JP6015375B2 - Continuous coating apparatus and continuous coating method - Google Patents

Description

  The present invention relates to a continuous coating apparatus and a continuous coating method in which a coating liquid is preliminarily applied to a metal strip and then main-coated.

  Conventionally, as a means of coating the surface of a metal strip such as a galvanized steel strip that is generally transported with a surface coating substance, paint, chemical reactant, etc., the metal strip is immersed in a coating solution or applied to the surface of a metal strip. There are various means such as spraying the liquid or applying the coating liquid using a roll coater or a brush.

  Among these various methods, in the technique using a roll coater, when a low-viscosity coating solution is used for roll coating on a metal strip, a uniform coating layer is formed due to insufficient wettability of the metal strip. However, there is a problem that uneven coating tends to occur.

  In order to solve this problem, a method has been proposed in which a metal band is preliminarily applied with a precoater having a preliminary application roll immediately before an applicator roll of a roll coater for applying a coating liquid (Patent Document 1). As another method, a method of preliminarily applying to a metal band using a precoat nozzle provided with a slit-like opening having an opening length shorter than the width of the metal band to be conveyed has been proposed. (Patent Document 2).

JP 2006-142276 A JP 2005-246313 A

Comparing the method of Patent Document 1 in which preliminary coating is performed using a preliminary coating roll and the method of Patent Document 2 in which preliminary coating is directly performed with a pre-coating nozzle, the method of Patent Document 1 is a coating liquid for preliminary coating on a metal strip. It is easy to adjust the amount of liquid and the like.
Then, the present inventors applied the coating liquid to the metal strip by supplying the coating liquid to the preliminary coating roll described in Patent Document 1 using the precoat nozzle described in Patent Document 2.
However, in this aspect, particularly when a wide metal band (1260 mm or more) is run at a high speed to perform high-speed coating (particularly when the line speed is higher than 280 mpm), the metal band edge (end) is applied. The coating liquid did not spread and coating unevenness (scratch) occurred.

  In view of the above circumstances, an object of the present invention is to provide a continuous coating apparatus and a continuous coating method in which the occurrence of blurring at the edge portion of a wide metal band is suppressed even during high-speed coating.

As a result of intensive studies on the problems of the prior art, the present inventors have found that coating defects such as scumming occur depending on the method of supplying the coating liquid to the pre-coating roll of the precoater. The present inventors have further studied based on this finding, and by supplying a coating solution to the preliminary coating roll using a precoat nozzle having a slit-shaped opening of a predetermined size and shape, Has found that can be solved.
That is, the present inventors have found that the above problem can be solved by the following configuration.

  That is, the continuous coating apparatus of the present invention includes a preliminary coating roll that preliminarily coats a coating solution on at least one surface of a metal strip, and a slit-like opening that is provided immediately below the preliminary coating roll and extends in the axial direction of the preliminary coating roll. A precoater having a portion and having a precoat nozzle for supplying the coating liquid to the preliminary coating roll from the slit-shaped opening, and a roll coater for applying the coating liquid to the surface of the metal band preliminarily applied on the downstream side of the precoater. Slit-shaped opening along the direction perpendicular to the axial direction of the preliminary coating roll, which is a continuous coating device, and the length of the slit-shaped opening along the axial direction of the preliminary coating roll is equal to or greater than the width of the metal band The width is gradually increased from the center of the slit-shaped opening in the axial direction of the preliminary application roll toward the both ends.

Further, the width W _C of the slit-like opening at the center of the slit-like opening in the axial direction of the preliminary application roll, and the width W _E of the slit-like opening at the end of the slit-like opening in the axial direction of the preliminary application roll The ratio (W _E / W _C ) is preferably 1.2 to 2.0.
Moreover, it is preferable that a precoat nozzle is equipped with a pair of linear brush provided along the slit-shaped opening part on both sides which pinched | interposed the slit-shaped opening part in the axial direction of the preliminary application roll.

