JP2003053245A - Coating apparatus and coating method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a coating apparatus capable of performing stable coating without generating a flaw in a coating film even if a web is allowed to run at a high speed, and a coating method using the same. SOLUTION: The coating apparatus is equipped with a forward rotary bar rotated around its axial line in the same direction as the running direction of a continuously running strip-like web while being in contact with the web, a liquid supply flow channel for supplying a coating solution to the gap between the web and the upstream side of the forward rotary bar at the coating of the web with the coating solution and an amount control means arranged on the downstream side of the forward rotary bar with respect to the running direction of the web and controlling the amount of the coating solution applied to the web by the forward rotary bar so as to obtain a predetermined coating thickness. The coating method is also disclosed.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a coating device and a coating method, and more particularly, to a bar coater capable of performing stable coating even when a coating liquid is applied by running a web at a high speed. And a coating method.

[0002]

2. Description of the Related Art A lithographic printing plate usually has at least one surface of a web of pure aluminum or an aluminum alloy, which is sharpened, and an anodic oxide film is formed on the surface to form a support web. It is manufactured by applying a photosensitive layer forming liquid or a heat sensitive layer forming liquid to the surface of the support web on the side of which is sharpened and drying it to form a photosensitive or heat sensitive plate-making surface.

A bar coater is generally used to apply a coating liquid such as a photosensitive layer forming liquid and a heat sensitive layer forming liquid to a belt-shaped web such as the support web.

Conventionally, as the bar coater, a bar that rotates in the same direction or in the opposite direction to the running direction of the web while contacting the lower surface of the web that is continuously running, and when the web is running, The coating liquid is discharged to the upstream side (hereinafter, simply referred to as “upstream side”) of the bar with respect to the running direction of the web to form a coating liquid reservoir, and the coating liquid is applied to the lower surface of the web. The one provided with a coating section has been generally used.

The bar coater is provided on the upstream side of the bar in the vicinity of the bar and at the upper end portion thereof on the downstream side with respect to the traveling direction of the web (hereinafter, simply "downstream side"). The first dam plate has a thickness of 0.1 to 1 mm, and the upper end of the first dam plate is bent toward the bar and the top has a length of 0.1 to 1 mm. SLB type bar coater having a flat surface (Japanese Utility Model Application No. 63-126213), and a first dam plate and a bar formed so that the thickness of the upper end portion becomes thinner toward the downstream side, A PBS type bar coater (Japanese Patent Publication No. Sho 58-004589) having a second dam plate on the downstream side of the bar has been generally used.

[0006]

However, when the traveling speed of the carrier web is increased, an entrained air film, which is a film of air traveling along the carrier web, that is, entrained air, is formed on the surface of the carrier web. Will be formed.

In both the SLB type bar coater and the PBS type bar coater, when an entrained air film is formed on the surface of the support web, the entrained air film is applied by the support web to the coating liquid in the coating section. It is said that the coating film of the coating liquid formed on the surface of the support web when brought into the pool causes defects such as film breakage, ripple streaks, and coating unevenness, and the coating liquid cannot be stably coated. There was a problem.

The present invention provides a coating apparatus capable of performing stable coating without causing the above-mentioned various defects in the coating film even when the coating such as the support web is run at a high speed. The purpose is to provide a coating method.

[0009]

According to a first aspect of the present invention, a forward rotation bar that rotates in the same direction as the running direction of the web around an axis while contacting a continuously running strip-shaped web. And, at the time of applying the coating liquid to the web, a liquid supply channel that supplies the coating liquid between the web and the upstream side of the forward bar with respect to the traveling direction of the web, and the web. A metering unit that is disposed on the downstream side of the forward rotation bar with respect to the traveling direction and that adjusts the coating liquid applied to the web by the forward rotation bar so as to have a predetermined coating thickness. The present invention relates to a coating device characterized by being provided.

In the coating apparatus, the coating liquid supplied from the liquid supply flow path is caused to collide with the web by the forward rotation bar so that entrained air is trapped between the web and the coating liquid. To prevent. Since the coating liquid is excessively applied to the web by the forward rotation bar, the excessive amount of the coating liquid is adjusted by scraping the adjusting liquid to a predetermined coating thickness. Measure.

