KR102310630B1 - Plate coating layer distance measuring equipment for secondary cell - Google Patents

Abstract

The present invention relates to a plate coating layer distance measuring device for a secondary cell. A horizontal guide part, which has a rail part formed between supporting frames, is formed on the upper surface of a worktable, a horizontal moving device is slid and combined with a rail part of the horizontal guide part, and an optical device, which photographs a plate while radiating light to the plate mounted on top of the worktable, is installed on one surface of the horizontal moving device to be moved horizontally in the lengthwise direction of the plate by the horizontal moving device moving along the rail part. The optical device calculates a distance between coating layers of the plate by photographing the upper surface of the plate while radiating light to the upper surface of the plate. According to the present invention, a distance between the coating layers between the plate can be calculated automatically while moving the optical device horizontally in the lengthwise direction of the plate, and the distance between the coating layers is calculated automatically, thereby preventing the generation of an error in the calculated value of the distance between the coating layers due to a mistake of a worker. In addition, the defect of a plate can be discerned easily through the automatic calculation of the distance between the coating layers, the distance between the coating layers of the plate is calculated swiftly by the simple operation of moving the optical device horizontally with the plate mounted on top of a worktable, thereby reducing operation time, and the optical device is moved uniformly in a horizontally direction by the horizontal moving device, thereby enabling an unskilled worker to measure a distance between the coating layers of the plate can be measured easily using the device.

Description

Electrode coating layer distance measuring device for secondary battery {Plate coating layer distance measuring equipment for secondary cell}

The present invention relates to an electrode coating layer distance measuring apparatus for a secondary battery, and more particularly, while moving a horizontal movement device installed with an optical device along a rail portion of a horizontal guide part, horizontally moving the optical device from one side of a secondary battery cell to the other side It relates to a secondary battery coating layer distance measuring device for calculating the distance between the coating layers of the secondary battery cell.

In general, as the structures of electronic products such as video cameras, portable telephones, and portable PCs become lighter or more functional, a lot of research is being conducted on secondary batteries used as power sources for these electronic products. The secondary battery is used repeatedly by charging and discharging, and typically includes a nickel cadmium battery, a nickel hydride battery, a nickel zinc battery, and a lithium secondary battery.

Here, a plurality of stacked electrode plates are formed in the secondary battery, and a plurality of coating layers spaced apart from each other by a predetermined interval are formed on the upper surface of the electrode plate.

That is, the electrode plate forms a plurality of coating layers on its upper surface during the manufacturing process, and by cutting and processing a plurality of electrode plates in that state, a cell unit electrode plate having a coating layer inserted into the secondary battery is formed.

And, the electrode plate determines whether the electrode plate is defective by checking the state of the coating layer on its upper surface.

Therefore, in the prior art, a portion of the electrode plate on which the coating layer is formed is cut, and the cut plate is seated on the workbench.

Then, while pressing and pressing one end of the pole plate with a steel ruler or tape measure to correspond to the longitudinal direction of the pole plate seated on the workbench, the scale of the steel ruler or tape measure is positioned to cross the plurality of coating layers formed on the pole plate, and then the scale is It is to visually confirm the distance between the coating layers of the electrode plate by checking.

In addition, the electrode plate on which the coating layer is formed is seated on the workbench as described above, and in that state, both ends of the electrode plate are pressed with a pressing member having a predetermined weight, and in a state in which the electrode plate is flattened, the scale of a steel ruler or a tape measure The distance between the coating layers can be visually checked.

At this time, when the distance between the coating layers is more than the error range or the distances between the plurality of coating layers are measured differently, the electrode plate on which the coating layer is formed is determined as defective.

