KR102473483B1 - Device for manufacturing electrode plate for cell - Google Patents

Abstract

An apparatus for manufacturing an electrode plate for a battery capable of forming a coating film layer with high flatness on a substrate is provided. Specifically, the slurry 3 ) to the base material 2, a die 10 formed with a discharge port 18, a second manifold 24 elongated in the width direction provided in the middle of the slit 12, and a first manifold 11 Equipped with a supply means 20 for supplying the slurry 3 to the first manifold 11 from the inlet 16 communicating with the inlet 16 on the second manifold 24 One adjusting part 31 which adjusts the discharge amount of the slurry 3 from the discharge port 18 by flowing out the slurry 3 is provided in the part which intersects the shortest path to the discharge port 18.

Description

Battery electrode plate manufacturing device {DEVICE FOR MANUFACTURING ELECTRODE PLATE FOR CELL}

The present invention relates to a manufacturing apparatus for manufacturing an electrode plate for a battery by applying a slurry containing an active material to a substrate.

For example, as in Patent Document 1, a battery electrode plate is manufactured by applying a slurry containing an active material, a binder, a conductive auxiliary agent, and a solvent to a base material that is transferred in a roll-to-roll manner. In the electrode plate for a battery manufactured in this way, the thickness of the layer containing the active material formed on the substrate directly affects the charge and discharge amount of the battery, especially in the case of a high-capacity battery (battery), Controlling the film thickness of the slurry becomes very important. That is, the slurry needs to be applied with a uniform thickness along the width direction and the conveying direction of the substrate.

As disclosed in Patent Literature 1, a die for applying such a slurry to a substrate is formed with a manifold (liquid reservoir) long in the width direction and a slit connected to the manifold, and the slurry is formed on the manifold It is supplied to the fold and discharged from the manifold through a slit to the substrate. The slits are formed with a uniform gap size so that the slurry is discharged in a uniform amount along the width direction of the substrate.

Japanese Unexamined Patent Publication No. 11-233102

However, in the conventional battery electrode plate manufacturing apparatus as disclosed in Patent Document 1, there is a problem that the film thickness of the coating layer of the slurry applied to the base material is difficult to be uniform across the width direction. Specifically, for a manifold that is long in the width direction, since the inlet portion for supplying the slurry through communication with the manifold is provided at only one point, even if the flow rate of the slurry is equalized in the width direction in the manifold, within the manifold The pressure of the slurry tends to drop from the inlet towards the end of the manifold. Therefore, the flow rate of the slurry increases in the vicinity of the inlet, and as shown in FIG. 5, the shape of the coating layer of the slurry 3 applied to the substrate 2 is close to the inlet with respect to the width direction of the manifold. It had a thick convex shape in the part.

In particular, since the slurry used to manufacture the battery electrode plate has a high viscosity and is difficult to spread in the width direction within the manifold, the coating layer of the slurry 3 easily becomes convex as described above, and the slurry If the supply rate of the slurry 3 is increased in order to apply (3) at a high speed, there is a concern that the tendency of the coating layer to become convex gradually becomes stronger.

The present invention has been made in light of the above problems, and aims to form a coating layer with high flatness on a substrate.

An apparatus for manufacturing an electrode plate for a battery of the present invention is connected to a first manifold composed of a space for storing slurry elongated in the width direction, and connected to the first manifold via a slit wide in the width direction, and the slurry to a base material A die having a discharge port for discharging, a second manifold elongated in the width direction provided in the middle of the slit, and a supply means for supplying slurry to the first manifold from an inlet communicating with the first manifold. , On the second manifold, at a portion intersecting the shortest path from the inlet to the discharge port, one adjusting unit is provided to adjust the discharge amount of the slurry from the discharge port by flowing the slurry.