Therefore, according to the coating apparatus, it is possible to effectively prevent coating unevenness caused by entrainment of entrained air when the coating liquid is coated by running the web at a high speed.

The rotation speed of the forward rotation bar may be such that it does not wear unevenly due to friction with the web. Therefore, the forward rotation bar may be a same-speed rotation bar that rotates at the same peripheral speed as the traveling speed of the web, that is, the same speed, and rotates at a peripheral speed different from the traveling speed of the web, that is, a different speed. It may be a different speed rotation bar.

The coating apparatus can be used not only for producing a lithographic printing plate, but also for producing a photosensitive material such as a photographic film, a magnetic recording material such as a recording tape, and a coated metal thin plate such as a color iron plate. .

Therefore, as the web, in addition to the support web described in the section of the prior art, a lithographic printing original plate web in which a photosensitive or heat-sensitive plate-making surface is formed on the surface of the support web on the side of sharpening, Made of metal, plastic, or paper, such as photographic film base material, photographic paper baryta paper, recording tape base material, video tape base material, floppy (R) disk base material, etc. A flexible base material or the like can be used.

Examples of the coating solution include solutions used for coating on the web and drying to form a film. Specifically, in addition to the photosensitive layer forming solution and the heat sensitive layer forming solution, , An intermediate layer forming liquid for forming an intermediate layer on the surface of the support web to improve the adhesion of the plate making layer, and polyvinyl used for forming an oxidation protective film for protecting the plate making surface of the lithographic printing original plate web from oxidation. Aqueous alcohol solution, colloidal liquid for photographic film used for forming photosensitive layer in photographic film, colloidal liquid for photographic paper used for forming photosensitive layer of photographic paper, recording tape, video tape , A magnetic layer forming liquid used for forming a magnetic layer of a floppy (R) disk, and various paints used for coating metal.

Examples of the metering means include a reversing bar which will be described later, as long as it has a function of scraping off the coating liquid applied to the web by the normalizing bar and adjusting it to a specified amount. However, it is not limited to the reversing bar.

According to a second aspect of the present invention, the metering means is arranged in parallel with the forward rotation bar, and is in contact with the web while being in a direction opposite to the running direction of the web. The present invention relates to a coating device provided with a reversing bar that rotates in a vertical direction.

In the coating apparatus, the reverse rotation bar is provided on the downstream side (hereinafter, simply referred to as “downstream side”) of the forward rotation bar with respect to the traveling direction of the web. Rotate in the opposite direction.

Therefore, the coating liquid applied to the web by the forward rotation bar is scraped to a prescribed amount by the reverse rotation bar and is metered.

The third aspect of the present invention relates to a coating apparatus having a downstream side liquid supply flow path for supplying the coating liquid between the forward rotation bar, the reverse rotation bar and the web.

In the coating device, the coating liquid is supplied between the forward rotation bar, the reverse rotation bar and the web by the downstream side liquid supply flow path to form a coating liquid reservoir. Therefore, even when the entrained air cannot be sufficiently removed in the forward rotation bar, the entrained air is pushed back to the upstream side by the liquid pressure of the coating liquid pool, so that the entrained air is applied to the coating surface of the coating liquid. There is no defect caused by. Further, even when the coating liquid applied in the forward rotation bar is corrugated along the direction perpendicular to the traveling direction of the web due to the forward rotation bar, and coating unevenness called ripple occurs, the web remains When passing through the coating liquid pool, the ripples are leveled and disappear in the coating liquid pool, so that in the web,
It is possible to prevent the generation of streak-like defects due to the ripple.

The invention according to claim 4 relates to a coating apparatus in which the downstream side liquid supply passage is a slit-shaped liquid supply passage formed in a slit shape parallel to the priority bar and the reverse bar. .

In the coating apparatus, since the volume of the coating liquid reservoir can be reduced, even if the flow rate of the coating liquid supplied from the downstream liquid supply passage to the coating liquid reservoir is small,
A high liquid pressure can be obtained in the coating liquid reservoir. Therefore, in the forward rotation bar, the entrained air cannot be sufficiently removed, and even when a ripple occurs, the coating liquid can be uniformly applied, which is so-called avalanche-shaped application unevenness due to the entrained air. The occurrence of avalanche unevenness can be effectively prevented.

