KR20210079019A - Cylindrical secondary battery charge and discharge electrode probe - Google Patents

Abstract

The present invention relates to an electrode probe for charging and discharging a cylindrical secondary battery and a charging and discharging device including the same which have a magnet to fix a battery to a lower probe, thereby fixing the battery during charging/discharging and preventing a short circuit of an electrode.

Description

Cylindrical secondary battery charge and discharge electrode probe

The present invention relates to an electrode probe including a pair of probes for supporting and charging a cylindrical secondary battery at upper and lower portions. Specifically, the electrode probe of the present invention is composed of an upper probe and a lower probe, and the lower probe is provided with a magnet to fix the cylindrical secondary battery.

With the increase in technology development and demand for mobile devices, the demand for secondary batteries is also rapidly increasing. Among them, a lithium secondary battery is widely used as an energy source for various electronic products as well as various mobile devices in that it has high energy density and operating voltage and excellent preservation and lifespan characteristics.

Such a secondary battery is manufactured through a process of assembling a cell and a process of activating the battery, and in the battery activation step, charging is performed under conditions necessary for activation by using a charge/discharge pin supplied with power from the outside. Such a charging/discharging device performs a function of imparting characteristics of a secondary battery by repeating the charging and discharging process several times so that the first battery, which is assembled during the production process of the secondary battery, can store electrical energy.

In the conventional charging/discharging of a cylindrical secondary battery, the charging/discharging process of the cylindrical secondary battery is performed as the top cap located at the top of the cylindrical secondary battery and the charging/discharging pin supplied with power from the outside contact and conduct electricity.

1 is a view showing a state of use of an electrode probe for charging and discharging for a conventional cylindrical secondary battery. As shown in FIG. 1A , the conventional electrode probe for charging and discharging includes a lower probe and an upper probe, and the probe has a cylindrical shape. In addition, each of the lower and upper probes includes a tip through which a current flows when the secondary battery is fastened, and serves to fix the secondary battery at the same time. Referring to FIG. 1A , in the conventional electrode probe, when the center of the secondary battery is exactly matched to the electrode probe, charging and discharging are normally performed. However, when the contact between the probe tip and the electrode terminal is misaligned or shaken, a short circuit may occur. Referring to FIG. 1B , when the battery is tilted in the process of fastening the cylindrical secondary battery to the charge/discharge probe, both the probe tips of the upper and lower probes come into contact with the negative terminal and a short circuit occurs. In addition, as shown in FIG. 1C , a short circuit may occur even if the center of the battery is incorrectly aligned with the charge/discharge probe. Specifically, a short circuit occurs because the upper probe tip simultaneously touches the positive and negative terminals of the cell.

Japanese Patent No. 2944030 Korean Patent No. 1772062 Japanese Patent Laid-Open No. 1995-006788 Korea Patent Publication No. 2018-0026940

The problem to be solved by the present invention is to protect the tip through which current flows when the battery is fastened during the charging/discharging process of the cylindrical secondary battery and to prevent the electrode short circuit that occurs when the secondary battery is tilted at the same time as an electrode probe is to provide

The present invention relates to an electrode probe including a pair of probes for supporting and charging a cylindrical secondary battery at upper and lower portions,

an upper probe in contact with the upper surface of the secondary battery and including an upper tip in electrical contact with the first electrode; and

It includes a lower tip in contact with the lower surface of the secondary battery, and a lower tip in electrical contact with the second electrode, and a lower probe in which a magnet for positioning and fixing the secondary battery is accommodated.

In one example, the upper probe may include: an upper probe body having a through hole formed therein; an upper tip electrically contacting the first electrode of the secondary battery while being inserted into the through hole of the upper probe body; and an upper elastic member supporting the upper tip to maintain electrical contact with the first electrode of the secondary battery.

In a specific example, the upper tip is supported by the upper elastic member and protrudes by a predetermined distance from the end of the upper probe body.

In another specific example, the upper probe body has a cylindrical structure having a through hole through which the upper tip passes, and the upper elastic member is inserted into the upper probe body and has a spring shape surrounding the upper tip.

In another example, the lower probe, the through-hole is formed, the lower probe body is formed with a receiving portion for accommodating the magnet at the end; a lower tip electrically contacting the second electrode of the secondary battery while being inserted into the through hole of the lower probe body; a lower elastic member supporting the lower tip to maintain electrical contact with the second electrode of the secondary battery; and a magnet accommodated in the accommodating part of the lower probe body, for designating and fixing the position of the secondary battery.

In a specific example, the lower tip is supported by the lower elastic member and protrudes by a predetermined distance from the end of the lower probe body.