However, in the conventional coating layer inspection method as described above, when inspecting the coating layer of the electrode plate, the operator must directly seat a tape measure or a steel ruler on the electrode plate, and visually check the scale of the tape measure or steel ruler, and this tape measure or steel ruler must be used on the electrode plate While seated on the top, there is an inconvenience that the direction of the tape measure or steel ruler must be readjusted to be orthogonal to the coating layer of the electrode plate. , The operator manually checks the distance between the coating layers of the electrode plate while checking the fine scale with the naked eye, and the eye fatigue increases rapidly. Due to the difficulty of calculating this distance, an error occurs in determining whether it is normal or defective, and it takes a lot of time to repeatedly align the coating layer with a tape measure or steel ruler to form an orthogonal state when inspecting the electrode plate. There is a problem in that the reliability of the product is lowered at the same time as the efficiency is lowered.

US 10-2015-0086042 A

The present invention is to solve the problems as described above, and an object of the present invention is to form a horizontal guide part having a rail part formed between the support frame on the upper surface of the work bench, and sliding the horizontal moving device to the rail part of the horizontal guide part, , By installing an optical device for photographing the pole plate while irradiating light with the pole plate seated on the workbench on one side of the horizontal shifting device, the optical device is horizontally moved in the longitudinal direction of the pole plate by the horizontal shifting device moving along the rail part, At this time, the optical device is to provide an electrode coating layer distance measuring device for a secondary battery that calculates the distance between the coating layers of the electrode plate by photographing the upper surface of the electrode plate while irradiating light to the upper surface of the electrode plate.

In order to achieve the object of the present invention as described above, the electrode coating layer distance measuring apparatus for a secondary battery according to the present invention, a workbench; a horizontal guide part forming a pair of support frames symmetrical to each other on both sides of the upper surface of the work table, and forming a rail part between the support frames; a horizontal movement device that is slidably coupled to the rail portion of the horizontal guide portion and slides left and right along the rail portion; An optical device that is fixedly installed on one surface of the horizontal movement device, moves in the horizontal direction by the horizontal movement device, and shoots the distance between the coating layers of the electrode plate while irradiating light with the electrode plate mounted on the work table; Consisting of characterized in that

In the electrode plate coating layer distance measuring apparatus for a secondary battery according to the present invention, the work table is formed in a pair symmetrically to each other on both sides of the upper surface, allowing the support frame to be slidably coupled, so that the horizontal guide part before and after the work table It is characterized in that a guide rail for sliding movement in the direction is further formed.

In the electrode plate coating layer distance measuring apparatus for a secondary battery according to the present invention, the work table is formed along the longitudinal direction of the upper surface of the work table, rotates in a direction perpendicular to the longitudinal direction of the work table, and the electrode plate mounted on the work table By pressing and pressing one end in the longitudinal direction, it is characterized in that a distance meter is further formed to display the distance between the coating layers of the electrode plate.

In the electrode coating layer distance measuring device for a secondary battery according to the present invention, the horizontal guide part is formed along the longitudinal direction on the upper surface of the rail part, and a horizontal guide rail for guiding the horizontal movement device to slide along the rail part. characterized by being formed.

In the electrode coating layer distance measuring apparatus for a secondary battery according to the present invention, the horizontal guide part is formed in a pair symmetrically on both sides of the front surface of the rail part, and the horizontal movement device moving along the rail part is moved to both sides of the rail part. It is characterized in that a stopper is further formed to block the separation.

In the electrode coating layer distance measuring device for a secondary battery according to the present invention, the horizontal guide part forms a rack gear along the longitudinal direction on the front surface of the rail part, and the horizontal movement device is slidingly coupled to the rail part, a moving block sliding along the rail unit; and a fine adjustment device installed on one side of the moving block, engaged with the rack gear, rotated to move along the rack gear, and finely adjusting the moving distance of the horizontal moving device; characterized in that it is further formed. .

In the electrode coating layer distance measuring device for a secondary battery according to the present invention, the fine adjustment device is rotatably installed on one side of the moving block, and the outer surface thereof is coupled to engage the rack gear, and along the rack gear. a moving pinion gear; It is installed on the other side of the moving block corresponding to the pinion gear, is connected to the pinion gear, a fine adjustment knob for rotating the pinion gear; characterized in that it is composed of.