The invention according to claim 5 relates to a coating apparatus in which the forward rotation bar is a different speed rotation bar which rotates at a peripheral speed different from the traveling speed of the web.

In the coating apparatus, the rotation speed of the forward rotation bar can be set within a range in which entrainment of entrained air does not occur in the web regardless of the traveling speed of the web. The entrainment of the entrained air can be prevented at the traveling speed.

The invention according to claim 6 relates to a coating apparatus in which the forward rolling bar is a smooth bar having a smooth surface.

The coating apparatus is characterized in that the forward rotation bar can be manufactured at low cost.

The invention according to claim 7 relates to a coating apparatus in which the forward rolling bar is a grooved bar in which grooves are formed on the surface at regular intervals.

In the coating apparatus, since the amount of the coating liquid deposited on the forward rotation bar is larger, the coating unevenness caused by the entrained air can be more effectively prevented.

According to an eighth aspect of the present invention, between the continuously running belt-shaped web and a forward rotation bar that rotates in the same direction as the running direction of the web while being in contact with the web, the web is provided. The coating liquid is supplied from the upstream side with respect to the traveling direction of to apply the coating liquid to the web, and then the metering is provided on the downstream side of the forward rotation bar with respect to the traveling direction of the web. A coating method, wherein the means adjusts the coating liquid applied to the web by the forward rotation bar so as to have a predetermined coating thickness.

In the coating method, the coating liquid supplied from the liquid supply flow path is caused to collide with the web by the forward rotation bar so that entrained air is trapped between the web and the coating liquid. To prevent. The coating solution excessively coated on the web by the forward rotation bar is scraped off by the metering means or the like so that a predetermined coating thickness is obtained.

Therefore, the coating method can also effectively prevent coating unevenness due to entrainment of entrained air, as in the coating apparatus according to the first aspect.

[0033]

BEST MODE FOR CARRYING OUT THE INVENTION 1. Embodiment 1 FIG. 1 is a diagram showing the configuration of an example of a coating apparatus according to the present invention for coating a photosensitive layer forming liquid on the support web W.
Shown in.

As shown in FIG. 1, the coating apparatus 100 according to the first embodiment is in contact with the aluminum support web W traveling in the direction indicated by the arrow a, and is in the same direction as the conveyance direction a of the support web. The forward rotation bar 2 that rotates in the direction of the forward rotation bar 2, the reverse rotation bar 4 that is provided on the downstream side of the forward rotation bar 2 and that rotates in the direction opposite to the main conveyance direction a, and the top surface are in the traveling path of the support web W. A forward rotation bar support member 6 which is provided so as to face a certain traveling surface T and supports the forward rotation bar from below,
The reverse rotation bar support member 8 is provided adjacent to the forward rotation rotation bar support member 6 so that the top surface faces the traveling surface T, and supports the reverse rotation bar 4 from below.

Both the forward rotation bar 2 and the reverse rotation bar 4 are provided along the width direction of the coating apparatus 100. Here, the width direction of the coating device 100 is a direction perpendicular to the running direction a of the support web W. Each of the forward rotation bar 2 and the reverse rotation bar 4 may be a smooth bar whose surface is finished to be smooth, or a grooved bar in which grooves are circumferentially provided on the surface at regular intervals, Further, it may be a wire bar in which fine wires such as stainless steel are wound around the surface in a circumferential direction at regular intervals or densely.

Forward bar support member 6 and reverse bar support member 8
A slit-shaped downstream liquid supply flow path 10 is formed between and in the width direction of the coating device 100. Reverse bar 4
Corresponds to the metering means in the coating apparatus of the present invention. When the photosensitive layer forming liquid is applied to the support web W,
The photosensitive layer forming liquid is supplied from the downstream side liquid supply flow path 10 toward the support web W, and the support web W and the forward rotation bar 2 are supplied.
A coating liquid pool A is formed in a space surrounded by the reverse rotation bar 4, the forward rotation bar support member 6, and the reverse rotation bar support member 8.

An upstream dam plate 12 extending toward the traveling surface T is provided on the upstream side of the normal rotation bar 2, and a normal space is provided between the normal rotation bar support member 6 and the upstream dam plate 12. A liquid supply passage 14 for supplying the photosensitive layer forming liquid is formed on the upstream side of the transfer bar 2.

