KR20140067229A - Secondary battery charge and discharge probe - Google Patents

Abstract

The purpose of the present invention is to provide a probe for charging and discharging a battery. The configuration of the probe for charging and discharging a battery of the present invention, in the probe for charging and discharging a battery applying a current by being in contact with an electrode (4) of a battery (2) in a process of charging and discharging the battery (2), includes a pin body (10) with a plurality of pin insertion holes (12); a plurality of probe pins (20) coupled to the pin insertion hole (12) of the pin body (10) to be relatively slid; and a curved part (30) formed on the edge of the probe pin (20) and forming a contact surface in a certain area between the electrode (4) of the battery (2) and the edge of the probe pin (20).

Description

[0001] The present invention relates to a secondary battery charge and discharge probe,

More particularly, the present invention relates to a probe for battery charging, and more particularly, to a probe for charging a battery, more specifically, It is possible to prevent the oxidization phenomenon from occurring near the edge of the outer edge of the probe pin to prevent deterioration of the charging and discharging efficiency of the probe and to prolong the life of the probe by preventing deterioration due to edge oxidation of the probe pin, The present invention relates to a probe dedicated to charge and discharge of a battery, which can minimize the contact resistance between the probe pin and the battery during charging and discharging of the battery by maximizing the contact point between the probe pin and the electrode of the battery, will be.

Generally, the secondary battery is a secondary battery that can be recharged after recharging or recharging, such as a rechargeable battery or a lead-acid battery. In recent years, portable electronic devices such as mobile phones, PDAs, It is required to develop a technology for a rechargeable battery which can be used for a long time and has a long life. Such secondary batteries include nickel-cadmium (Ni-Cd), nickel-hydrogen (Ni-MH), lead batteries (SLA), lithium-ion and lithium-polymer. Such a secondary battery is formed of a battery pack type in which a plurality of cells, that is, unit cells, are connected in consideration of charging / discharging efficiency and current capacity. Currently, the secondary battery has high energy density, light weight, high voltage, And excellent life span. Lithium batteries are classified as lithium ion batteries, lithium ion polymer batteries, and lithium metal polymer batteries.

A manufacturing process of a lithium battery will be described as follows: a hard pack process in which a circuit, a terminal or a connecting component is coupled to a bare cell and then a case is assembled; Charging and discharging process. Here, the shape and shape of the battery are determined in accordance with the use of the product and the required characteristics in the hard pack process, and the performance of the battery is determined during the charging / discharging process, and the product is determined.

On the other hand, the charging and discharging process of the battery is often performed using a probe. The probe includes a probe pin to which a current and a voltage are applied so that the current probe pin and the voltage probe pin 20B of the probe are respectively charged and discharged .

However, due to factors such as the angle of the battery being changed during charging / discharging due to the probe pin of the probe being brought into contact with the electrode of the battery, a spark is generated at the edge portion of the outer edge portion of the probe pin, There is a problem that the edge portion of the semiconductor wafer is oxidized and deteriorated.

In other words, the mechanical tolerance (mechanical error) or the horizontal error (that is, the electrode of the battery is in a correct horizontal state with respect to the contact surface between the probe pin and the probe pin) The probe pin can not be placed as wide as possible in contact with the electrode of the battery due to the tolerance of the jig for supporting the battery and some points are high and some points are relatively low. Since the edge is brought into contact with the electrode surface of the battery in a point-like manner, when the battery is charged and discharged in such a state, a spark is generated and the end portion of the probe pin is oxidized and deteriorated.

In addition, if the edge of the probe pin is oxidized, the electrical resistance increases, which may lead to a reduction in charge / discharge efficiency of the battery. In order to minimize the contact resistance of the battery during charging and discharging, it is necessary to maximize the number of contact points between the probe pins and the electrodes of the battery. However, due to errors in the mechanical equipment and horizontal errors of the battery itself, The electrical resistance between the probe pin and the electrode of the battery must be increased. In addition, when the battery is charged and discharged in the state where the edge of the probe pin is oxidized, the electrical resistance is increased and ultimately the battery charge / Resulting in undesirable results.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide an apparatus and a method for manufacturing a battery, It is possible to prevent the oxidation phenomenon from occurring near the edge of the outer edge of the probe pin in contact with the electrode to prevent deterioration of the charging and discharging efficiency of the probe and to prevent degradation due to edge oxidation of the probe pin, Further, by maximizing the contact point between the probe pin and the electrode of the battery, it is possible to minimize the contact resistance between the probe pin and the battery at the time of charge / discharge of the battery, and therefore, It is intended to provide a dedicated probe.

