KR102398212B1 - Velvet coating system for oil-based ink pringing paper - Google Patents

Abstract

An objective of the present invention is to provide a velvet coating system for oil-based ink printing fabric capable of realizing a velvet coating effect by water-based coating the surface of fabric (110) using an aqueous coating solution after printing with oil-based ink in order to improve the cost and environmental problems which may occur in the conventional velvet coating method using plastic. The present invention comprises: an oil-based ink printing unit (120) which performs printing on a printing fabric (110) by using oil-based ink; a light irradiation assembly (130) for hardening the oil-based ink by irradiating light onto the fabric (110) printed by the oil-based ink printing unit (120); and a water-based coating unit (140) for forming a coating film by applying a water-based coating solution to the oil-based ink printing fabric (110) on which oil-based ink is printed. The present invention can provide a velvet coating effect by water-based coating the surface of fabric using an aqueous coating solution after printing with oil-based ink, hardening the fabric using a lamp, and drying the same in a water-based coating solution drying method using IR in order to improve the cost and environmental problems which may occur in the conventional velvet coating method using plastic.

Description

Velvet coating system for oil-based ink pringing paper}

The present invention relates to a velvet coating system for oil-based ink printing fabrics, and more particularly, to improve costs and environmental problems that may occur in the conventional velvet coating method using vinyl, printing with oil-based ink and then using an aqueous coating solution. It relates to a velvet coating system for oil-based ink-printed fabric that is implemented so that the velvet coating effect can be realized by water-based coating on the surface of the fabric.

UV curable printing ink absorbs UV energy to cause photopolymerization and cures and dries in the shortest time (within 0.1 seconds). To improve production by using these advantages, it is used in each industrial field such as wood and furniture, floor decoration, leather processing, can or pack coating, and in the printing field, some offsets, textile printing, printed circuit boards, etc. It is also applied to silk screen and high-speed letterpress printing, but the type, composition, manufacturing method, and physical properties of the colorant used for these inks are different depending on the characteristics of use.

In general, gravure printing is mainly used for packaging printing and printing for construction materials in Korea, since most of the gravure printing uses a roll-type rotary press to perform multi-color double-sided printing at higher speed than other printing methods.

In the case of a conventional printing apparatus, there was a problem in that it accompanies the cost and environmental problems that may occur in the velvet coating method using vinyl.

On the other hand, the above-mentioned background art is technical information that the inventor possessed for the purpose of derivation of the present invention or acquired during the derivation process of the present invention, and it cannot be said that it is necessarily known technology disclosed to the general public before the filing of the present invention. .

Korean Patent Registration No. 10-2326083 (Registered on November 08, 2021) Korean Patent Registration No. 10-1953783 (registered on March 05, 2019) Korean Patent No. 10-1530818 (registered on June 16, 2015) Korean Patent Registration No. 10-2267211 (registered on June 15, 2021)

The present invention was developed to solve the above problems, and an object of the present invention is to use an aqueous coating solution after printing with oil ink to improve the cost and environmental problems that may occur in the conventional velvet coating method using vinyl. This is to provide a velvet coating system for oil-based ink-printed fabric that can achieve the velvet coating effect by water-based coating on the surface of the fabric, curing using UV lamp, and drying water-based coating solution using IR.

The technical problems of the present invention are not limited to the technical problems mentioned above, and other technical problems not mentioned will be clearly understood by those skilled in the art from the following description.

According to the present invention, oil-based ink printing fabric velvet comprising; a water-based coating unit 140 for forming a coating film by applying an aqueous coating solution to the oil-based ink printing fabric 110 on which the oil-based ink is printed on the surface A coating system is provided.

Oil-based ink printing unit 120 for performing printing using oil-based ink on the fabric for printing 110; and a light irradiation assembly 130 for curing the oil ink by irradiating light to the fabric 110 printed by the oil ink printing unit 120 .

A light source 136 is provided in the light irradiation assembly 130, and the light source 136 is a UV lamp that irradiates light to the printing fabric 110 on which oil ink is printed by the oil ink printing unit 120. It is characterized in that it further includes; a drying unit 150 for drying by irradiating light to the aqueous coating liquid applied to the printing fabric 110 by the aqueous coating unit 140 .

The light irradiation assembly 130 is configured to include an inner sleeve 131 and an outer sleeve 133 so as to be disposed on a path through which the fabric 110 printed with the oil ink passes, and the inner sleeve 131 has a longitudinal direction. A light passage hole 132 extending to ) is provided with an external light passage hole 134 extending in the longitudinal direction and meeting the light passage hole 132 of the inner sleeve 131 , so that the light from the plurality of light sources 136 passes through the light passage hole 132 . ) and the external light passage hole 134, characterized in that it is configured to evenly irradiate the light to the fabric 110.

The external light passage hole 134 is arranged in plurality along the circumferential direction of the outer sleeve 133 , the outer sleeve 133 is provided with a plurality of external light passage holes 134 , and a plurality of the external light passage holes 134 are provided. The width between the pair of facing inner surfaces of each of the outer light passage holes 134 in the passage hole 134 is configured to gradually narrow in the circumferential direction of the outer sleeve 133, so that the outer sleeve ( 133) is configured such that the width of each of the external light passage holes 134 gradually decreases along the circumferential direction.

The outer sleeve 133 is configured to be rotatable, so that as the outer sleeve 133 rotates, the outer light passage hole 134 having a different width meets the light passage hole 132 of the inner sleeve 131 . Aligned, the range in which the light of the light source 136 is irradiated to the surface of the fabric 110 is adjusted, characterized in that the curing speed of the oil ink printed on the surface of the fabric 110 is adjusted.

The water-based coating unit 140 includes a coating roller 142 installed on the path through which the oil-based ink printing fabric 110 on which the oil-based ink is printed on the surface passes, and the coating roller 142 is the oil-based ink printing fabric ( 110) is configured to apply an aqueous coating solution to the surface, and a coating spraying sleeve 144 having a coating liquid spraying hole 145 that meets the outer circumferential surface of the coating roller 142 is arranged in parallel with the coating roller 142 characterized in that

The coating liquid spraying hole 145 is configured in a circular hole shape, and the coating liquid spraying hole 145 is provided at regular intervals along the circumferential direction of the coating spraying sleeve 144 and the length of the coating spraying sleeve 144 at the same time. It is provided at regular intervals along the direction, the coating liquid spray hole 145 is provided in plurality along the circumferential direction and the longitudinal direction of the coating spray sleeve 144, a plurality of coating liquid provided in the coating spray sleeve 144 The coating liquid spraying holes 145 adjacent to each other in the spraying hole 145 are arranged to be shifted from each other in the longitudinal direction of the coating spraying sleeve 144 .

