KR20230082396A - Welding error detection apparatus for negative tap of secondary battery - Google Patents

Abstract

The present invention relates to an apparatus for detecting welding defects on a negative electrode tab of a secondary battery assembly, an electrode assembly in which a positive electrode plate, a separator, and a negative electrode plate according to the present invention are stacked and wound, and extending from the negative electrode plate of the electrode assembly to one side of the electrode assembly. An apparatus for detecting a negative electrode tab welding defect of a secondary battery assembly having a protruding negative electrode tab and a case in which the electrode assembly is inserted and the negative electrode tab is welded to a bottom surface, comprising: a seating portion on which the secondary battery assembly is seated; a vibration application unit for applying vibration in a vertical direction to the seating unit; a vibration signal collection unit for collecting a vibration signal generated from the secondary battery assembly in a state in which vertical vibration is applied to the seating unit; and a defect determination unit that analyzes the vibration signal collected through the vibration signal collection unit and compares the vibration signal with a reference signal to determine whether or not the vibration signal is defective.

Description

Welding error detection apparatus for negative tap of secondary battery}

The present invention relates to an apparatus for detecting defective welding of a negative electrode tab of a secondary battery assembly, and more specifically, to a defective welding of the negative electrode tab of a secondary battery assembly capable of improving reliability by detecting defective welding of the negative electrode tab of a secondary battery. It's about detection devices.

Recently, as the demand for portable electronic products such as laptop computers, video cameras, and mobile phones has rapidly increased, and development of electric vehicles, batteries for energy storage, robots, and satellites has been in full swing, high-performance secondary batteries capable of repetitive charging and discharging have been developed. Research on batteries is actively progressing.

Currently commercialized secondary batteries include nickel cadmium batteries, nickel hydrogen batteries, nickel zinc batteries, and lithium secondary batteries. It is free, has a very low self-discharge rate, and is in the limelight due to its high energy density.

In general, a secondary battery means a battery that can be charged and discharged, unlike a primary battery that cannot be charged, and is widely used in electronic devices such as mobile phones, laptop computers, and camcorders, or electric vehicles. In particular, since the lithium secondary battery has a higher capacity than a nickel-cadmium battery or a nickel-hydrogen battery and has a high energy density per unit weight, the degree of its utilization is rapidly increasing.

These lithium secondary batteries mainly use a lithium-based oxide and a carbon material as a positive electrode active material and a negative electrode active material, respectively. A lithium secondary battery includes an electrode assembly in which a positive electrode plate and a negative electrode plate coated with such a positive electrode active material and a negative electrode active material are disposed with a separator interposed therebetween, and an exterior material for sealing and housing the electrode assembly together with an electrolyte solution.

On the other hand, lithium secondary batteries are manufactured in various shapes such as cylindrical, prismatic, and pouch-shaped. Briefly describing the configuration of the cylindrical secondary battery, the cylindrical secondary battery includes a rechargeable electrode assembly, one side of which is open, and the electrode It includes a cylindrical case accommodating the assembly, and a cap assembly sealing an open side of the cylindrical case. Here, the electrode assembly has a circular cross section to be accommodated in the cylindrical case.

Briefly explaining the configuration of the cylindrical electrode assembly, a positive electrode plate and a negative electrode plate are wound with a separator interposed therebetween, where the electrode assembly is wound in order of a positive electrode plate, a separator, and a negative electrode plate based on its outermost shell. It has a structure. In addition, a negative electrode tab extending from the negative electrode plate of the electrode assembly and protruding to one side of the electrode assembly is provided, and the negative electrode tab is welded to the bottom surface of the case. Accordingly, due to the nature of a cylindrical secondary battery in which a cylindrical case forms a negative electrode, a separator for finishing and insulating tape may be additionally wound around the outermost part of the electrode assembly to prevent an internal short circuit between the positive electrode plate and the cylindrical case.