According to the present invention, on the second manifold, at a portion crossing the shortest path from the inlet to the discharge port, one adjusting unit is provided to adjust the discharge amount of the slurry from the discharge port by flowing the slurry out, so that across the width direction The amount of the slurry flowing through the discharge port can be adjusted in the adjusting unit, and the discharge amount of the slurry from the discharge port can be maintained at a predetermined amount in the width direction to form a coating layer with high flatness. Specifically, on the shortest path from the inlet to the discharge port, where the flow rate of the slurry tends to increase when flowing from the first manifold to the slit, the flow rate of the slurry is reduced by the regulator and the flow rate of the slurry discharged from the discharge port It is possible to uniformly approximate in the width direction.

In addition, it is preferable that the inflow part and the adjustment part are provided along the center line of the slit.

In this case, the thickness difference between the thickest part (near the inflow part) and the thinnest part (near the end) of the coating layer when applied without the function of the adjusting part is the smallest, and the slurry discharge is adjusted by the adjusting part. High flatness can be easily achieved at any time.

Also, it is preferable that the volume of the second manifold is smaller than the volume of the first manifold.

In this case, compared with the case where the adjustment unit is provided on the first manifold, the flow rate of the slurry can be adjusted with high sensitivity by the adjustment unit.

Further, the second manifold may have a shape in which a lower portion is a flat surface coplanar with a surface forming the slit, and a portion above a connection portion with the slit does not have a corner portion.

In this case, retention of the slurry in the second manifold can be prevented.

ADVANTAGE OF THE INVENTION According to this invention, it becomes possible to form a coating film layer with high flatness on a base material.

1 is an explanatory diagram showing a schematic configuration of an apparatus for manufacturing an electrode plate for a battery according to the present invention.
FIG. 2 is a cross-sectional view seen in the direction of arrow a in FIG. 1 .
3 is an explanatory view showing the shape of a coating layer formed on a base material by the battery electrode plate manufacturing apparatus of the present embodiment.
4 is an explanatory diagram showing a schematic configuration of an apparatus for manufacturing electrode plates for batteries in another embodiment.
5 is an explanatory view showing the shape of a coating layer formed on a base material by a conventional battery electrode plate manufacturing apparatus.

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described based on drawing.

1 is an explanatory diagram showing a schematic configuration of an apparatus for manufacturing electrode plates for batteries. This manufacturing device 1 is a device for applying a slurry 3 containing an active material, a binder, a conductive additive and a solvent to a substrate 2 made of metal foil that is transferred by roll-to-roll. According to this manufacturing apparatus, a layer containing an active material is formed on the substrate 2 by drying the applied slurry 3, and the substrate 2 is cut into a predetermined shape to become a battery electrode plate. Since the thickness of the layer containing the active material formed on the substrate 2 directly affects the charge and discharge amount of the battery, management of the film thickness of the coating layer formed by the slurry 3 applied to the substrate 2 This is very important, and according to this manufacturing apparatus 1, as described in the following embodiments, the slurry 3 is applied with a uniform thickness (uniform coating amount) along the transport direction of the substrate 2 do. In addition, the width direction of the base material 2 is a direction orthogonal to the conveyance direction of the base material 2, and the Y-axis direction in FIG. 1 corresponds to this.

The manufacturing apparatus 1 includes a die 10 elongated along the width direction of the substrate 2 and a supply means 20 for supplying the slurry 3 to the die 10 . In the die 10, the longitudinal direction (the Y-axis direction in FIG. 1) is referred to as the width direction. In this manufacturing apparatus 1, a roller 5 opposing the die 10 is provided, and the width direction of the die 10 and the direction of the center line of rotation of the roller 5 are parallel. The base material 2 is guided by the roller 5 so that the distance (gap) between the base material 2 and the die 10 (the front end of the slit 12 described later) is kept constant, and in this state, the slurry ( The application of 3) is performed.

