KR101240453B1 - Apparatus and Method for Welding of Electrode of Secondary Battery - Google Patents

Abstract

A welding device for welding a first electrode provided in a first secondary battery and a second electrode provided in a second secondary battery, the beam irradiator emitting energy of a laser beam higher than a melting point of the first electrode and lower than a melting point of the second electrode. And an optical system for condensing a laser beam emitted from the beam irradiator and irradiating the contact region between the first electrode and the second electrode.

Description

Apparatus and Method for Welding of Electrode of Secondary Battery}

The present invention relates to a welding apparatus and method, and more particularly to a welding apparatus and method of a secondary battery electrode.

In recent years, in Korea, electric vehicles are allowed to travel in the city by special regulations on low-speed electric vehicles, and electric carts used in golf courses and airports also require large-capacity rechargeable batteries. In addition, since 2011, electric vehicles driving on the highway are expected to emerge, so that the demand for large-capacity rechargeable batteries will increase with the spread of electric vehicles.

Examples of secondary batteries include lead-acid batteries, nickel-cadmium batteries (NIi-Cd), nickel-hydrogen batteries (Ni-MH, Nikel Metal Hydride), and lithium ion batteries (Li-Ion). Among these, lithium ion batteries have the highest evaluation among commercially available secondary batteries because of their excellent electrochemical properties, and the amount of use of them is the highest.

Lithium-ion batteries use a single battery alone when a small amount of power is required, such as a mobile phone. However, when a large amount of power is required, such as an electric vehicle, several batteries are connected in series. In order to combine a lithium ion battery in series, aluminum (Al) used as an anode of the battery and copper plate (Cu) used as a cathode are bonded to each other, and the thickness of these electrodes is usually 0.2 to 0.5 mm.

As a method of joining a Cu-Al electrode, a welding method and a mechanical fastening method are applied. First of all, the mechanical fastening method is fastening with bolts and nuts. Compared with the welding method, there are many problems such as higher contact resistance, higher resistance due to corrosion of aluminum and copper when used for a long time, and weakening force due to vibration during movement. Holding it.

Methods using welding include resistance welding and laser welding.

Resistance welding means that a large current flows under pressure applied to the welded material, and heat is obtained by the contact resistance generated at the contact surface between the metals and the specific resistance of the metal.As a result, when the metal is heated or melted, the welding is performed by the applied pressure. It is a method of making it happen. By the way, aluminum and copper, as shown in [Table 1], have very low electrical resistance, so resistance welding is difficult. In addition, the joining method by resistance welding is inappropriate because the difference between the melting points of these two metals is extreme.

characteristic Cu
(Cu-ETP) Al
(Al 99.5%) Crystal structure fcc fcc Density [g / cm3] 8.9 2.7 Electrical conductivity
[106 * S / m] 57 34 Thermal conductivity
[W / m * K] 394 210 Coefficient of thermal expansion [10-6 / m] 16.8 23.5 Melting Point [℃] 1,083 646 Boiling point [° C] 2,567 2,467

Accordingly, there is a trend of developing a process for welding aluminum of the positive electrode and copper plate of the negative electrode using a laser.

However, there are various problems in laser welding aluminum and copper sheets. First, aluminum and copper have low laser absorption, and one study reported that the absorption of aluminum and copper in the wavelength range of industrial lasers was less than 5%. That is, because of high reflectance and low beam absorption, efficient laser welding is difficult.

The second problem is metallurgical, in which aluminum and copper form intermetallic compounds in the molten state. Such intermetallic compounds have a problem of so-called brittleness, which is vulnerable to mechanical vibration and thermal fluctuations.

The third problem is that it is difficult to design the base material shape in consideration of productivity improvement. That is, the base material shape design of aluminum and copper electrode should be designed in consideration of reflectance of laser beam, large melting point difference between two base materials, minimization of intermetallic compound formation, and base metal fixing method.

In spite of these difficulties, various welding methods have been proposed since laser welding is most efficient for welding secondary batteries.

1 is a view for explaining a welding method of a typical secondary battery electrode.

(A) of FIG. 1 shows a butt joint method, (b) and (c) a lap joint method, and (d) shows an edge welding method. Also, (e) shows a method of welding while oscillating the laser beam emitted through the scanner. In addition, (f) shows that Al electrode is welded by Al and Cu electrode is welded by Cu to prevent the formation of highly brittle intermetallic compounds generated by Cu-Al electrode welding. It shows how.

2 is a view for explaining problems of butt and overlap welding.