  Further, the continuous coating method of the present invention is provided with a slit-like opening provided on the upstream side at least on one side of the metal strip and immediately below the preliminary coating roll and extending in the axial direction of the preliminary coating roll. A coating method in which a coating liquid is preliminarily applied by a precoater having a precoat nozzle, and after the preliminary coating, the coating liquid is finally coated by a roll coater on the downstream side, and is a slit-shaped opening along the axial direction of the preliminary coating roll The length of the part is equal to or greater than the width of the metal band, and the width of the slit-shaped opening along the direction orthogonal to the axial direction of the preliminary application roll is from the center to the both ends of the slit-shaped opening in the axial direction of the preliminary application roll In this method, the coating liquid is gradually increased from the slit-shaped opening to the surface of the preliminary coating roll immediately above the precoat nozzle.

Further, in the continuous coating method of the present invention, the width W _C of the slit-shaped opening at the center of the slit-shaped opening in the axial direction of the preliminary coating roll and the end of the slit-shaped opening in the axial direction of the preliminary coating roll. It is preferable that the ratio (W _E / W _C ) with the width W _E of the slit-shaped opening is 1.2 to 2.0.
Further, in the continuous coating method of the present invention, a pair of linear brushes are disposed along the slit-shaped opening on both sides of the slit-shaped opening in the axial direction of the preliminary coating roll. It is preferable to guide the brush so that the flow direction of the supplied coating liquid is directed to the axial direction of the preliminary coating roll.

  According to the present invention, it is possible to provide a continuous coating apparatus and a continuous coating method in which the occurrence of blurring at the edge portion of a wide metal strip is suppressed even during high-speed coating.

It is a schematic diagram which shows the principal part structural example of the 1st embodiment of the continuous coating apparatus of this invention. It is a typical perspective view of the precoat nozzle used for the continuous application apparatus shown in FIG. It is a schematic diagram which shows the principal part structural example of the 2nd embodiment of the continuous coating apparatus of this invention. It is sectional drawing which looked at the structure of the precoat nozzle used for the continuous coating apparatus shown in FIG. 2 from the front. FIG. 5 is a cross-sectional view taken along line AA in FIG.

  Below, the continuous coating apparatus and the continuous coating method of this invention are demonstrated with reference to drawings.

<Continuous Coating Device (First Preferred Embodiment)>
First, a first preferred embodiment of the continuous coating apparatus of the present invention will be described with reference to FIG.
FIG. 1 is a schematic diagram illustrating an exemplary configuration of a main part of a continuous coating apparatus 100 according to the present invention.
As shown in FIG. 1, a metal strip S, which is a band-shaped object to be coated, is disposed on the downstream side through a continuous coating apparatus 100 of the present invention from an upstream processing section (not shown), for example, a continuous annealing facility, a coating pretreatment facility, or the like. It is continuously conveyed at a predetermined speed in the direction of the arrow along the pass line 10 to a processing section, for example, a baking facility or a drying facility.
The continuous coating apparatus 100 includes a pair of precoaters (preliminary coating apparatuses) 12 and 12 and a pair of roll coaters (main coating apparatuses) 30 and 30, and the precoaters 12 and 12 are provided on the pass line 10 more than the roll coaters 30 and 30. It is upstream. And the metal strip S conveyed by the pass line 10 is between the pair of precoaters 12 and 12 arranged so as to face each other with the metal strip S sandwiched from both sides in the thickness direction, and the metal strip S in the thickness direction. It is sandwiched between a pair of roll coaters 30 and 30 arranged so as to be opposed to each other from both sides.
Hereinafter, the metal strip S will be described in detail first, and then the configurations of the precoater 12 and the roll coater 30 will be described in detail.

(Metal strip S)
The metal strip S is long and the type is not particularly limited. For example, a cold-rolled steel plate, various plated steel plates, an aluminum plate, etc. are mentioned.

(Precoater)
The precoater 12 is a device that performs a preliminary application by applying a coating liquid P to the surface of the metal band S prior to the main application to the surface of the metal band S.
The precoater 12 includes a coating liquid tank (not shown), a coating liquid supply pipe (not shown), a pump (not shown), a preliminary coating roll 14, a precoat nozzle 16, and a liquid receiving pan 24.