The die 10 of the present embodiment includes a first division body 13 having a tapered first lip 13a and a second division having a tapered second lip 14a. It consists of a structure in which the sieve 14 is combined by sandwiching the shim plate 15 therebetween. FIG. 2 is a cross-sectional view seen in the direction of arrow a in FIG. 1 . In the die 10, a first manifold 11 formed of a space elongated in the width direction and a slit 12 connected to the first manifold 11 are formed therein, and a first lip ( 13a) and the second lip 14a, a discharge port 18, which is a release end of the slit 12, is formed. That is, the first manifold 11 and the discharge port 18 are connected via the slit 12 .

With this configuration, the slurry 3 supplied by the supply means 20 is first stored in the first manifold 11 and then discharged from the discharge port 18 via the slit 12 .

The slit 12 is formed to be long in the width direction similarly to the first manifold 11, and the width direction dimension of the slit 12 is determined by the inner dimension W of the shim plate 15, and the slit 12 ), the slurry 3 having substantially the same width direction dimension as the width direction dimension of ) can be applied onto the base material 2 . The clearance dimension (height dimension) of the slit 12 is 0.4-1.5 mm, for example. In the present embodiment, the die 10 is installed in such a posture that the direction of the gap between the slits 12 is the vertical direction and the direction of the width is the horizontal direction. That is, the die 10 is installed in an attitude in which the first manifold 11 and the slits 12 are aligned in the horizontal direction. Therefore, the direction in which the slurry 3 stored in the first manifold 11 flows through the slit 12 and the discharge port 18 to the substrate 2 is the horizontal direction.

In addition, by changing the thickness of the shim plate 15, the pressure inside the first manifold 11 (coating pressure) can be adjusted, and by this adjustment, a uniform film of the slurry 3 having various characteristics can be obtained. It becomes possible to perform thick coating construction.

In addition, in the middle of the slit 12 in the direction in which the slurry 3 flows (X-axis direction in FIG. 1), the length in the width direction (Y-axis direction) is equivalent to that of the first manifold and the slit 12 A second manifold 24 is installed. The cross-sectional area of the second manifold 24 in the width direction is smaller than that of the first manifold. That is, the volume of the second manifold 24 is smaller than that of the first manifold.

In addition, the shape of the second manifold 24 is such that the lower part is a flat surface on the same plane as the surface forming the slit 12, and the part above the connection part with the slit 12 does not have a corner part. . By doing in this way, within the 2nd manifold 24, there is no place where the slurry 3 easily stays.

In addition, an inlet 16 is provided at the center of the die 10 in the width direction and corresponding to the center line of the slit 12, and the inlet 16 is removed from the outside of the die 10. 1 consists of a through hole (inlet) connected to the manifold (11). The supply means 20 includes an inlet pipe 21 connected at one end to the inlet 16, a tank 22 storing the slurry 3, and the slurry 3 in the tank 22 It has a pump 23 for supplying to the die 10 through the pipe 21. From the above, the supply means 20 can supply the slurry 3 to the 1st manifold 11 from the inflow part 16. In addition, in this embodiment, as shown in FIG. 1, the inflow part 16 is connected with the bottom part 17 of the 1st manifold 11, and the slurry 3 is supplied from this bottom part 17. It is composed of inlet.

And the 1st manifold 11 can store the slurry 3 supplied from the supply means 20, and the slurry 3 stored in the 1st manifold 11, through the slit 12 Through the discharge port 18, the slurry 3 can be continuously applied to the base material 2 that is transferred in a roll-to-roll manner. The size of the gap between the slits 12 is constant in the width direction, and the thickness of the slurry 3 applied on the substrate 2 is constant in the width direction.

The slurry 3 is supplied to the die 10 by a pump supplying a certain amount, and the supply amount is appropriately adjusted. this is adjusted

In addition, a pressure sensor (not shown) may be installed in the die 10, and this pressure sensor may measure the internal pressure of the slurry 3 in the first manifold 11. And supply of the slurry 3 by the supply means 20 is controlled based on this measurement result, and the internal pressure of the slurry 3 of the 1st manifold 11 is kept constant. The slurry 3 whose internal pressure is constant in the first manifold 11 is discharged in an equal amount over the entire length in the width direction from the slit 12, and based on the measurement result of the pressure sensor, the slit 12 ) is controlled so that the amount of the slurry 3 discharged from is not fluctuated, so that the thickness of the slurry 3 applied on the substrate 2 in the conveying direction is constant. In addition, although not shown, a filter for the slurry 3 is provided in the middle of the pipe 21 .