For butt welding, the electrode, which is a thin plate of about 0.4mm, must be exactly butted. However, it is practically difficult to keep the gaps G1 and G2 mechanically constant between the densely arranged lithium ion batteries, and in particular, there is a great difficulty in seam tracking.

In the case of overlapping joints, it is mechanically difficult to maintain Cu-Al electrodes, which are also thin plates, at regular intervals without a gap G3.

Moreover, a laser beam may pass through the gap between the two electrodes and irradiate the electrode assembly, which may cause breakage of the unit cell, fire, or the like. In order to solve this problem, a method of irradiating the laser beam from the side may be considered as shown in FIG.

The present invention has a technical problem to provide an apparatus and method for welding secondary battery electrodes that can minimize the electrical resistance.

Another technical problem of the present invention is to provide an apparatus and method for welding secondary battery electrodes that can prevent the production of intermetallic compounds.

Welding device for a secondary battery electrode according to an embodiment of the present invention for achieving the above technical problem is a welding device for the first electrode provided in the first secondary battery and the second electrode provided in the second secondary battery, A beam irradiator which emits a laser beam of energy higher than the melting point of the first electrode and lower than the melting point of the second electrode; And an optical system that focuses the laser beam emitted from the beam irradiator and irradiates the contact region between the first electrode and the second electrode.

On the other hand, the welding method of the secondary battery electrode according to an embodiment of the present invention is a welding method for the first electrode provided in the first secondary battery and the second electrode provided in the second secondary battery, the first electrode and the Contacting the second electrode; Emitting a laser beam of energy higher than the melting point of the first electrode and lower than the melting point of the second electrode; And condensing the laser beam and irradiating the contact portion between the first electrode and the second electrode.

In the present invention, laser welding the electrode of the secondary battery by irradiating a laser beam of energy lower than the melting point of copper and lower than the melting point of aluminum. Therefore, copper can suppress generation | occurrence | production of an intermetallic compound by the liquefied aluminum spread | diffused to the copper side in contact with two electrodes in the state which hold | maintained the solid phase.

In addition, when the present invention is applied to a secondary electrode having a reflector at its end, the laser beam may cause multiple reflections between the two electrodes so that the two electrodes may be connected even when the laser beam is irradiated or the electrodes are misaligned.

In addition, since welding is performed in a state in which the two electrodes are in close contact by the pressing means, the contact area between the two electrodes is increased, and as a result, there is an advantage that the electrical resistance can be lowered to the base material level.

1 is a view for explaining a welding method of a typical secondary battery electrode,
2 is a view for explaining problems of butt and overlap welding;
3 is a block diagram of a welding device of a secondary battery electrode according to an embodiment of the present invention,
4 is a view for explaining an example of a secondary battery electrode structure applied to the welding device shown in FIG.
5 is a view for explaining another example of a secondary battery electrode structure applied to the welding device shown in FIG.
6 is a view for explaining a welding method for the electrode of the secondary battery shown in FIG.
7 is a view for explaining a welding method for the electrode of the secondary battery shown in FIG.
8 is a view for explaining the principle of laser welding according to the present invention;
9 is a flowchart illustrating a welding method of a secondary battery electrode according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the present invention in more detail.

3 is a block diagram of a welding device of a secondary battery electrode according to an embodiment of the present invention.

As shown, the welding device 10 according to an embodiment of the present invention is a control unit 110 for controlling the overall operation, the beam irradiator 130 for outputting the laser beam emitted from the light source 120 at a specified power and size ), A motor 140 for driving the optical system 150, an optical system 150 for condensing a laser beam output from the beam irradiator 130, and irradiating the welding object, that is, a contact portion to a pair of electrodes, a pair of electrodes And a pressing unit 160 for linearly moving the first and second pressing means 162 and 164 and the first and second pressing means 162 and 164 to press the electrode to be in close contact with the outside of the contact portion.

The optical system may be configured using a telecentric lens or an f-theta lens. The optical system reciprocates at high speed by the driving force of the motor 140 to irradiate a laser beam to the contact portion of the electrode. To be possible.

The first and second pressing means 162, 164 may be configured in a cylindrical or semi-cylindrical shape, the length can be determined in consideration of the width of the electrode. In addition, the diameters of the first and second pressing means 162 and 164 may be determined in consideration of the contact area of the electrode. Preferably, the larger the contact area between the first and second pressurizing means 162 and 164 and the electrode is, the more advantageous it is to increase the contact area between the two electrodes to lower the electrical resistance.

By using the welding device 10, the pressing unit 160 is driven through the control unit 110. The pressurizing unit 160 linearly moves the first and second pressurizing means 162 and 164 to closely adhere the pair of electrodes to be welded from the outside to the welding site.