In the electrode coating layer distance measuring apparatus for a secondary battery according to the present invention, the optical device comprises: a vertical plate portion fixedly installed on one surface of the horizontal movement device; an optical camera fixedly installed on the front surface of the vertical plate portion and calculating the distance between the coating layers by photographing the distance between the coating layers of the electrode plate mounted on the work table; It is characterized in that it consists of; a lighting device that is fixedly installed at the bottom of the vertical plate portion, irradiating light to the electrode plate.

In the electrode plate coating layer distance measuring apparatus for a secondary battery according to the present invention, the vertical plate portion includes: a first plate portion fixedly installed on one surface of the horizontal movement device; It is characterized in that it is composed of a; is coupled to move up and down at the lower end of the first plate, the second plate having the lighting device fixedly installed at the lower end thereof.

According to the present invention, while horizontally moving the optical device along the longitudinal direction of the pole plate, the distance between the coating layers of the pole plate can be automatically calculated, and the distance between the coating layers is automatically calculated. Errors are prevented, and it is possible to easily determine whether the electrode plate is defective by automatically calculating the distance between the coating layers. By quickly calculating the distance between the coating layers, the working time is shortened, and the optical device is uniformly moved in the horizontal direction by the horizontal movement device, so that an unskilled person can easily calculate the distance between the coating layers of the electrode plate using this device, In addition, moving the optical device to a predetermined position of the electrode plate, resetting this movement position to a zero point, calculating the distance between the coating layers of the electrode plate, there is no restriction on the starting point for calculating the distance, and thus, the improvement of work efficiency and At the same time, there is an advantage in that the reliability of the product is improved.

1 is a perspective view showing an electrode coating layer distance measuring device for a secondary battery according to the present invention.
Figure 2 is an exploded perspective view of Figure 1;
Figure 3 is an enlarged view showing the horizontal guide portion of the electrode plate coating layer distance measuring device for a secondary battery according to the present invention.
4 is an exploded perspective view of the horizontal movement device and the optical device of the electrode plate coating layer distance measuring device for a secondary battery according to the present invention.
5 is a plan view showing the electrode plate of the electrode plate coating layer distance measuring device for a secondary battery according to the present invention.

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

1 to 5, the work table 100 is formed to protrude from the ground to a predetermined height.

The work table 100 allows the horizontal guide unit 200, the horizontal movement device 300, and the optical device 400 to be installed on its upper surface.

The work table 100 allows the support frame 201 of the horizontal guide part 200 to be installed on both sides of the upper surface.

The work table 100 allows the electrode plate 10 having the coating layer 11 formed thereon to be seated.

The work table 100 is formed as a pair symmetrically on both sides of the upper surface, allowing the support frame 201 to be slidably coupled, and moving the horizontal guide unit 200 in the front and rear directions of the work table 100 . A guide rail 101 for sliding movement is further formed.

The guide rail 101 slides the horizontal guide part 200 in the front and rear directions of the workbench to move the optical device 400 installed in the horizontal movement device 200 to the center of the electrode plate 10 . It is positioned on an imaginary horizontal line HL formed to cross the .

The workbench 100 is formed along the longitudinal direction of the upper surface of the workbench 100, rotates in a direction perpendicular to the longitudinal direction of the workbench 100, and the electrode plate 10 mounted on the workbench 100. One end is pressed in the longitudinal direction to further form a distance meter 102 indicating the distance between the coating layers 11 of the electrode plate 10 .

The distance meter 102 forms a scale on its upper surface, and checks the distance between the coating layers 11 through the scale.

The range finder 102 is rotated to the outside of the workbench 100 when not in use, and is disposed on one side of the workbench 100 .

The horizontal guide part 200 forms a pair of support frames 201 symmetrical to each other on both sides of the upper surface of the work table 100 , and forms a rail part 202 between the support frames 201 .

The horizontal guide unit 200 guides the horizontal movement device 300 to slide left and right.