The coating liquid spraying hole 145 is configured in the shape of a long hole extending a certain length in the longitudinal direction of the coating spraying sleeve 144 , and the coating liquid spraying hole 145 in the long hole shape is in the circumferential direction of the coating spraying sleeve 144 . are provided at regular intervals along the and at the same time provided at regular intervals along the longitudinal direction of the coating spraying sleeve 144, the coating solution spraying holes 145 are provided in a plurality along the circumferential direction and the longitudinal direction of the coating spraying sleeve 144 and the coating liquid spraying holes 145 adjacent to each other in the plurality of coating liquid spraying holes 145 provided in the coating spraying sleeve 144 are arranged to be shifted from each other based on the longitudinal direction of the coating spraying sleeve 144 . characterized by being

The coating liquid injection hole 145 is characterized in that it is configured in a tapered hole shape in which the diameter gradually increases from the inner circumferential surface to the outer circumferential surface of the coating spray sleeve 144 .

A base blade body 162 disposed adjacent to the outer circumferential surface of the coating roller 142, and rotatably mounted to the base blade body 162 by a hinge, the blade portion is in contact with the outer circumferential surface of the coating roller 142 A contact that is connected between the cleaning blade 163 and the cleaning blade 163 and the base blade body 162 so that the blade portion of the cleaning blade 163 is in elastic contact with the outer peripheral surface of the coating roller 142 . The coating roller 142 further includes an elastic body 164, wherein the blade portion of the cleaning blade 163 is in elastic contact with the outer circumferential surface of the coating roller 142 by the contact elastic body 164. It is characterized in that it is configured to clean the coating solution residue remaining on the outer peripheral surface of the coating roller 142 by rotating.

The base blade body 162, the cleaning blade 163, and the contact elastic body 164 are moved to be removed from the outer peripheral surface of the coating roller 142 by the operation of the moving unit 166, or the coating roller 142. It is characterized in that it is configured to move toward the outer peripheral surface of.

The moving unit 166 is composed of a moving working cylinder connected to the cylinder rod via a fixed support means to the base blade body (162).

A cleaning tray 167 is provided under the cleaning blade 163 so that the coating solution residue scraped off from the outer peripheral surface of the coating roller 142 by the cleaning blade 163 is collected in the cleaning tray 167 . characterized in that it is composed.

The cleaning tray 167 is configured to enter under the cleaning blade 163 by the moving unit when scraping the coating solution residue from the outer peripheral surface of the coating roller 142 by the cleaning blade 163. do.

The cleaning tray 167 collects the aqueous coating solution from below when the aqueous coating solution sprayed from the coating solution spray hole 145 of the coating spray sleeve 144 is sprayed on the outer peripheral surface of the coating roller 142. The coating roller 142 It may be configured to be disposed at a lower position of

The present invention is to improve the cost and environmental problems that may occur in the conventional velvet coating method using vinyl, after printing with oil ink, the surface of the fabric is aqueous coated using an aqueous coating solution, and curing using a lamp and an aqueous coating solution using IR A velvet coating effect can be provided by a drying method.

The effects of the present invention are not limited to the above-mentioned effects, and various effects may be included within the range apparent to those skilled in the art from the following description.

1 is a front view showing the schematic configuration of the velvet coating system of the oil-based ink printing fabric of the present invention;
2 is a front view schematically showing the configuration of the aqueous coating part, which is the main part shown in FIG. 1;
Figure 3 is a perspective view showing an enlarged part of the aqueous coating portion shown in Figure 2;
4 is a perspective view showing the disassembled state of the inner sleeve and the outer sleeve constituting the light irradiation assembly of the velvet coating system of the oil-based ink printing fabric according to the present invention;
5 is a perspective view of an outer sleeve which is a main part of the light irradiation assembly shown in FIG. 4;
6 is a perspective view of an inner sleeve which is a main part of the light irradiation assembly shown in FIG. 4;
7 is a perspective view schematically showing the process of curing the oil-based ink on the surface of the oil-based ink printing fabric by the light irradiation assembly of the velvet coating system of the oil-based ink printing fabric according to the present invention;
8 is a longitudinal cross-sectional view showing the structure of the light irradiation assembly shown in FIG. 7;
9 is a longitudinal cross-sectional view schematically showing a process of irradiating light from a light source by the light irradiation assembly shown in FIG. 8;
10 is a longitudinal cross-sectional view schematically showing a process of irradiating by changing the irradiation range of the light of the light source by the light irradiation assembly shown in FIG. 9;
11 is a perspective view of the coating roller and the coating spray sleeve, which are the main parts of the aqueous coating part of the velvet coating system of the oil-based ink printing fabric according to the present invention;
12 is a side view of the coating spray sleeve shown in FIG. 11;
13 is a side view schematically showing the process of spraying the aqueous coating solution on the outer peripheral surface of the coating roller in the coating spray sleeve of the aqueous coating unit shown in FIG. 11;
14 is a perspective view of a modified embodiment of the coating spray sleeve, which is the main part of the water-based coating part, and the coating roller in the velvet coating system of the oil-based ink printing fabric according to the present invention;
15 is a side view schematically showing the process of spraying an aqueous coating solution on the outer peripheral surface of the coating roller in the coating spray sleeve of the aqueous coating unit shown in FIG. 14;
16 is a longitudinal cross-sectional view enlargedly showing an embodiment in which the coating liquid spray hole of the coating spray sleeve, which is the main part of the aqueous coating part, has a tapered hole structure in the present invention;
17 is a perspective view schematically showing the process of forming a coating film by curing the aqueous coating solution on the surface of the oil-based printing coating fabric by the drying unit, which is the main part of the present invention;
18 is a side view of the base blade body and the cleaning blade for cleaning the outer peripheral surface of the coating roller in the velvet coating system of the oil-based ink printing fabric according to the present invention;
19 is a side view schematically showing a state in which the base blade body and the cleaning blade shown in FIG. 18 are pulled out from the outer peripheral surface of the coating roller;
20 is a side view schematically showing a state in which the base blade body and the cleaning blade shown in FIG. 19 enter into a position facing the outer peripheral surface of the coating roller;
21 is a front view schematically showing the process of cleaning the residual coating solution on the outer peripheral surface of the coating roller by the cleaning blade shown in FIG. 20;
22 is a plan view of an embodiment in which a curtain is installed around a coating roller in a velvet coating system for oil-based ink printing fabric according to the present invention;
23 is a perspective view showing an embodiment in which a plurality of conveyor belts are installed on a work stand in a velvet coating system for oil-based ink printing fabric according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0012] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS [0010] Reference is made to the accompanying drawings, which show by way of illustration specific embodiments in which the present invention may be practiced. These embodiments are described in sufficient detail to enable those skilled in the art to practice the present invention. It should be understood that the various embodiments of the present invention are different but need not be mutually exclusive. For example, certain shapes, structures, and characteristics described herein with respect to one embodiment may be implemented in other embodiments without departing from the spirit and scope of the invention. In addition, it should be understood that the location or arrangement of individual components within each disclosed embodiment may be changed without departing from the spirit and scope of the present invention. Accordingly, the detailed description set forth below is not intended to be taken in a limiting sense, and the scope of the present invention, if properly described, is limited only by the appended claims, along with all scope equivalents as those claimed. Like reference numerals in the drawings refer to the same or similar functions throughout the various aspects.