In the secondary battery as described above, the negative electrode tab is welded to the bottom surface of the case by a welding method such as spot welding, and defects occur during the welding process, resulting in a problem in that the negative electrode tab is separated from the case.

In the case of a secondary battery, the bonding of the negative electrode tab depends only on the welding strength, and accordingly, there is a high possibility that the welding condition of the negative electrode tab to the case may deteriorate during the use of the secondary battery.

That is, the cylindrical secondary battery has a higher capacity than the prismatic secondary battery, and therefore, the cylindrical secondary battery is widely used in power tools that consume a lot of power. For this reason, when the cylindrical secondary battery is used to supply power to a power tool, the cylindrical secondary battery is subjected to considerable vibration by the operation of the power tool in the process of use, and the cylindrical secondary battery is furthermore accommodated with a cylindrical electrode assembly inside the cylindrical case. Therefore, the vibration applied to the secondary battery is transmitted to the electrode assembly, and thus an external force acts on the welding portion between the negative electrode tab and the case. As a result, when welding is not performed properly, cracks are generated at the welded portion of the negative electrode tab and the case, causing a problem in that the negative electrode tab is separated from the case.

Therefore, a test for detecting welding defects, such as the fixed state of the welding portion of the negative electrode tab and the case, is required, but in the conventional case, a method of checking by an operator is used, which has a reliability problem.

Republic of Korea Patent Registration No. 10-1239618 (2013.02.27.)

Accordingly, an object of the present invention is to provide an apparatus for detecting a welding defect of a negative electrode tab of a secondary battery assembly that can overcome the above conventional problems.

Another object of the present invention is to provide an apparatus for detecting welding defects in a negative electrode tab of a secondary battery assembly, which can easily detect welding defects and improve reliability.

According to the embodiment of the present invention for achieving some of the above technical problems, an electrode assembly in which a positive electrode plate, a separator, and a negative electrode plate according to the present invention are stacked and wound, and extends from the negative electrode plate of the electrode assembly to protrude to one side of the electrode assembly An apparatus for detecting a negative electrode tab welding defect of a secondary battery assembly having a negative electrode tab and a case in which the electrode assembly is inserted and the negative electrode tab is welded to a bottom surface, comprising: a seating portion on which the secondary battery assembly is seated; a vibration application unit for applying vibration in a vertical direction to the seating unit; a vibration signal collection unit for collecting a vibration signal generated from the secondary battery assembly in a state in which vertical vibration is applied to the seating unit; and a defect determination unit that analyzes the vibration signal collected through the vibration signal collection unit and compares the vibration signal with a reference signal to determine whether or not the vibration signal is defective.

The vibration applying unit may include a vibrator for applying vibration in a vertical direction to the seating unit at a designated frequency.

The vibration signal collection unit may include a microphone that collects vibration signals of the secondary battery assembly.

The seating portion may include a seating groove into which the secondary battery assembly is inserted and seated, and a seating body in which the seating groove is formed at a central portion.

The seating body has a structure divided into a plurality of divided bodies, and each divided body is movable toward the center of the seating body and in a direction opposite to the center of the seating body, so that the size of the seating groove can be adjusted.

The vibration signal may be collected in the form of sound waves.

The defect determination unit analyzes the envelope spectrum of the vibration signal collected through the vibration signal collection unit, and determines that the product is normal when only one main frequency component is detected, and other defective frequency components other than the main frequency component are detected. If it is, it is determined as a defective product, and the defective frequency component may be due to a vibration signal generated in a state in which the welded portion of the negative electrode tab is separated.

According to the present invention, welding defects can be easily detected and reliability can be improved. In addition, even in the case of partial defects in which welding is partially completed, the welded portion can be separated by vertical vibration, so that not only all defects but also partial defects can be determined, so that product reliability can be expected to be improved. In addition, there is an advantage in that it is possible to determine jamming defects other than welding defects.

