KR102646379B1 - Multiple slot die coater - Google Patents

Abstract

We provide a multi-slot die coater that is easy to adjust the coating gap and can control the width direction deviation of the coating gap. According to the present invention, a step is formed between the back surfaces of die blocks through a fixing block including a step adjustment block. The step adjustment block has a predetermined thickness, and a step adjustment block is mounted between one die block and a flat block, and the other die block is coupled to the flat block, so that the die blocks with respect to the fixed block including the step adjustment block are adjusted. By combining, a step is naturally formed between the back surfaces of the die blocks. Then, the distance between the tips of the dies and the substrate, that is, the coating gap, can always be maintained at the desired level. Since the dies are fixed, the coating gap once set is maintained without changing easily during the process, so the coating gap in the width direction is maintained. It is possible to suppress the occurrence of deviations.

Description

Multiple slot die coater

The present invention relates to a multi-slot die coater capable of forming two or more layers simultaneously in a wet manner, and more specifically, to a multi-slot die coater having a means for controlling the width direction deviation of the coating gap.

As technology development and demand for mobile devices increase, the demand for secondary batteries as an energy source is rapidly increasing, and these secondary batteries essentially include an electrode assembly, which is a power generation element. The electrode assembly has a form in which a positive electrode, a separator, and a negative electrode are stacked at least once, and the positive electrode and the negative electrode are manufactured by applying and drying the positive electrode active material slurry and the negative electrode active material slurry on a current collector made of aluminum foil and copper foil, respectively. In order to make the charging and discharging characteristics of the secondary battery uniform, the positive electrode active material slurry and the negative electrode active material slurry must be evenly coated on the current collector, and conventionally, a slot die coater has been used.

Figure 1 shows an example of a coating method using a conventional slot die coater.

Referring to FIG. 1, in the electrode manufacturing method using a slot die coater, the active material slurry discharged from the slot die coater 30 is applied onto the current collector 20 transported by the coating roll 10. The active material slurry discharged from the slot die coater 30 is widely spread on one side of the current collector 20 to form an active material layer. The slot die coater 30 includes two die blocks 31 and 32 and has a slot 35 formed between the two die blocks 31 and 32, and has a discharge port communicating with one slot 35. 37), one type of active material slurry can be discharged to form one active material layer. Slot die coaters have the advantage of being able to apply at high speeds compared to bar coating or comma coating, so they are widely applied in terms of high productivity.

In order to manufacture secondary batteries with high energy density, the thickness of the active material layer, which was about 130㎛, gradually increases and reaches 300㎛. After forming a thick active material layer using a conventional slot die coater 30, migration of the binder and conductive material in the active material slurry intensifies during drying, causing the final electrode to be manufactured unevenly. To solve this problem, there is a disadvantage in that it takes a long time to coat the active material layer twice, such as by applying a thin layer, drying it, and then applying it again on top of it and drying it. In order to simultaneously improve electrode performance and productivity, a dual slot die coater that can apply two types of active material slurries simultaneously is required.

Figure 2 is a cross-sectional view along the traveling direction (MD direction) of the current collector 20 in a conventional dual slot die coater.

Referring to FIG. 2, the dual slot die coater 40 is constructed by assembling three die blocks 41, 42, and 43. Since slots are formed between neighboring die blocks 41, 42, and 43, two slots 45 and 46 are provided. Two types of active material slurries are simultaneously discharged onto the current collector 20 through the discharge ports 47 and 48 connected to each slot 45 and 46, thereby depositing additional active material slurry on the active material layer formed by the previously applied active material slurry. By continuously applying, two active material layers can be formed simultaneously.

Since the process using this dual slot die coater 40 must use active material slurries simultaneously discharged from different discharge holes 47 and 48, it is quite difficult to form each active material layer to a desired thickness.

The separation distance G from the discharge ports 47 and 48 to the surface of the current collector 20 is a coating gap and is a very important variable in determining the coating quality of the active material layer. In general, the thickness of each active material layer is affected by the amount of active material slurry discharged through the discharge ports 47 and 48, the type of active material slurry, and the coating gap. In addition, stable coating is possible only when the coating gap is uniform in the width direction of the current collector (TD direction), and any deviation in the coating gap in the width direction has a significant impact on the coating width and the shape of the boundary of the uncoated area. The thickness of the active material layer is a very small value of tens to hundreds of ㎛, and it must be managed very strictly because even a change of just a few ㎛ can seriously affect the coating quality, and in order to stably perform uniform application in the width direction of the current collector. It needs to be managed very strictly to ensure uniform dimensional accuracy in the width direction. However, as the width of the dual slot die coater 40 increases in order to use a long-width current collector to increase production, it becomes more difficult to apply uniformly in the width direction, making precise control of the coating gap more necessary.

In addition, the range of the appropriate coating gap is determined depending on the type of active material slurry. In the production process, various products must be manufactured using several types of active material slurries rather than using just one type of active material slurry. In order to use a variety of active material slurries, it is difficult to separately provide a dual slot die coater dedicated to each active material slurry. Therefore, after coating a certain type of active material slurry with one dual slot die coater, it is necessary to coat a different type of active material slurry with the dual slot die coater, and at that time, the previously set coating gap must be closed. There is a need to change. In addition, since it is difficult to always manufacture the same type of active material slurry uniformly, there is a dispersion in physical properties depending on the manufacturing time, so it must be possible to respond to such dispersion. The higher the high-speed application, the more the coating changes according to the dispersion of the active material slurry's physical properties. Coating gap control becomes more important as quality variations become more evident.

Conventionally, in order to create a desired coating gap, it is required to repeat the process of disassembling and reassembling each die block, adjusting the coating gap, and confirming the coating process several times on a trial basis. However, this coating gap is not only a variable that can be adjusted sensitively to the extent that it changes depending on the fastening strength of the bolts used for assembling the die blocks 41, 42, and 43, but also can be changed by the force with which the active material slurry is discharged. There is a possibility that it can be done. Since the slot die coater configures slots on the mating surfaces of die blocks, basically three die blocks (41, 42, 43) are required to have two slots (45, 46) like the dual slot die coater (40). do. In order to configure a device with a similar footprint and volume as the existing slot die coater 30 with one slot, the thickness of each die block 41, 42, and 43 must be thin, so it is inevitable. Therefore, it is structurally vulnerable to deformation and torsion. If deformation or distortion occurs, the carefully adjusted coating gap becomes distorted, which becomes a serious problem that causes defects in the electrode process. In addition, this problem will become more serious in multi-slot die coaters, which include two or more slots and increase the number of die blocks.

The present invention was created in consideration of the above-mentioned problems, and the problem to be solved by the present invention is to provide a multi-slot die coater that can easily adjust the coating gap and control the width direction deviation of the coating gap.

However, the problem to be solved by the present invention is not limited to the above-mentioned problem, and other problems not mentioned can be clearly understood by those skilled in the art from the description of the invention described below.