1 is a front view showing the schematic configuration of the velvet coating system of the oil-based ink printing fabric of the present invention, FIG. 2 is a front view schematically showing the configuration of the aqueous coating part, which is the main part shown in FIG. 1, FIG. 3 is FIG. A perspective view showing an enlarged part of the aqueous coating part shown in Fig. 4 is a perspective view showing the disassembled state of the inner sleeve and the outer sleeve constituting the light irradiation assembly of the velvet coating system of the oil-based ink printing fabric according to the present invention, Fig. 5 is a perspective view of an outer sleeve which is a main part of the light irradiation assembly shown in FIG. 4, FIG. 6 is a perspective view of an inner sleeve which is a main part of the light irradiation assembly shown in FIG. 4, and FIG. 7 is a velvet coating of oil-based ink printing fabric according to the present invention A perspective view schematically showing the process of curing the oil-based ink on the surface of the oil-based ink printing fabric by the light irradiation assembly of the system, FIG. 8 is a longitudinal cross-sectional view showing the structure of the light irradiation assembly shown in FIG. 7, FIG. 9 is shown in FIG. A longitudinal sectional view schematically showing a process of irradiating light from a light source by the light irradiating assembly, FIG. 10 is a longitudinal sectional view schematically showing a process of irradiating by changing the irradiation range of the light of the light source by the light irradiating assembly shown in FIG. Figure 11 is a perspective view of the coating roller and the coating spray sleeve, which are the main parts of the aqueous coating part of the velvet coating system of the oil-based ink printing fabric according to the present invention, Figure 12 is a side view of the coating spray sleeve shown in Figure 11, Figure 13 is Figure A side view schematically showing the process of spraying an aqueous coating solution on the outer peripheral surface of the coating roller from the coating spray sleeve of the aqueous coating part shown in 11, FIG. 14 is a coating that is the main part of the aqueous coating part in the velvet coating system of the oil-based ink printing fabric according to the present invention A perspective view of a modified embodiment of the spray sleeve and the coating roller, FIG. 15 is a side view schematically showing the process of spraying the aqueous coating solution on the outer peripheral surface of the coating roller in the coating spray sleeve of the aqueous coating part shown in FIG. 14, FIG. 16 is the present invention shows an enlarged example in which the coating liquid spray hole of the coating spray sleeve, which is the main part of the water-based coating part, has a tapered hole structure. 17 is a perspective view schematically showing the process of forming a coating film by curing the aqueous coating solution on the surface of the oil-based printing coating fabric by the drying unit, which is the main part of the present invention, and FIG. 18 is the oil-based ink printing fabric according to the present invention A side view of the base blade body and the cleaning blade for cleaning the outer peripheral surface of the coating roller in the velvet coating system of A side view, FIG. 20 is a side view schematically showing a state in which the base blade body and the cleaning blade shown in FIG. 19 enter a position facing the outer peripheral surface of the coating roller, and FIG. 21 is the outer peripheral surface of the coating roller by the cleaning blade shown in FIG. A front view schematically showing the process of cleaning the residual coating solution of It is a perspective view showing an embodiment in which a plurality of conveyor belts are installed on a work stand in a velvet coating system of a printed fabric.

Referring to the drawings, the velvet coating system of the oil-based ink printing fabric according to the present invention includes an oil-based ink printing unit 120 that performs printing using oil-based ink on a printing fabric 110, and the oil-based ink printing unit 120 . It includes a light irradiation assembly 130 for curing the oil ink by irradiating light to the printed fabric 110 . The present invention is a water-based coating unit ( 140), and a drying unit 150 for drying by irradiating light to the aqueous coating solution applied to the printing fabric 110 by the aqueous coating unit 140 is further included.

The oil-based ink printing unit 120 includes a fabric supply unit 122 and an oil-based ink supply unit 124 .

The fabric supply unit 122 may include a fabric supply roll 122FR rotatably coupled to the main frame 172, and a rotational driving motor (not shown) for rotating the fabric supply roll 122FR. The fabric 110 is wound on the outer circumferential surface of the fabric supply roll 122FR, and the motor shaft of the rotary drive motor is connected to the roll shaft of the fabric feed roll 122FR, and as the motor shaft of the rotary drive motor rotates The printing fabric 110 wound in the form of a winding roll on the outer peripheral surface of the fabric supply roll 122FR can be continuously supplied.

The oil ink supply unit 124 is installed at the front end of the fabric supply unit 122 so that the oil ink is printed on the printing fabric 110 supplied from the fabric supply unit 122 . The front end of the fabric supply unit 122 means the front of the fabric supply unit 122 . When the main frame 172 is viewed from the side, the oil ink supply unit 124 is disposed in front of the fabric supply unit 122 . The fact that the oil-based ink supply unit 124 is installed at the front end of the fabric supply unit 122 means that the oil-based ink supply unit 124 is disposed in front of the fabric supply unit 122 . Since the oil-based ink supply unit 124 is a configuration (for example, a configuration that performs gravure printing or silk-screen printing) by supplying a conventional oil-based ink to the fabric 110 to be printed, further detailed description thereof will be omitted. do it with

In the present invention, the oil-based ink printing unit 120 performs printing, and the light irradiation assembly 130 to be described later performs curing (mainly UV curing) of oil-based ink printing so that the oil-based ink printed on the surface of the fabric 110 for printing is applied. hardening will be performed. The light source 136 provided in the light irradiation assembly 130 may be composed of a UV lamp, and the light source 136 composed of the UV lamp is applied to the fabric 110 on which the oil ink is printed from the oil ink supply unit 124 . and curing the oil ink by irradiating light. In the present invention, a plurality of light sources 136 are mounted on a printed circuit board 136PCB at regular intervals, and the printed circuit board 136PCB is a pair of side-by-side substrate coupling slits extending in the longitudinal direction of the inner sleeve 131. can be inserted. A plurality of light sources 136 mounted on a printed circuit board (136PCB) is slidably pushed into a pair of side-by-side board coupling slits extending in the longitudinal direction of the inner sleeve 131 to form a plurality of inside the inner sleeve 131 . A light source 136 may be built-in, and the plurality of light sources 136 are disposed at positions facing the light passage hole 132 formed in the inner sleeve 131 , and are generated when the plurality of light sources 136 emit light. Light passes through the light passage hole 132 of the inner sleeve 131 and passes through the outer light passage hole 134 of the outer sleeve 134, and then irradiates the surface of the oil ink printing fabric 110 on which the oil ink is printed. Therefore, the oil ink printed on the surface of the fabric 110 may be cured.

