negative electrode connection part 426 formed integrally with the negative electrode coupling part 424 and extending downward. The positive electrode terminal portion 440 includes a positive electrode ground portion 442 connected to the positive electrode can 14, a positive electrode coupling portion 444 formed integrally with the positive electrode ground portion 442, And an anode connection portion 446 formed integrally downward from the anode connection portion 444.

The negative electrode grounding portion 422 and the positive electrode grounding portion 442 are elastically connected to the negative electrode can 12 and the positive electrode can 14 of the button cell 10, respectively. At this time, the anode grounding portion 442 is resiliently connected to the anode can 14, which includes two connecting flaps 442a formed on both upper ends thereof, so that the grounding flap 442a is connected to the anode can The contact area with the anode can 14 can be increased by being grounded on the upper side surface of the anode can 14. The negative electrode coupling portion 424 and the positive electrode coupling portion 444 provide a coupling force with the cell mounting portion 300. Specifically, as described above, the fitting portion 344 formed between the two terminal supporting portions 340 So that it has a bonding force with the cell mounting portion 300. The anode connection portion 426 and the anode connection portion 446 are connected to the connection portions 52 and 54 provided in the lower body 100 and are electrically connected to the performance measuring device and the like.

6 and 8, a first connection hole 152 and a second connection hole 154 may be formed in the lower body 100. The first connection hole 152 and the second connection hole 154 may be formed to penetrate the lower body 100 in the vertical direction. The first connection part 52 may be inserted and coupled to the first connection hole 152 and the second connection part 54 may be inserted and coupled to the second connection hole 154. [ At this time, the first connection part 52 may be connected to the cathode connection part 426, and the second connection part 54 may be connected to the cathode connection part 446. The connecting portions 52 and 54 and the engaging portions 426 and 446 may be electrically connected to each other through, for example, an electrically conductive wire W (see FIG. 8). Specifically, the first connection portion 52 and the cathode connection portion 426 are connected to each other via a wire W via solder or the like. In the case of the second connection portion 54 and the anode connection portion 446, ) Via solder or the like.

The first and second connection portions 52 and 54 are electrically conductive, for example, selected from electrically conductive metal materials and the like. The first and second connecting portions 52 and 54 may have hollows 52a and 54a in the shape of a cylinder or a polygonal cylinder. The first and second connecting portions 52 and 54 may be formed with a finishing portion 52b or 54b on one side thereof (the upper side in FIG. 8), and the finishing portions 52b and 54b may be provided with wires W may be connected through solder or the like. Thus, for example, at the time of measuring the performance of the button cell 10, the connecting terminals drawn out from the performance measuring instrument are inserted into and connected to the hollows 52a and 54a of the first and second connecting portions 52 and 54 The performance of the button cell 10 can be measured.

The rotary coupling means 500 is for coupling the lower body 100 and the upper body 200 to each other and is capable of attaching and detaching the lower body 100 and the upper body 200 through a rotation operation . The rotational coupling means 500 may include the coupling protrusion 110 and the coupling groove 210 as described above. More specifically, the rotational coupling means 500 includes a coupling protrusion 110 formed at the upper center of the lower body 100 and having a first thread S1 formed on the outer periphery thereof, And a coupling groove 210 in which a second thread S2 is formed on the inner periphery. Accordingly, the lower body 100 and the upper body 200 are freely engaged and separated by rotation through the threads S1 and S2.

The cell holder according to the present invention may further include a stopper 600 for preventing further rotation when the lower body 100 and the upper body 200 are rotated together with the above components have. The stopper 600 is not particularly limited as long as it can prevent excessive rotation of the lower body 100 and the upper body 200. The specific structure and operation of the stopper 600 will be described later.

In addition, the cell holder according to the present invention may further include a gas injection unit 700 and / or a gas discharge unit 800. A gas such as air and / or oxygen can be injected / discharged through the gas injecting unit 700 and the gas discharging unit 800. The gas injecting unit 700 and the gas discharging unit 800 are useful when the gas injection hole 15 is formed in the button cell 10, Which is an air cell product into which air (or oxygen) is injected through the gas injection hole 15. [

The gas injection unit 700 is for injecting gas into the gas injection hole 15 of the button cell 10 and may be installed in the upper body 200, for example. The gas exhaust part 800 is for discharging gas and may also be installed in, for example, the upper body 200. In one example, the upper body 200 is formed with an inclined surface 201, and the gas injection portion 700 and the gas discharge portion 800 are disposed adjacent to each other on the inclined surface 201 of the upper body 200 .