The multi-slot die coater of the present invention for solving the above problems is a multi-slot die coater including a lower die having a lower slot and an upper die having an upper slot and disposed on an upper part of the lower die. A first flat surface formed at the top and a second flat surface formed at the bottom of the upper die contact each other to form a sliding surface, and one side of the upper die and the lower die slides along the sliding surface in a horizontal direction. It is installed to enable relative movement, and is fastened with bolts to the back surfaces of the lower die and the upper die on the back surfaces opposite to the front ends of the lower die and the upper die, so as to couple the lower die and the upper die. The fixed block further includes a flat block having a reference plane in close contact with the rear surface of one of the two die blocks, and between the flat block and the rear surface of the other die block of the two die blocks. It is characterized in that it includes a step adjustment block that is detachable and has a thickness such that a step is formed between the back surfaces of the two die blocks coupled to the fixing block when mounted.

The lower die includes a lower die block and a first intermediate die block disposed on an upper part of the lower die block and forming the lower slot between the lower die block and the upper die block. It may include a second intermediate die block installed above, and an upper die block disposed above the second intermediate die block and forming the upper slot between the second intermediate die block and the second intermediate die block.

At this time, the flat block connects the first intermediate die block and the second intermediate die block, and the step adjustment block is in close contact with the rear surface of the second intermediate die block or the rear surface of the first intermediate die block. You can.

The flat block extends to the rear surface of the lower die block and can be coupled to the rear surface of the lower die block.

The flat block extends to the rear surface of the upper die block and can be coupled to the rear surface of the upper die block.

A flat fixing part bolted to the back of the upper die block and the back of the second intermediate die block, or a flat fixing part bolted to the back of the first middle die block and the back of the lower die block. More may be included.

The step adjustment block may be in close contact with the rear surface of the second intermediate die block, and the length of the upper die may be shorter than the length of the lower die.

The lower die block, the first middle die block, the second middle die block, and the upper die block each have a lower die lip, a first middle die lip, a second middle die lip, and an upper die lip forming the tip portion thereof, The lower die lip, the first middle die lip, the second middle die lip, and the upper die lip may be located on the same straight line.

The lower die block, the first middle die block, the second middle die block, and the upper die block each have a lower die lip, a first middle die lip, a second middle die lip, and an upper die lip forming the tip portion thereof, A lower discharge port communicating with the lower slot is formed between the lower die lip and the first middle die lip, and an upper discharge port communicating with the upper slot is formed between the second middle die lip and the upper die lip, The multi-slot die coater applies the active material slurry by extruding it through at least one of the lower slot and the upper slot on the continuously running surface of the substrate, and a step may be formed between the lower discharge port and the upper discharge port.

The fixed block may be provided in plural numbers in the width direction of the multi-slot die coater.

A cross section of the fixed block that passes both the step adjustment block and the reference plane may include a first cross section and a second cross section extending vertically from the first cross section.

The step adjustment block may be a plate-shaped member having a groove recessed from the lower surface perpendicular to the direction of the thickness so as to be inserted into a bolt fastened to the flat block. The upper surface of the plate-shaped member may be provided with a handle portion used for mounting and dismounting.

There are a plurality of bolts fastened to the flat block along the horizontal or vertical direction of the flat block, and the step adjustment block may be inserted into one or more of the bolts. For example, the step adjustment block may have a size corresponding to each bolt.

According to the present invention, a step is formed between the back surfaces of die blocks through a fixing block including a step adjustment block. The step adjustment block has a predetermined thickness, and a step adjustment block is mounted between one die block and a flat block, and the other die block is coupled to the flat block, so that the die blocks with respect to the fixed block including the step adjustment block are adjusted. By combining, a step is naturally formed between the back surfaces of the die blocks. Then, the distance between the tips of the dies and the substrate, that is, the coating gap, can always be maintained at the desired level. Since the dies are fixed, the coating gap once set is maintained without changing easily during the process, so the coating gap in the width direction is maintained. It is possible to suppress the occurrence of deviations.

Therefore, according to the present invention, there is no need to adjust the coating gap while disassembling and reassembling die blocks, which are structurally weak due to their thin thickness, and by a simple operation of joining die blocks to a fixed block, and Through simple installation and removal of the step adjustment block, a constant coating gap can always be maintained. In addition, the fixed block is clearly effective in controlling the gap in the width direction uniformly through the large surface contact of the block.

According to the present invention, even considering that the die block is deformed by the pressure of the discharged active material slurry, it is possible to maintain a uniform (±2%) coating gap, thereby uniformly controlling the coating amount and the resulting coating quality. . Therefore, it is possible to obtain uniform quality coated products, especially electrodes for secondary batteries, by using a multi-slot die coater with a uniform coating gap.

In this way, according to the present invention, even if the discharge pressure of the active material slurry increases or thin die blocks are used, the effect of maintaining the once adjusted coating gap is excellent. This has the effect of securing coating fairness and reproducibility.

Using such a multi-slot die coater, it is possible to uniformly form a coating layer, especially an active material layer, with a desired thickness. Preferably, simultaneous coating of two types of active material slurries is possible, resulting in excellent effects in both performance and productivity.

According to the present invention, a plurality of fixed blocks can be provided in the width direction of the multi-slot die coater. Then, precise control is possible without deviation of the coating gap in the width direction. Therefore, even for a wide current collector, it is possible to maintain uniform dimensional accuracy so that uniform application in the width direction can be performed stably.

An appropriate coating gap range can be determined depending on the type of active material slurry. In the present invention, various types of step control blocks with appropriate thicknesses are provided and the process is performed by replacing them with the step adjustment blocks required for each production process, so that multiple slots dedicated to each active material slurry are used to use various active material slurries. Even if you do not have a die coater individually, a multi-slot die coater can be used for general purposes. In addition, the desired coating gap can be achieved by installing and dismounting the step adjustment block without the need to dismantle the entire flat block. In addition, even if there is dispersion in the active material slurry, it is possible to quickly respond to such dispersion by immediately replacing only the step adjustment block portion to adjust the coating gap.

In this way, by using the multi-slot die coater of the present invention, when manufacturing electrodes of secondary batteries by applying active material slurry on the current collector while traveling, uniform application is possible even under high-speed traveling or long-width application conditions. There is an advantage.

The following drawings attached to this specification illustrate preferred embodiments of the present invention, and serve to further understand the technical idea of the present invention together with the detailed description of the invention described later, so the present invention includes the matters described in such drawings. It should not be interpreted as limited to only .
Figure 1 is a schematic diagram showing an example of use of a slot die coater according to the prior art.
Figure 2 is a schematic cross-sectional view of a dual slot die coater according to the prior art.
Figure 3 is a schematic cross-sectional view of a multi-slot die coater according to an embodiment of the present invention.
Figure 4 is a schematic exploded perspective view of a multi-slot die coater according to an embodiment of the present invention.
FIG. 5 is a perspective view of a fixed block included in the multi-slot die coater shown in FIG. 3.
FIG. 6 shows another example of the step adjustment block shown in FIG. 5.
Figure 7 is a plan view from the back of a multi-slot die coater according to an embodiment of the present invention.
Figure 8 is a modified example of Figure 7.
9 to 14 are schematic cross-sectional views of multi-slot die coaters according to other embodiments of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the attached drawings. Prior to this, the terms or words used in this specification and claims should not be construed as limited to their usual or dictionary meanings, and the inventor should appropriately define the concept of terms in order to explain his or her invention in the best way. It must be interpreted as meaning and concept consistent with the technical idea of the present invention based on the principle of definability. Accordingly, the embodiments described in this specification and the configurations shown in the drawings are only some of the most preferred embodiments of the present invention and do not represent the entire technical idea of the present invention, so at the time of filing the present application, various options that can replace them are available. It should be understood that equivalents and variations may exist.