1 is a cross-sectional view of a general cylindrical secondary battery,
2 is a schematic perspective view of a negative electrode tab welding defect detection device of a secondary battery assembly according to an embodiment of the present invention;
3 is a partial cross-sectional view of a state in which the secondary battery assembly is seated in FIG. 2;
Figure 4 shows another embodiment of the mounting portion of Figure 2,
Figure 5 shows the operating state of the mounting unit of Figure 4,
6 is a graph of a vibration signal in the case of a normal product, not a defective one;
7 and 8 show vibration signal graphs in the case of defects.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, without any intention other than to provide a thorough understanding of the present invention to those skilled in the art to which the present invention pertains.

1 is a cross-sectional view of a general cylindrical secondary battery.

As shown in FIG. 1, the cylindrical secondary battery includes a rechargeable electrode assembly 110, a case 120 having one side open to accommodate the electrode assembly 110, and one open side of the cylindrical case 120. It is provided with a cap assembly (not shown) for sealing. Here, the electrode assembly 110 has a circular cross section to be accommodated in the cylindrical case.

Briefly describing the configuration of the electrode assembly, the positive electrode plate and the negative electrode plate are wound with a separator interposed therebetween, and the electrode assembly 110 has a structure in which the positive electrode plate, the separator, and the negative electrode plate are wound in order based on the outermost shell. . In addition, a negative electrode tab 130 extending from the negative electrode plate of the electrode assembly 110 and protruding to one side (lower side) of the electrode assembly 110 is provided, and the negative electrode tab 130 is the bottom surface of the case 120. to be welded to An insulating plate 140 is provided to insulate the electrode assembly 110 from the bottom surface of the case 120 , and a positive electrode tab 150 protrudes from the top of the electrode assembly 110 .

In the present invention, as shown in FIG. 1, the electrode assembly 110 is accommodated in the case 120 and the negative electrode tab 130 is welded to the bottom surface of the case 120, and the cap assembly (not shown) is A structure in an empty state is defined as a secondary battery assembly 100. A cap assembly (not shown) for sealing the opened side of the case 120 is additionally provided in the secondary battery assembly 100 to constitute a general secondary battery.

Further, in the present invention, although the secondary battery assembly 100 having a cylindrical structure is described as an example, it is clear that it can be applied to secondary batteries of various shapes such as prismatic or pouch types.

As described above, the negative electrode tab 130 protruding to one side (lower side) of the electrode assembly 110 in the secondary battery assembly 100 is welded to the bottom surface of the case 120 by a welding method such as a spot welding method. However, a defect occurs during the welding process and the negative electrode tab 130 is separated from the case 120 or a defect in a partially welded state is a problem.

A defect detection device for detecting defects in welding the negative electrode tab of the secondary battery assembly will be described with reference to FIGS. 2 to 5 .

2 is a schematic perspective view of a negative electrode tab welding defect detection device 200 of a secondary battery assembly according to an embodiment of the present invention, and FIG. 3 is a partial cross-sectional view of a state in which the secondary battery assembly is seated in FIG. 2 . In addition, FIG. 4 shows another embodiment of the seating part of FIG. 2, and FIG. 5 shows an operating state of the seating part of FIG.

As shown in FIGS. 2 to 5 , the apparatus 200 for detecting a negative electrode tab welding defect of a secondary battery assembly according to an embodiment of the present invention includes a seating part 210, a vibration applying part 220, and vibration signal collection. A unit 230 and a defect determination unit 240 are provided.

The seating part 210 is for the secondary battery assembly 100 to be seated, and is provided in a shape corresponding to the outer shape of the secondary battery assembly 100, and a seating groove into which the secondary battery assembly is inserted and seated. 212 and the seating groove 212 may be provided with a seating body 214 formed in the central portion. That is, it has a structure in which the seating groove 212 is formed in the center of the seating body 214 . When the secondary battery assembly 100 has a cylindrical structure, the seating groove 212 may also be formed in a cylindrical structure.