In this state, the laser beam collected by the optical system 150 is irradiated to the contact portion of the electrode.

When the temperature of the electrode rises to a preset temperature by the laser beam, the pressing unit 160 vertically raises the first and second pressing means 162 and 164 in a pressurized state by the rotational force. Accordingly, it is possible to enlarge the contact portion for the pair of electrodes to be welded.

The melting point of aluminum and copper used as electrodes of a lithium-ion secondary battery is very different. That is, the melting point of copper is as high as 1,083 ℃ while the melting point of aluminum is relatively low as 646 ℃.

Therefore, when the laser beam is irradiated with energy such that aluminum is melted without melting the copper, aluminum converted into a liquid phase is diffused to the copper side maintaining the solid phase, thereby welding the two electrodes. That is, since copper maintains a solid phase, it can prevent that an intermetallic compound generate | occur | produces.

Furthermore, the pair of electrodes are strongly adhered by the first and second pressing means 162 and 164 from the outside to the inside of the contact portion, and the laser beam is irradiated to set the temperature of the electrode, preferably the temperature of the aluminum electrode. When the temperature rises to the pressure contact temperature, the pressing means 162 and 164 are rotated so as to vertically move upward, thereby preventing the laser beam from being irradiated, and ensuring a sufficient contact area.

In order to maximize the welding efficiency in the welding device 10 of the present invention, the electrode of the secondary battery may be configured as shown in FIGS. 4 and 5.

4 is a view for explaining an example of a secondary battery electrode structure applied to the welding device shown in FIG.

Referring to FIG. 4, the secondary battery 20 according to the present invention has an electrode tab 24 having an electrode assembly embedded therein and one end thereof connected to the body 22 and extending out of the body 22. It includes. In addition, the electrode tab 24 includes a reflector 241 configured to bend at an angle θ specified at the other end. The reflector 241 may be formed to be bent to a length (a; 0.2 to 5 mm) specified to the opposite side of the contact portion to contact the electrode of the adjacent unit cell. In other words, the bending angle θ of the reflecting portion 241 may be 0 ° <θ <90 °, preferably 2 ° <θ <45 ° with respect to the vertical side.

In addition, the electrode tab 24 further includes lead portions 243 and 245 connecting the reflecting portion 241 and the main body 22. The lead portions 243 and 245 connect the first plate portion 243 and the first plate portion 243 and the main body which are vertically formed in the longitudinal direction of the main body 22 from the reflecting portion 241 to the main body 22 side. It may be formed to include the second plate portion 245.

Here, the 1st board part 243 is flat form, The length b can be formed in 1-10 mm.

FIG. 5 is a view for explaining another example of the structure of a secondary battery electrode applied to the welding apparatus shown in FIG. 3.

The secondary battery 30 illustrated in FIG. 5 includes a main body 32 having an electrode assembly embedded therein and an electrode tab 34 having one end connected to the main body 32 and extending out of the main body 32. In addition, the electrode tab 34 includes a reflector 341 configured to bend at an angle specified at the other end. Similar to the case of FIG. 4, the reflector 341 may be formed to be bent to a length (0.2 to 5 mm) designated to the opposite side of the contact portion to contact the electrode of the adjacent unit cell. That is, the bending angle of the reflecting portion 341 may be set to 0 ° <θ <90 ° with respect to the vertical side.

In addition, the electrode tab 34 further includes lead portions 343, 345, and 347 connecting the reflective portion 341 and the main body 32. The lead portions 343, 345, and 347 are curved from the first plate portion 343 and the first plate portion 343 vertically formed in the longitudinal direction of the body 32 from the reflecting portion 341 to the body 32. It may be formed to include a refracting portion 345 extending to have, a second plate portion 347 connecting the refracting portion 345 and the main body.

6 is a view for explaining a welding method for the electrode of the secondary battery shown in FIG.

When the adjacent electrode tabs provided on the main bodies 22a and 22b of the pair of secondary batteries are brought into contact with each other, the first plate portions 243a and 243b are brought into contact with each other. In addition, the first and second pressing means 162 and 164 shown in FIG. 1 are located outside the contact portions of the first plate portions 243a and 243b, and when pressed to the contact portion side, the first plate portions 243a and 243b. The adhesion characteristic of is greatly improved.

In this state, a laser beam of energy lower than the melting point of copper and higher than the melting point of aluminum is irradiated through the beam irradiator 130, which is focused by the optical system 150, and irradiated to the contact portion of the two electrodes.