The multi-slot die coater of the present invention may have two or more slots. Basically, it is a device that has a lower slot and an upper slot and coats the substrate with a double layer of coating liquid. The 'substrate' described below is a current collector, and the coating liquid is an 'active material slurry'. The first coating liquid and the second coating liquid are both active material slurries, and may refer to active material slurries with the same or different composition (type of active material, conductive material, binder), content (amount of active material, conductive material, binder), or physical properties. . The multi-slot die coater of the present invention is optimized for electrode manufacturing by simultaneously applying two or more types of active material slurries or pattern coating while alternately applying two or more types of active material slurries. However, the scope of the present invention is not necessarily limited thereto. For example, the substrate may be a porous support constituting a separator, and the first coating solution and the second coating solution may be organic materials with different compositions or physical properties. That is, if thin film coating is required, the substrate, first coating liquid, and second coating liquid may be any.

Figure 3 is a schematic cross-sectional view of a multi-slot die coater according to an embodiment of the present invention, and Figure 4 is a schematic exploded perspective view of a multi-slot die coater according to an embodiment of the present invention. FIG. 5 is a perspective view of a fixed block included in the multi-slot die coater shown in FIG. 3. FIG. 6 shows another example of the step adjustment block shown in FIG. 5. Figure 7 is a plan view from the back of a multi-slot die coater according to an embodiment of the present invention.

The multi-slot die coater 100 according to an embodiment of the present invention is a dual slot die coater having a lower slot 101 and an upper slot 102, and the two slots are the same or the same as each other through the lower slot 101 and the upper slot 102. This is a device that can simultaneously or alternately coat two different types of coating liquids on the substrate 300. 3 and 4, the multi-slot die coater 100 includes a lower die (A) and an upper die (B) disposed on top of the lower die (A). The lower die (A) includes a lower die block 110 and a first intermediate die block 122 disposed on the lower die block 110. The first intermediate die block 122 forms a lower slot 101 between the lower die block 110 and the lower die block 110 . The upper die B includes a second intermediate die block 124 installed on the first intermediate die block 122, and an upper die block 130 disposed on the second intermediate die block 124. The second intermediate die block 124 forms an upper slot 102 between the upper die block 130 and the second intermediate die block 124 .

In FIG. 3, the multi-slot die coater 100 is installed so that the direction (X direction) in which the active material slurry, which is a coating liquid, is discharged is almost horizontal (approximately: ±5 degrees). The first intermediate die block 122 and the second intermediate die block 124 constitute the intermediate die block 120. The middle die block 120 is a block located in the middle among the blocks constituting the multi-slot die coater 100, and is disposed between the lower die block 110 and the upper die block 130. The intermediate die block 120 of this embodiment has a cross-section of approximately a right triangle, but it is not necessarily limited to this shape. For example, the cross-section may be an isosceles triangle. In the intermediate die block 120, the first intermediate die block 122 and the second intermediate die block 124 are in vertical contact with each other and are provided to slide along the contact surface to enable relative movement.

The first side 124a of the second intermediate die block 124 facing the upper die block 130 lies substantially horizontal and the first side 124a of the second intermediate die block 124 faces the upper die block 130. The two surfaces 124b are in face-to-face contact with the first surface 122a of the first intermediate die block 122, and are relatively moved along the contact surface between them. A second side 122b opposite the first side 122a of the first middle die block 122 faces the lower die block 110 .

The first surface 124a of the second intermediate die block 124 facing the upper die block 130 lies substantially horizontally, and the surface 130b of the upper die block 130 faces the first surface 124a. ) The opposite surface (130d, that is, the surface forming the upper surface of the outer peripheral surface of the multi-slot die coater 100) is also placed almost horizontally. In this way, the first surface 124a and the opposite surface 130d are substantially parallel. And the opposite surface (110d, that is, the surface forming the lower surface of the outer peripheral surface of the multi-slot die coater 100) of the surface 110b of the lower die block 110 facing the first intermediate die block 122 is also substantially horizontal. It is placed, and this surface becomes the floor surface (110d, X-Z plane).

A surface opposite to the direction in which the active material slurry is discharged from the lower die block 110, the first and second intermediate die blocks 122 and 124, and the upper die block 130, that is, the back surface 110c, 122c, 124c, 130c) lies almost vertically (Y direction).

Among the surfaces forming the outer peripheral surface of the multi-slot die coater 100 in the lower die block 110 and the upper die block 130, which are the outermost die blocks, the bottom surface 110d of the lower die block 110 and the upper die block ( The upper surface 130d of 130 may be manufactured to be almost perpendicular to the rear surfaces 110c and 130c. Additionally, the first surface 124a of the second intermediate die block 124 may be manufactured to be almost perpendicular to the rear surface 124c. In these die blocks (110, 124, 130), the edges formed by the faces are formed at right angles, so there is a right angle in the cross section, and since the vertical or horizontal plane can be used as the reference surface, it is easy to manufacture and handle, and the precision is high. guaranteed. In addition, the combined state of the lower die block 110, the first and second intermediate die blocks 122 and 124, and the upper die block 130 has an overall shape of approximately a rectangular parallelepiped, and only the front portion where the coating liquid is discharged is described. It has an inclined shape toward 300 (see the surface 130a of the upper die block 130 and the surface 110a of the lower die block 110). This has the advantage that the shape after assembly is approximately similar to a slot die coater (for example, 30 in FIG. 1) having a single slot, so that a slot die coater stand, etc. can be shared.

The lower die block 110, the first and second intermediate die blocks 122 and 124, and the upper die block 130 are not necessarily limited to the form exemplified above, and for example, the direction in which the active material slurry is discharged may be selected. It can also be configured as a vertical die with the die facing upward and the back surface (110c, 122c, 124c, 130c) as the bottom surface.

The die blocks 110, 120, and 130 are, for example, made of SUS. Materials that are easy to process, such as SUS420J2, SUS630, SUS440C, SUS304, and SUS316L, can be used. SUS is easy to process, inexpensive, has high corrosion resistance, and has the advantage of being able to be manufactured into desired shapes at low cost.

The lower die block 110 is a block located at the bottom among the blocks constituting the multi-slot die coater 100, and the surface 110b facing the first intermediate die block 122 is on the bottom surface 110d. It has an inclined shape so as to form an angle of approximately 20 to 60 degrees.