The support frame 201 is installed in an upright state on the upper surface of the work bench 100 so that the rail unit 202 maintains a state spaced apart from the upper surface of the work bench 100 by a predetermined distance.

The support frame 201 is moved forward and backward along the guide rail 101 of the work table 100 to move the horizontal movement device 300 to a predetermined position of the electrode plate 10 .

The rail part 202 is formed parallel to the electrode plate 10 seated on the work table 100 to guide the movement of the horizontal movement device 300 .

The horizontal guide part 200 is formed along the longitudinal direction on the upper surface of the rail part 202, and guides the horizontal movement device 300 to slide along the rail part 202. A horizontal guide rail 202a. form more

The horizontal guide rail 202a is formed as an LM guide to guide the sliding movement of the moving block 310 of the horizontal moving device 300 .

The horizontal guide part 200 is formed as a pair symmetrically on both sides of the front side of the rail part 202 , and the horizontal movement device 300 moving along the rail part 202 is the rail part 202 . Further forming a stopper (202b) to block the separation to both sides

The stopper 202b blocks the horizontal movement device 300 from moving more than a predetermined distance to both sides of the rail unit 202 .

The stopper (202b) is formed of a rubber material, to relieve the impact of the horizontal movement device (300).

The horizontal guide part 200 forms a rack gear 202c on the front surface of the rail part 202 in the longitudinal direction.

The rack gear 202c is such that the pinion gear 321 formed in the fine adjustment device 320 of the horizontal movement device 300 is engaged, and the pinion gear 321 is the horizontal movement device ( The movement distance of the movement block 310 of 300) is finely adjusted.

The horizontal movement device 300 is slidably coupled to the rail portion 202 of the horizontal guide portion 200 and slides left and right along the rail portion 202 .

The horizontal moving device 300 moves the optical device 400 in one direction while sliding along the rail unit 202 .

The horizontal movement device 300 is slid along the rail portion 202 by the pressing force applied by the operator in a state held by the operator.

The horizontal movement device 300 guides the optical device 400 to photograph the distance between the coating layers 11 of the electrode plate 10 while moving in the horizontal direction.

The horizontal moving device 300 is slidably coupled to the rail 202, and a moving block 310 that slides along the rail 202, and is installed on one side of the moving block 310 and the rack A fine adjustment device 320 for finely adjusting the moving distance of the horizontal movement device 300 while being engaged with the gear 202c and rotating to move along the rack gear 202c is further formed.

The moving block 310 is coupled to the horizontal guide rail 202a of the rail part 202 and slides along the horizontal guide rail 202a.

The moving block 310 is blocked by the stopper 202b of the rail unit 202 and is blocked from moving more than a predetermined distance in both directions of the rail unit 202 .

The moving block 310 fixedly installs the optical device 400 on one surface thereof.

The fine adjustment device 320 is controlled by an operator, and finely adjusts the moving distance of the moving block 310 of the horizontal moving device 300 .

The fine adjustment device 320 is rotatably installed on one side of the moving block 310, its outer surface is coupled to engage the rack gear 202c, and the pinion moves along the rack gear 202c. A gear 321 and a fine adjustment knob 312 installed on the other side of the moving block 310 corresponding to the pinion gear 321, connected to the pinion gear 321, and rotating the pinion gear 321 ) is composed of

The pinion gear 321 is coupled to the rack gear 202c in a gear manner, and moves the moving block 310 while moving along the rack gear 202c.

The fine adjustment knob 322 is gripped by the operator, and in this state, the pinion gear 321 is rotated while being forcibly rotated by the operator.

The optical device 400 is fixedly installed on one surface of the horizontal movement device 300 , moves in the horizontal direction by the horizontal movement device 300 , and emits light to the electrode plate 10 mounted on the work table 100 . While irradiating, the distance between the coating layers 11 of the electrode plate 10 is photographed.

The optical device 400 calculates the distance between the coating layers 11 by photographing the distance between the coating layers 11 of the electrode plate 10 .