In another specific example, the lower probe body has a cylindrical structure having a through hole through which the lower tip passes, and the lower elastic member has a spring shape surrounding the lower tip while being inserted into the lower probe body.

In another specific example, the lower probe body may include: a first lower probe body having a cylindrical structure in which a through hole through which a lower tip passes; and a second lower probe body extending from the distal end of the first lower probe body to form a receiving portion for accommodating a magnet, the second lower probe body having a cylindrical shape having a larger diameter than that of the first lower probe body.

In another specific example, the magnet accommodated in the accommodating part of the second lower probe body is characterized in that it has a cylindrical shape in which a through hole through which the lower tip penetrates is formed.

In one example, the upper tip formed on the upper probe and the lower tip formed on the lower probe are located on the same straight line.

In another example, the magnet accommodated in the lower probe has a cylindrical shape with a through hole formed in the center, and the diameter (R1) of the magnet is in the range of 50 to 80% of the diameter (R2) of the cylindrical secondary battery to be charged and discharged. .

In another example, the lower and upper probes are each fixed to a support.

In one example, the lower probe is fixed to the support, and the upper probe is in the form of pressing the interposed secondary battery in a state in which the secondary battery is interposed.

The present invention also provides a cylindrical secondary battery charging/discharging device including the electrode probe.

Since the electrode probe according to the present invention has a magnet in the lower probe, the probe tip prevents simultaneous contact between the positive and negative terminals due to the inclination of the cylindrical secondary battery or an error in battery arrangement. In this way, a short circuit of the battery can be prevented.

In addition, since a separate temporary wall used for fixing the battery in the conventional electrode probe is not required, space efficiency can be improved.

1 is a view showing a conventional charging/discharging probe for charging and discharging of a cylindrical secondary battery and a cylindrical secondary battery.
2 is a view showing an electrode probe of the present invention.
3 is a view showing a structure in which a cylindrical secondary battery disposed in the center of an electrode probe according to the present invention is fixed.
4 is a view showing a cross-section of a lower probe and a cylindrical secondary battery according to an embodiment of the present invention.
5 is a view showing a cross-section of a lower probe and a cylindrical secondary battery according to another embodiment of the present invention.

Hereinafter, the present invention will be described in detail. Prior to this, the terms or words used in the present specification and claims are not to be construed as being limited to their ordinary or dictionary meanings, and the inventor must properly understand the concept of the term in order to best describe his invention. It should be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined in

The present invention provides an electrode probe for charging and discharging a cylindrical secondary battery. The electrode probe includes a pair of probes for supporting and charging the cylindrical secondary battery at upper and lower portions. Specifically, the electrode probe may include: an upper probe in contact with the upper surface of the secondary battery and including an upper tip in electrical contact with the first electrode; and a lower probe in contact with the lower surface of the secondary battery, but including a lower tip in electrical contact with the second electrode, and in which a magnet for positioning and fixing the secondary battery is accommodated.

2 illustrates an electrode probe according to the present invention by way of example, and the present invention will be described with reference to this.

2, the present invention relates to an electrode probe 100 including a pair of probes for supporting and charging a cylindrical secondary battery at upper and lower portions, and is in contact with the upper surface of the secondary battery, but includes a first electrode and a first electrode. an upper probe 110 comprising an upper tip 112 in electrical contact; and a lower probe 120 in contact with the lower surface of the secondary battery, including a lower tip 122 in electrical contact with the second electrode, and in which a magnet for specifying and fixing the position of the secondary battery is accommodated.

In the electrode probe 100 of the present invention, after each tip of the upper probe 110 and the lower probe 120 contacts the electrode terminal of the cylindrical secondary battery, a current is applied.

Specifically, the upper probe 110 may include an upper probe body 111 having a through-hole formed therein; an upper tip 112 electrically contacting the first electrode of the secondary battery while being inserted into the through hole of the upper probe body 111; and an upper elastic member 113 supporting the upper tip 112 to maintain electrical contact with the first electrode of the secondary battery.

Here, the first electrode is generally a positive electrode positioned at the upper end of the cylindrical secondary battery, and may also be a negative electrode positioned at the lower end.

The upper probe body 111 has a cylindrical structure in which a through hole through which the upper tip 112 passes is formed, and the upper elastic member 113 is inserted into the upper probe body 111 and has a spring shape surrounding the upper tip 112 . characterized by being. Through such a structure, the upper tip 112 is positioned at the center of the upper probe body 111 , and the upper tip 112 can move up and down by the upper elastic member 113 .