The lower slot 101 may be formed between the lower die block 110 and the first middle die block 122 facing each other. For example, the first spacer 113 is interposed between the lower die block 110 and the first intermediate die block 122 to provide a gap between them, thereby providing a passage through which the first coating liquid 50 can flow. A lower slot 101 may be formed. In this case, the thickness of the first spacer 113 determines the vertical width (Y-axis direction, slot gap) of the lower slot 101.

As shown in FIG. 4, one area of the first spacer 113 is cut to have a first opening 113a, and each of the lower die block 110 and the first middle die block 122 has opposing surfaces. It may be included in the remaining portion of the border area except for one side. Accordingly, the lower discharge hole 101a through which the first coating liquid 50 can be discharged to the outside is formed only between the front end of the lower die block 110 and the front end of the first intermediate die block 122. The tip of the lower die block 110 and the tip of the first intermediate die block 122 are defined as the lower die lip 111 and the first intermediate die lip 121a, respectively. In other words, the lower discharge port 101a is defined as the lower die lip 111 and the first intermediate die lip 121a. It can be said to be a place formed by separating the lip 111 and the first intermediate die lip 121a.

For reference, the first spacer 113 allows the first coating liquid 50 to flow into the gap between the lower die block 110 and the first intermediate die block 122, except for the area where the lower discharge hole 101a is formed. Since it also functions as a gasket to prevent leakage, it is preferably made of a material with sealing properties.

The lower die block 110 has a first manifold 112 on the surface 110b facing the first intermediate die block 122 and has a predetermined depth and communicates with the lower slot 101. The first manifold 112 is a space provided from the surface 110b of the lower die block 110 facing the first middle die block 122 toward the opposite surface 110d, which is the opposite surface of the surface 110b. am. This first manifold 112 is connected to an externally installed first coating liquid supply chamber (not shown) through a supply pipe and receives the first coating liquid 50. When the first coating liquid 50 fills the first manifold 112, the first coating liquid 50 is guided to flow along the lower slot 101 and is discharged to the outside through the lower discharge port 101a.

The upper die block 130 is disposed to face the first surface 124a, which is the upper surface of the second middle die block 124, which is horizontal with respect to the bottom surface. The upper slot 102 is formed between the second middle die block 124 and the upper die block 130 facing each other.

Like the lower slot 101 described above, a second spacer 133 may be interposed between the second middle die block 124 and the upper die block 130 to provide a gap therebetween. As a result, an upper slot 102 corresponding to a passage through which the second coating liquid 60 can flow is formed. In this case, the vertical width (Y-axis direction, slot gap) of the upper slot 102 is determined by the second spacer 133.

In addition, the second spacer 133 has a structure similar to the above-described first spacer 113 and has one area cut to provide a second opening 133a, and includes a second middle die block 124 and an upper die block ( 130) It is included only in the remaining portion excluding one side of the border area of each opposing surface. Likewise, the circumferential direction except the front of the upper slot 102 is blocked, and the upper discharge port 102a is formed only between the front end of the second middle die block 124 and the front end of the upper die block 130. The tip of the second intermediate die block 124 is defined as the second middle die lip 121b, and the tip of the upper die block 130 is defined as the upper die lip 131. In other words, the upper discharge port 102a is defined as the second middle die lip 121b. It can be said to be a place formed by separating the die lip 121b and the upper die lip 131.

In addition, the second intermediate die block 124 is provided with a second manifold 132 having a predetermined depth on the first surface 124a, which is the surface facing the upper die block 130, and communicating with the upper slot 102. do. The second intermediate die block 124 has a second surface 124b that is opposite to the first surface 120a. The second side 124b is also the side where the second intermediate die block 124 faces the first intermediate die block 122. The second manifold 132 is a space provided from the first side 124a toward the second side 124b. Although not shown in the drawing, the second manifold 132 is connected to the externally installed second coating liquid 60 supply chamber and a supply pipe to receive the second coating liquid 60. When the second coating liquid 60 is supplied from the outside along a pipe-shaped supply pipe and fills the second manifold 132, the second coating liquid 60 is connected to the upper slot ( The flow is induced along 102) and discharged to the outside through the upper discharge port 102a.

The upper slot 102 and the lower slot 101 form a certain angle, and the angle may be approximately 20 to 70 degrees. These upper slots 102 and lower slots 101 intersect each other at one point, and an upper discharge port 102a and a lower discharge port 101a may be provided near the intersection point. Accordingly, the discharge points of the first coating liquid 50 and the second coating liquid 60 can be concentrated at approximately one location.

Meanwhile, the first side 124a of the second middle die block 124 faces the upper die block 130 and the second side of the first middle die block 122 faces the lower die block 110. The angle θ formed by (122b) is preferably within a range in which the active material slurry discharged from the upper discharge port 102a and the active material slurry discharged from the lower discharge port 101a do not form a vortex immediately after simultaneous discharge. If the angle θ becomes too small, the intermediate die block 120 becomes too thin and becomes very vulnerable to deformation and twisting.

According to the multi-slot die coater 100 having this configuration, the rotatable coating roll 200 is placed in front of the multi-slot die coater 100, and the coating roll 200 is rotated to coat the substrate ( While driving 300, the first coating liquid 50 and the second coating liquid 60 are continuously brought into contact with the surface of the substrate 300, thereby coating the substrate 300 in a double layer. Alternatively, a pattern coating may be formed intermittently on the substrate 300 by alternately supplying and stopping the first coating liquid 50 and supplying and stopping the second coating liquid 60.

Here, bolts 141a and 141b are attached to the rear surfaces 110c, 122c, 124c and 130c of the die blocks 110, 122, 124 and 130, which are surfaces opposite to the front ends of the lower die A and upper die B. ) and further includes a fixing block 140 that couples the lower die (A) and the upper die (B).

The fixed block 140 includes a flat block 142 having a reference plane in close contact with the back of one of the lower die (A) and the upper die (B), and the back of the other of the two die blocks. It includes a step adjustment block 144 that is detachable between the flat blocks 142 and has a thickness such that a step is formed between the back surfaces of the two die blocks coupled to the fixing block 140 when mounted.

As shown in FIG. 5, the fixed block 140 includes a flat block 142 having a reference plane 142a in close contact with the back surface 122c of the first intermediate die block 122. In addition, it includes a step adjustment block 144 that is provided toward the front end relative to the reference plane 142a and can be mounted or removed. The step adjustment block 144 has a thickness h, and forms a step between the back surfaces 122c and 124c of the two die blocks 122 and 124 coupled to the fixed block 140 by an amount corresponding to this thickness. . The fixing block 140 may be made of SUS material.

The flat block 142 may further have a hole 143 through which the bolts 141a and 141b pass for fastening the bolts 141a and 141b. The number and location of the holes 143 can be changed as shown. In this embodiment, the flat block 142 has a reference plane 142a that is in close contact with the back surface 122c of the first intermediate die block 122, and is different from the back surface 122c of the first intermediate die block 122. It is fastened to the second intermediate die block 124 via a bolt 141b and the second intermediate die block 124 via a bolt 141a.