The oil-based ink printing unit 120 prints using oil-based ink on the printing fabric 110 , and the oil-based ink-printed fabric 110 in the oil-based ink printing unit 120 passes through the light irradiation assembly 130 to provide oil-based ink. It is configured such that the oil-based ink on the surface of the ink printing fabric 110 is cured and then transferred to the aqueous coating unit 140 to be described later. In this case, the fabric 110 on which the oil ink is printed may be configured to be delivered to the water-based coating unit 140 by the transfer operation unit. For example, a conveyor belt 117 that moves in an endless orbit is installed on the path through which the fabric 110 is transported, and the fabric 110 printed with oil ink is placed on the conveyor belt 117 that moves in an endless orbit. It may be configured to be delivered toward the aqueous coating 140 .

In the present invention, a light source 136 is provided in the light irradiation assembly 130, and the light source 136 is composed of a UV lamp that irradiates light to the printing fabric 110 printed by the oil-based ink printing unit 120. can

In addition, the present invention is an aqueous coating unit 140 for performing aqueous coating by applying an aqueous coating solution to the printing fabric 110 in which the oil ink is cured by the light source 136 (mainly, a UV lamp) of the light irradiation assembly 130 . ), and a drying unit 150 for drying by irradiating light to the aqueous coating solution applied to the printing fabric 110 by the aqueous coating unit 140 .

In the present invention, the light irradiation assembly 130 includes an inner sleeve 131 and an outer sleeve 133 . The light irradiation assembly 130 is disposed on a path through which the oil ink printing fabric 110 on which the oil ink is printed passes, and the inner sleeve 131 is provided with a light passage hole 132 extending in the longitudinal direction, A plurality of light sources 136 facing the light passage hole 132 are provided inside the sleeve 131 at regular intervals, and the outer sleeve 133 extends in the longitudinal direction so that the light passage of the inner sleeve 131 is provided. An external light passage hole 134 that meets the hole 132 is provided, so that light from a plurality of light sources 136 passes through the light passage hole 132 and the external light passage hole 134 to evenly light the fabric 110 . By allowing this to be irradiated, the oil ink printed on the fabric 110 is cured. As described above, the light source 136 of the light irradiation assembly 130 may be configured as a UV lamp. A plug 133CP having a hollow shaft is detachably coupled to both ends of the outer sleeve 133, one of the two plugs is opened to embed the inner sleeve 131 inside the outer sleeve 133 and When both ends of the sleeve 133 are blocked, the light irradiation assembly 130 can have a configuration including the inner sleeve 131 and the outer sleeve 133 .

The light irradiation assembly 130 may be embedded in the housing 112 supported by the main frame 172 . In the present invention, the light irradiation assembly 130 is configured to be disposed above the fabric 110 on which the oil ink is printed in a state supported by the main frame 172 . This is so that the light of the light source 136 provided in the light irradiation assembly 130 is irradiated to the surface of the oil-based ink printing fabric 110 below.

At this time, in the present invention, a plurality of external light passage holes 134 are disposed along the circumferential direction of the outer sleeve 133 , and a plurality of external light passage holes 134 are provided in the outer sleeve 133 , and a plurality of external light passage holes 134 are provided. A width between a pair of facing inner surfaces of each of the external light passage holes 134 in the outer light passage hole 134 is configured to gradually narrow in the circumferential direction of the outer sleeve 133 .

It is configured such that the width of each of the external light passage holes 134 gradually decreases in the circumferential direction of the outer sleeve 133 . For example, along the circumferential direction of the outer sleeve 133 , the first external light passage hole 134 , the second external light passage hole 134 , the third outer light passage hole 134 , and the fourth external light passage hole When the 134 is provided, the width of the first external light passage hole 134 is the largest, and the width of the second external light passage hole 134 is smaller than the width of the first external light passage hole 134, The width of the third external light passage hole 134 is smaller than the width of the second external light passage hole 134 , and the width of the fourth external light passage hole 134 is greater than the width of the third external light passage hole 134 . By being configured to be small, the width of each external light passage hole 134 becomes smaller and smaller as it goes along the circumferential direction of the outer sleeve 133 .

Meanwhile, the inner sleeve 131 is fixed to the main frame 172 by a fixing support means such as a bracket, and the outer sleeve 133 is coaxially disposed on the inner sleeve 131 and the main frame 172 at the same time. It is rotatably supported on the main frame 172 and is configured to rotate relative to the inner sleeve 131 by the outer sleeve 133 rotating unit provided in the main frame 172 . The rotation unit of the outer sleeve 133 is composed of a rotation drive motor mounted on the main frame 172 , and the motor shaft of the rotation drive motor is on one rotation support shaft among the rotation support shafts provided at both ends of the outer sleeve 133 . It may be connected so that the outer sleeve 133 can rotate relative to the inner sleeve 131 as the motor shaft of the rotation driving motor rotates. That is, in the present invention, the inner sleeve 131 of the light irradiation assembly 130 is fixed and only the outer sleeve 133 is configured to be rotatable.

As the outer sleeve 133 rotates, the outer light passage holes 134 having different widths are aligned to meet the light passage holes 132 of the inner sleeve 131 . In the outer sleeve 133 along the circumferential direction, a first external light passage hole 134 , a second external light passage hole 134 , a third external light passage hole 134 , and a fourth external light passage hole 134 are provided. When provided, as the outer sleeve 133 rotates, the first outer light passage hole 134, the second outer light passage hole 134, and the third outer light passage hole 132 of the inner sleeve 131 rotate. The light passage hole 134 and the fourth external light passage hole 134 may be arranged to selectively meet each other. For example, if the first outer light passage hole 134 of the outer sleeve 133 is aligned to meet the light passage hole 132 of the inner sleeve 131 , the second outside of the outer sleeve 133 . The light passage hole 134 , the third external light passage hole 134 , and the fourth outer light passage hole 134 return to positions where they do not meet the light passage hole 132 of the inner sleeve 131 .