Forward bar support member 6 and upstream dam plate 12
Is fixed on the upstream side base 16A forming the upstream side of the base 16 of the coating apparatus 100 via the substrate 18,
The reverse rotation bar support member 8 is fixed on the downstream side base 16B forming the downstream side of the base 16 of the coating apparatus 100.

The upstream side base 16A and the downstream side base 16B are integrally connected to each other via a plate-shaped connecting member 16C to form the base 16. A liquid supply passage 20 communicating with the downstream liquid supply passage 10 is formed between the coupling member 16C and the upstream base 16A.

[0040] near the upstream edge of the upstream base 16A is dam-shaped protrusions 16A ₂ which projects upward is formed. Among the photosensitive layer forming liquid supplied from the liquid supply channel 14, the upstream dam plate 12 has a J-shaped cross section between the dam-shaped projection 16A ₂ , the substrate 18, and the upstream dam plate 12. Upstream side coating liquid recovery flow path 22 for recovering what has overflowed beyond the upstream side
Are formed.

On the other hand, the reversing bar 4 is provided on the downstream side base 16B.
A downstream coating liquid recovery channel 24 is provided for receiving the photosensitive layer forming liquid overflowing to the downstream side.

The photosensitive layer forming liquid is supplied to the liquid supply passage 14 by the liquid supply pump P ₂ , and the downstream liquid supply passage 10 is exposed by the liquid supply pump P ₄ via the liquid supply passage 20. A layer forming liquid is supplied.

Above the transport surface T, the coating device 1 is provided upstream of the forward rotation bar 2 and downstream of the reverse rotation bar 4.
00, a pressing roller 26 and a pressing roller 28 for pressing the support web W running on the forward rotation bar 2 and the reverse rotation bar 4 are provided.

The operation of the coating apparatus 100 will be described below.

First, the photosensitive layer forming liquid is supplied from the liquid supply pump P ₂ through the liquid supply flow path 14 to the upstream side of the forward rotation bar 2, and at the same time, the downstream liquid supply flow path 10 is supplied from the liquid supply pump P _4. The coating liquid is supplied to the coating liquid reservoir A through the above.

In the forward rotation bar 2, the photosensitive layer forming liquid is applied to the support web W by scraping the photosensitive layer forming liquid and colliding it with the back surface of the support web W. The entrained air brought into the coating device 100 along with the back surface of the support web W is cut by the photosensitive layer forming liquid scraped up by the forward rotation bar 2 colliding with the support web. On the other hand, the support web W is excessively coated with the photosensitive layer forming liquid.

The support web coated with the photosensitive layer forming liquid in the forward rotation bar 2 then passes through the coating liquid reservoir A.

Since the liquid pressure of the photosensitive layer forming liquid supplied from the downstream liquid supply passage 10 is applied to the inside of the coating liquid reservoir A, the entrained air remains in the forward rotation bar 2 without being cut. Also in this case, the entrained air is pushed back to the upstream side by the hydraulic pressure. Further, even when a ripple is generated in the normal rotation bar 2, the ripple is evened out by the hydraulic pressure and disappears.

Support web W which has passed through the coating liquid reservoir A
Then contacts the reversing bar 4. As described above, the reverse rotation bar 4 rotates in the direction opposite to the traveling direction a of the support web W, so that the forward rotation bar 2 causes the support web W to rotate.
The photosensitive layer forming liquid excessively applied to the lower surface of the
Is scraped off to a predetermined coating thickness.

At least a part of the photosensitive layer forming liquid scraped off by the reversing bar 4 is pushed downstream by the liquid pressure of the photosensitive layer forming liquid supplied to the coating liquid reservoir A. The photosensitive layer forming liquid extruded on the downstream side exceeds the reverse rotation bar 4 and overflows on the downstream side. The image forming liquid overflowing on the reverse rotation bar 4 flows down toward the downstream coating liquid recovery flow path 24.

In the coating apparatus 100 according to the first embodiment, the downstream side liquid supply flow channel 10 is formed in a narrow slit shape, and the volume of the coating liquid reservoir A communicating with the downstream side liquid supply flow channel 10 is also large. small. Therefore, even if the liquid amount of the photosensitive layer forming liquid supplied from the liquid supply pump P ₄ is small, the liquid pressure between the normal rotation bar 2 and the reverse rotation bar 4 can be increased. Ripple disappears, and due to the entrained air that could not be completely removed in the forward rotation bar 2,
It is possible to effectively prevent the occurrence of avalanche unevenness.