In addition, in the second manifold 24, an adjustment unit 31 for flowing the slurry 3 flowing from the first manifold 11 to the discharge port 18 to the outside of the die 10 from other than the discharge port 18 It is provided. In this embodiment, the adjustment part 31 is provided in the part corresponding to the center line of the slit 12 shown by the chain line in FIG. Here, as described above, the inlet 16 is also provided on the center line of the slit 12, that is, the adjustment unit 31 is the shortest path from the inlet 16 to the outlet 18 and the second manifold 24 ) is provided at the intersection.

The adjustment unit 31 is composed of a through hole connecting the slit 12 and the outside of the die 10 and a pipe 51 connected to the through hole. In this embodiment, one end of the pipe 51 is connected to the tank 22, and the slurry 3 stored in the tank 22 flows into the first manifold 11 from the inlet 16. Alternatively, the slurry 3 discharged from the regulator 31 is returned to the tank 22 . In addition, although not shown, a filter may be provided in the middle of the pipe 51 .

Moreover, in this embodiment, the control device which adjusts the quantity of the slurry 3 made to flow out from the 2nd manifold 24 is provided in this adjustment part 31. Specifically, as shown in FIG. 2 , a valve 61 is connected to the pipe 51 as the control device. The valve 61 has a function of adjusting the flow rate of the slurry 3 flowing out from the regulator 31 . In addition, the valve 61 may adjust the pressure of the slurry 3 flowing out from the adjusting part 31 . Alternatively, in the middle of the pipe 51 connecting the regulator 31 and the tank 22, a device (for example, a pump) may be installed to control the flow rate of the slurry 3 (adjust the flow rate), in this case , This device functions as a control device for adjusting discharge of the slurry 3 to be discharged from the second manifold 24 .

Next, the shape of the coating layer of the slurry 3 formed on the base material 2 by the manufacturing apparatus 1 of this embodiment is shown in FIG.

As described above, in the present invention, the second manifold 24 of the die 10 is provided with an adjustment unit 31 that allows the slurry 3 to flow out of the die 10 from other than the discharge port 18. . And since this adjustment part 31 is provided in the part where the shortest path from the inflow part 16 to the discharge port 18 and the 2nd manifold 24 cross, as shown by hatching in FIG. 3, flatness is high. A coating layer of the slurry 3 may be formed on the substrate 2 . Specifically, it is as follows.

For example, when the slurry 3 is discharged from the die 10 to the base material 2 without activating the adjusting unit 31, the shape of the coating layer of the slurry 3 formed on the base material 2 is 2 points in FIG. As indicated by the dashed line, it tends to be convex in the width direction (Y-axis direction). This is because the flow rate of the slurry 3 flowing from the first manifold 11 of the die 10 to the discharge port 18 is greatest near the inlet 16, and the flow rate from the inlet 16 to the manifold 11 This is because the flow rate of the slurry 3 decreases as it moves away from the end of the, and the film thickness increases as the flow rate increases, and the coating layer has a convex shape where the portion discharged from the vicinity of the inlet 16 is the thickest. .

On the other hand, in the present invention, since the adjustment unit 31 is provided at the portion where the shortest path from the inlet 16 to the discharge port 18 and the second manifold 24 intersect, the slurry 3 is removed from the adjustment unit 31. By flowing out of the die 10, the amount of the slurry 3 discharged from the discharge port 18 near the inlet portion 16 can be controlled to be reduced. As a result, in the coating layer of the slurry 3, the film thickness of the part where the original film thickness is the largest can be reduced, and as shown in FIG. 3, a coating layer with high flatness is obtained.