As the outer sleeve 133 rotates, the outer light passage holes 134 of different widths are aligned to meet the light passage holes 132 of the inner sleeve 131, so that the light from the light source 136 is transmitted to the fabric ( The range irradiated to the surface of 110) is adjusted, so that the curing speed of the oil ink printed on the surface of the fabric 110 is adjusted.

In the outer sleeve 133 in the circumferential direction, a first external light passage hole 134 , a second external light passage hole 134 , a third external light passage hole 134 , and a fourth external light passage hole 134 . If this is provided, the outer sleeve 133 is rotated and aligned so that the first outer light passage hole 134 of the outer sleeve 133 meets the light passage hole 132 of the inner sleeve 131, The light source 136 is irradiated with the widest range, so the curing speed of the oil ink printed on the surface of the fabric 110 is the fastest, and the outer sleeve 133 rotates to allow the light to pass through the inner sleeve 131 . If the hole 132 is aligned so that the fourth external light passage hole 134 of the outer sleeve 133 meets, the light irradiated range of the light source 136 becomes the narrowest, so that the surface of the fabric 110 is Printed oil inks have the slowest curing rate.

Therefore, in the present invention, as the outer sleeve 133 of the light irradiation assembly 130 rotates, the range in which the light of the light source 136 is irradiated to the surface of the fabric 110 is adjusted while the printed on the surface of the fabric 110 is adjusted. Since the curing speed of the oil ink is controlled, there is an effect that the curing speed of the oil ink can be suitably adjusted according to the type of the fabric 110 on which the oil ink is printed. It is necessary to adjust the curing speed of the oil ink according to the type of the fabric 110 on which the oil ink is printed. In the present invention, as the outer sleeve 133 of the light irradiation assembly 130 rotates, the light source 136 As the range in which light is irradiated to the surface of the fabric 110 is adjusted, the curing speed of the oil ink printed on the surface of the fabric 110 is adjusted, so regardless of the type of the fabric 110 on which the oil ink is printed. It has the effect of creating an appropriate curing condition for In response to the type of the fabric 110 on which the oil ink is printed, as well as the type of oil ink or the curing temperature condition of the oil ink, the outer sleeve 133 of the light irradiation assembly 130 rotates so that the light source 136 Of course, the curing speed of the oil ink printed on the surface of the fabric 110 can be controlled by adjusting the range in which light is irradiated to the surface of the fabric 110 . The configuration of the light irradiation assembly 130 has a great meaning in that it allows the oil ink to be properly printed on the fabric 110 to respond to all conditions for curing.

A coating roller 142 is provided on the path through which the fabric 110 passes. The coating roller 142 functions to apply a coating solution to the surface of the fabric 110 . The coating roller 142 rotates in a state in which the coating liquid is supplied to the outer peripheral surface of the coating roller 142, and the fabric 110 printed with oil ink passes between the outer peripheral surface of the rotating coating roller 142 and the work stand. 110) is configured so that the coating solution is applied.

On the other hand, the coating roller 142 and parallel to the coating spray sleeve 144 is provided. The coating spray sleeve 144 is supported by a support means such as a bracket on the main frame 172 so that the outer peripheral surface of the coating roller 142 and the outer peripheral surface of the coating spray sleeve 144 are arranged in parallel with each other. The coating spraying sleeve 144 is provided with a coating liquid spraying hole 145 that meets the outer peripheral surface of the coating roller (142).

At this time, a plurality of the coating liquid spraying holes 145 are provided along the circumferential and longitudinal directions of the coating spraying sleeve 144 , and adjacent to each other in the plurality of coating liquid spraying holes 145 provided in the coating spraying sleeve 144 . One coating liquid spraying hole 145 is disposed to be shifted from each other in the longitudinal direction of the coating spraying sleeve 144 .

In the present invention, the coating liquid injection hole 145 may be configured in a circular hole shape or may be configured in a long hole shape extending by a predetermined length along the longitudinal direction of the coating injection sleeve 144 .

A plurality of coating liquid spraying holes 145 having a circular hole shape are provided along the circumferential and longitudinal directions of the coating spraying sleeve 144 , and each other in the plurality of coating liquid spraying holes 145 provided in the coating spraying sleeve 144 . The adjacent coating liquid spraying holes 145 are disposed to be shifted from each other in the longitudinal direction of the coating spraying sleeve 144 .

On the other hand, a plurality of coating liquid spraying holes 145 in the shape of a long hole extending a certain length in the longitudinal direction of the coating spraying sleeve 144 are also provided along the circumferential and longitudinal directions of the coating spraying sleeve 144, and the coating spraying sleeve The coating solution jetting holes 145 adjacent to each other in the plurality of coating solution jetting holes 145 provided at 144 are disposed to be shifted from each other based on the longitudinal direction of the coating jetting sleeve 144 .

Specifically, if the circumferential direction of the coating spraying sleeve 144 is referred to as a row direction and the longitudinal direction of the coating spraying sleeve 144 is referred to as a column direction, a plurality of coating liquid spraying holes 145 are formed in a row of the coating spraying sleeve 144 . direction and column direction.

In the present invention, the coating liquid spraying holes 145 are provided in two rows along the circumferential direction of the coating spraying sleeve 144 . That is, two parallel coating liquid spray holes 145 are provided along the circumferential direction of the coating spray sleeve 144 . The coating liquid injection hole 145 is provided in two rows along the circumferential direction of the coating injection sleeve 144 whether the circular hole shape or the long hole shape.

A plurality of coating solution spraying holes 145 are provided in the row direction and column direction in the coating spraying sleeve 144. Among the coating spraying holes 145 provided in a plurality of columns in the coating spraying sleeve 144, adjacent to each other. The heat of the coating liquid injection hole 145 is disposed so as to be displaced from each other when going along the longitudinal direction of the coating injection sleeve 144 . The coating liquid spraying holes 145 in odd rows are arranged on the same line along the longitudinal direction of the coating spraying sleeve 144 , and the coating liquid spraying holes 145 in even rows are in odd rows along the longitudinal direction of the coating spraying sleeve 144 . While displaced from the holes 145 , the coating liquid spraying holes 145 in even rows are disposed on the same line along the longitudinal direction of the coating spraying sleeve 144 . For example, when the coating spraying sleeve 144 is viewed from the side, the first row of the coating liquid spraying holes 145 and the second row of the coating liquid spraying holes 145 are arranged so that the coating spraying sleeve 144 is shifted from each other in the longitudinal direction, and , 3 rows of the coating solution spraying holes 145 are arranged to be shifted from the second row of coating solution spraying holes 145 in the longitudinal direction of the coating spraying sleeve 144, and at the same time, the coating solution spraying holes 145 in the first row of the coating spraying sleeve (144) is arranged on the same line with respect to the longitudinal direction, and the coating liquid spraying holes 145 in the fourth row are arranged to be displaced from the coating liquid spraying holes 145 in the third row in the longitudinal direction of the coating spraying sleeve 144. At the same time, the second row of the coating liquid spraying holes 145 are arranged on the same line in the longitudinal direction of the coating liquid spraying sleeve. In other words, the plurality of coating liquid spraying holes 145 are configured to be arranged in a zigzag form in the circumferential direction of the coating spraying sleeve 144 .