According to an aspect of the present invention, there is provided a battery charge-only probe for contacting a battery (2) with an electrode (4) during charging / discharging operation of the battery (2) A pin body 10 provided with a pin 12; A plurality of probe pins (20) relatively slidably coupled to the pin insertion holes (12) of the pin body (10); And a curved surface portion 30 provided at an outer portion of the probe pin 20 to form a contact surface having a predetermined area between the electrode 4 of the battery 2 and the outer edge of the probe pin 20 A probe for exclusive use of the battery for improving the anti-oxidation function is provided.

The probe pin 20 is disposed in a radial direction with respect to a central portion of the pin body 10 and the curved surface portion 30 is formed on the probe pin 20 with reference to a contact center portion of the probe pin 20. [ And a plurality of curved portions 30 that are configured to be upwardly rounded in the direction of the upper end of the probe pin 20 and gradually decrease in radius of curvature radially outward from the contact center portion of the probe pin 20.

The probe pin body 10 is provided with a plurality of contact protrusions 32 on the surface facing the surface of the electrode 4 and the contact protrusion 32 is provided with a flat surface 34, The current is applied while the flat surface 34 of the projection 32 is in contact with the surface of the electrode 4. [

The contact protrusions 32 are arranged in a lattice pattern on the bottom surface of the probe pin body 10 and a concave groove 36 is formed between the contact protrusions 32 in a lattice shape.

The probe pin 20 includes a voltage probe pin 20B provided at the center of the pin body 10 and a plurality of current probe pins 20A radially arranged around the voltage probe pin 20B. And the voltage probe pin 20B is provided with a contact tip portion 24 having a sharp end at an end of the voltage probe pin 20B which is in contact with the surface of the electrode 4 of the battery 2.

The probe pins 20 are divided into a plurality of groups of probe pins 20 while the probe pins 20 are coupled to the probe pins 20 so that the plurality of probe pins 20 are separated from the group of probe pins 20 And a plurality of probe pin blocks (38) formed on the outer surface of the probe pin brolle to form a curved surface portion (30) forming a contact surface with the electrode (4) of the battery (2) Is formed.

The curved surface portion 30 is formed to be upwardly rounded in the direction of the upper end of the probe pin block 38 with reference to the contact center portion of the probe pin block 20 and at the same time, It is preferable to include a plurality of curved portions 30 gradually decreasing in radius of curvature toward the outer side.

According to the present invention, the lower end of a plurality of current probe pins, the lower end of a voltage probe pin, and the lower end of a current probe pin, which are mounted side by side on a pin body, The current probe pin is charged and discharged by forming a curved portion at the edge of the outer frame portion which is likely to be oxidized by point contact with the electrode of the battery in the entire lower surface of the current probe pin, The edge of the current probe pin is prevented from point-to-point contact with the electrode of the battery and the large-area contact is caused. Therefore, it is possible to prevent the oxidation of the edge of the current probe pin due to spark There are advantages.

In a state where the electrode surface of the battery is not in a normal horizontal state, and the angle of the electrode surface of the battery is changed based on the tolerance on the mechanical equipment, the tolerance on the assembly or the tolerance of the jig supporting the battery, The edge of the current probe pin is not point-contacted due to the curved surface portion of the current probe pin on the surface of the electrode of the battery, even if the surface of the battery is inclined to one side with respect to the vertical direction When the surface of the electrode of the battery and the current probe pin are in contact with each other through the curved surface portion, sparking due to point contact is prevented. Oxidation due to spark during charging and discharging of the battery can be prevented. , Due to the prevention of edge oxidation of the current probe pin, It also has the advantage of increased life span.

In the present invention, the current probe pin is disposed in the radial direction with respect to the central portion of the pin body, the curved surface portion is configured to be upwardly rounded toward the upper end of the current probe pin with reference to the contact center portion of the probe pin, Wherein the curved surface portion of the current probe pin has a curved surface portion in which the curvature radius gradually decreases gradually from the center portion to the radially outward portion, It is advantageous in that the oxidation prevention efficiency is further improved. Furthermore, since a plurality of surface contact portions are secured between the current probe pin and the battery electrode, the battery charge / discharge efficiency is improved.