The coating liquid tank is a tank for storing the coating liquid P used in the precoater 12, and the coating liquid P is supplied to the precoat nozzle 16 via a coating liquid supply pipe described later.
The coating liquid supply pipe is a pipe that connects the coating liquid tank and the precoat nozzle 16 and includes a pump in the middle thereof. The pump supplies the coating liquid P from the coating liquid tank to the precoat nozzle 16 via the coating liquid supply pipe.
The method of supplying the coating liquid P to the precoat nozzle 16 is not limited to the above-described coating liquid tank, and may be supplied from a coating liquid pan 38, which will be described later, by a pump through a coating liquid supply pipe.
Further, the position of the coating liquid tank or the coating liquid pan 38 is set higher than the position of the precoat nozzle 16, and the coating liquid P is supplied to the precoat nozzle 16 using the height difference without using a pump. Good.

The preliminary application roll 14 comes into contact with the transported (running) metal strip S and applies (transfers) the coating liquid P supplied from the precoat nozzle 16 to the metal strip S. The preliminary application roll 14 is composed of a rubber lining roll having a rubber lined surface.
The preliminary application roll 14 is configured to be capable of reverse rotation in the direction opposite to the traveling direction of the metal strip S. That is, when the surface of the preliminary application roll 14 and the surface of the metal strip S are in contact with each other, the traveling direction of the surface of the preliminary coating roll 14 is opposite to the traveling direction of the metal strip S at the contact position. The preliminary application roll 14 is configured to be rotatable.

The precoat nozzle 16 is a nozzle used for supplying the coating liquid P to the preliminary coating roll 14 described above, and is disposed immediately below the preliminary coating roll 14.
FIG. 2 is a schematic perspective view of the precoat nozzle 16.
The precoat nozzle 16 includes a nozzle body 16a and a slit-shaped opening forming member 16b. The precoat nozzle 16 is provided with a slit-shaped opening 18, and the coating liquid P is discharged from the opening 18, and the coating liquid P is supplied to the preliminary coating roll 14. The slit-shaped opening 18 extends in the axial direction of the preliminary coating roll 14, and the axial length L of the slit-shaped opening 18 in the preliminary coating roll 14 has the same length as the band width of the metal band S. That is, the slit-shaped opening 18 is provided so that the longitudinal direction of the slit-shaped opening 18 is substantially parallel to the axial direction of the preliminary application roll 14. 1 shows an embodiment in which the opening length L of the slit-shaped opening 18 along the axial direction of the preliminary application roll 14 is the same as the band width of the metal band S. The opening length L is a metal Even if it is larger than the band S, blurring of the edge portion of the metal band S is suppressed.

On the other hand, when the opening length L of the slit-shaped opening 18 in the axial direction of the preliminary application roll 14 is less than the band width of the metal band S, defective coating such as scraping occurs at the edge of the metal band S.
In the aspect described in Patent Document 2 described above, a precoat nozzle having a slit-like opening shorter than the width of the metal band S is used. However, when preliminarily applying using the preliminarily applying roll 14 as in the present embodiment, the opening length of the slit-shaped opening 18 is contrary to the aspect of Patent Document 2 in order to suppress coating defects such as scraping. The length L is required to be equal to or greater than the width of the metal band S.

Further, the width of the slit-shaped opening 18 along the direction orthogonal to the axial direction of the preliminary application roll 14 is the same as the width of the slit-shaped opening 18 in the axial direction of the preliminary application roll 14 (longitudinal direction of the slit-shaped opening 18). It gradually increases from the center toward both ends. As described above, the opening width of the slit-like opening 18 is larger at both ends than the center, so that the occurrence of coating defects such as scraping at the edge of the metal band S is further suppressed.
Note that the ratio (W _E / W _C ) between the opening width W _C at the center in the axial direction (longitudinal direction) of the preliminary application roll 14 of the slit-shaped opening 18 and the opening width W _E at the end is the edge of the metal band S It is preferable that it is 1.2-2.0 at the point by which generation | occurrence | production of application | coating defects, such as a blur in a part, is suppressed further.
Although FIG. 1 shows an aspect in which the opening width of the slit-like opening 18 gradually increases linearly (linearly) from the longitudinal center to both ends in the longitudinal direction, other aspects may be used. For example, the slit-shaped opening 18 may gradually increase in a non-linear manner (for example, in a curvilinear manner) from the longitudinal center to both longitudinal ends.