2. Embodiment 2 FIG. 2 shows the configuration of another example of the coating apparatus according to the present invention for coating the support web W with the photosensitive layer forming liquid. 2, the same reference numerals as those in FIG. 1 denote the same elements as those shown in FIG.

As shown in FIG. 2, in the coating apparatus 102 according to the second embodiment, the forward rotation bar 2 and the reverse rotation bar 4 are
They are provided so as to be adjacent to each other with a downstream side liquid supply passage 30 sandwiched therebetween.

The forward rotation bar support member 32 for supporting the forward rotation bar 2 from below and the reverse rotation bar support member 34 for supporting the reverse rotation bar 4 from below respectively have the forward rotation bar 2 or the reverse rotation bar 4 on their top surfaces. Retaining groove-shaped recesses 32A and 34
Have A. The cross-sectional shape of the recesses 32A and 34A includes, for example, an arc and a V shape, but is not limited to these shapes. Between the forward rotation bar 2 and the reverse rotation bar 4, and between the forward rotation bar support member 32 and the reverse rotation bar support member 34, there is a downstream liquid supply passage 30 for supplying the photosensitive layer forming liquid to the coating liquid reservoir A. Has been formed. The downstream liquid supply passage 30 is connected to the liquid supply passage 20 at the lower end.

The coating device 102 has the same structure as the coating device 100 except for these points.

Even when the photosensitive layer forming liquid is applied to the support web W, as in the case of the coating apparatus 100, the photosensitive layer forming liquid scraped up by the forward rotation bar 2 collides with the support web. , Entrained air is cut, and forward bar 2
The entrained air that could not be cut in
Is pushed back to the upstream side. Further, even when a ripple is generated in the normal rotation bar 2, the ripple is evened out by the hydraulic pressure and disappears. Then, the photosensitive layer forming liquid excessively applied to the lower surface of the support web W by the forward rotation bar 2 is scraped off by the reverse rotation bar 4 to a predetermined coating thickness.

The coating device 102 has the same features as the coating device 100 according to the first embodiment.

3. Embodiment 3 FIG. 3 shows another example of a coating apparatus according to the present invention for coating a support web with a photosensitive layer forming liquid.

The coating apparatus 104 according to the third embodiment is shown in FIG.
As shown in FIG.
0, and a reversing bar coater 42 having a reversing bar 46 located on the downstream side of the forward bar coater 40. The forward bar coater 40 and the reverse bar coater 42 are both located below the traveling surface T of the support web W. Forward bar coater 4
0 above the traveling surface T between the 0 and the reverse rotation bar coater 42, when the support layer W is coated with the photosensitive layer forming liquid, the support web W is pressed against the forward rotation bar 44 and the reverse rotation bar 46 from above. The pressing roller 48 is provided.

The forward rotation bar coater 40 is positioned not only on the forward movement bar 44, but also on the forward movement bar support member 50 that supports the forward movement bar 44 from below, and on the upstream side of the forward rotation bar support member 50. An upstream side weir plate 52 extending vertically toward
The downstream side weir plate 54, which is located on the downstream side of the normal rotation bar support member 50 and extends in the vertical direction toward the traveling surface T, and the base 56 on which the normal rotation bar support member 50 is placed. .

An upstream liquid supply passage 58 for supplying a photosensitive layer forming liquid to the upstream side of the normal bar 44 is formed between the normal bar support member 50 and the upstream dam plate 52. Between the support member 50 and the downstream dam plate 54, a downstream liquid supply passage 60 for supplying the photosensitive layer forming liquid to the downstream side of the normal bar 44 is formed. Upstream side liquid supply flow path 58 and downstream side liquid supply flow path 60
And the lower part of the forward rotation bar support member 50 communicate with each other through the communication flow path 62. A liquid supply conduit 64 for supplying the photosensitive layer forming liquid is connected to the lower end of the upstream liquid supply passage 58.