In addition, in the present invention, the voltage probe pin may be resiliently raised and lowered relative to the pin body by an elastic body (spring or the like) separately from the current probe pin, and at least two The probe pin block is divided into a plurality of groups and is simultaneously held together with the probe pin block by an elastic body (spring or the like) separately from the current probe pin so that the probe pin block contacts the electrode surface of the battery with a uniform elastic pressure And the curved surface portion is provided at the outer edge of the probe pin block. Therefore, even if the electrode of the battery is arranged to be inclined, the portion of the battery that is in contact with the electrode is replaced with the probe pin block, The contact area between the electrode and the portion to which the current is applied can be maximized, Further improve efficiency while still around the edge of the probe pin block is made, the surface contact portion due to surface non-contacting the electrode of the battery and that also have antioxidant effect. If the curved portion of the probe pin block also has a plurality of curved portions (for example, a first curved portion, a second curved portion, and a third curved portion) having different radii of curvature, Since a plurality of contact points can be secured, the oxidation preventing effect can be further enhanced and the charge / discharge efficiency of the battery can be further increased.

Further, in the present invention, the voltage probe pin is provided with a contact peak having a sharp end at an end of the battery which contacts the electrode. The contact peak may penetrate the foreign substance on the electrode surface of the battery, Therefore, the voltage sensing efficiency of the voltage probe pin can be further improved.

1 is a perspective view of a battery dedicated charging probe according to a first embodiment of the present invention;
Figure 2 is a perspective view of the bottom of Figure 1;
Fig. 3 is a longitudinal sectional view of Fig. 1
Fig. 4 is a perspective view showing the use state of the battery lifting exclusive probe of the present invention
5 and 6 are side views schematically showing the contact state between the current probe pin and the electrode of the battery,
7 is a perspective view showing a bottom surface of a battery dedicated charge probe according to another embodiment of the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Referring to the drawings, a battery charge-only probe according to the present invention applies electric current in contact with an electrode 4 of a battery 2 during charging / discharging operation of a battery 2, and includes a plurality of pin insertion holes 12 A plurality of probe pins 20 coupled to the pin insertion holes 12 of the pin body 10 to be slidable relative to each other; And a curved surface portion 30 which forms a contact surface of a predetermined area between the electrode 4 of the battery 2 and the outer edge of the probe pin, and the edge of the probe pin (in particular, the current probe pin 20A) The surface contact between the electrode 4 of the battery 2 and the probe pin is brought into surface contact with the curved surface portion 30 of the battery 2, There is a main feature in that the edges are prevented from being oxidized. In the present invention, the curved surface portion 30 is provided on the outer edge portion on the lower end side of the current probe pin 20A.

The pin body 10 is formed in a substantially circular block shape. The center pin of the pin body 10 is provided with a center pin insertion hole 12a in the form of a straight hole for mounting the voltage probe pin 20B. Around the insertion hole 12a, there are provided a plurality of outline pin insertion holes 12b in the shape of a straight hole in the circumferential direction. The pin insertion hole 12 of the pin body 10 is constituted by the center pin insertion hole 12a and the outer pin insertion hole 12b. At this time, the center pin insertion hole 12a is communicated from the upper surface of the pin body 10 to the lower surface. In addition, the plurality of outer pin insertion holes 12a are in the shape of a straight hole for mounting the current probe pin 20A. A plurality of outer pin insertion holes 12a disposed around the center pin insertion hole 12a are also communicated from the upper surface of the pin body 10 to the bottom surface. In the present invention, the center pin insertion hole 12a is provided in the central part of the pin body 10 and the outer pin insertion hole 12a for mounting the eight current probe pins 20A is mounted on the center And is arranged around the pin insertion hole 12a. It goes without saying that the number of the outer pin insertion holes 12a for mounting the current probe pins 20A and the number of the current probe pins 20A can be increased or decreased as needed.