In the present embodiment, the slit-shaped opening 18 is provided in the slit-shaped opening forming member 16b. The slit-shaped opening forming member 16b is a member that is provided along the axial direction on the outer peripheral surface of the cylindrical nozzle body 16a and communicates with the nozzle body 16a. The slit-shaped opening forming member 16b extends from the outer peripheral surface of the nozzle body 16a toward the preliminary application roll 14. By providing the slit-shaped opening 18 in the slit-shaped opening forming member 16b, the coating liquid P is more discharged toward the preliminary coating roll 14, and the supply efficiency of the coating liquid P is increased, which is preferable.
In addition, it is not limited to this embodiment, You may provide the slit-shaped opening part 18 on the outer peripheral surface of the nozzle main body 16a, without providing the slit-shaped opening part formation member 16b.

The liquid receiving pan 24 is installed immediately below the precoat nozzle 16. The liquid receiving pan 24 is a receiving tray opened upward to receive the coating liquid P dropped from the preliminary coating roll 14 and the precoat nozzle 16, and is positioned below the preliminary coating roll 14 and the precoat nozzle 16. The liquid receiving pan 24 has an area sufficient for the preliminary application roll 14 and the precoat nozzle 16 to be always positioned above.
The liquid receiving pan 24 is connected to a return line (not shown), and the recovered coating liquid P is returned to a coating liquid tank (not shown).

(Roll coater)
The roll coater 30 is a device that applies the coating liquid P to the metal band S preliminarily applied by the precoater 12 by a roll and performs the main application.
The roll coater 30 includes a pickup roll 32, a metering roll 34, an applicator roll 36, and a coating liquid pan 38.

  The pickup roll 32 is a roll that pumps up the coating liquid P from the coating liquid pan 38. The pickup roll 32 is a metal roll whose surface is chrome plated or the like, and the surface of the pickup roll 32 and the surface of the applicator roll 36 are in contact with each other. The pickup roll 32 is configured to be rotatable in the same direction as the rotating direction of the applicator roll 36 that comes into contact.

The mitering roll 34 is a roll that adjusts the amount of the coating liquid P on the pickup roll 32. The mitering roll 34 is a metal roll whose surface is chrome plated or the like, and the surface of the mitering roll 34 and the surface of the pickup roll 32 are close to each other with a predetermined gap. The position of the Mitering roll 34 can be adjusted, and the size of the gap between the Mitering roll 34 and the pickup roll 32 can be adjusted. By adjusting the gap, the amount of the coating liquid P on the pickup roll 32 can be adjusted. The rotation direction of the mitering roll 34 is the same as the rotation direction of the pickup rolls 32 that are arranged close to each other.
Note that a blade (not shown) for scraping the coating liquid P is installed on the mitering roll 34.

  The applicator roll 36 is a roll that transfers the coating liquid P on the pickup roll 32 to the metal strip S, and is arranged so as to contact the pickup roll 32. The applicator roll 36 is a rubber roll whose surface is covered with rubber, and the applicator roll 36 is configured to be capable of reverse rotation in the direction opposite to the traveling direction of the metal band S. That is, when the surface of the applicator roll 36 and the surface of the metal band S are in contact with each other, the traveling direction of the surface of the applicator roll 36 is opposite to the traveling direction of the metal band S at the contact position Xb1. In the direction, the applicator roll 36 is configured to be rotatable.

The coating liquid pan 38 is a receiving tray opened upward, and the pickup roll 32 is located immediately above. The height position of the lower end of the pickup roll 32 is below the liquid surface of the coating liquid P in the coating liquid pan 38.
The coating liquid pan 38 is connected to a coating liquid tank (not shown) via a supply line (not shown), and a constant amount of the coating liquid P is constantly supplied. It is kept constant. The bottom of the coating liquid pan 38 has a coating liquid P discharge port (not shown), and is connected to a return line (not shown) for returning the coating liquid P to the coating liquid tank.