5 and 8, the upper body 200 includes a gas inflow hole 207 through which the gas injected from the gas injection unit 700 flows, a gas injection hole 207 through which the introduced gas flows into the gas discharge unit 800 A gas discharge hole 208 for discharging the gas can be formed. At this time, the gas inflow hole 207 is communicated with the gas injection unit 700, and may be formed through the upper surface 211 of the coupling groove 210. The gas discharge hole 208 communicates with the gas discharge portion 800 and may be formed to penetrate the upper surface 211 of the coupling groove 210. Thus, the gas introduced from the gas injection unit 700 passes through the gas inlet hole 207, and then is injected into the button cell 10 through the gas injection hole 15. Then, the remaining gas passes through the gas discharge hole 208, and then is discharged through the gas discharge portion 800.

In addition, the cell holder according to the present invention may further include at least one or more sealing members 21 and 22 for maintaining the airtightness at the time of injecting / discharging the gas. Airtightness is maintained by the sealing members 21 and 22, and gas can be injected into the gas injection hole 15 at a high pressure. The sealing members 21 and 22 are not particularly limited as long as they have airtightness. The sealing members 21 and 22 may be selected from, for example, an O-ring composed of an elastic material such as rubber or the like, but are not limited thereto .

In addition, the sealing members 21 and 22 may include a first sealing member 21 and a second sealing member 22. 5 and 8, the upper body 200 includes a circular inner protrusion 231 and a circular outer protrusion 232 formed at the outer peripheries of the gas inlet holes 207 and the gas outlet holes 208 can do. The inner protrusion 231 and the outer protrusion 232 protrude downward from the upper surface 211 of the coupling recess 210. At this time, the outer protrusion 232 is formed on the outer periphery of the inner protrusion 231, and a first packing groove 221 is provided between the inner protrusion 231 and the outer protrusion 232. A first sealing member 21 is packed in the first packing groove 221. In addition, the second sealing member 22 may be packed in the lower body 100. Specifically, the lower body 100 includes a second packing groove 122 provided around the coupling protrusion 110, and a second sealing member 22 is packed in the second packing groove 122 .

Accordingly, when the lower body 100 and the upper body 200 are rotationally coupled, the first sealing member 21 installed in the first packing groove 221 closely contacts the button cell 10, And the second sealing member 22 provided in the second packing groove 122 is brought into close contact with the upper body 200 so that the second gas tightness is improved. The gas is injected into the gas injection hole 15 at a high pressure while effectively preventing gas leakage due to the airtightness of the first and second phases.

In addition, a gas injector (not shown) may be connected to the gas injection unit 700 to supply gas. In the present invention, the gas injection unit 700 may have various shapes and structures as long as it can inject gas into the cell holder, and it may be constructed as follows according to an exemplary embodiment of the present invention.

6 to 8, according to an exemplary embodiment of the present invention, the gas injection unit 700 includes an injection unit main body 710, a gas injector inserted into the injection unit main body 710, A stopping pin 730 for preventing the detachment of the fixing member 720 and an elastic member 740 for applying an elastic force to the fixing member 720.

The injection unit main body 710 includes an injection port 711 and a connection port 712. A gas injector is inserted into the injection port 711. The connection hole 712 is engaged with the coupling hole 202 formed in the inclined surface 201 of the upper body 200. The connector 712 and the coupling hole 202 are screwed together, for example. A sliding groove 714 is formed at an upper end of the injection unit main body 710 to insert and slide the pressing portion 722 of the fixing member 720 and a fitting hole 715 into which the detent pin 730 is inserted Respectively. The fitting hole 715 is formed in the wall of the injection unit main body 710. At this time, the elastic spring 716 is first inserted into the fitting hole 715, and then one end (lower side) of the stop pin 730 is inserted on the elastic spring 716.

The fixing member 720 elastically fixes the gas injector inserted into the injection port 711 of the injection unit main body 710. The fixing member 720 includes a pressing portion 721 and a pressing portion 722 integrally formed from the pressing portion 721 and inserted and moved in the sliding groove 714, And a slit hole 724 formed at one side of the pressing portion 722 and inserted and installed with the stopping pin 730. The through hole 723 is formed in a substantially circular shape at the center and includes a gas injector, do. The slit hole 724 includes a first slit hole 724a extending from the through hole 723 and a second slit hole 724b extending from the first slit hole 724a, The hole 724a has a larger size (width) than the second slit hole 724b. Specifically, the first slit hole 724a has a size (width) allowing the body 732 of the detent pin 730 to be inserted and moved, and the second slit hole 724b has a size (Width) smaller than the thickness (diameter). Accordingly, the body portion 734 can be inserted into the first slit hole 724a, but can not be inserted into the second slit hole 724b.