By doing this, the slurry 3 formed on the base material 2 is adjusted by adjusting the discharge amount of the slurry 3 only by one adjusting part 31 provided on the shortest path from the inlet part 16 to the discharge port 18 Since the coating layer of can be highly flattened, a coating layer with high flatness can be obtained with simple control. Moreover, since the number of adjustment parts 31 is small, maintenance, such as cleaning of the adjustment part 31, is also easy.

In addition, at the end of the first manifold 11, the reason why the discharge amount of the slurry 3 from the discharge port 18 is smaller than the vicinity of the inlet 16 is that at this end, the first manifold 11 Since there are walls constituting the end faces in the width direction of ), the pressure of the slurry 3 supplied from the inlet 16 and diffused on both sides in the width direction is lowered at the end, and accordingly the flow rate is lowered. to be. In particular, since the viscosity (viscosity) of the slurry 3 is high, the flow rate tends to decrease at the end.

In addition, as the slurry 3 discharged from the die 10 of the manufacturing apparatus 1 of the present embodiment, one having a viscosity of several thousand to several tens of thousands cP (when shear rate = 1) can be employed.

Here, in the present invention, the adjustment unit 31 is provided on the second manifold 24 instead of the first manifold 11 . This is because the first manifold 11 has a large cross-sectional area in the width direction in order to spread the slurry 3 introduced from the inlet 16 to the entire first manifold 11, that is, the volume is large. This is because, for example, when the adjustment unit 31 is provided in the first manifold 11, even if the flow rate of the slurry 3 is adjusted locally by the adjustment unit 31, the sensitivity is poor and sufficient adjustment effect is difficult to obtain. .

On the other hand, for example, when the adjustment unit 31 is provided directly in the slit 12 instead of the second manifold 24, the sensitivity of the adjustment is too high, making it difficult to control the discharge amount of the slurry 3 from the discharge port 18. At the same time, The range in the width direction (Y-axis direction) affected by the adjustment of the discharge amount by the adjustment unit 31 is narrowed, the shape of the coating layer is not flattened, and only the portion adjusted by the adjustment unit 31 is a concave shape. There is a risk of becoming

On the other hand, by providing the adjuster 31 in the second manifold 24 having a smaller cross-sectional area in the width direction than the first manifold 11, the adjustment in the adjuster 31 can be appropriately sensitized and also in the width direction. Thus, it is possible to flatten the coating layer by reflecting the amount of discharge from the discharge port 18 over a wide area.

In addition, in this embodiment, the inflow part 16 and the adjustment part 31 are provided along the central axis of the slit 12. Here, in the first manifold 11, the distance between the inlet 16 and the part most spaced from the inlet 16 (the end of the manifold 11) is the inlet 16 to the manifold 11 ) becomes the minimum when it is provided in the center (on the central axis of the slit 12). Since the film thickness of the coating layer of the slurry 3 formed on the substrate 2 becomes smaller as the portion formed by being discharged from a position spaced apart from the inlet portion 16, the coating layer when applied without the adjustment unit 31 functioning The difference between the thickness of the thickest part (near the inlet) and the thinnest part (near the end) is when the inlet 16 is provided in the center of the manifold 11 (on the central axis of the slit 12). is the smallest, and high flatness can be easily achieved when the discharge of the slurry 3 is adjusted by the adjusting unit 31.

Moreover, the manufacturing apparatus 1 may be equipped with the sensor 36 (refer FIG. 1) which measures the film thickness of the slurry 3 apply|coated on the base material 2. A plurality of these sensors 36 may be provided along the width direction. The sensor 36 is non-contact and can measure the film thickness of the slurry 3 on the substrate 2 at a plurality of points along the width direction or over the entire length in the width direction, and the measurement result is the manufacturing device 1 ) is output to the control device (computer) 37 equipped with. The control device 37 adjusts the opening degree of the valve 61 by performing feedback control based on the measurement result from the sensor 36 . That is, according to the measurement result of the film thickness of the slurry 3, the control apparatus 37 outputs a control signal with respect to the valve 61, and adjusts the opening degree of the valve 61. This makes it possible to cope with changes over time in the flow of the slurry 3 due to retention of the slurry 3 in the manifold 11, for example, and to reduce the film thickness of the coating layer of the slurry 3. Flattening in the width direction becomes easy.