In this embodiment, the step adjustment block 144 is mounted between the second intermediate die block 124 and the flat block 142. For this purpose, the step adjustment block 144 is preferably a plate-shaped member with a groove 146 indented from the lower surface perpendicular to the direction of the thickness so as to be inserted into the bolt 141a fastened to the flat block 142. . Through this configuration, it becomes easy to mount and demount the step adjustment block 144 by inserting the groove portion 146 from the top of the bolt 141a to the bottom or pulling it out in the opposite direction. Of course, at this time, it is also possible to insert the groove 146 from the bottom of the bolt 141a or pull it out in the opposite direction, and it is also possible to insert the groove 146 from the side of the bolt 141a or pull it out in the opposite direction. With the bolt 141a inserted into the groove 146, the step adjustment block 144 is in close contact between the flat block 142 and the back surface 124c of the second intermediate die block 124, so there is no risk of it falling off during use. does not exist.

There may be a plurality of bolts 141a and 141b fastened to the flat block 142 along the horizontal or vertical direction of the flat block 142. In this case, the step adjustment block 144 may be fitted into one or more bolts 141a. In this embodiment, the step adjustment block 144 is provided to have a size corresponding to each bolt 141a. The size (for example, horizontal length LL and vertical length VL) of the step adjustment block 144 can be changed.

After inserting the groove 146 into the bolt 141a, the center of gravity of the groove 146 is adjusted so that the step adjustment block 144 does not rotate in place even if the bolt 141a is not tightened. It is desirable to design it to be stable. The groove portion 146 may be formed by digging deep so that the bolt 141a can be inserted into the groove portion 146 and sufficiently accommodated. For example, the depth DL of the groove 146 may be a depth that allows the groove 146 to be formed up to the middle of the vertical length VL of the step adjustment block 144. The vertical length VL of the step adjustment block 144 and the depth of the groove portion 146 so that the step adjustment block 144 does not invade the first intermediate die block 122 while the groove portion 146 is inserted into the bolt 141a. DL should be reflected when designing.

A cross section of the fixed block 140 that passes through both the step adjustment block 144 and the reference plane 142a may include a first cross section and a second cross section extending perpendicularly from the first cross section. For example, it has an 'ㄱ' or 'L' shape. Since the flat block 142 and the step adjustment block 144 have a simple block shape, processing is not cumbersome and precise processing is possible. In addition, in this way, like the die blocks 110, 124, and 130, the edges of the fixed block 140 are formed at right angles, so there is a right angle in the cross section, and a vertical or horizontal plane can be used as the reference surface. Because it is easy to manufacture and handle, precision is guaranteed. In addition, when fastening this fixing block 140 in a state where the lower die block 110, the middle die block 120, and the upper die block 130 are combined, the facing parts will support each other with a high degree of surface contact. Because it can be fastened, fixation and retention are very excellent.

Multi-slot die coaters can usually be manufactured from SUS material. In general, liquid leakage easily occurs at the joint surface of the SUS assembly, so leakage is suppressed by placing a rubber ring or other soft material between the components to seal them. However, this sealing method is not suitable for controlling a uniform assembly shape (for example, assembly deviation of less than 10㎛), so it is difficult to apply to a multi-slot die coater.

For this reason, in a multi-slot die coater, die blocks processed with very high precision (straightness, flatness ±5㎛) must be bolted and assembled. Since liquid leakage must be prevented, bolt fastening requires high pressure of approximately 200 to 350 N. However, during such high-pressure bolt fastening, a slight imbalance in stress may occur, which may cause deformation of the block die, and the pressure of the coating liquid supplied during coating may also cause deformation or distortion of the die block. By combining the flat block 142 and the step adjustment block 144, the cross section includes a first cross section and a second cross section extending vertically from the first cross section, for example, an 'ㄱ' shape or The fixing block 140 having an 'L' shape has a structure that can withstand such high-pressure bolt fastening.

In this embodiment, the fixing block 140 couples the first intermediate die block 122 and the second intermediate die block 124. In addition, the step adjustment block 144 is mounted between the flat block 142 and the back surface 124c of the second intermediate die block 124 so that the step adjustment block 144 is in close contact with the rear surface 124c of the second intermediate die block 124. As a result, a step is formed between the rear surfaces 122c and 124c of the two die blocks 122 and 124 coupled to the fixed block 140. Here, since the size of the step corresponds to the thickness h of the step adjustment block 144, the step is adjusted between the back surfaces 122c and 124c of the two die blocks 122 and 124 by adjusting the thickness h of the step adjustment block 144. can be adjusted. The step formed between the back surfaces 122c and 124c of the two die blocks 122 and 124 is the first middle die lip 121a and the second middle die lip 121b, which are the front ends of each die block 122 and 124. ), so it affects the coating gap.

Step adjustment by installing and dismounting the step adjustment block 144 is an on/off method. When the step adjustment block 144 is mounted, a step is formed. When the step adjustment block 144 is removed, there is no step. Usually, the range of coating gap adjustment required when coating an active material slurry is very fine, approximately 10㎛ to 300㎛. It is very difficult to adjust the coating gap to an accurate target value by changing the fastening force of the bolt 141 or moving the die blocks to artificially adjust the coating gap. According to the present invention, various types of step adjustment blocks 144 with a fixed thickness h within the range of 10㎛ to 300㎛ are provided, and the determined step can be turned on/off by attaching or demounting the step adjustment block 144. This improves the control precision of the coating gap.

An appropriate coating gap range can be determined depending on the type of active material slurry. In the present invention, various types of step adjustment blocks 144 with appropriate thickness are provided and the process is performed by replacing them with the step adjustment blocks 144 necessary for each production process, so that each active material slurry can be used in order to use various active material slurries. Even if you do not have a dedicated multi-slot die coater, you can use the multi-slot die coater for general purposes. In addition, without the need to dismantle the bolt 141 coupled to the flat block 142, the desired coating gap can be created by selecting the step adjustment block 144 with the desired thickness and inserting it into the bolt 141. It can be implemented. In addition, even if there is dispersion in the active material slurry, it is possible to quickly respond to such dispersion by immediately replacing only the step adjustment block 144 portion to adjust the coating gap.

In this way, according to the present invention, there is no need to adjust the coating gap while disassembling and reassembling die blocks, which are structurally weak due to their thin thickness, and a simple operation of coupling the die blocks to the fixing block 140. By and through simple installation and removal of the step adjustment block 144, it is possible to always maintain a constant coating gap. In addition, the fixed block 140 is clearly effective in controlling a uniform gap in the width direction through the large surface contact of the block.

As shown in FIG. 6, as another example of the step adjustment block 144, a handle portion 148 used for mounting and dismounting may be provided on the upper surface of the plate-shaped member. The handle portion 148 may be a portion that protrudes and extends outward from one side of the step adjustment block 144. Preferably, the handle portion 148 is formed opposite the groove portion 146. The operator can hold the handle 148 and insert the groove 146 of the step adjustment block 144 into the bolt 141 from top to bottom or pull it out conversely, making handling easy.