As shown in FIG. 2, the seating body 214 may have a structure in which the size of the seating groove 212 is fixed by having an integral structure, but as shown in FIGS. 4 and 5, the seating body ( 214) may have a divided structure divided into a plurality of divided bodies 214a. When the seating body 214 has a split structure, there is an advantage in that it is possible to test (defect) the secondary battery assembly 100 having various sizes.

In the seating groove 212, the lower side of the secondary battery assembly 100, that is, the welded portion of the electrode tab 130 and the case 120 is inserted into the seating groove 212, and the secondary battery The assembly 100 is inserted into the seating groove 212 .

As shown in FIG. 2, the seating part 210 can test the secondary battery assembly 100 of only one size (diameter or width) when the seating body 214 has an integral structure, As shown in FIGS. 4 and 5 , in the case where the seating body 214 has a split structure, it is possible to test the secondary battery assembly 100 having various sizes (diameter or width).

The seating body 214 of the split structure shown in FIGS. 4 and 5 may have a variety of split structures, such as each split body 214a having a two-part or four-part structure, and each split body 214a has a base plate 216 ) may have a structure capable of moving in the center direction and the opposite direction of the seating groove 212 or the seating body 214 on the ). Accordingly, the seating part 210 is a seating body composed of a base plate 216 connected to the vibration applying part 220 and each division body 214a having a movable structure on the base plate 216. (214) may have a structure. Here, the seating groove 212 is formed by each of the division bodies 214a.

Specifically, as shown in (a) of FIG. 5, each division body (214a) is moved in a direction toward the center, and as shown in (b) of FIG. 5, it is possible to move in a direction opposite to the center. can have a structure. Here, each division body 214a may move toward the center and become closer to each other, and may move toward the opposite center and move away from each other. Accordingly, the size of the seating groove 212 can be adjusted. Since the divisions 214a are movable in a central direction or a counter-center direction, it is possible to accommodate secondary battery assemblies 100 of various sizes. That is, as shown in (b) of FIG. 5, the secondary battery assembly 100 is installed in the center of the seating groove in a state in which the divisions 214a move in the opposite direction and the distance between the divisions 213a widens. (212) When placed in the formation position, as shown in FIG. A seating groove 212 suitable for the size of the battery assembly 100 is formed, and the secondary battery assembly 100 can be firmly seated and supported.

Accordingly, it is possible to adjust the size of the seating groove 212, and accordingly, the test of the secondary battery assembly 100 of various sizes is possible. In addition, since the configuration for moving each division body 214a is well known to those skilled in the art in various ways, such as a gear method, a rail method, and a spring method, descriptions or drawings of the driving means or driving structure are omitted.

The seating groove 212 is formed as a cylindrical groove when the secondary battery assembly 100 is cylindrical, and formed as a prismatic groove when the secondary battery assembly 100 is prismatic, and corresponds to the outer shape of the secondary battery assembly 100 can have the shape of

The vibration applying unit 220 is for applying vertical vibration to the seating unit 210, and the vibration applying unit 220 is an exciter for applying vertical vibration to the seating unit 210 at a designated frequency. can include

The designated frequency has been confirmed through a number of experiments, and in the case of a normal product, if vibration is applied through the vibration applying unit 220 and the secondary battery assembly 100 is vibrated, if the welding part does not fall off It may be an optimal frequency that is advantageous even in case of bad judgment.

The exciter may be any type as long as it can apply vertical vibration at a designated frequency to the seating part 210, and an exciter well known to those skilled in the art may be applied.

As shown in FIG. 3 , in the vibration signal collection unit 230, the secondary battery assembly 100 is inserted into the seating unit 210, and vibration in the vertical direction is transmitted through the vibration signal application unit 220. It is for collecting vibration signals generated from the secondary battery assembly 100 in an applied state.