Therefore, in the present invention, the coating solution is supplied to the outer circumferential surface of the coating roller 142 through the coating solution spray hole 145 of the coating spray sleeve 144, and the coating roller 142 is rotated to work with the outer circumferential surface of the coating roller 142 A coating film by a coating solution is formed on the surface of the oil-based ink printing fabric 110 by passing the oil-based ink printed fabric 110 (referred to as the oil-based ink printing fabric 110 for convenience) between the upper surfaces of the stance, and a plurality of rows of the coating solution The injection holes 145 take a structure arranged in rows that are displaced from each other when proceeding along the longitudinal direction of the coating injection sleeve 144, so that the coating liquid is transferred from the plurality of rows of the coating liquid injection holes 145 to the coating roller 142. When sprayed on the outer circumferential surface of the oil-based ink printing fabric 110, the coating solution is evenly sprayed without falling out of the surface. 110) can reliably prevent the deterioration of the coating quality.

In addition, in the present invention, the coating liquid spraying holes 145 are arranged in at least two rows on the coating spraying sleeve 144, so that the coating liquid is sprayed on the coating roller 142 in at least two rows, so the coating roller 142 ), the coating solution is more uniformly supplied to the outer peripheral surface, thereby more reliably improving the coating quality of the oil-based ink printing fabric 110 .

On the other hand, in the present invention, the coating liquid injection hole 145 is configured in the shape of a long hole extending to a predetermined length along the longitudinal direction of the coating injection sleeve (144).

When the coating liquid injection hole 145 has a long hole shape, the width through which the coating liquid is sprayed becomes larger so that the coating liquid spread out to the outer circumferential surface of the coating roller 142 is supplied to a wider area, so oil-based ink printing fabric 110 Since the coating liquid can be supplied to this surface without omission on the printing surface, it is possible to more reliably prevent a coating defect in which the coating film is not properly formed due to the coating liquid leaking from the oil-based ink printing fabric 110 .

Of course, the coating liquid spraying holes 145 of the long hole shape are also arranged in at least two rows in the coating spraying sleeve 144, so that the coating liquid is sprayed on the coating roller 142 in at least two rows, so the coating roller 142 ), the coating solution is more uniformly supplied to the outer circumferential surface, thereby making it possible to more reliably improve the coating quality of the oil-based ink printing fabric 110 .

On the other hand, in the present invention, the coating liquid injection holes 145 are configured in a tapered hole shape. The coating liquid injection hole 145 is configured in a tapered hole shape in which the diameter gradually increases from the inner peripheral surface to the outer peripheral surface of the coating injection sleeve 144 .

When the coating liquid spray hole 145 has a circular hole shape, the diameter of the coating liquid spray hole 145 increases from the inner circumferential surface to the outer circumferential surface of the coating spray sleeve 144 so that the circular coating solution spray holes 145 have a tapered hole shape. is composed of

Even when the coating liquid spray hole 145 has a long hole shape extending a certain length in the longitudinal direction of the coating spray sleeve 144, the diameter of the coating liquid spray hole 145 increases from the inner circumferential surface of the coating spray sleeve 144 toward the outer circumferential surface. The coating liquid injection hole 145 having a long hole shape is also configured in a tapered hole shape.

When the coating liquid spray hole 145 has a tapered hole shape, the coating liquid is discharged into the coating liquid spray hole 145 inside the coating spray sleeve 144 and automatically spreads widely, so that it is more and more on the outer circumferential surface of the coating roller 142 It is possible to spray the coating solution without omission, and thereby the coating roller 142 can more reliably guarantee the high quality of the coating film coated on the surface of the oil-based ink printing fabric 110 . While adopting a simple structure in which the coating liquid injection hole 145 is a tapered hole, the coating liquid is uniformly supplied to the outer peripheral surface of the coating roller 142, ultimately forming a coating film of the oil-based ink printing fabric 110. More reliable quality It is of great significance in that it guarantees

On the other hand, in the present invention, it further includes a drying unit 150 , the drying unit 150 is supported by the main frame 172 on which the coating roller 142 is supported and disposed above the work stand 116 . The drying unit 150 may be configured such that the drying lamp 152 is mounted on the drying lamp 152 frame supported by the main frame 172 . A plurality of drying lamps 152 may be disposed along the left and right width directions of the work stand 116 .

The aqueous coating solution is dried by the drying unit 150 in a state in which the oil-based ink printing fabric 110 on which the aqueous coating solution is applied while passing the coating roller 142 is discharged onto the work stand 116, so that the It is possible to form a cured coating film on the surface of the oil-based ink printing fabric 110 . A coating film is formed on the surface of the oil-based ink printing fabric 110 by irradiating light to the aqueous coating solution applied to the surface of the oil-based ink printing fabric 110 in the drying lamp 152 of the drying unit 150 to cure the aqueous coating solution. can do.

The drying unit 150 covers the upper side of the housing 112 forming an inner space for the printing fabric 110 to move, and the housing 112 that is opened so that a worker can move across the housing 112 , An oil-based ink coating fabric on which an oil-based ink is printed and cured by irradiating light to the installed working scaffold 115 and the printing fabric 110 that is built into the housing 112 and is moving along the inner space of the housing 112 A lamp 152 for drying the coating film of 110 may be included. 17, the lamp 152 may be composed of a plurality of IR lamps. The lamp 152 is mounted on a lamp mounting plate 151 (which may be a printed circuit board mainly), and the lamp mounting plate 151 is supported on the housing 112, so that a plurality of lamps 152 are installed with an aqueous coating solution. It is disposed above the applied oil-based ink printing fabric 110, by irradiating the light of the lamp 152 to dry the aqueous coating solution, it is possible to form a coating film on the surface of the oil-based ink printing fabric 110.