The detent pin 730 includes a head portion 731, a body portion 732 integrally extended from the head portion 731, and a neck portion 732 formed between the head portion 731 and the body portion 732 733). At this time, the neck portion 733 has a thickness (diameter) smaller than at least the body portion 732 among the head portion 731 and the body portion 732. The head portion 731 and the body portion 732 may have the same thickness (diameter). The underside of the detent pin 730 is inserted into the fitting hole 715 as described above and tightly fitted on the elastic spring 716 inserted into the fitting hole 715. Thus, the stop pin 730 is elastically moved in the up-and-down direction by the elastic spring 716.

The elastic member 740 is for elastic movement of the fixing member 720 and is installed, for example, between the outer peripheral surface of the wall of the injection unit main body 710 and the pressing portion 721. Thus, the fixing member 720 is elastically moved in the horizontal direction by the elastic member 740. The elastic member 740 may be selected from, for example, an elastic spring, but is not limited thereto.

According to the gas injection unit 700 as described above, at least the connection and disconnection of the gas injector can be easily realized. 7A shows a state before the gas injector is connected (before insertion), and FIG. 7B shows a state after the gas injector is connected (after insertion). The gas injector is not shown in the drawing.

7A, the injection port 711 and the through hole 723 are located on the same circle before the gas injector is connected (before insertion), and the first slit hole And the body portion 732 of the stop pin 730 is positioned in the body portion 724a. At this time, the body 732 has a thickness (diameter) larger than the size (width) of the second slit hole 724b and is not inserted into the second slit hole 724b, As shown in Fig. Accordingly, the injection port 711 ensures a sufficient space for inserting the gas injector.

Thereafter, the gas injector is inserted through the through hole 723 and fully inserted into the injection port 711, and then the pressing portion 722 presses the head portion 731 of the stop pin 730 elastically pressurizes the gas injector And fixed. Specifically, when the head 731 of the detent pin 730 is pressed, the detent pin 730 moves downward, and the body 732 of the detent pin 730 moves away from the first slit hole 724a And is inserted into the fitting hole 715. The neck portion 733 is located at the second slit hole 724b by the elastic force of the elastic member 740 immediately after being positioned in the first slit hole 724a and at the same time the pressing portion 722 is located at one side (Rightward direction in Fig. 7), resulting in the appearance as shown in Fig. 7 (b). At this time, the pressing portion 722 resiliently presses and fixes the gas injector. In this state, gas is injected.

Next, when the pressing portion 721 of the fixing member 720 is pressed after the gas injection is completed, the pressing portion 722 moves along the sliding groove 714 to the other side (left direction in FIG. 7) And the neck portion 733 positioned in the second slit hole 724b is positioned in the first slit hole 724a. At the same time, the stop pin 730 is moved upward by the elastic force of the elastic spring 716 and returned to the same shape as shown in FIG. 7 (a). At this time, the body 732 is positioned in the first slit hole 724a, and the injection port 711 and the through hole 723 are located on the same circle. By releasing the pressing force of the pressing portion 722, Can be separated.

Further, a gas discharger (not shown) may be connected to the gas discharging unit 800 to discharge the gas. In the present invention, the gas discharging portion 800 may have various shapes and structures as long as it can discharge gas in the cell holder. The gas discharge portion 800 may have the same configuration as the gas injection portion 700 according to the exemplary embodiment of the present invention.

6 to 8, according to an exemplary embodiment of the present invention, the gas discharging portion 800 includes a discharging portion main body 810 and a gas discharger inserted into the discharging portion main body 810, A stop pin 830 for preventing the fixing member 820 from being separated from the fixing member 820 and an elastic member 840 for applying an elastic force to the fixing member 820.

The discharge unit main body 810 includes a discharge port 811 and a connection port 812. The gas outlet is inserted into the outlet 811. The connector 812 is engaged with a coupling hole 202 formed in the inclined surface 201 of the upper body 200. The connector 812 and the coupling hole 202 are, for example, screwed together. A sliding groove 814 into which the pressing portion 822 of the fixing member 820 is inserted and slid and a fitting hole 815 into which the detent pin 830 is inserted are formed at the upper end of the discharging portion main body 810.
The fitting hole 815 is formed in the wall of the discharge unit main body 810. One end (lower side) of the stop pin 830 is inserted into the fitting hole 815 on the elastic spring 816 after the elastic spring 816 is first inserted.