Alternatively, the opening degree of the valve 61 may be controlled by a timer function of the controller 37 instead of the sensor 36 . That is, when a certain time elapses from the start of application, precipitation or aggregation of the solid component of the slurry 3 occurs at the end of the first manifold 11, etc., and a change occurs in the flow of the slurry 3, this time A predetermined time before this elapse is measured by a timer, and when the predetermined time elapses, the controller 37 may perform control to increase the opening degree of the valve 61 .

With the above apparatus for manufacturing electrode plates for batteries, it becomes possible to form a coating layer with high flatness on a base material.

In addition, the manufacturing apparatus 1 of this invention is not limited to the form shown in figure, Another form may be sufficient within the scope of this invention. For example, in this embodiment (see FIG. 2 ), although the inflow part 16 and the adjustment part 31 are set to the structure provided along the center line of the slit 12, it is not limited to the position along the center line, Yes For example, as shown in FIG. 4, the structure provided near the end part of the die 10 may be sufficient. Even with this configuration, the adjustment unit 31 reduces the discharge amount of the slurry 3 near the inlet 16 where the film thickness of the coating layer of the slurry 3 becomes the largest when the adjustment unit 31 is not functioning Thus, the flatness of the coating layer in the width direction can be increased.

Further, in the above embodiment, the die 10 is configured such that the direction in which the slurry 3 of the first manifold 11 flows from the discharge port 18 to the substrate 2 through the slit 12 is the horizontal direction. Although the installation case has been described, the installation posture of the die 10 may be other than this. For example, the die 10 may be installed in an attitude in which the first manifold 11 and the slits 12 are aligned in the vertical direction, and in this case, the slurry of the first manifold 11 The die 10 may be installed so that the direction in which (3) flows through the slit 12 from the discharge port 18 to the substrate 2 is vertically upward.

In addition, the manufacturing apparatus 1 of the present invention is effective when the coating liquid to be applied is a high-viscosity slurry, and may be applied when a product (eg, an optical film) is manufactured by applying a high-viscosity slurry. do.

1: manufacturing device
2: Substrate
3: Slurry
5 : Roller
10: die
11: first manifold
12: slit
13: first division body
13a: first lip
14: second division body
14a: second lip
15: trial board
16: inlet
17: bottom
18: discharge port
20: supply means
21: inlet pipe
22 : tank
23: pump
24: second manifold
25: stay
31: adjustment unit
36: sensor
37: control device
51: pipe
61: valve

Claims (4)

A first manifold composed of a space for storing slurry elongated in the width direction, and a die connected to the first manifold via a slit wide in the width direction and having a discharge port for discharging the slurry to a substrate;
a second manifold elongated in the width direction provided in the middle of the slit;
A supply means for supplying slurry to the first manifold from an inlet communicating with the first manifold,
On the second manifold, at a portion crossing the shortest path from the inlet to the discharge port, one adjustment unit is provided to adjust the discharge amount of the slurry from the discharge port by flowing the slurry out,
The apparatus for manufacturing an electrode plate for a battery, characterized in that the volume of the second manifold is smaller than the volume of the first manifold. According to claim 1,
The apparatus for manufacturing an electrode plate for a battery, characterized in that the inlet and the adjusting part are provided along the center line of the slit. delete According to claim 1 or 2,
The second manifold is characterized in that the lower portion is a flat surface on the same plane as the surface forming the slit, and a portion above the connection portion with the slit does not have a corner portion.

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