On the other hand, as shown in FIG. 23 , in the present invention, the work stand 116 is arranged to be spaced apart from each other at regular intervals along the left and right width directions of the oil-based printing ink fabric 110 , and the conveyor is between the adjacent work stands 116 . A belt accommodating hole 116VH is formed, and a conveyor belt 117 that moves in an endless orbit is accommodated in the conveyor belt accommodating hole 116VH. When the printing fabric 110 is raised to the work stand 116, the conveyor belt 117 is fed smoothly toward the drying unit 150 while moving in an endless orbit, and in the drying ramp 152 of the drying unit 150, By irradiating light to the aqueous coating solution applied to the surface of the oil-based ink printing fabric 110 to cure the aqueous coating solution, it is possible to form a coating film on the surface of the oil-based ink printing fabric 110 . In the process of forming a coating solution on the surface of the oil-based ink printing fabric 110, reliability can be increased.

On the other hand, as shown in Figure 22, the present invention may further include a curtain 148 disposed adjacent to the outer peripheral surface of the coating roller 142. In this case, the curtain 148 includes a main curtain 148MC disposed at a position facing the outer circumferential surface of the coating roller 142 and a side curtain 148SC disposed at a position facing both ends of the printing hole.

The main curtain 148MC prevents the coating liquid from splashing outward from the coating roller 142, and the side curtain 148SC blocks the coating liquid even if the coating liquid splashes toward both ends of the coating roller 142. It completely prevents the case of splashing the coating solution from the coating roller 142 by giving it. By preventing the coating liquid from splashing by the curtain 148 during the coating operation, it is possible to completely prevent the surrounding environment from being dirty by the coating liquid.

In addition, the present invention is a base blade body 162 disposed adjacent to the outer circumferential surface of the coating roller 142, and is rotatably mounted to the base blade body 162 by a hinge, so that the blade portion of the coating roller 142 is rotatably mounted. The cleaning blade 163 in contact with the outer circumferential surface is connected between the cleaning blade 163 and the base blade body 162 so that the blade portion of the cleaning blade 163 is in elastic contact with the outer circumferential surface of the coating roller 142 A contact elastic body 164 may be further included.

The base blade body 162 includes a bracket on the auxiliary support frame 174 provided on the side of the main frame 172 in which the oil ink printing unit 120, the light irradiation assembly 130, and the drying unit 150 are supported. It may be configured to be supported by a fixed support means such as a bolt to move to a position facing the outer circumferential surface of the coating roller 142 or to fall out of the coating roller 142 . The base blade body 162, the cleaning blade 163, and the contact elastic body 164 are moved to a position facing the outer peripheral surface of the coating roller 142 by the moving unit 166 or fall out of the coating roller 142. It may be configured, and the mobile unit 166 will be described later.

The contact elastic body 164 is composed of a spring, both ends of the contact elastic body 164 are connected to the base blade body 162 and the cleaning blade 163, respectively, so that the base blade and the cleaning blade 163 are connected to the contact elastic body ( 164), it is maintained in a state of being spread out on the same line in a straight line.

The base blade body 162, the cleaning blade 163, and the contact elastic body 164 move so as to be removed from the outer peripheral surface of the coating roller 142 by the operation of the moving unit 166, or move toward the outer peripheral surface of the coating roller 142. is configured to

An auxiliary support frame 174 is provided on the side of the main frame 172 on which the oil ink printing unit 120, the light irradiation assembly 130, and the drying unit 150 are supported, and the moving unit 166 is an auxiliary In the support frame 174 , the base blade body 162 , the cleaning blade 163 , and the contact elastic body 164 move so as to be removed from the outer peripheral surface of the coating roller 142 or move toward the outer peripheral surface of the coating roller 142 .

The moving unit 166 includes a moving driving motor mounted on an auxiliary support frame 174, a ball screw coupled to a motor shaft of the moving driving motor, a support block supporting the base blade body 162, and the It may be configured to include a ball screw nut provided on the support block and coupled to the ball screw. Even in this case, the support block is movably coupled to the auxiliary support frame 174 by the LM guide.

In the present invention, the support block may be referred to as a fixed support means. For convenience of description, the fixed support means may be referred to as a support block in advance.

When the motor shaft of the moving drive motor rotates in one direction and the ball screw rotates in one direction, the support block is positioned opposite the outer circumferential surface of the coating roller 142 by the ball screw and the ball screw nut. 142), the base blade body 162, the cleaning blade 163, and the contact elastic body 164 are moved so as to be removed from the outer peripheral surface of the coating roller 142.

When the motor shaft of the moving drive motor rotates in the other direction and the ball screw rotates in the other direction, the support block is brought to a position facing the outer circumferential surface of the coating roller 142 by the ball screw and the ball screw nut. Comes, the blade of the cleaning blade 163 is in contact with the outer peripheral surface of the coating roller 142, due to the elastic force of the contact elastic body 164, the blade of the cleaning blade 163 is the outer peripheral surface of the coating roller 142 with an appropriate pressure. can be kept in contact.

On the other hand, the moving unit 166 may be configured to include a moving actuating cylinder in addition to a moving actuating motor, a ball screw, and a ball screw nut, and a cylinder rod of the moving actuating cylinder may be connected to the support block.

In this case, if the cylinder rod of the moving operation cylinder is moved backward, the support block falls out of the coating roller 142 at a position facing the outer circumferential surface of the coating roller 142, and the base blade body 162 and the cleaning blade 163 and the contact elastic body 164 are moved so as to be removed from the outer circumferential surface of the coating roller 142, and when the cylinder rod of the moving operation cylinder is advanced, the support block faces the outer circumferential surface of the coating roller 142 The blade portion of the cleaning blade 163 may come into contact with the outer peripheral surface of the coating roller 142 . Of course, even in this case, due to the elastic force of the contact elastic body 164, the blade portion of the cleaning blade 163 may be maintained in contact with the outer peripheral surface of the coating roller 142 with an appropriate pressure.

A cleaning tray 167 is provided under the cleaning blade 163 . The cleaning tray 167 is mounted on the support block on which the base blade body 162 is supported by fixed support means such as brackets and bolts, and the base blade body 162 and the cleaning blade ( When the 163) and the contact elastic body 164 are moved so as to be removed from the outer circumferential surface of the coating roller 142, the cleaning tray 167 also moves and the cleaning tray 167 is disposed under the cleaning blade 163, and the moving unit When the base blade body 162, the cleaning blade 163, and the contact elastic body 164 are moved to a position facing the outer circumferential surface of the coating roller 142 by the 166, the cleaning tray 167 is also moved and the cleaning blade ( The cleaning tray 167 may be disposed under the 163 , and at the same time the cleaning tray 167 may also be disposed at a position facing the outer peripheral surface of the coating roller 142 . The cleaning tray 167 is configured to enter under the cleaning blade 163 by the moving unit when scraping the coating solution residue from the outer peripheral surface of the coating roller 142 by the cleaning blade 163 .