The upper tip 112 is supported by the upper elastic member 113 and protrudes by a predetermined distance from the end of the upper probe body 110 . That is, the upper tip 112 is partially protruded from the upper probe body 111 and the upper elastic member 113 is maximally relaxed in the through hole. The upper tip 112 moves inside the upper probe body 111 while making contact with the first electrode of the secondary battery, and at this time, the upper elastic member 113 is in a state of maximum contraction within the through hole.

Meanwhile, the upper tip 112 further includes an upper tip stopper 114 , which prevents the upper tip 112 from being separated from the upper probe body 111 by the upper elastic member 113 .

In addition, the upper tip 112 moves up and down in a state of being fixed by the upper elastic member 113, and when the battery is fastened, it moves into the upper probe body 111, so that the tip is bent by an external force. It protects the tip by preventing damage.

In addition, the lower probe 120, the through-hole is formed, the lower probe body 121 is formed with a receiving portion for accommodating the magnet 125 at the end; a lower tip 122 electrically contacting the second electrode of the secondary battery while being inserted into the through hole of the lower probe body 121; a lower elastic member 123 supporting the lower tip 122 to maintain electrical contact with the second electrode of the secondary battery; and a magnet 125 accommodated in the receiving part of the lower probe body 121 to designate and fix the position of the secondary battery.

Here, the second electrode is generally a negative electrode positioned at the lower end of the cylindrical secondary battery, and may also be a cathode positioned at the upper end.

In the present invention, since a magnet 125 is included in the lower probe body 121 to reduce an error in inclination or arrangement of the cylindrical secondary battery, it is characterized in that a short circuit is prevented during charging and discharging.

Specifically, the lower probe body 121 has a cylindrical structure in which a through-hole through which the lower tip 122 passes, and the lower elastic member 123 is inserted into the lower probe body 121 and the lower tip 122 is inserted into the lower tip 122 . It is characterized in that it has a spring shape surrounding it. Through this structure, the lower tip 122 is positioned at the center of the lower probe body 121 , and the lower tip 122 can move up and down by the lower elastic member 123 .

And, like the upper tip 112 , the lower tip 122 moves up and down while being fixed by the lower elastic member 123 , and when the battery is fastened, the tip moves into the lower probe body 121 , so that the tip The tip can be protected by preventing physical damage such as bending under external force.

Specifically, the upper and lower probe body 121 may include a first lower probe body 121a having a cylindrical structure in which a through hole through which the lower tip 122 passes is formed; and a second lower probe body 121b having a cylindrical shape with a larger diameter than that of the first lower probe body 121a, which is formed to extend at the distal end of the first lower probe body 121a and has a receiving part for accommodating the magnet. include

Since the diameter of the second lower probe body 121b is larger than the diameter of the first lower probe body 121a, the contact area with the cylindrical secondary battery increases, so that the battery can be stably positioned. At the same time, the diameter of the second lower probe body 121b is preferably smaller than the diameter of the cylindrical secondary battery. Specifically, the diameter of the second lower probe body 121b may be 60 to 90% of the diameter of the cylindrical secondary battery, and specifically 70 to 80%. Since the diameter of the second lower probe body 121b is smaller than that of the cylindrical secondary battery, space efficiency can be increased when applied to a charging/discharging device, and at the same time, it is possible to secure a minimum space in which a magnet to be accommodated is sufficiently located.

Also, the diameter of the first lower probe body 121a may be equal to or greater than the diameter of the upper probe body 110 .

Meanwhile, the magnet 125 accommodated in the receiving portion of the second lower probe body 121b has a cylindrical shape in which a through hole through which the lower tip 122 passes is formed in the center. Specifically, the magnet accommodated in the lower probe has a cylindrical shape with a through hole formed in the center, and the diameter (R1) of the magnet may be in the range of 50 to 80% of the diameter (R2) of the cylindrical secondary battery to be charged and discharged. Specifically, it may be 50 to 67%. When the diameter (R1) of the magnet is less than 50% of the diameter (R2) of the cylindrical secondary battery, the fixing force of the cylindrical secondary battery is lowered to increase the probability of a short circuit. Considering the size of the second lower probe body (121b), a maximum of 80 % can be accounted for.

The thickness of the magnet 125 may be adjusted according to the accommodation space in the second lower probe body 121b, and as the thickness of the magnet 125 increases, the battery may be effectively fixed.

On the other hand, since the magnet 125 forms a through hole in the center, it does not interfere with the vertical movement of the lower tip 122 . Accordingly, the size of the through hole formed in the magnet 125 may be the same as the size of the through hole of the lower probe body 121 .

As the material of a typical cylindrical secondary battery case is made of iron (Fe), attractive force is applied by the magnet 125 .