Meanwhile, a flat fixing part 140' fastened to the rear surface 130c of the upper die block 130 and the rear surface 124c of the second intermediate die block 124 with a bolt 141 and a first intermediate die block ( It may further include a flat fixing part 140 "fastened to the rear surface 122c of the 122) and the rear surface 110c of the lower die block 110 with a bolt 141. The fixing block 140 is shown in FIG. 7 As shown, several may be provided along the width direction of the multi-slot die coater 100. Bolts 141a and 141b are fastened to the fixing block 140, and through this, the lower die (A) and the middle die are connected. (B) are assembled together. The flat fixing part 140' may be provided between the two fixing blocks 140. A bolt 141 is fastened to the flat fixing part 140', through which The upper die block 130 and the second middle die block 124 are assembled together. As another example, the fixing block 140 may be provided between two flat fixing parts 140'. Flat fixing parts ( 140"), a bolt 141 is fastened, and through this, the first middle die block 122 and the lower die block 110 are assembled together. As another example, the fixing block 140 may be provided between two flat fixing parts 140". The fixing block 140 has a clear effect of controlling the gap in the width direction uniformly through the large surface contact of the block. do.

The assembly sequence may be for example: First, the upper die (B) is assembled by assembling the upper die block 130 and the second intermediate die block 124 by fastening the flat fixing part 140' and the bolt 141. Then, the lower die (A) is assembled by assembling the first middle die block 122 and the lower die block 110 by fastening the flat fixing part 140" and the bolt 141. Next, the flat block ( 142) and bolts 141a and 141b to assemble the second intermediate die block 124 and the first intermediate die block 122, thereby assembling the lower die (A) and the upper die (B). Appropriate coating If it is determined that it is necessary to form a step between the back surfaces 124c and 122c of the second intermediate die block 124 and the first intermediate die block 122 for the gap, the flat block 142 and the second intermediate die block After dismantling the bolt (141a) connecting (124), insert the step adjustment block 144 between the flat block 142 and the second intermediate die block 124. Then, reinstall the bolt (141a). While fastening the flat block 142 and the second intermediate die block 124, the step adjustment block 144 is fixed therebetween.

Alternatively, it is also possible to mount the step adjustment block 144 without loosening the bolt 141a. When assembling the second intermediate die block 124 and the first intermediate die block 122 by fastening the flat block 142 and the bolts 141a and 141b, the level difference adjustment block 144 can be mounted. Tighten the bolt (141a) with a tolerance. That is, the bolt 141a is tightened with sufficient margin. If it is determined that it is necessary to form a step between the back surfaces 124c and 122c of the second intermediate die block 124 and the first intermediate die block 122 for an appropriate coating gap, the flat block 142 and the second intermediate die block 122 Without dismantling the bolt 141a connecting the die block 124, insert the step adjustment block 144 while inserting the groove 146 into the bolt 141a from the top of the bolt 141a or from the side to the inside. Put it in. When disassembling the assembled state, follow the reverse order. That is, the step adjustment block 144 is first separated, then the bolts 141a and 141b are loosened to separate the flat block 142.

There may be cases where it is judged necessary to form a step from the time of assembly. In such a case, when assembling the second intermediate die block 124 and the first intermediate die block 122 by fastening the flat block 142 and the bolts 141a and 141b, the step adjustment block 144 is used from the beginning in advance. Just fasten the bolts 141a and 141b together with the flat block 142.

Figure 8 is a modified example of Figure 7. Referring to FIG. 8, two bolts per die block are fastened perpendicularly to the coupling surface of the second intermediate die block 124 and the first intermediate die block 122, so that the second intermediate die block 124 has two bolts. Two bolts 141a are fastened and two bolts 141b are fastened to the first intermediate die block 122. At this time, the depth of the groove 146 of the step adjustment block (see 144 in FIG. 6) is long enough to fit into the two bolts 141a.

In this way, the step adjustment block 144 has an area of thickness h formed throughout the horizontal and vertical lengths of the step adjustment block 144, except for the groove portion 146 around the bolt 141a into which it is inserted. . Therefore, it is possible to secure a sufficient contact area between the flat block 142 and the second intermediate die block 124, and there is an effect of forming a level difference evenly. In addition, the level difference adjustment block 144 is provided with a bolt ( 141a) It is not divided into several parts around it, but is itself a monolithic part. In other words, it is an integrated, seamless part. In this way, not only does the accuracy improve when assembling the flat block 142 and the step adjustment block 144, but it is also structurally strong, so it has excellent stability against external impacts during handling and use. If the step adjustment block 144 is not a monolithic part but consists of two or more separate parts, the alignment of each part must be considered when mounting around the bolt 141a, and the total tolerance between each part increases after assembly.

The advantage of the integrated step block 144 is more noticeable when the part where the step adjustment block 144 is fastened is inclined. If the joining surface of the second intermediate die block 124 and the first intermediate die block 122 is inclined with respect to the horizontal plane, it is very difficult to assemble the die blocks while considering the alignment of separate parts rather than integrated parts. do. The step adjustment block 144 according to the present invention is integrated and can be easily mounted and removed even on inclined parts.

According to the configuration of the flat fixing part 140', the upper die block 130 and the second intermediate die block 124 are fixedly coupled to each other, and according to the configuration of the flat fixing part 140', the first middle die block 130 and the second intermediate die block 124 are fixedly coupled to each other. The die block 122 and the lower die block 110 are fixedly coupled to each other. Therefore, the upper die block 130 and the second intermediate die block 124 move as one piece, and the first intermediate die block 122 and the lower die block 110 move as one piece. The die block 110 can move integrally, that is, the first flat surface formed on the upper part of the lower die A (in this embodiment, the first surface 122a of the first intermediate die block 122) and The second flat surface formed at the bottom of the upper die (B) (in this embodiment, the second surface (124b) of the second intermediate die block 124) contacts each other to form a sliding surface, and the upper die (B) and the lower die (A) are installed so that one side slides along the sliding surface to enable relative movement in the horizontal direction.

The multi-slot die coater 100 according to an embodiment of the present invention uses the lower die (A) and/or the upper die when a change in the relative position between the lower discharge port (101a) and the upper discharge port (102a) is required. It can be easily adjusted by sliding movement of (B), and there is no need to disassemble and reassemble each die block (110, 120, 130), which can greatly improve fairness. The relative positions of the upper discharge port (102a) and the lower discharge port (101a) are adjusted, and the fixing block 140 is coupled between the lower die (A) and the upper die (B), so that the coating gap is determined accordingly. Also, if level adjustment is necessary, the level difference adjustment block 144 can be mounted or removed. Therefore, the inconvenience of manually dismantling the die blocks 130, 122, 124, and 110 and adjusting their positions to adjust the coating gap can be greatly reduced.

In this embodiment, the length of the upper die (B) (e.g., the horizontal distance from the back surface 130c of the upper die block 130 to the upper die lip 131) is the length of the lower die (A) (e.g. The horizontal distance from the back surface 110c of the lower die block 110 to the lower die lip 111 is shown as an example. In this state, when the back of the upper die (B) is stepped with respect to the back of the lower die (A) as shown in FIG. 3, the lower die lip 111, the first and second middle die lips 121a, 121b, and The upper die lip 131 can be positioned on the same straight line. In this case, various films can be applied by moving the entire multi-slot die coater 100 forward or backward with respect to the substrate 300.