<Continuous application method>
Next, a continuous coating method using the above-described continuous coating apparatus 100 will be described in detail.
First, the metal strip S is continuously conveyed from the downstream side to the upstream side by a conveyance roll (not shown), and enters between the pair of precoaters 12 and 12.

In one precoater 12, the surface of the preliminary application roll 14 is in contact with one surface of the metal band S, and the preliminary application roll 14 rotates reversely in the direction opposite to the traveling direction of the metal band S. The coating liquid P discharged from the slit-shaped opening 18 of the precoat nozzle 16 adheres to the surface of the preliminary coating roll 14, and the coating liquid P adhered to the surface of the preliminary coating roll 14 at the contact position Xa1. Is transferred to the surface of the metal strip S.
Also in the other precoater 12, the coating liquid P adhering to the surface of the preliminary coating roll 14 is transferred to the other surface of the metal strip S at the contact position Xa2.
That is, at the contact position Xa1 and the contact position Xa2, both sides of the metal band S are preliminarily applied, and the preliminarily applied metal band S is conveyed to the roll coater 30 on the downstream side.

  The precoat nozzle 16 is supplied with a coating liquid P from a coating liquid tank (not shown) by a pump (not shown) via a supply line (not shown). The supplied coating liquid P is slit-shaped. It is discharged from the opening 18 and applied to the surface of the preliminary application roll 14.

The metal strip S, which has been applied with a certain amount of the coating liquid P and finished the preliminary coating, is continuously conveyed from below to above the pass line 10 and enters between the pair of roll coaters 30.
Since the lower end of the pick-up roll 32 of the roll coater 30 is at a height position below the liquid surface of the coating liquid P in the coating liquid pan 38, it is immersed in the coating liquid P in the coating liquid pan 38. Adheres to the surface of the pickup roll 32. The pick-up roll 32 rotates and the coating liquid P adhering to the surface of the pick-up roll 32 passes through the gap between the metering roll 34 and the pick-up roll 32 and is measured so as to have a predetermined liquid amount. The coating liquid P adhering to the surface of the mitering roll 34 after measurement is removed by a blade (not shown).

The coating liquid P having reached a predetermined amount rotates with the pickup roll 32 and is carried to a contact position where the pickup roll 32 and the applicator roll 36 are in contact with each other. Is transcribed. The coating liquid P transferred to the surface of the applicator roll 36 rotates with the applicator roll 36 and reaches the contact position Xb1 between the surface of the applicator roll 36 and the surface of the metal band S. At the contact position Xb1, the coating liquid P adhering to the surface of the applicator roll 36 is transferred onto the preliminarily applied metal strip S and the main coating is finished.
In the other roll coater 30 as well, the coating liquid P adhering to the surface of the applicator roll 36 is transferred onto the preliminarily applied metal strip S at the contact position Xb2.

  The metal band S that has been subjected to the main application is conveyed by the pass line 10 to the next process downstream of the continuous application apparatus 100. For example, the coated metal strip S is heated and dried by a baking facility, a drying facility, etc. (not shown) to form a desired film.

  In the present invention, the length in the axial direction of the preliminary application roll 14 of the slit-shaped opening 18 provided in the precoat nozzle 16 is set to be longer than the width of the metal band S, and the preliminary opening of the slit-shaped opening 18. By gradually increasing the width of the coating roll 14 in the direction perpendicular to the axial direction from the central portion in the longitudinal direction of the slit-shaped opening toward both ends, the metal band S having no coating defects at the edge portion even in a high-speed line of 280 mpm or more. Can be obtained.

<Continuous Coating Device (Second Preferred Embodiment)>
Below, with reference to FIG. 3, 2nd preferred embodiment of the continuous coating apparatus of this invention is described.
FIG. 3 is a schematic diagram showing a configuration example of a main part of the continuous coating apparatus 200 of the present invention.
As shown in FIG. 3, the continuous coating apparatus 200 includes a precoater 112 and a roll coater 30. The precoat nozzle 116 in the precoater 112 includes a nozzle body 16 a, a standing wall 20, and a brush 22.
The continuous coating apparatus 200 shown in FIG. 3 has the same configuration as the continuous coating apparatus 100 shown in FIG. 1 except that the slit-like opening forming member 16b is not provided and the standing wall 20 and the brush 22 are provided. Therefore, the same constituent elements are denoted by the same reference numerals, description thereof is omitted, and the standing wall 20 and the brush 22 will be mainly described.