The present invention can prevent a short circuit that may occur when the upper tip 112 and the lower tip 122 come into contact with the same electrode terminal by attaching or fixing the cylindrical secondary battery on the lower probe using this.

Like the upper tip 112 , the lower tip 122 is supported by the lower elastic member 123 and protrudes by a predetermined distance from the end of the lower probe body 121 . That is, the lower tip 122 is partially protruded from the lower probe body 121 and the lower elastic member 123 is maximally relaxed in the through hole. While in contact with the second electrode of the secondary battery, the lower tip 122 moves inside the lower probe body 121, and at this time, the upper elastic member 123 is in a state of maximum contraction within the through hole.

In the present invention, the upper tip 112 formed on the upper probe 110 and the lower tip 122 formed on the lower probe 120 are positioned on the same straight line. When the upper tip 112 and the lower tip 122 are not positioned on the same straight line, each tip may contact the same electrode terminal to cause a short circuit.

In one example, the lower and upper probes may be fixed to a support (not shown), respectively. In another example, the lower probe may be fixed to the support, and the upper probe may be pressurized with the secondary battery interposed therebetween.

As described above, the lower and upper probes of the present invention are fixed to the support and can be moved. Although the support is not shown in the present invention, it is preferable to additionally include a support in order to position the lower probe and the upper probe on a straight line. The support not only fixes each probe so as to be perpendicular to the battery terminal, but also moves the upper probe up and down during the charging/discharging process of the battery to be used as a means to pressurize the battery.

In addition, the present invention provides a cylindrical secondary battery charging/discharging device including the electrode probe. The charging/discharging device may further include elements related to charging and discharging of the battery, such as the electrode probe of the present invention, a probe support, a battery holder, a charging/discharging tray, a power source, a current/voltage measuring device, and the like.

Hereinafter, the present invention will be described in more detail through embodiments.

(Embodiment 1)

The electrode probe shown in FIG. 2 was prepared. Specifically, a magnet 125 was provided at one end of the lower probe body in contact with the battery. After disposing the cylindrical secondary battery in the center on the lower probe body, the upper probe is moved downward toward the cylindrical secondary battery. The positive terminal of the cylindrical secondary battery is in contact with the upper tip, and the negative terminal is in contact with the lower tip.

3 is a view showing a structure in which a cylindrical secondary battery disposed in the center of an electrode probe according to the present invention is fixed.

Referring to FIG. 3 , the cylindrical secondary battery 200 is fixed between the upper probe 110 and the lower probe 120 . Here, the cylindrical secondary battery 200 is positioned between the upper probe 110 and the lower probe 120, and the upper tip 112 and the lower tip 122 are in contact with the terminals of the battery. At this time, due to the magnet 125 located at one end of the second lower probe body 121b of the lower probe body 121 , the battery of the cylindrical secondary battery 200 is safely fixed.

In general, in the case of a cylindrical secondary battery, the jelly-roll type electrode assembly is accommodated in the receiving part of the cylindrical can, and the electrolyte is injected into the receiving part so that the electrode assembly is completely immersed in the cylindrical can, and then the cap is mounted on the upper end of the cylindrical can and combined. is in the form The electrode assembly has a structure in which a positive electrode, a separator, and a negative electrode are sequentially stacked and wound in a round shape, and a positive electrode tab protrudes in the upper axial direction at the center of the electrode assembly and is connected to the positive terminal. In addition, the cylindrical can may be made of metal, may include a accommodating part in which the electrode assembly may be accommodated, and may have an open upper end. At this time, the cylindrical can is connected to the negative electrode tab of the electrode assembly to act as a negative terminal.

In general, if the battery is not located in the center of the probe, the battery may be tilted by its weight. As mentioned above, in the cylindrical secondary battery, the cylindrical can serves as the negative terminal, so if the battery is not correctly aligned, the upper tip may come into contact with the cylindrical can and cause a short circuit. However, in the present invention, the battery is fixed so as not to be tilted by the magnet to prevent contact between the upper tip and the cylindrical can. In addition, even if the accuracy of battery placement is somewhat reduced, the upper tip is fixed in a range where it does not meet the negative electrode, so that a short circuit does not occur.

In this embodiment, as shown in Figure 4, the diameter (R2) of the cylindrical secondary battery 200 was 18mm, the diameter (R1) of the magnet 125 in the lower probe body 121 was 12mm, the diameter of the magnet This is 67% of the diameter of this cylindrical secondary battery.

(Embodiment 2)

A cylindrical secondary battery was placed on the electrode probe as in Embodiment 1, except for changing the size of the magnet accommodated in the lower probe body. As shown in FIG. 5 , the diameter R2 of the cylindrical secondary battery 200 was 18 mm, the diameter R1 of the magnet 125 in the lower probe body 121 was 9 mm, and the diameter of the magnet was a cylindrical secondary battery. 50% of the diameter.