According to the present embodiment described above, a step is formed between the back surfaces of the upper die (B) and the lower die (A) through the fixing block 140 including the step adjustment block 144. That is, after joining the die blocks by fastening the bolts 141a and 141b to the flat block 142, if it is necessary to adjust the level between the die blocks, a level adjustment block 144 of an appropriate thickness h to create the level is installed. A step can be created by additionally installing it between the flat block 142 and the die block. In this embodiment, the step adjustment block 144 is mounted between the second intermediate die block 124 and the flat block 142, and the first intermediate die block 122 is coupled to the flat block 142, By combining, a step corresponding to the thickness h of the step adjustment block 144 may be naturally formed between the back surfaces 124c and 123c of the die blocks 124 and 122. In this way, the distance between the first and second intermediate die lips 121a and 121b, which are the leading ends of the die blocks 124 and 122, and the substrate 300, that is, the coating gap, can be maintained at a desired level at all times, and the die block Since it is fixed between the fields 124 and 122, the coating gap once determined is maintained without any change during the process.

According to the present invention, even considering that the die block is deformed by the pressure of the discharged active material slurry, it is possible to maintain a uniform (±2%) coating gap, thereby uniformly controlling the coating amount and the resulting coating quality. . Therefore, it is possible to obtain uniform quality coated products, especially electrodes for secondary batteries, by using a multi-slot die coater with a uniform coating gap.

In this way, according to the present invention, even if the discharge pressure of the active material slurry increases, the effect of maintaining the once adjusted coating gap is excellent. This has the effect of securing coating fairness and reproducibility.

Using such a multi-slot die coater, it is possible to uniformly form a coating layer, especially an active material layer, with a desired thickness. Preferably, simultaneous coating of two types of active material slurries is possible, resulting in excellent effects in both performance and productivity.

In particular, by providing a plurality of fixing blocks 140 with step adjustment blocks 144 in the width direction of the multi-slot die coater 100, precise control is possible without deviation of the coating gap even in the width direction.

In this way, by using the multi-slot die coater of the present invention, when manufacturing electrodes of secondary batteries by applying active material slurry on the current collector while traveling, uniform application is possible even under high-speed traveling or long-width application conditions. There is an advantage.

Meanwhile, in this embodiment, the case of applying the coating liquid in two layers or the case of pattern coating by alternately supplying the coating liquid was described as an example, but it can also be applied in the case of simultaneous application of three or more layers by providing three or more slots. You will know what is possible without further explanation. You will know without going into detail that more than 4 die blocks are needed to have 3 or more slots.

Next, other embodiments of the present invention will be described with reference to FIGS. 9 to 14. The same member numbers as those in the above-described embodiment indicate the same members, and redundant descriptions of the same members will be omitted and the description will focus on the differences from the above-described embodiment.

In the multi-slot die coater shown in FIG. 9, the flat block 142 of the fixed block 140 shown and explained in FIG. 3 extends to the rear surface 110c of the lower die block 110, so that the flat block 142 It is shown that it is also coupled to the back surface 110c of the lower die block 110. In this case, the second intermediate die block 124 and the first intermediate die block 122 are coupled through the flat block 142, and a step is created between the back surfaces 124c and 122c by the step adjustment block 144. In addition to forming the lower die block 110 to the flat block 142, the rear surface 122c of the first intermediate die block 122 and the rear surface 110c of the lower die block 110 are connected to each other. It may not include a flat fixing part (see 140" in FIG. 7) fastened with bolts 141, and, if necessary, may further include a flat fixing part in addition to the fixing block 140.

In the multi-slot die coater shown in FIG. 10, the flat block 142 of the fixed block 140 shown and explained in FIG. 3 extends to the rear surface 130c of the upper die block 130, so that the flat block 142 This shows that it is also coupled to the back surface 130c of the upper die block 130. In this case, the second intermediate die block 124 and the first intermediate die block 122 are coupled through the flat block 142, and a step is created between the back surfaces 124c and 122c by the step adjustment block 144. In addition to forming the upper die block 130 to the flat block 142, the rear surface 130c of the upper die block 130 and the rear surface 124c of the second intermediate die block 124 It may not include a flat fixing part (see 140' in FIG. 7) fastened with bolts 141, and, if necessary, may further include a flat fixing part in addition to the fixing block 140.

Unlike the multi-slot die coater 100 of FIG. 3, the multi-slot die coater shown in FIG. 11 has a step D formed between the lower discharge port 101a and the upper discharge port 102a. In the case where the length of the upper die (B) is the same as the length of the lower die (A), the upper die lip 131 and the second middle die lip are formed by the thickness h of the step adjustment block 144 of the fixing block 140. (121b) may advance toward the substrate 300 rather than the first middle die lip (121a) and the lower die lip (111). Therefore, the step D between the lower outlet 101a and the upper outlet 102a may be equal to the thickness h of the step adjustment block 144 of the fixed block 140. When a step D is provided between the lower discharge port 101a and the upper discharge port 102a, the lower discharge port 101a and the upper discharge port 102a are disposed at positions spaced apart from each other along the horizontal direction, and the upper discharge port 102a ), there is no concern that the second coating liquid 60 discharged from the lower discharge port 101a will flow into the lower discharge port 101a, or the first coating fluid 50 discharged from the lower discharge port 101a will flow into the upper discharge port 102a.

That is, the coating liquid discharged through the lower discharge port (101a) or the upper discharge port (102a) is blocked by the surface forming the step formed between the lower discharge port (101a) and the upper discharge port (102a), so there is no risk of it flowing into the other discharge port. , This allows a more smooth multilayer active material coating process to proceed.

In this way, the multi-slot die coater 100 has two discharge ports (101a, 102a) and can be used to form two active material layers on the current collector, and these two discharge ports (101a, 102a) are used to form the active material layer. For smooth coating of slurry, they can be spaced apart from each other along the horizontal direction and placed back and forth. A separate device may be used to adjust the shape of the multi-slot die coater 100, or an operator may manually create relative movement of the lower die (A) and upper die (B).

For example, while the lower die (A) is left motionless, the upper die (B) is moved forward along the sliding surface by a certain distance (D) in the same direction as the discharge direction of the active material slurry to open the lower discharge port (101a). A step may be formed between and the upper discharge port (102a). And this step is maintained by fastening the fixing block 140. The width D of the step formed in this way can be determined within the range of approximately several micrometers to several millimeters, and can be determined depending on the thickness of the active material layer formed on the current collector. For example, as the thickness of the active material layer to be formed on the current collector becomes thicker, the width (D) of the step may increase.