The optical system 150 irradiates a laser beam to the contact portion of the two electrodes while reciprocating at a high speed by the driving of the motor 140, and the first and second pressing means 162 and 164 strongly press the two electrodes. Since it is in close contact, the two electrodes can be welded strongly without generating an intermetallic compound. In addition, when the laser beam is irradiated and the temperature of the electrode rises to a predetermined temperature, the first and second pressing means 162 and 164 are raised by the rotational force to further improve the adhesion characteristics of the two electrodes as well as to enlarge the contact area. can do.

In addition, when the electrode tab of the secondary battery has a structure as shown in FIG. 4, the contact area of the two electrodes is secured by the length b of the first plate portions 243a and 243b, thereby minimizing electrical resistance and Can be strongly contacted.

7 is a view for explaining a welding method for the electrode of the secondary battery shown in FIG.

When the adjacent electrode tabs provided on the respective main bodies 32a and 32b of the pair of secondary batteries are brought into contact with each other, the first plate portions 343a and 343b are brought into contact with each other. In addition, the first and second pressing means (162, 164) shown in Figure 1 is located outside the contact portion of the first plate portion (343a, 343b), and when pressed to the contact portion side of the first plate portion (343a, 343b) The adhesion characteristic of is greatly improved.

In this state, a laser beam of energy lower than the melting point of copper and higher than the melting point of aluminum is irradiated through the beam irradiator 130, which is focused by the optical system 150, and irradiated to the contact portion of the two electrodes.

The optical system 150 irradiates a laser beam to the contact portion of the two electrodes while reciprocating at a high speed by the driving of the motor 140, and the first and second pressing means 162 and 164 strongly press the two electrodes. Since it is in close contact, the two electrodes can be welded strongly without generating an intermetallic compound.

In addition, when the laser beam is irradiated and the temperature of the electrode rises to a predetermined temperature, the first and second pressurizing means 162 and 164 are raised by the rotational force to further improve the adhesion characteristics of the two electrodes and to further expand the contact area. can do.

When the electrode tab of the secondary battery has a structure as shown in FIG. 5, the contact area of the two electrodes is secured by the lengths of the first plate portions 343a and 343b, so that the two electrodes can be strongly contacted while minimizing electrical resistance. have.

Furthermore, the electrode tab shown in FIG. 5 includes refractive portions 345a and 345b. As a result, when the two electrodes are in contact with each other, the refraction parts 345a and 345b are fastened to each other. Therefore, even when the first plate portions 343a and 343b do not exactly contact and form a gap, the laser beam is reflected from the refraction portions 345a and 345b without being irradiated to the main bodies 32a and 32b. The destruction of 32a, 32b, etc. can be prevented beforehand.

8 is a view for explaining the principle of laser welding according to the present invention.

In the present invention, a laser beam of energy lower than the melting point of copper and higher than the melting point of aluminum is irradiated to dissolve aluminum to assure the copper side. That is, since copper maintains a solid phase, two electrodes can be contacted without the occurrence of an intermetallic compound.

Furthermore, as shown in FIG. 8, even when the laser beam is not irradiated to the contact portion accurately due to the laser beam misalignment or the deformation and misalignment of the thin electrode, the reflecting portion 241a of the one electrode is irradiated. Multiple reflection phenomenon occurs in which the beam is reflected to the other electrode. Therefore, the laser beam dissolves the aluminum electrode while reflecting the movement between the first plate portions 243a and 243b, and the dissolved aluminum diffuses to the copper electrode side so that the two electrodes can be strongly contacted.

9 is a flowchart illustrating a welding method of a secondary battery electrode according to an embodiment of the present invention.

First, the secondary battery unit cells to be welded are aligned, and a control parameter including a laser output energy, an output time, etc. is set through the controller 110 (S10).

Subsequently, the pressing unit 160 is driven under the control of the control unit 110 (S20) to press the first and second pressing means 162 and 164 toward the contact portion side of the secondary battery electrode.

In addition, the motor 140 is driven to reciprocate the optical system 150 (S30), and the laser beam of a predetermined energy is irradiated to the optical system 150 through the beam irradiator 130 (S40).

The optical system 150 reciprocating by the motor 140 irradiates a laser beam of a predetermined energy to the contact portion of the two electrodes, wherein the first and second pressing means 162 and 164 contact the two electrodes. Since it presses toward a site | part side, the 1st board part (243a, 243b of FIG. 6) (343a, 343b of FIG. 7) maintains the state which strongly contacted each other.

The laser beam irradiated to the contact site dissolves aluminum and diffuses to the copper side while causing a reflection phenomenon between the two electrodes, whereby the two electrodes are electrically connected.