The above description is merely illustrative of the technical spirit of the present invention, and various modifications and variations will be possible without departing from the essential characteristics of the present invention by those skilled in the art to which the present invention pertains. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments. The protection scope of the present invention should be construed by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100: electrode probe, 110: upper probe,
111: upper probe body, 112: upper tip (tip),
113: upper elastic member, 114: upper tip stopper (stopper),
120: lower probe, 121: lower probe body,
121a: a first lower probe body, 121b: a second lower probe body;
122: lower tip, 123: lower elastic member,
124: lower tip stopper, 125: magnet,
200: cylindrical secondary battery.

Claims (14)

An electrode probe comprising a pair of probes for supporting and charging a cylindrical secondary battery at upper and lower portions,
an upper probe in contact with the upper surface of the secondary battery and including an upper tip in electrical contact with the first electrode; and
A cylindrical secondary battery charging/discharging electrode probe including a lower probe in contact with the lower surface of the secondary battery, but including a lower tip in electrical contact with the second electrode, and a lower probe housing a magnet for specifying and fixing the position of the secondary battery.
The method of claim 1,
The upper probe is
an upper probe body having a through hole formed therein;
an upper tip electrically contacting the first electrode of the secondary battery while being inserted into the through hole of the upper probe body; and
and an upper elastic member supporting the upper tip to maintain electrical contact with the first electrode of the secondary battery.
3. The method of claim 2,
The upper tip is a cylindrical secondary battery charging/discharging electrode probe having a shape that protrudes by a predetermined distance from the end of the upper probe body while being supported by the upper elastic member.
3. The method of claim 2,
The upper probe body has a cylindrical structure with a through hole through which the upper tip passes,
The upper elastic member is a cylindrical secondary battery charging/discharging electrode probe, characterized in that it has a spring shape surrounding the upper tip while being inserted into the upper probe body.
The method of claim 1,
The lower probe is
a lower probe body having through-holes formed thereon and having a receiving portion at an end portion for accommodating a magnet;
a lower tip electrically contacting the second electrode of the secondary battery while being inserted into the through hole of the upper probe body;
a lower elastic member supporting the lower tip to maintain electrical contact with the second electrode of the secondary battery; and
An electrode probe for charging and discharging a cylindrical secondary battery, which is accommodated in the receiving part of the lower probe body and includes a magnet for designating and fixing the position of the secondary battery.
6. The method of claim 5,
The lower tip is a cylindrical secondary battery charging/discharging electrode probe having a shape that protrudes by a predetermined distance from the end of the lower probe body while being supported by the lower elastic member.
6. The method of claim 5,
The lower probe body has a cylindrical structure with a through hole through which the lower tip passes,
The lower elastic member is a cylindrical secondary battery charging/discharging electrode probe, characterized in that it has a spring shape surrounding the lower tip while being inserted into the lower probe body.
6. The method of claim 5,
The lower probe body,
a first lower probe body having a cylindrical structure in which a through hole through which a lower tip passes; and
A cylindrical secondary battery charging/discharging electrode probe including a second lower probe body having a cylindrical shape having a larger diameter than that of the first lower probe body, wherein the first lower probe body has a structure extending at the end of the first lower probe body to form a receiving part for accommodating the magnet.
9. The method of claim 8,
The magnet accommodated in the accommodating part of the second lower probe body is a cylindrical secondary battery charging/discharging electrode probe, characterized in that it has a cylindrical shape in which a through hole through which the lower tip passes is formed.
The method of claim 1,
An electrode probe for charging and discharging a cylindrical secondary battery, characterized in that the upper tip formed on the upper probe and the lower tip formed on the lower probe are positioned on the same straight line.
The method of claim 1,
The magnet housed in the lower probe has a cylindrical shape with a through hole in the center,
The diameter (R1) of the magnet is an electrode probe for charging and discharging a cylindrical secondary battery, characterized in that 50 to 80% of the diameter (R2) of the cylindrical secondary battery to be charged and discharged.
The method of claim 1,
The electrode probe for charging and discharging a cylindrical secondary battery, characterized in that the lower and upper probes are fixed to the support, respectively.
The method of claim 1,
The lower probe is fixed to the support,
The upper probe is an electrode probe for charging and discharging a cylindrical secondary battery, characterized in that the secondary battery is pressurized with the secondary battery interposed therebetween.
A cylindrical secondary battery charging/discharging device comprising the electrode probe according to claim 1 .

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