The vibration signal collecting unit 230 may include a microphone that collects the vibration signal of the secondary battery assembly 100, converts the digital signal, and provides the result to the failure determination unit 240. Here, the vibration signal may be collected in the form of a sound signal or sound wave.

That is, when vertical vibration is applied through the vibration applying unit 220 to the vibration signal collection unit 230, the sound generated from the secondary battery assembly 100 seated on the seating unit 210 ( sound waves) are collected, digitally converted, and provided to the defect determination unit 240 .

The defect determination unit 240 embeds a signal processing program and an algorithm for determining a defect, and analyzes the vibration signal collected through the vibration signal collection unit 230 to obtain a reference signal (e.g., normal vibration). signal) to determine whether it is defective or not.

A defect determination process through the defect determination unit 240 will be described through the graphs of FIGS. 6 to 8 . 6 is a vibration signal graph in the case of a non-defective product, and FIGS. 7 and 8 show vibration signal graphs in the case of a defect. FIG. 7 shows a case in which welding of the negative electrode tab is defective, and FIG. 8 shows a case in which the electrode assembly and the case are caught in a state in which the electrode assembly and the case vibrate as one body.

As shown in FIG. 6 , when the secondary battery assembly 100 is a normal product and vertical vibration is applied through the vibration application unit 220, the secondary battery assembly 100 generates specific sound waves. A vibration signal of the form is generated. That is, the vibration signal generated while the portion where the cathode tab 130 is welded to the case 120 or the portion of the welded cathode tab 130 serves as an elastic spring is collected through the vibration signal collection unit 230 . Here, the collected vibration signal in the form of a sound wave appears in the upper part of FIG. envelope) spectrum, it can be seen that one peak waveform is detected in the range of approximately 53Hz.

In the present invention, a number of experiments have been conducted to facilitate the determination of defects without the welded portion falling off even when vibration occurs in the secondary battery assembly 100, and applying vibration through the vibration applying unit 220 at a specific frequency In the case of the normal product, it was confirmed that the envelope spectrum of the collected vibration signal had a frequency component detected as one peak waveform. This will be referred to as a main frequency component.

In the case of a normal product, an optimal vibration frequency was found through a number of experiments to ensure that there were no other peak waveforms other than the main frequency component, and using this optimal vibration frequency, the vibration application unit 220 vibrated in the vertical direction. In the case of applying , it was confirmed that only the main frequency component was detected as one peak waveform in the envelope spectrum of the vibration signal collected in the case of a normal product. Of course, if the vibration frequency is changed, frequency components other than the main frequency component appear in the form of a peak waveform even in the case of a normal product, so multiple experiments are conducted until only one peak waveform corresponding to the main frequency component is derived This is required, and if the shape or size of the secondary battery assembly 100 is changed, the optimal vibration frequency will also have to be changed.

The defect determination unit 240 uses the signal in the case of a normal product as shown in FIG. 6 as a reference signal to determine a defect.

As shown in FIG. 7, when the secondary battery assembly 100 is a defective product, when vertical vibration is applied through the vibration applying unit 220, the secondary battery assembly 100 has a negative electrode tab ( Since the electrode assembly 110 collides with the case 120, another vibration signal (sound wave signal) different from the normal product is generated because the case 120 is not welded or the welded portion is separated due to vibration. ) will occur. Accordingly, the vibration signal in the form of a sound wave collected and detected through the vibration signal collection unit 230 shows a sine wave form including a plurality of defective waveforms, and the envelope shown in the middle of FIG. 7 Looking at the (envelope) spectrum, it can be seen that in addition to one main frequency component detected in the range of approximately 53 Hz, defective frequency components of about 17 Hz to 18 Hz, which are 1/3 of the main frequency component, are detected. Here, the frequency band of the defective frequency component may vary according to the degree of defects or defective parts. In addition, the defective frequency component is due to a vibration signal generated when the welding portion of the negative electrode tab 130 is separated.