Accordingly, the base blade body 162, the cleaning blade 163, the contact elastic body 164, and the cleaning tray 167 are moved to a position facing the outer peripheral surface of the coating roller 142 by the moving unit 166. When the coating roller 142 rotates while the blade portion of the cleaning blade 163 is in elastic contact with the outer circumferential surface of the coating roller 142 by the contact elastic body 164, the coating roller 142 outer circumferential surface It will clean the coating solution residue remaining in the Since the blade of the cleaning blade 163 is in contact with the outer circumferential surface of the coating roller 142, the aqueous coating solution remaining attached to the outer circumferential surface of the coating roller 142 by the cleaning blade 163 when the coating roller 142 rotates. Since the residue is removed, the outer peripheral surface of the coating roller 142 is cleaned by the cleaning blade 163 . When the coating roller 142 rotates, the cleaning blade 163 scrapes off the residue of the aqueous coating solution remaining on the outer peripheral surface of the coating roller 142 and removes it, so the outer peripheral surface of the coating roller 142 is cleaned. . The blade portion of the cleaning blade 163 is scraped off from the outer circumferential surface of the coating roller 142 to remove the residue of the aqueous coating solution remaining on the outer circumferential surface of the coating roller 142 .

At this time, the coating solution residue scraped off from the outer peripheral surface of the coating roller 142 is collected in the cleaning tray 167 . Since the residue of the aqueous coating solution scraped off from the outer circumferential surface of the coating roller 142 by the cleaning blade 163 falls to the cleaning tray 167 below, the aqueous coating solution remaining attached to the outer circumferential surface of the coating roller 142 in the cleaning tray 167 water can be collected.

On the other hand, when the cleaning operation of scraping and removing the aqueous coating solution residue from the outer circumferential surface of the coating roller 142 is completed, the base blade body 162 and the cleaning blade 163 are in contact with the operation of the moving unit 166 The elastic body 164 and the cleaning tray 167 are moved to fall out from the outer peripheral surface of the coating roller 142 together.

Therefore, since the present invention can clean the residue of the aqueous coating solution remaining on the outer peripheral surface of the coating roller 142, the coating film is formed on the oil-based ink printing fabric 110 while maintaining the coating roller 142 properly. It is possible to increase the reliability in the operation and to ensure the quality of the coating film of the oil-based ink printing fabric (110).

On the other hand, in the present invention, the cleaning tray 167 collects the aqueous coating solution from below when the aqueous coating solution sprayed from the coating solution spray hole 145 of the coating spray sleeve 144 is sprayed on the outer peripheral surface of the coating roller 142. The coating It may be configured to be disposed at a lower position of the roller 142 .

The above-described embodiments are for illustration, and those of ordinary skill in the art to which the above-described embodiments pertain can easily transform into other specific forms without changing the technical idea or essential features of the above-described embodiments. You will understand. Therefore, it should be understood that the above-described embodiments are illustrative in all respects and not restrictive. For example, each component described as a single type may be implemented in a dispersed form, and likewise components described as distributed may also be implemented in a combined form.

The scope to be protected through this specification is indicated by the claims described below rather than the above detailed description, and should be construed to include all changes or modifications derived from the meaning and scope of the claims and their equivalents. .

110. Fabric 112. Housing
113. Lamp mounting plate 115. Working platform
116. Working Stand 117. Conveyor Belt
120. Oil-based ink printing unit 122. Fabric supply unit
124. Oil-based ink supply unit 130. Light irradiation assembly
131. Inner sleeve 132. Light passage hole
133. Outer sleeve 134. Outer light passage hole
136. Light source 140. Water-based coating
142. Coating roller 144. Coating spray sleeve
145. Coating liquid spray hole 148. Curtain
148MC. Main curtain 148SC. side curtain
150. Dryer 152. Lamp
162. Base blade body 163. Cleaning blade
164. Contact elastic body 166. Moving unit
167. Cleaning tray 172. Main frame
174. Auxiliary Support Frame

Claims (4)

A water-based coating unit 140 for forming a coating film by applying an aqueous coating solution to the oil-based ink printing fabric 110 on which the oil-based ink is printed on the surface;
Oil-based ink printing unit 120 for performing printing by using oil-based ink on the fabric for printing 110;
A light irradiation assembly 130 for curing the oil ink by irradiating light to the fabric 110 printed by the oil ink printing unit 120;
The light irradiation assembly 130 is configured to include an inner sleeve 131 and an outer sleeve 133 and is disposed on a path through which the oil-based ink printed fabric 110 passes, and the inner sleeve 131 has a longitudinal direction. A light passage hole 132 extending to ) is provided with an external light passage hole 134 extending in the longitudinal direction and meeting the light passage hole 132 of the inner sleeve 131 , so that the light from the plurality of light sources 136 passes through the light passage hole 132 . ) and the external light passage hole 134 and is configured to evenly irradiate the light to the fabric 110,
The external light passage hole 134 is arranged in plurality along the circumferential direction of the outer sleeve 133 , the outer sleeve 133 is provided with a plurality of external light passage holes 134 , and a plurality of the external light passage holes 134 are provided. The width between the pair of facing inner surfaces of each of the outer light passage holes 134 in the passage hole 134 is configured to gradually narrow in the circumferential direction of the outer sleeve 133, so that the outer sleeve ( 133) is configured such that the width of each of the external light passage holes 134 gradually decreases along the circumferential direction,
The outer sleeve 133 is configured to be rotatable, so that as the outer sleeve 133 rotates, the outer light passage hole 134 having a different width meets the light passage hole 132 of the inner sleeve 131 . and the range in which the light of the light source 136 is irradiated to the surface of the fabric 110 is adjusted so that the curing speed of the oil ink printed on the surface of the fabric 110 is adjusted. Velvet coating system for ink-printed fabrics.
delete According to claim 1,
A light source 136 is provided in the light irradiation assembly 130, and the light source 136 emits UV light through a UV lamp to the printing fabric 110 on which oil ink is printed by the oil ink printing unit 120. It consists of a UV lamp that irradiates,
The velvet coating system of oil-based ink printing fabric, characterized in that it further comprises; a drying unit 150 for drying by irradiating light to the aqueous coating solution applied to the printing fabric 110 by the aqueous coating unit 140 . delete

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