A voltage probe pin 20B and a current probe pin 20A are coupled to the center pin insertion hole 12a and the plurality of outer pin insertion holes 12b of the pin body 10, respectively. A voltage probe pin 20B is coupled to the center pin insertion hole 12a at the center of the pin body 10 and each of the outer pin insertion holes 12a provided at predetermined intervals in the circumferential direction of the pin body 10, A current probe pin 20A is coupled to the pin body 10 and a voltage probe pin 20B is provided at the center of the pin body 10. A plurality of current probe pins 20A are arranged around the voltage probe pin 20B in the circumferential direction And a plurality of the probe pins 20 are arranged side by side on the pin body 10. The current probe pin 20A and the voltage probe pin 20B are coupled to each other by a snap ring 26 so as not to be disengaged from the pin insertion hole 12 of the pin body 10 and to be capable of relative lift.

The current probe pins 20A and the voltage probe pins 20B are connected to the pin body 10 through the pin insertion holes 12 of the pin body 10, The current probe pin 20A and the voltage probe pin 20B are resiliently coupled to the pin insertion hole 12 of the battery 2 So as to contact the surface of the electrode (4).

Meanwhile, among the probe pins 20, the current probe pin 20A is electrically connected to a current cable, and the voltage probe pin 20B is electrically connected to a voltage sensing cable The current probe pins 20A apply current to the electrode 4 of the battery 2 from the power supply connected to the current cable and the voltage probe pin 20B contacts the electrode 4 of the battery 2 State to determine whether or not the current is properly charged.

In the present invention, the curved surface portion 30 is provided at the edge of the outer edge of the probe pin 20. In particular, the curved surface portion 30 is provided at the edge of the current probe pin 20A for applying the current to the electrode 4 of the battery 2, (30). The probe pin 20 is disposed radially with respect to the central portion of the pin body 10 and the curved surface portion 30 is disposed in the direction of the upper end portion of the probe pin 20 with respect to the contact center portion of the probe pin 20 As shown in FIG. The curved surface portion 30 is preferably composed of a plurality of curved surface portions 30 whose curvature radii gradually decrease from the contact center portion of the probe pin 20 radially outwardly. The radius of curvature of each of the curved surface portions 30 is gradually decreased from the center portion of the current probe pin 20A toward the radially outward side of the current probe pin 20A. That is, the inside of the curved surface portion 30 of the current probe pin 20A is formed as a flat surface and the curved surface portion 30 is formed outside the center flat surface portion, 20A having a curvature radius gradually decreasing toward the outer periphery thereof. The plurality of curved portions 30 may be formed of the first curved portion 30A, the second curved portion 30B and the third curved portion 30C. The curved radius R 1 of the first curved portion 30A Is relatively larger than the curvature radius R2 of the second curved surface portion 30B and the curvature radius R2 of the second curved surface portion 30B is relatively larger than the curvature radius R3 of the third curved surface portion 30C . That is, the relationship R1> R2> R3 is established. At this time, it is preferable that the difference in height from the flat area portion of the current probe pin 20A to the curved surface portion 30 of the outermost portion (that is, the height difference to the third curved surface portion 30C) Do.

The probe for charging the battery according to the present invention is mounted on the battery 2 charging / discharging system (for example, DCIR system equipment) described in Patent Application No. 10-2011-0138960, The probe pin block 38 can be configured to be brought into contact with or unactuated while being lifted or lowered.

According to the present invention, according to the present invention, the lower ends of the plurality of current probe pins 20A, the lower ends of the voltage probe pins 20B, and the current probe pins 20A, The battery 2 is charged and discharged by applying a current to the electrode 4 of the battery 2 through the current probe pin 20A in a state in which the lower end of the battery 2 is brought into contact with the surface of the electrode 4 of the battery 2 The curved surface portion 30 is formed at the edge of the outer frame portion where point contact is caused between the entire surface of the lower end portion of the current probe pin 20A and the electrode 4 of the battery 2 and is easily oxidized, It is possible to avoid point contact between the edge of the current probe pin 20A and the electrode 4 of the battery 2 due to the edge curved portion 30 of the battery cell 20A, (2) During charging / discharging, a spark is generated at the edge of the current probe pin 20A There is an advantage of preventing the oxidation phenomenon caused by the oxidation.

The surface of the electrode 4 of the battery 2 is not in a horizontal state and the surface of the electrode 4 of the battery 2 is in a horizontal state due to a tolerance in a mechanical system or a tolerance in assembly or a tolerance of a jig for supporting the battery 2. [ (I.e., a state in which the surface of the electrode 4 is tilted to one side with respect to the vertical direction so that the height difference is generated with respect to the upper and lower sides), the surface of the electrode 4 of the battery 2 The edges of the current probe pin 20A are not in point contact but are in wide contact with each other due to the curved surface portion 30 of the current probe pin 20A. It is possible to prevent sparking due to point contact when the outer contour of the current probe pin 20A is brought into surface contact through the curved surface portion 30 and oxidation phenomenon due to sparking during charging and discharging of the battery 2 can be prevented The edge of the current probe pin 20A The life of the battery dedicated probe is also increased because of oxidation prevention.