Accordingly, the defect determination unit 240 compares the defect peak waveform in the case of a defective product as shown in FIG. 7 based on the signal in the case of a normal product as shown in FIG. 6 as a reference signal to determine welding defects. be able to determine whether

FIG. 8 shows a case where the electrode assembly is in a state where the case is jammed, regardless of welding defects, when the electrode assembly 110 is in close contact with the case 120 or is in a state where it is jammed, the electrode assembly 110 In the case where the and case 120 operate as one body, it can be seen that the vibration signal in the form of a sound wave collected and detected through the vibration signal collection unit 230 has a smooth sine wave shape, that is, there is no peak waveform and the main frequency It can be seen that no components were detected.

Through this, when the signal as shown in FIG. 8 is detected, the defect determination unit 240 can determine a jamming defect state different from a welding defect.

As described above, according to the present invention, welding defects can be easily detected and reliability can be improved. In addition, even in the case of some defects where the welding is not 100% but about 30%, the welding part can be separated by vertical vibration, so it is possible to determine not only all defects but also partial defects, improving product reliability. can be expected In addition, there is an advantage in that it is possible to determine jamming defects other than welding defects.

The description of the above embodiment is merely an example with reference to the drawings for a more thorough understanding of the present invention, and should not be construed as limiting the present invention. In addition, it will be apparent to those skilled in the art that various changes and modifications are possible within a range that does not deviate from the basic principles of the present invention.

100: secondary battery assembly 110: electrode assembly
120: case 130: cathode tab
210: seating unit 220: vibration application unit
230: Vibration signal collection unit 240: Defect determination unit

Claims (7)

An electrode assembly in which a positive electrode plate, a separator, and a negative electrode plate are stacked and wound, a negative electrode tab extending from the negative electrode plate of the electrode assembly and protruding to one side of the electrode assembly, and a case in which the electrode assembly is inserted and the negative electrode tab is welded to the bottom surface In the negative electrode tab welding defect detection device of a secondary battery assembly having:
a seating portion on which the secondary battery assembly is seated;
a vibration application unit for applying vibration in a vertical direction to the seating unit;
a vibration signal collection unit for collecting a vibration signal generated from the secondary battery assembly in a state in which vertical vibration is applied to the seating unit;
The device for detecting defective welding of the negative electrode tab of the secondary battery assembly, characterized in that it includes a defect determination unit that analyzes the vibration signal collected through the vibration signal collection unit and compares it with a reference signal to determine whether or not there is a defect.
The method of claim 1,
The negative electrode tab welding defect detection device of the secondary battery assembly, characterized in that the vibration applying unit includes an exciter for applying vibration in a vertical direction to the seating unit at a designated frequency.
The method of claim 1,
The negative electrode tab welding defect detection device of the secondary battery assembly, characterized in that the vibration signal collection unit includes a microphone for collecting the vibration signal of the secondary battery assembly.
The method of claim 1,
The negative electrode tab welding defect detection device of the secondary battery assembly, characterized in that the seating portion includes a seating groove into which the secondary battery assembly is inserted and seated, and a seating body formed in a central portion of the seating groove.
The method of claim 4,
The seating body has a divided body structure divided into a plurality of parts, and each divided body is movable in the center direction and the opposite direction of the seating body to adjust the size of the seating groove. Welding defect detection device.
The method of claim 1,
The negative electrode tab welding defect detection device of the secondary battery assembly, characterized in that the vibration signal is collected in the form of sound waves.
The method of claim 1,
The defect determination unit analyzes the envelope spectrum of the vibration signal collected through the vibration signal collection unit, and determines that the product is normal when only one main frequency component is detected, and other defective frequency components other than the main frequency component are detected. If it is, it is determined as a defective product, and the defective frequency component is due to a vibration signal generated in a state in which the welding portion of the negative electrode tab is separated.

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