The optical device 400 is positioned on the horizontal line HL of the electrode plate 10 by the horizontal guide part 200 moving forward and backward along the guide rail 101 .

The optical device 400 includes a vertical plate part 401 fixedly installed on one surface of the horizontal moving device 300 , and a pole plate 10 fixedly installed on the front surface of the vertical plate part 401 and mounted on the workbench 100 . An optical camera 402 that calculates the distance between the coating layers 11 by photographing the distance between the coating layers 11 of It consists of a device 403 .

The vertical plate part 401 fixes the optical camera 402 and the lighting device 403 to be positioned on one surface of the horizontal moving device 300 .

The optical camera 402 photographs the distance between the coating layers 11 and calculates the photographed distance value.

It is preferable that the optical camera 402 captures the distance between the coating layers 11 of the electrode plate 10 while the magnification is enlarged or reduced by the operator.

The vertical plate portion 403 is coupled to the first plate portion 401a fixedly installed on one surface of the horizontal movement device 300 and the first plate portion 401 so as to move up and down at the lower end thereof, and the lighting device ( It is composed of a second plate portion 401b to which 403) is fixedly installed.

The second plate portion 401b is moved up and down based on the first plate portion 401a so that the lighting device 403 is brought closer to the upper surface of the electrode plate 10 seated on the work table 100 or Or to be spaced apart a predetermined distance from the electrode plate (10).

After the second plate part 401b is moved up and down along the first plate part 401a, it is fixed at a predetermined height by a fixing member (unsigned) penetrating the first and second plate parts 401a and 401b. do.

It is preferable that the lighting device 403 is formed in a “ㅁ” shape so that the central part thereof is penetrated, so that the optical camera 402 takes the distance between the coating layers 11 of the electrode plate 10 through the central part. do.

The electrode coating layer distance measuring device for a secondary battery according to the present invention configured as described above is used as follows.

First, a part of the electrode plate 10 on which the coating layer 11 is formed is cut off, and the electrode plate 10 having the coating layer 11 formed thereon to be spaced apart from each other by a predetermined interval is seated on the workbench 100, and in that state, the electrode plate The support frame 201 of the horizontal guide part 200 is moved forward and backward along the guide rail 101 so that the optical device 400 is positioned on the horizontal line HL of (10). .

At this time, in the state of holding the moving block 310 of the horizontal moving device 300, by pushing or pulling the horizontal guide unit 200 to the front or rear of the work table 100, the horizontal guide unit 200 ) while the support frame 201 is moved forward and backward along the guide rail 101 , it enables movement of the optical device 400 .

And, when the optical camera 402 of the optical device 400 is positioned on the horizontal line HL of the electrode plate 10, the moving block 310 is moved while the moving block 310 is gripped. While pushing the rail unit 202 in one direction, the rail unit 20 is moved to one side.

Then, while the moving block 310 is moved in the horizontal direction along the horizontal guide rail 202a, the optical device 400 is moved so as to be positioned directly above one side of the electrode plate 10, and the moving block ( 310) and the optical device 400 are positioned on one side of the rail unit 202 .

At this time, the moving block 310 is moved to one side of the rail unit 202 by the operator and is blocked by the stopper 202b, thereby preventing the moving block 310 from being moved more than a predetermined distance in one direction of the rail unit 202 .

Then, the lighting device 403 installed on the vertical plate portion 401 of the optical device 400 is moved up and down, and the light irradiated from the lighting device 403 is reflected on the upper surface of the electrode plate 10 . let it go

At this time, by adjusting the distance between the electrode plate 10 and the lighting device 403 while moving the second plate part 401b of the vertical plate part 401 up and down along the first plate part 401a, It is to adjust the illuminance of the light illuminated on the electrode plate (10).

And, when the position of the lighting device 403 is determined, a fixing member (unsigned) that is fastened to pass through the first and second plate parts 401a and 401b in that state is coupled to the second plate part 401b. ) to be fixed on a predetermined height of the first plate portion 401a.