The fixing member 820 elastically fixes the gas ejector inserted into the injection port 811 of the ejection unit main body 810. The fixing member 820 includes a pressing portion 821 and a pressing portion 822 which is integrally formed from the pressing portion 821 and inserted and moved in the sliding groove 814, And a slit hole 824 formed at one side of the pressing portion 822 and into which a stop pin 830 is inserted and installed. The slit hole 824 includes a first slit hole 824a extending from the through hole 823 and a second slit hole 824b extending from the first slit hole 824a and the first slit hole 824a Has a larger size (width) than the second slit hole 824b. Specifically, the first slit hole 824a has a size (width) allowing the body portion 832 of the stop pin 830 to be inserted and moved, and the second slit hole 824b is a portion of the body 832 (Width) smaller than the thickness (diameter). Accordingly, the body 834 can be inserted into and passed through the first slit hole 824a, but can not be inserted into the second slit hole 824b.

The stop pin 830 includes a head 831 and a body 832 extending integrally from the head 831. A neck 833 formed between the head 831 and the body 832, And the neck portion 833 has a thickness (diameter) smaller than at least the body portion 832 of the head portion 831 and the body portion 832. The head portion 831 and the body portion 832 may have the same thickness (diameter). The underside of the detent pin 830 is inserted into the fitting hole 815 as described above and is tightly supported on the elastic spring 816 inserted into the fitting hole 815. [ Accordingly, the stop pin 830 elastically moves in the up-and-down direction by the elastic spring 816.

The elastic member 840 is for elastic movement of the fixing member 820 and is installed, for example, between the outer peripheral surface of the wall of the discharge unit main body 810 and the pressing portion 821. Thus, the fixing member 820 is elastically moved in the horizontal direction by the elastic member 840. The elastic member 840 may be selected from, for example, an elastic spring, but is not limited thereto.

According to the gas discharge unit 800 as described above, at least the connection and disconnection of the gas discharge unit can be easily implemented. Since the operation of the gas discharger 800 is the same as that of the gas injector 700 described above, a detailed description thereof will be omitted.

As described above, the cell holder according to the present invention may include a stopper 600, and the stopper 600 may be formed of any material that can prevent over-rotation of the lower body 100 and the upper body 200 good. Referring to FIG. 5, the stopper 600 may include a protrusion 610 and a guide groove 620 for guiding the protrusion 610. At this time, the protrusion 610 protrudes upward from the lower body 100, and the guide groove 620 may be recessed in the upper body 200. The protrusion 610 may protrude downward from the upper body 200 and the guide groove 620 may be recessed in the lower body 100.

The protrusion 610 protrudes from the surface of the lower body 100 at a predetermined height and is inserted and guided into the guide groove 620 when the lower body 100 and the upper body 200 are rotationally coupled. The guide groove 620 is curved so as to have a predetermined length in the upper body 200 and may have the same radius of curvature as the threads S1 and S5. Further, the guide groove 620 may be formed deeper from one side 621 to the other side 622, for example. That is, the depth of the groove may gradually increase from one side 621 to the other side 622 of the guide groove 620. At the end of the other side 622 having a large depth, a latching protrusion 625 can be formed which is in close contact with the protrusion 610.

Accordingly, when the lower body 100 and the upper body 200 are rotated together, the protrusion 610 moves along the guide groove 620 and is brought into close contact with the engagement protrusion 625 of the guide groove 620, do. Thus, when the protrusion 610 is tightly engaged with the engaging protrusion 625, further rotation is prevented, and this state can be a fully engaged state and / or a good connected state.

When the upper body 200 and the upper body 200 are excessively rotated, the upper body 200 strongly presses the button cell 10, for example, the grounding flap 442a and the cathode can 14 May occur, and in some cases, deformation of the shape of the button cell 10 may occur (for example, sinking occurs). Further, in the case where the rotational coupling is less, not only the complete coupling between the lower body 100 and the upper body 200 is not achieved, and in some cases, the connection failure between the cathode grounding portion 422 and the cathode can 12 May occur.