In the present invention, the current probe pin 20A is disposed in the radial direction with respect to the center of the pin body 10, and the curved surface portion 30 has a current probe pin 20A), and a plurality of curved surface portions (30) configured to be gradually rounded radially outward from the contact center portion of the probe pin (20) in a stepwise manner, It is possible to secure a plurality of points at which the surface contact with the electrode 4 of the battery 2 is made not by point contact but by the stepwise curved surface portion 30 of the pin 20A, And further the charge / discharge efficiency of the battery 2 is improved by securing a plurality of surface contact portions between the current probe pin 20A and the electrode 2 of the battery 2.

In the present invention, the voltage probe pin 20B is configured to be able to be resiliently raised and lowered relative to the pin body 10 by an elastic body 42 (spring or the like) separately from the current probe pin 20A, The current probe pins 20A are divided into a plurality of groups and coupled to the respective probe pin blocks 38 divided into the plurality of probe pins 30A and 30B and simultaneously the probe pins 20A are separated from the probe pins 20A by the elastic body 42 And the probe pin block 38 together with the pin block 38 so that the probe pin 20 block contacts the surface of the electrode 4 of the battery 2 with a uniform elastic compression force. And the curved surface portion 30 is also provided at the outer edge of the probe pin block 38 so that the electrode 4 of the battery 2 is arranged at an angle (4) is replaced with the probe pin block (38), so that the battery (2) It is possible to maximize the contact area between the electrode 4 and the portion to which the current is applied so as to further improve the charging and discharging efficiency of the battery 2, Since the surface contact with the electrode 4 of the electrode 2 is not made in point contact, the electrode 4 can be prevented from oxidation. If the curved surface portion 30 of the probe pin block 38 is formed of a curved surface portion 30 having a plurality of curvature radii different from each other, a plurality of surface contact points, which are in contact with the electrode 4 of the battery 2 in a large area, It is possible to further increase the oxidation preventing effect and to further increase the charging / discharging efficiency of the battery 2.

In the present invention, the probe pin block 38 is provided with a plurality of contact protrusions 32 on the surface facing the surface of the electrode 4 (that is, the bottom surface of the probe pin block 38), and the contact protrusions 32 Is provided with a flat surface 34 to apply a current in a state in which the flat surface 34 of the contact protrusion 32 is in contact with the surface of the electrode 4. [ That is, the flat surface 34 (flat surface) of the contact protrusion 32 is configured to have surface contact with the surface of the electrode 4 with a predetermined area. The contact protrusions 32 are arranged in a lattice pattern on the bottom surface of the probe pin block 38 and recessed grooves 36 are formed between the contact protrusions 32 in a lattice shape.

The flat surface of the contact pin protrusion of the probe pin block 38 is brought into contact with the surface of the electrode 4 of the battery 2 to maximally prevent the contact between the electrode 4 of the battery 2 and the probe pin block 38 And the probe pin block 38 is pressed against the surface of the electrode 4 of the battery 2 to charge and discharge the battery 2. In this case, The heat is released through the concave grooves 36 of the grid shape, thereby contributing to prevention of the charge / discharge efficiency deterioration of the battery 2 due to heat. That is, the concave groove 36 between the contact protrusions 32 of the probe pin block 38 functions as a heat dissipating groove for discharging heat to the outside when the battery 2 is charged and discharged.

The voltage probe pin 20B and the current probe pin 20A are connected to each other in a relatively slidable manner (that is, the center pin insertion hole 12a of the pin body 10) The voltage probe pin 20B and the current probe pin 20A are resiliently biased by the elastic body 42 to be electrically connected to the voltage probe pin 20B and the respective probe pin blocks 20A, (38) elastically contacts the surface of the electrode (4) of the battery (2). The elastic body 42 is constituted by a coil spring. The coil spring is fitted to the outer circumferential surface of the voltage probe pin 20B and the outer circumferential surface of the current probe pin 20A, and both ends of the coil spring are connected to the voltage probe pin 20B and the pin body The voltage probe pin 20B and the probe pin block 38 are mounted on the electrode 4 of the battery 2 by the coil spring being interposed between the supporting end portions provided in the pin insertion hole 12 of the battery 10, And elastically contacts the surface.