  4 is a cross-sectional view of the configuration of the precoat nozzle 116 as seen from the front, and FIG. 5 is a cross-sectional view taken along the line AA in FIG.

  As shown in FIGS. 4 and 5, along the slit-shaped opening 18 on both sides of the slit-shaped opening 18 of the precoat nozzle 116 in the axial direction of the preliminary application roll 14 (longitudinal direction of the slit-shaped opening 18). A pair of standing walls 20 extending in the direction is provided. By providing the standing wall 20, the coating liquid P discharged from the slit-shaped opening 18 is guided to the standing wall 20 and flows in the axial direction of the preliminary coating roll 14, and is applied to the preliminary coating roll 14. A more uniform coating can be applied, which is preferable.

As shown in FIGS. 4 and 5, a linear brush 22 is provided on the standing wall 20. By providing the brush 22, the flow of the coating liquid P discharged from the slit-shaped opening 18 to the preliminary application roll 14 is further promoted, and the discharged coating liquid P passes through a small gap in the brush 22. It rises, the scattering of the liquid also decreases, and the application liquid P can be supplied to the preliminary application roll 14 more efficiently, which is preferable.
4 and 5, the brush 22 is provided on the standing wall 20, but the brush 22 is directly along the slit opening 18 on both sides of the slit opening 18 of the nozzle body 16 a. You may provide in linear form.

The material constituting the brush 22 is not particularly limited, and a material that does not easily scratch the roll and that does not easily generate residue when it comes into contact with the roll is preferable. It may be felt-like.
The length of the brush 22 is preferably from 0.3 to 3.0 cm, and more preferably from 0.5 to 2.0 cm in terms of preventing the edge of the metal band S from being scraped.

In the drawing, the metal band S is described as a path that flows vertically (perpendicular to the ground), but the metal band S may be a path that flows horizontally. Moreover, although the case of front-and-back simultaneous application | coating was illustrated, it is good also as the application | coating position of front and back shifting, or application | coating of front and back one side each.
In the drawings, the rotation of the roll is reverse rotation, but it may be natural rotation.

In this example, a continuous coating apparatus 200 having the same configuration as that of the second embodiment shown in FIG. 3 was used, and the coating liquid P was continuously applied to the metal strip S while changing the line speed. The continuously applied metal strip S had a plate thickness of 0.5 mm and a plate width of 1290 mm. The opening length L of the slit-shaped opening 18 of the precoat nozzle 116 along the axial direction of the preliminary application roll 14 was 1290 mm. Moreover, the opening width of the slit-shaped opening 18 gradually increased linearly from the center of the slit-shaped opening 18 in the axial direction of the preliminary application roll 14 toward both ends. More specifically, the ratio (W _E / W _C ) between the width W _C at the center of the slit-shaped opening 18 and the width W _E at the end in the axial direction of the preliminary application roll 14 is 1.5. there were. Both end portions had the same opening width.
Note that a 9 mm long brush made of polypropylene is used as the brush 22, and the precoat nozzle 116 passes through the center line in the width direction of the metal strip S and is supplied from the precoat nozzle 116 in the slit-shaped opening 18. The position of the precoat nozzle 116 was adjusted so that P was supplied to the entire width of the metal strip S. In other words, the position is adjusted so that the normal passing through the center line in the width direction of the metal band S passes through the center line in the width direction of the slit-shaped opening 18 of the precoat nozzle 116.
Further, as Comparative Example 1, the slit-shaped opening 18 of the precoat nozzle 116 is rectangular, the opening length L is 1270 mm, and the width W _C at the center of the slit-shaped opening 18 in the axial direction of the preliminary application roll 14 is The coating solution P was continuously applied to the metal strip S using the continuous coating apparatus 200 used in the example except that the ratio (W _E / W _C ) with the width W _E at the end was 1.0. . Further, as Comparative Example 2, the slit-shaped opening 18 of the precoat nozzle 116 is rectangular, the opening length L is 1290 mm, and the width W _C at the center of the slit-shaped opening 18 in the axial direction of the preliminary application roll 14 is The coating solution P was continuously applied to the metal strip S using the continuous coating apparatus 200 used in the example except that the ratio (W _E / W _C ) with the width W _E at the end was 1.0. .