The stopper 600 prevents the above phenomenon. More specifically, the stopper 600 prevents further rotation (prevents excessive rotation). A state in which the rotation of the stopper 600 is prevented by the stopper 600, that is, a state in which the projection 610 is in close contact with the stopping protrusion 625 is engaged with the complete rotation of the lower body 100 and the upper body 200 The button cell 10 and the grounding portions 422 and 442 can be in a good connection state.

3 and 4, the lower body 100 and the upper body 200 are provided on one surface thereof with a combined state indicator 30 for confirming a fully coupled state and / or a preferable connected state, Can be formed. That is, when the display unit 30 displayed on the lower body 100 and the displayed display unit 30 displayed on the upper body 200 coincide with each other after the rotation, the rotation is prevented by the stopper 600 It can be visually confirmed that it is in a fully coupled state and / or a good connected state.

In addition, an electrode display unit 40 may be formed on the surface of the lower body 100 and / or the upper body 200. The electrode display portion 40 corresponds to the terminal portions 400, 420, and 440 and / or the connection portions 52 and 54. For example, the negative electrode display portion 40 of "-" is formed on the surface of the side where the negative electrode terminal portion 420 is provided and the positive electrode display portion 40 of "+" Can be formed.

The cell holder according to the present invention described above has at least the following operational effects.

First, the cell holder according to the present invention can easily and stably mount the button cell 10 through storing and rotating operations. Specifically, when the button cell 10 is housed in the cell mounting portion 300 of the lower body 100 and then the upper body 200 is engaged with the lower body 100, It is stably mounted in the holder and is not detached by external shock or vibration. At the same time, the button cell 10 is electrically connected to the cathode and anode terminal portions 400, 420, and 440, so that the performance of the button cell 10 and the charge / discharge can be easily performed.

Further, when the stopper 600 and / or the engagement state indicator 30 are included, further rotation (over-rotation) of the lower body 100 and the upper body 200 is prevented as described above, And / or a good connection state can be easily confirmed visually.

In addition, when the gas injecting unit 700 and the gas discharging unit 800 are included, air (or oxygen) can be injected / discharged into the cell holder, and the button cell 10, such as an air cell product, It is possible to simultaneously perform air injection and performance measurement while being mounted on the cell holder.

10: Button cell 12: cathode can
14: anode can 15: gas injection hole
21, 22: sealing member 30:
40: electrode display section 52, 54:
100: Lower body 110:
200: upper body 201: inclined surface
210: coupling groove portion 300: cell mounting portion
310: cell storage part 320: cell support part
340: terminal support part 400: terminal part
420: negative terminal portion 422: negative electrode ground portion
424: negative electrode coupling portion 426: negative electrode connection portion
440: positive electrode terminal portion 442: positive electrode ground portion
444: positive electrode coupling portion 446: positive electrode connection portion
500: rotation coupling means 600: stopper
610: projection 620: guide groove
700: gas injection part 710: injection part main body
800: gas discharge part 810: discharge part main body
720, 820: fixing member 730, 830: stop pin
740, 840: elastic members S1, S2: threads

Claims (9)