As a result, the individual probe pin blocks 38 to which the current probe pins 20A are coupled are pressed against the surface of the electrode 4 of the battery 2 at a predetermined pressure (about 5 kg / cm 2) The contact protrusions 32 and 22 having a flat surface at the lower end of the probe pin block 38 pressed against the surface of the electrode 4 of the battery 2 are provided in the present invention. The flat surface of the contact protrusion 32 is in contact with the surface of the electrode 4 of the battery 2 in a surface contact state so that the electrical contact resistance can be minimized during charging and discharging of the battery 2.

The voltage probe pin 20B of the present invention is provided with a contact tip portion 24 having a sharp end at an end portion of the battery 2 which contacts the electrode 4. The contact tip portion 24 Foreign substances on the surface of the electrode 4 of the battery 2 can be penetrated to improve contact with the electrode 4, which further enhances the voltage sensing efficiency of the voltage probe pin 20B. For example, the electrode 4 of the battery 2 may be made of aluminum, and an aluminum oxide film may be formed on the surface of the electrode 2 so that the contact between the voltage probe pin 20B and the electrode 4 of the battery 2 The pointed contact portion 24 of the voltage probe pin 20B may penetrate the oxide film formed on the surface of the electrode 4 of the battery 2, So that the contact between the voltage probe pin 4 and the voltage probe pin 20B is increased, thereby further enhancing the voltage sensing efficiency.

In the present invention, in the present invention, the voltage probe pin 20B is configured to be able to be resiliently raised and lowered relative to the pin body 10 by an elastic body 42 (spring or the like) separately from the current probe pin 20A The current probe pins 20A are divided into a plurality of groups and coupled to the respective probe pin blocks 38 divided into at least two or more parts and at the same time an elastic body 42 With the probe pin block 38 together with the probe pin block 38 so that the probe pin 20 block is brought into contact with the surface of the electrode 4 of the battery 2 with a uniform elastic pressure force, (2) charging and discharging are performed, and further, the curved surface portion 30 is provided on the edge of the outer frame of the probe pin block 38.

The electrode 4 of the battery 2 is replaced by the probe pin block 38 so that the electrode 4 of the battery 2 is replaced with the electrode 4 of the battery 2, It is possible to maximize the charge / discharge efficiency of the battery 2 and to improve the charging / discharging efficiency of the battery 2 due to the curved surface portion 30 of the probe pin block 38, Since the surface contact with the electrode 4 is not made in point contact, it can also have an antioxidant effect. Since the curved surface portion 30 of the probe pin block 38 is also formed of the curved surface portions 30 having a plurality of curvature radii different from each other, the surface contact portion, which contacts the electrode 4 of the battery 2 in a large area, It is possible to further secure the oxidation preventing effect and to further improve the charging / discharging efficiency of the battery (2).

In other words, each of the probe pin blocks 38 is divided into a plurality of individual probe pin blocks 38, and a plurality of current probe pins 20A are coupled to a predetermined number of groups in each of the probe pin blocks 38, The body 20 and the current probe pins 20A can be raised and lowered separately from the other probe pins 20 and the current probe pins 20A so that the surface of the electrode 4 of the battery 2 is not in a normal horizontal state, The surface of the electrode 4 of the battery 2 is in a state in which the surface of the electrode 4 is angularly displaced with respect to the horizontal state (that is, the surface of the electrode 4) The contact point at which the body of the probe pin 20 is in contact with the surface of the electrode 4 of the battery 2 can be maximized even if the probe 2 is in a state of being inclined toward either side , Whereby the battery 2 And the probe pin 20 can be minimized and a phenomenon such as loss of electricity due to a large amount of heat due to the minimization of the contact resistance can be prevented, And the charge / discharge efficiency can be improved. It is possible to minimize the contact resistance at the contact portion between the cell 2 and the probe pin 20 and prevent the phenomenon that electricity is lost due to a large amount of heat due to the minimization of the contact resistance, 2 and the curved surface portion 30 is formed on the edge of the outer edge of the probe pin block 38 so that the electrode 4 of the battery 2 and the probe The edge contact portion of the outer edge portion of the pin block 38 is brought into surface contact with the wide surface of the battery 2 not in point contact with the electrode 4 by the curved surface portion 30, Effect. Since the curved surface portion 30 of the edge of the probe pin block 38 is also formed of the curved surface portions 30 having a plurality of curvature radii different from each other, the surface contact portion, which contacts the electrode 4 of the battery 2 in a large area, A plurality of batteries can be secured, so that the oxidation preventing effect can be further enhanced and the charging / discharging efficiency of the battery 2 can be further improved.