Then, while holding the moving block 310 of the horizontal moving device 300, while moving the moving block 310 in the opposite direction to the other side of the rail unit 202, the optical camera 402 is It is positioned at the boundary line between the upper surface of the electrode plate 10 and the coating layer 11 .

At this time, the moving block 310 is moved first so that the moving block 310 moves along the horizontal guide rail 202a, so that it is close to the boundary line between the upper surface of the electrode plate 10 and the coating layer 11 . and then, by holding the fine adjustment knob 322 of the fine adjustment device 320, the fine adjustment knob 322 is rotated.

Then, the pinion gear 321 is rotated by the fine adjustment knob 322, and at this time, the pinion gear 321 moves along the rack gear 202c to which the meshing is coupled, the moving block 310 movement distance is finely adjusted.

That is, as the pinion gear 321 is rotated, the pinion gear 321 moves along the rack gear 202c by a gear method, and the moving distance of the moving block 310 is finely adjusted. , to position the optical camera 402 on the boundary line between the upper surface of the electrode plate 10 and the coating layer 11 .

And, when the optical camera 402 is positioned at the boundary line between the upper surface of the electrode plate 10 and the coating layer 11, the moving block 310 is gripped to move the moving block 310 toward the other direction. move at speed

At this time, the optical camera 402 is based on the boundary line between the upper surface of the pole plate 10 and the coating layer 11, then the distance to the boundary line between the upper surface of the pole plate 10 and the coating layer 11 By taking a picture, this distance is calculated.

Next, the moving block 310 is continuously moved in the other direction of the rail part 202 as described above, and in that state, in the same manner as above, the boundary line between the upper surface of the electrode plate 10 and the coating layer 11 . Then, the distance to the boundary line between the upper surface of the electrode plate 10 and the coating layer 11 is taken based on the , and this distance is calculated.

Thereafter, by comparing the distances between the plurality of coating layers 11 continuously measured in the same manner as described above, it is determined whether the electrode plate 11 is defective or normal based on the comparison value.

On the other hand, when you want to visually check the distance between the coating layers 11 of the electrode plate 10 seated on the work table 100, the horizontal movement device 300 is moved to the rail portion of the horizontal guide portion 200 ( 202) is moved to one side, and in that state, the distance measurer 102 is rotated in the direction of the upper surface of the workbench 100 so that one end of the electrode plate 10 is press-fitted to the distance measurer 102 in the longitudinal direction.

Then, the scale formed on the distance meter 102 is positioned in the longitudinal direction of the electrode plate 10, and at this time, the distance between the coating layers 11 of the electrode plate 10 is confirmed by visually checking the scale.

In the above description, the optical device 400 or the distance measurer 102 is used as an example, but in a state where one end of the electrode plate 10 is press-fitted with the distance measurer 102, the optical device 400 ) to check the distance between the coating layers 11 of the electrode plate 10 and at the same time check the distance through the scale of the distance meter 102 .

While horizontally moving the optical device 400 in the longitudinal direction of the electrode plate 10 through the horizontal movement device 300 as described above, the distance between the coating layers 11 of the electrode plate 10 is photographed, and the coating layer 11 The structure for calculating the distance between the two can automatically calculate the distance between the coating layers 11 of the electrode plate 10 while horizontally moving the optical device 400 along the longitudinal direction of the electrode plate 10, and the coating layer 11 ) by automatically calculating the distance between the coating layers 11 due to the operator's mistake, it is prevented that an error is generated in the distance calculation value between the coating layers 11 It can be easily determined, and the distance between the coating layers 11 of the electrode plate 10 is quickly calculated by a simple operation of horizontally moving the optical device 400 in a state where the electrode plate 10 is seated on the workbench 100 . Thus, the working time is shortened, and the optical device 400 is uniformly moved in the horizontal direction by the horizontal movement device 300, so that an unskilled person can easily change the distance between the coating layers 11 of the electrode plate 10 using this device. can be calculated.