A lower body 100;
An upper body 200 coupled to an upper portion of the lower body 100;
A cell mounting part 300 formed between the lower body 100 and the upper body 200 and to which the button cell 10 having the gas injection hole 15 is mounted;
A terminal portion 400 electrically connected to the button cell 10;
Rotating coupling means (500) for rotationally coupling the lower body (100) and the upper body (200);
A gas injection unit 700 for injecting gas into the gas injection hole 15 of the button cell 10; And
And a gas discharging part (800) for discharging residual gas after the gas injection,
The gas injection unit 700 includes:
An injection unit main body 710 coupled to the upper body 200 and having a gas injector inserted therein;
A fixing member 720 elastically fixing a gas injector inserted into the injection unit main body 710 and slidingly inserted into a sliding groove 714 formed in the injection unit main body 710;
A detent pin 730 for preventing the detachment of the fixing member 720 and moving the fixing member 720 upward and downward to press the gas injector elastically and to release the pressing force, ; And
And an elastic member (740) for applying an elastic force to the fixing member (720).
The method according to claim 1,
The gas discharger 800 includes:
A discharge unit main body 810;
A fixing member 820 for elastically fixing the gas discharger inserted into the discharge unit main body 810;
A detent pin 830 for preventing the detachment of the fixing member 820; And
And an elastic member (840) for applying an elastic force to the fixing member (820).
The method according to claim 1,
The rotation coupling means (500)
A coupling protrusion 110 formed on the lower body 100 and having a first thread S1 formed on an outer periphery thereof; And
And a coupling groove part (210) formed in the upper body (200) and having a second thread (S2) formed on an inner peripheral edge thereof.
The method according to claim 1,
Wherein the button cell holder further comprises a stopper (600) for preventing further rotation when the lower body (100) and the upper body (200) are rotated together.
The method according to claim 1,
The injection unit main body 710,
An inlet 711 into which a gas injector is inserted,
A coupling hole 712 coupled to the coupling hole 202 formed in the upper body 200,
A sliding groove 714 into which the pressing portion 722 of the fixing member 720 is inserted and slid,
A fitting hole 715 into which the stop pin 730 is inserted,
And an elastic spring 716 inserted into the fitting hole 715,
The fixing member 720 includes:
A pressing portion 721,
A pressing part 722 integrally formed from the pressing part 721 and inserted and sliding in the sliding groove 714,
A through hole 723 formed in the pressing portion 722 and through which the gas injector is inserted,
And a slit hole 724 formed at one side of the pressing portion 722 and into which the stop pin 730 is inserted,
The detent pin 730,
A head portion 731,
A body portion 732 integrally extended from the head portion 731 and closely attached to the elastic spring 716 inserted into the fitting hole 715,
And a neck portion 733 formed between the head portion 731 and the body portion 732 and having a smaller diameter than the body portion 732,
The slit hole 724 includes a first slit hole 724a extending from the through hole 723 and a second slit hole 724b extending from the first slit hole 724a, The hole 724a has a larger size than the second slit hole 724b,
The body 732 of the stop pin 730 has a diameter that can be inserted into the first slit hole 724a but can not be inserted into the second slit hole 724b.
6. The method according to any one of claims 1 to 5,
The cell mounting part 300 includes:
A cell storage part 310 on which the button cell 10 is seated;
A cell supporting portion 320 protruding from an edge of the cell accommodating portion 310 and supporting a side surface of the button cell 10 mounted on the cell accommodating portion 310; And
And a plurality of terminal supporting portions 340 extending from the cell supporting portion 320 and supporting the side surfaces of the terminal portions 400,
The terminal unit 400 includes:
An anode terminal part 420 provided at one side of the cell mounting part 300; And
And a positive electrode terminal part 440 provided on the other side of the cell mounting part 300,
The negative electrode terminal portion 420 is formed,
An anode grounding portion 422 connected to the cathode can 12 of the button cell 10;
A negative electrode coupling portion 424 extended from the negative electrode grounding portion 422 and inserted and held between the terminal supporting portions 340; And
And a cathode connection portion 426 extending from the cathode connection portion 424 and connected to the first connection portion 52 provided on the lower body 100,
The positive electrode terminal portion 440,
A positive electrode ground portion 442 connected to the positive electrode can 14 of the button cell 10;
A positive electrode coupling portion 444 extending from the positive electrode grounding portion 442 and held between the terminal supporting portions 340; And
And an anode connection part (446) extending from the anode coupling part (444) and connected to a second connection part (54) provided on the lower body (100).
5. The method of claim 4,
The stopper (600)
A protrusion 610 formed on the lower body 100; And
And a guide groove 620 formed in the upper body 200 and guiding the projection 610 when the lower body 100 and the upper body 200 are rotated together,
The guide groove 620 is formed deeply from one side 621 to the other side 622,
Wherein the protrusion (610) is caught by the protrusion (625) formed at the end of the other side (622) of the guide groove (620) to prevent further rotation.
The method according to claim 1,
The gas injecting unit 700 and the gas discharging unit 800 are installed in the upper body 200,
The upper body (200)
A gas inflow hole 207 communicating with the gas injection unit 700 and formed through the upper surface 211 of the coupling groove 210;
A gas discharge hole (208) communicating with the gas discharge part (800) and formed through the upper surface (211) of the coupling groove part (210);
An inner protrusion 231 formed at an outer periphery of the gas inlet hole 207 and the gas outlet hole 207 and protruding from the upper surface 211 of the coupling groove 210;
An outer protrusion 232 formed on the outer periphery of the inner protrusion 231 and protruding from the upper surface 211 of the coupling recess 210; And
And a first packing groove 221 provided between the inner protrusion 231 and the outer protrusion 232,
The lower body 100 includes a second packing groove 122 provided around the coupling protrusion 110,
Wherein a first sealing member is provided in the first packing groove and a second sealing member is provided in the second packing groove.
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