The reversing bar coater 42 is located on the upstream side of the reversing bar supporting member 66, which supports the reversing bar 46 from below, and on the upstream side of the reversing bar supporting member 66 in addition to the reversing bar 46. The upstream weir plate 68 extending
And located on the downstream side of the reverse rotation bar support member 66,
And a downstream weir plate 70 extending in the vertical direction.

The reverse bar support member 66, the upstream dam plate 68, and the downstream dam plate 70 are mounted on a base 72.

An upstream channel 74 for supplying or discharging the photosensitive layer forming liquid is formed between the reversing bar supporting member 66 and the upstream dam plate 68, and the reversing bar supporting member 66 and the downstream dam plate are formed. A downstream side channel 76 for supplying or discharging the photosensitive layer forming liquid is formed between the same and 70.

The forward rotation bar 44 rotates in the same direction as the traveling direction of the support web W, similarly to the forward rotation bar 2 in the first and second embodiments. As the normal rotation bar 44, a smooth bar, a grooved bar, a wire bar, or the like can be used as in the normal rotation bar 2.

The reversing bar 46, like the reversing bar 4 in Embodiments 1 and 2, rotates in the direction opposite to the traveling direction of the support web W. The reversing bar 46 is preferably a smooth bar.

The operation of the coating device 104 will be described below.

In the normal bar coater 40, the photosensitive layer forming liquid is supplied from the liquid supply pipe 64 through the upstream liquid supply passage 58 to the upstream side of the normal bar 44, and at the same time, the downstream liquid supply passage is formed. The coating liquid is also supplied to the downstream side of the forward rotation bar 44 through 60.

In the forward rotation bar 44, the photosensitive layer forming liquid supplied from the upstream side liquid supply flow path 58 is scraped up and collided with the back surface of the support web W, so that the photosensitive layer forming liquid is supported. Apply to W. The entrained air brought into the coating device 104 along with the back surface of the support web W is
The photosensitive layer forming liquid scraped up by the forward rotation bar 44 collides with the support web W to be cut. On the other hand, the support web W is excessively coated with the photosensitive layer forming liquid.

The support web W coated with the photosensitive layer forming liquid in the forward rotation bar 44 then passes over the reverse rotation bar coater 42. As described above, the reverse rotation bar 46 rotates in the direction opposite to the traveling direction a of the support web W, so that the photosensitive layer forming liquid excessively applied in the forward rotation bar coater 40 is discharged in the reverse rotation bar 46. It is scraped off and the amount is adjusted so that a predetermined coating thickness is obtained.

Also in the coating apparatus 104 according to the third embodiment, even when the support web W is run at a high speed to apply the photosensitive layer forming liquid, the entrained air brought along with the support web W is normally transferred. Since the roll bar coater 40 can cut, various defects due to the entrained air do not occur in the coating film, and stable coating can be performed.

Further, since both the forward bar coater 40 and the reverse bar coater 42 can use conventional bar coaters, the coating device 104 can be inexpensively constructed.

[0073]

EXAMPLES Example 1 Using the coating apparatus shown in FIG.
Viscosity is 20 cp and surface tension is 24 dyne / cm
The solvent-based photosensitive layer forming liquid of was applied to an aluminum web having a width of 150 mm. The width of the coating device was 300 mm. The aluminum web is an example of the support web W.

In the liquid supply passage 14, liquid supply pumps P ₂ to P 5
The photosensitive layer forming liquid is supplied at a liquid supply amount of 00 cc / min, and the liquid supply amount V (cc / min) represented by the following formula is supplied to the downstream liquid supply flow path 10: V = 76.043 × r + 221 .57 (r, the rotational speed of the liquid feed pump P ₄ (rpm)) with and supplying the photosensitive layer forming liquid by variously changing the rotational speed of the liquid feed pump P _4.

The diameter of the forward rotation bar 2 was 13 mm, and the diameter of the reverse rotation bar 4 was 13 mm. Forward bar 2 is
700 rpm in the same direction as the running direction a of the support web W
And the reverse bar 4 rotates the support web W
It was rotated at a rotation speed of 5 rpm in the opposite direction to the running direction a. A smooth bar was used as the reversing bar 4.

When a smooth bar is used as the forward rotation bar 2, V is 3188 cc / min or more (the liquid supply pump P ₄
When the number of rotations is 40 rpm or more), neither the liquid running out of the photosensitive layer forming liquid nor the occurrence of avalanche unevenness was observed.