The electrode coating layer distance measuring device for secondary battery according to the present invention described above is not limited to the above-described embodiment, and without departing from the gist of the present invention as claimed in the following claims, it has common knowledge in the field to which the present invention pertains. It has the technical spirit to the extent that anyone who grows up can change and implement it in various ways.

10: electrode plate 11: coating layer
100: workbench 101: guide rail
102: distance meter 200: horizontal guide part
201: support frame 202: rail part
202a: horizontal guide rail 202b: stopper
202c: rack gear 300: horizontal movement device
310: moving block 320: fine adjustment device
321: pinion gear 322: fine adjustment knob
400: optical device 401: vertical plate part
401a: first plate part 401b: second plate part
402: optical camera 403: lighting device

Claims (9)

a workbench 100;
A horizontal guide part 200 forming a pair of support frames 201 symmetrical to each other on both sides of the upper surface of the workbench 100, and forming a rail part 202 between the support frames 201;
a horizontal movement device 300 that is slidably coupled to the rail portion 202 of the horizontal guide portion 200 and slides left and right along the rail portion 202;
The pole plate ( 10) an optical device 400 for photographing the distance between the coating layers 11;
is composed of
The work table 100 is formed as a pair symmetrically on both sides of the upper surface, allowing the support frame 201 to be slidably coupled, and moving the horizontal guide unit 200 in the front and rear directions of the work table 100 . Further forming a guide rail 101 for sliding movement,
The horizontal guide part 200,
A horizontal guide rail 202a is further formed on the upper surface of the rail part 202 in the longitudinal direction to guide the horizontal movement device 300 to slide along the rail part 202, and the rail part (202) Stoppers (202b) formed in a pair symmetrically on both sides of the front surface to block the horizontal movement device 300 moving along the rail part 202 from being separated to both sides of the rail part 202. forming a rack gear 202c along the longitudinal direction on the front surface of the rail part 202,
The horizontal moving device 300 is slidably coupled to the rail unit 202, and a moving block 310 that slides along the rail unit 202, and is installed on one side of the moving block 310 and the rack It is engaged with the gear 202c and rotates to move along the rack gear 202c, and includes a fine adjustment device 320 for finely adjusting the moving distance of the horizontal movement device 300,
The fine adjustment device 320 is rotatably installed on one side of the moving block 310, and its outer surface is coupled to engage the rack gear 202c, and the pinion moves along the rack gear 202c. A gear 321 and a fine adjustment knob 322 installed on the other side of the moving block 310 corresponding to the pinion gear 321, connected to the pinion gear 321, and rotating the pinion gear 321 ), the electrode coating layer distance measuring device for secondary batteries, characterized in that it is further formed. delete The method of claim 1,
The workbench 100 is
It is formed along the longitudinal direction of the upper surface of the work table 100, rotates in a direction perpendicular to the longitudinal direction of the work table 100, and presses one end of the electrode plate 10 mounted on the work table 100 in the longitudinal direction. Electrode coating layer distance measuring device for secondary batteries, characterized in that by pressing, a distance measuring device (102) for displaying the distance between the coating layers (11) of the electrode plate (10) is further formed. delete delete delete delete The method of claim 1,
The optical device 400,
a vertical plate portion 401 fixedly installed on one surface of the horizontal movement device 300;
An optical camera 402 that is fixedly installed on the front of the vertical plate unit 401 and calculates the distance between the coating layers 11 by photographing the distance between the coating layers 11 of the electrode plate 10 mounted on the work table 100 . );
a lighting device 403 which is fixedly installed at the bottom of the vertical plate portion 401 and irradiates light to the electrode plate 10;
Electrode coating layer distance measuring device for secondary batteries, characterized in that consisting of. 9. The method of claim 8,
The vertical plate portion 403,
a first plate portion 401a fixedly installed on one surface of the horizontal movement device 300;
a second plate portion (401b) coupled to a lower end of the first plate portion (401a) to be movable up and down, and having the lighting device (403) fixedly installed at the lower end thereof;
Electrode coating layer distance measuring device for secondary batteries, characterized in that consisting of.

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