In FIG. 12, the point where a step is formed between the back of the upper die (B) and the back of the lower die (A) is the same as the multi-slot die coater 100 of FIG. 3, but the step adjustment block of the fixing block 140 ( The only difference is that 144) is in close contact with the back surface 120c of the first intermediate die block 122 rather than the back surface 124c of the second intermediate die block 124. In this way, when a step is formed between the rear surfaces 124c and 122c of the two die blocks 124 and 122, the step adjustment block 144 of the fixing block 140 is positioned at one of the two die blocks 124 and 122. All you have to do is adhere it to the back of a single die block. The die block whose back is in close contact with the step adjustment block 144 advances toward the substrate (see 300 in FIG. 3).

In this example, if the lengths of the upper die (B) and the lower die (A) are the same, contrary to the case of FIG. 10, the lower discharge port (101a) advances toward the substrate 300 rather than the upper discharge port (102a) A step may be formed between (101a) and the upper discharge port (102a). At this time, the lower die lip 111 on the downstream side in the traveling direction of the substrate 300 is closer to the substrate 300 than the upper die lip 131 on the upstream side. Due to this feature, the first coating liquid 50 discharged from the lower discharge port 101a can be pressed to the lower die lip 111, and the thickness can be uniformly adjusted by expanding the first coating liquid 50 in the width direction. there is.

FIG. 13 is similar to FIG. 12 , except that the flat block 142 of the fixing block 140 extends to the rear surface 110c of the lower die block 110, so that it also extends to the rear surface 110c of the lower die block 110. This is an example showing that they can be combined.

14 is also similar to FIG. 12, except that the flat block 142 of the fixing block 140 extends to the rear surface 130c of the upper die block 130, so that the rear surface 130c of the upper die block 130 This is an example showing that it can also be combined.

Therefore, the slot die coater 100 according to the present invention allows the sliding of the lower die and/or the upper die when the relative position between the lower discharge port and the upper discharge section needs to be changed depending on the thickness of the active material layer coated on the current collector. It can be easily adjusted by moving, and fairness can be greatly improved by eliminating the need to disassemble and reassemble each die block like in a conventional slot die coater. In particular, through the simple operation of fastening the fixed block 140. A big advantage is that it is possible to set and maintain the level difference to achieve the desired coating gap.

As described above, although the present invention has been described with limited examples and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following will be understood by those skilled in the art to which the present invention pertains. Of course, various modifications and variations are possible within the scope of equivalence of the claims to be described.

Meanwhile, terms indicating directions such as up, down, left, and right are used in this specification, but these terms are only for convenience of explanation and may vary depending on the location of the object or the location of the observer, etc. It is obvious to those skilled in the art.

100: Multi-slot die coater A: lower die
B: Upper die 101: Lower slot
102: upper slot 110: lower die block
111: lower die lip 112: first manifold
113: first spacer 120: middle die block
121a: first intermediate die lip 121b: second intermediate die lip
122: first intermediate die block 124: second intermediate die block
130: upper die block 131: upper die lip
132: second manifold 133: second spacer
140: Fixed block 140', 140": Flat type fixed part
141: bolt 142: flat block
144: Step adjustment block 146: Groove
200: coating roll 300: base material

Claims (15)

A multi-slot die coater comprising a lower die having a lower slot and an upper die having an upper slot disposed on top of the lower die,
A first flat surface formed at the top of the lower die and a second flat surface formed at the bottom of the upper die contact each other to form a sliding surface, and one side of the upper die and the lower die slides along the sliding surface. It is installed to enable relative movement in the horizontal direction.
The back surfaces of the lower die and the upper die, which are surfaces opposite to the front ends, further include a fixing block that is bolted to the back surfaces of the lower die and the upper die to couple the lower die and the upper die,
The fixing block is detachable between a flat block having a reference plane in close contact with the back of one of the lower die and the upper die, and the flat block and the back of the other of the lower die and the upper die. It includes a step adjustment block having a thickness such that a step is formed between the back surfaces of the two dies coupled to the fixing block, and the step adjustment block is capable of being mounted and demounted without the need to dismantle the state in which the bolt is coupled to the flat block. Features a multi-slot die coater. The method of claim 1, wherein the lower die includes a lower die block and a first intermediate die block disposed on an upper part of the lower die block and forming the lower slot between the lower die block and the lower die block,
The upper die includes a second intermediate die block installed on the first intermediate die block, and an upper die block disposed on an upper part of the second intermediate die block to form the upper slot between the second intermediate die block and the second intermediate die block. A multi-slot die coater comprising a. The method of claim 2, wherein the flat block is for coupling between the first intermediate die block and the second intermediate die block, and the step adjustment block is located on the rear surface of the second intermediate die block or the rear surface of the first intermediate die block. A multi-slot die coater characterized in that it is in close contact with. The multi-slot die coater according to claim 3, wherein the flat block extends to the rear surface of the lower die block and is coupled to the rear surface of the lower die block. The multi-slot die coater of claim 3, wherein the flat block extends to the rear surface of the upper die block and is coupled to the rear surface of the upper die block. The method of claim 3, wherein a flat fixing part is bolted to the back of the upper die block and the back of the second intermediate die block, or is bolted to the back of the first middle die block and the back of the lower die block. A multi-slot die coater further comprising a flat fixture. The multi-slot die coater according to claim 2, wherein the step adjustment block is in close contact with the rear surface of the second intermediate die block and the length of the upper die is shorter than the length of the lower die. 3. The method of claim 2, wherein the lower die block, the first middle die block, the second middle die block, and the upper die block each have a lower die lip, a first middle die lip, a second middle die lip, and an upper die block forming the tip portion thereof. Equipped with a die lip,
A multi-slot die coater, wherein the lower die lip, first middle die lip, second middle die lip, and upper die lip are located on the same straight line. 3. The method of claim 2, wherein the lower die block, the first middle die block, the second middle die block, and the upper die block each have a lower die lip, a first middle die lip, a second middle die lip, and an upper die block forming the tip portion thereof. Equipped with a die lip,
A lower discharge port communicating with the lower slot is formed between the lower die lip and the first middle die lip, and an upper discharge port communicating with the upper slot is formed between the second middle die lip and the upper die lip,
The multi-slot die coater extrudes and applies the active material slurry through at least one of the lower slot and the upper slot on the continuously running surface of the substrate,
A multi-slot die coater, characterized in that a step is formed between the lower discharge port and the upper discharge port. The multi-slot die coater according to claim 1, wherein a plurality of fixed blocks are provided in the width direction of the multi-slot die coater. The multi-slot die according to claim 1, wherein the cross section of the fixed block that passes through both the step adjustment block and the reference plane includes a first cross section and a second cross section extending vertically from the first cross section. cotter. The multi-slot die coater according to claim 1, wherein the step adjustment block is a plate-shaped member having a groove recessed from the lower surface perpendicular to the direction of the thickness to be inserted into a bolt fastened to the flat block. The multi-slot die coater according to claim 12, wherein the upper surface of the plate-shaped member is provided with a handle for use in mounting and dismounting. The multi-slot die according to claim 12, wherein a plurality of bolts are fastened to the flat block along the horizontal or vertical direction of the flat block, and the step adjustment block is fitted into one or more of the bolts. cotter. The multi-slot die coater according to claim 14, wherein the step adjustment block has a size corresponding to each bolt.

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