The specific embodiments of the present invention have been described above. It is to be understood, however, that the scope and spirit of the present invention is not limited to these specific embodiments, and that various modifications and changes may be made without departing from the spirit of the present invention. If you have, you will understand.

Therefore, it should be understood that the above-described embodiments are provided so that those skilled in the art can fully understand the scope of the present invention. Therefore, it should be understood that the embodiments are to be considered in all respects as illustrative and not restrictive, The invention is only defined by the scope of the claims.

2. Battery 4. Electrode
10. Pin body 20. Probe pin
20A. Current probe pin 20B. Voltage probe pin
24. Contacting tip 30. Surface
30A. The first curved portion 30B. The second curved portion
30C. Third curved portion 32. Contact projection
34. Flat surface 36. Concave groove
38. Probe pin block 42. Elastic body

Claims (8)

A battery charger dedicated probe which contacts the electrode (4) of the battery (2) during charging / discharging operation of the battery (2)
A pin body 10 having a plurality of pin insertion holes 12;
A plurality of probe pins (20) relatively slidably coupled to the pin insertion holes (12) of the pin body (10);
A curved surface portion 30 provided at an outer portion of the probe pin 20 to form a contact surface having a predetermined area between the electrode 4 of the battery 2 and the outer edge of the probe pin 20; Wherein the first electrode is formed on the surface of the first electrode.
The method according to claim 1,
The probe pin 20 is disposed in a radial direction with respect to a central portion of the pin body 10 and the curved surface portion 30 is formed on the probe pin 20 with reference to a contact center portion of the probe pin 20. [ And a plurality of curved portions 30A, 30B, and 30C that are configured to be upwardly rounded in the direction of the upper end of the probe pin 20 and gradually decrease in radius of curvature radially outward from the contact center portion of the probe pin 20 Which is made up of an oxidation prevention function.
3. The method of claim 2,
The probe pin body 10 is provided with a plurality of contact protrusions 32 on the surface facing the surface of the electrode 4 and the contact protrusion 32 is provided with a flat surface 34, And a current is applied in a state in which the flat surface (34) of the projection (32) is in contact with the surface of the electrode (4).
The method of claim 3,
Wherein the contact protrusions (32) are arranged in a lattice shape on the bottom surface of the probe pin body (10), and a concave groove (36) is formed between the contact protrusions (32) in a lattice shape.
The method according to claim 1,
The probe pin 20 includes a voltage probe pin 20B provided at the center of the pin body 10 and a plurality of current probe pins 20A radially arranged around the voltage probe pin 20B. And the voltage probe pin 20B is provided with a contact tip portion 24 having a sharp end at an end which is in contact with the surface of the electrode 4 of the battery 2. [ .
6. The method of claim 5,
The voltage probe pin 20B and the current probe pin 20A are slidably coupled to each other in the pin body 10 and the voltage probe pin 20B and the current probe pin 20A are connected to each other through an elastic body 42. [ And is resiliently brought into contact with the surface of the electrode (4) of the battery (2).
The method according to claim 1,
The probe pins 20 are divided into a plurality of groups of probe pins 20 while the probe pins 20 are coupled to the probe pins 20 so that the plurality of probe pins 20 are separated from the group of probe pins 20 And a plurality of probe pin blocks (38) formed on the outer surface of the probe pin brolle to form a curved surface portion (30) forming a contact surface with the electrode (4) of the battery (2) Wherein the first electrode and the second electrode are formed on both sides of the first electrode.
8. The method of claim 7,
The curved surface portion 30 is formed to be upwardly rounded in the direction of the upper end of the probe pin block 38 with reference to the contact center portion of the probe pin block 20 and at the same time, And a plurality of curved portions (30A, 30B, 30C) gradually decreasing in radius of curvature gradually toward the outer side.

Images