Further, when a grooved bar is used as the forward rotation bar 2, if V is 2442 cc / min or more (rotational speed of the liquid supply pump P ₄ is 30 rpm or more), the above liquid shortage and avalanche unevenness will not occur. I couldn't see it.

When the photosensitive layer forming liquid is applied with the number of rotations of the liquid supply pump P ₄ set within a range where the liquid run-out and the avalanche unevenness do not occur, the aluminum web is conveyed at a speed of 155 m / min. Even when the temperature was raised to 0, the occurrence of the liquid runoff and avalanche unevenness was hardly seen.

(Comparative Example 1) The photosensitive layer was formed on the same aluminum web as in Example 1 by using a coating apparatus having the same structure as the coating apparatus 100 shown in FIG. 1 except that the reversing bar 4 was not provided. Even if the liquid is applied, and as a result, the liquid supply amount in the downstream liquid supply passage is increased up to 6245 cc / min (corresponding to the rotation speed of the liquid supply pump P ₄ of about 81.5 rpm), the liquid outage and It was not possible to prevent the occurrence of avalanche unevenness.

[0080]

As described above, according to the present invention,
Provided is a coating device and a coating method that can perform stable coating without causing the above-mentioned various defects in the coating film even when coating is performed by running a web such as the support web at a high speed.

[Brief description of drawings]

FIG. 1 shows an example of a coating apparatus according to the present invention,
It is sectional drawing which shows a structure.

FIG. 2 is a sectional view showing the structure of another example of the coating apparatus according to the present invention.

FIG. 3 is a cross-sectional view showing the configuration of still another example of the coating apparatus according to the present invention.

[Explanation of symbols]

2 Forward bar 4 Reverse bar 6 Forward rotation bar support member 8 Reverse bar support member 10 Downstream side liquid supply flow path 12 Upstream dam 14 Upstream side liquid supply flow path 16 bases 30 Downstream liquid supply channel 32 Forward rotation bar support member 34 Reversing bar support member 40 Normal bar coater 42 Reverse bar coater 44 Forward bar 46 Reverse bar 50 Forward rotation bar support member 52 Upstream dam 54 Downstream weir plate 56 base 58 upstream side liquid supply flow path 60 Downstream liquid supply channel 66 Reversing bar support member 68 Upstream dam 70 Downstream weir plate

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Claims (8)

[Claims] 1. A forward rotation bar that rotates in the same direction as the running direction of the web around an axis while contacting a continuously running strip-shaped web, and at the time of applying a coating liquid to the web, A liquid supply flow path that supplies the coating liquid between the upstream side of the forward rotation bar and the web with respect to the traveling direction of the web, and a downstream side of the forward rotation bar with respect to the traveling direction of the web. A coating device, which is provided and comprises a metering unit for metering the coating liquid applied to the web by the forward rotation bar so as to have a predetermined coating thickness. 2. The reversing bar, which is arranged in parallel with the forward rotation bar, rotates in a direction opposite to the traveling direction of the web while contacting the web. The coating device according to claim 1. 3. The coating apparatus according to claim 2, further comprising a downstream side liquid supply flow path for supplying the coating liquid between the forward rotation bar, the reverse rotation bar and the web. 4. The coating apparatus according to claim 3, wherein the downstream liquid supply passage is a slit-shaped liquid supply passage formed in a slit shape parallel to the forward rotation bar and the reverse rotation bar. 5. The coating apparatus according to claim 1, wherein the forward rotation bar is a different speed rotation bar that rotates at a peripheral speed different from a traveling speed of the web. 6. The coating apparatus according to claim 1, wherein the normal rotation bar is a smooth bar having a smooth surface. 7. The coating apparatus according to claim 1, wherein the forward rotation bar is a grooved bar in which grooves are formed on the surface at regular intervals. 8. An upstream side with respect to the running direction of the web between a continuously running band-shaped web and a forward bar that rotates in the same direction as the running direction of the web while contacting the web. The coating liquid is supplied from the side to apply the coating liquid to the web, and then the forward rotation bar is adjusted by a metering unit arranged on the downstream side of the forward rotation bar with respect to the running direction of the web. A coating method in which the coating liquid coated on the web is adjusted so as to have a predetermined coating thickness.