  When the line speed was changed to 250 to 300 mpm, it was determined whether or not there was a blur at the edge of the metal strip S. The case where there was no blur was “◯”, the case where there was a slight blur was “Δ”, and the case where there was a blur was “x”. The results are shown in Table 1.

As shown in Table 1, in the examples, even when the line speed was changed to 300 mpm, the coating liquid P was not confirmed to be blurred.
On the other hand, in Comparative Example 1 in which the slit-shaped opening 18 is rectangular and the opening length L is shorter than the metal strip S, the blur occurred at a line speed of 250 mpm. Further, in Comparative Example 2 in which the slit-shaped opening 18 is rectangular and the opening length L is the same as that of the metal strip S, the blur occurred at a line speed of 300 mpm.

DESCRIPTION OF SYMBOLS 100,200 Continuous coating apparatus 10 Line pass 12,122 Precoater 14 Preliminary application roll 16,116 Precoat nozzle 16a Nozzle main body 16b Slit-shaped opening formation member 18 Slit-shaped opening 20 Standing wall 22 Brush 30 Roll coater 32 Pickup roll 34 Mitering roll 36 Applicator roll S Metal strip P Coating solution

Claims (6)

A preliminary application roll for preliminarily applying a coating solution on at least one surface of a metal strip, and a slit-shaped opening provided immediately below the preliminary application roll and extending in the axial direction of the preliminary application roll, the slit-shaped opening A precoater having a precoat nozzle for supplying the coating liquid from the section to the preliminary coating roll;
A continuous coating apparatus comprising a roll coater for applying the coating liquid to the surface of a metal band preliminarily coated on the downstream side of the precoater,
The length of the slit-shaped opening along the axial direction of the preliminary application roll is equal to or greater than the width of the metal band,
The width of the slit-shaped opening along the direction orthogonal to the axial direction of the preliminary application roll gradually increases from the center of the slit-shaped opening in the axial direction of the preliminary application roll toward both ends. Continuous application equipment. And the width W _C of the slit opening in the slit opening center in the axial direction of the pre-coating roll, the slit opening in the slit opening end portion in the axial direction of the preliminary coating roll 2. The continuous coating apparatus according to claim 1, wherein a ratio to the width W _E (W _E / W _C ) is 1.2 to 2.0.   The pre-coat nozzle includes a pair of linear brushes provided along the slit-like opening on both sides of the slit-like opening in the axial direction of the preliminary application roll. The continuous coating apparatus as described. Coated by at least one surface of a metal strip with a pre-coating roll having a pre-coating nozzle on the upstream side, and a pre-coating nozzle provided immediately below the pre-coating roll and having a slit-like opening extending in the axial direction of the pre-coating roll The liquid is pre-applied, and after the pre-application, a continuous application method in which the application liquid is applied by a roll coater on the downstream side,
The length of the slit-shaped opening along the axial direction of the preliminary coating roll is equal to or greater than the width of the metal band, and the width of the slit-shaped opening along the direction orthogonal to the axial direction of the preliminary coating roll Gradually increases from the center of the slit-shaped opening in the axial direction of the preliminary application roll toward both ends,
A continuous coating method in which a coating solution is supplied from the slit-shaped opening to the surface of the preliminary coating roll immediately above the precoat nozzle. And the width W _C of the slit opening in the slit opening center in the axial direction of the pre-coating roll, the slit opening in the slit opening end portion in the axial direction of the preliminary coating roll The continuous application method according to claim 4, wherein a ratio to the width W _E (W _E / W _C ) is 1.2 to 2.0.   In the axial direction of the preliminary application roll, a pair of linear brushes are arranged along the slit-shaped opening on both sides of the slit-shaped opening, and the flow of the coating liquid supplied from the slit-shaped opening The continuous coating method according to claim 4, wherein the brush is guided so that a direction is directed to an axial direction of the preliminary coating roll.