As a result, the two electrodes can secure a contact area corresponding to the length of the first plate part 243a and 243b (FIG. 6, 343a and 343b), thereby minimizing electrical resistance. It is possible to connect the two electrodes with excellent contact characteristics in a state where no intermetallic compound is caused by Naga not dissolving copper but dissolving only aluminum to make contact.

In addition, when the laser beam is irradiated and the temperature of the electrode rises to a predetermined temperature, when the first and second pressurizing means 162 and 164 are raised by the rotational force, the adhesion characteristics of the two electrodes are further improved and the contact area is further increased. You can zoom in.

On the other hand, in the preferred embodiment of the present invention, the head of the optical system 150 constituting the welding device 10 and the first and second pressing means (162, 164) are moved to the same coordinate value in the X, Y, Z axis It can be designed to be. In this case, the arrival point of the laser beam and the welding line of the electrode to be welded can always be controlled identically. Therefore, it is very advantageous to build an automated system since no welding line tracking device is required.

The absorption rate of Cu-Al's low laser beam is inversely high. Accordingly, by actively utilizing the high reflectance of the Cu—Al electrode, a reflector is introduced at the other end of the electrode, thereby allowing the laser beam to multi-reflection by the high reflectance. In addition, since the whole plate part extended from the reflecting part to the main body side is welded, the electrical resistance between two electrodes after welding can be maintained at the base material level substantially.

Thus, those skilled in the art will appreciate that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the embodiments described above are to be considered in all respects only as illustrative and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

10: welding device
110:
120: light source
130: beam irradiator
140: motor
150: optical system
160: pressurization
162, 164: pressurization means

Claims (16)

A welding apparatus for a first electrode provided in a first secondary battery and a second electrode provided in a second secondary battery,
A beam irradiator which emits a laser beam of energy higher than the melting point of the first electrode and lower than the melting point of the second electrode;
An optical system condensing a laser beam emitted from the beam irradiator and irradiating the contact region between the first electrode and the second electrode;
First and second pressing means positioned outside the contact portions of the first electrode and the second electrode, respectively; And
And a pressing unit for moving the first and second pressing means toward the contact portion side.
When the temperature of the first electrode or the second electrode rises to a predetermined temperature by the laser beam emitted from the beam irradiator, the pressing unit welds the secondary battery electrode to rotate the first and second pressing means in rotation. Device. The method of claim 1,
The first electrode is a welding device for a secondary battery electrode having an angled reflecting portion specified to the opposite side of the contact portion at the end. 3. The method according to claim 1 or 2,
The second electrode is a welding device for a secondary battery electrode having a reflecting portion bent at the end opposite to the contact portion at the end. delete delete The method of claim 1,
The first electrode is a welding device for a secondary battery electrode having an angled reflecting portion specified to the opposite side of the contact portion at the end. The method according to claim 6,
The first electrode is a welding device of a secondary battery electrode having a plate portion formed to extend vertically from the reflecting portion to the main body side of the first secondary battery. The method of claim 7, wherein
The first electrode is a welding device of a secondary battery electrode having a refractive portion extending to be bent from the plate portion to the main body side of the first secondary battery. The method of claim 1,
The second electrode is a welding device for a secondary battery electrode having a reflecting portion bent at the end opposite to the contact portion at the end. The method of claim 9,
And the second electrode includes a plate portion vertically extending from the reflecting portion to the main body side of the second secondary battery. 11. The method of claim 10,
The second electrode is a welding device of a secondary battery electrode having a refractive portion extending to be bent from the plate portion to the main body side of the second secondary battery. The method of claim 1,
The head of the optical system, the first and second pressing means of the welding device of the secondary battery electrode to move to the same coordinate value. A welding method for a first electrode provided in a first secondary battery and a second electrode provided in a second secondary battery,
Contacting the first electrode and the second electrode;
Bringing the first electrode and the second electrode into close contact with the side of the contact portion through first pressing means and second pressing means outside the contact portion between the first electrode and the second electrode;
Emitting a laser beam of energy higher than the melting point of the first electrode and lower than the melting point of the second electrode;
Condensing the laser beam and irradiating the contact portion between the first electrode and the second electrode; And
Rotating the first and second pressing means when the temperature of the first electrode or the second electrode rises to a preset temperature after irradiating a laser beam;
Welding method of a secondary battery electrode comprising a. delete delete The method of claim 13,
And irradiating the contact portion between the first electrode and the second electrode is a step in which the laser beam causes multiple reflections on the first electrode and the second electrode.

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