KR102025230B1 - A method for manufacturing an infrared shielding tent fabric and a method for manufacturing a railway tent fabric - Google Patents

Abstract

Disclosed is a method for manufacturing an infrared shielding tent fabric, and a thermal barrier tent fabric produced thereby.
Among them, a method for manufacturing an infrared shielding tent fabric is a coat coating step of forming a infrared absorbing layer by wet coating an infrared absorbing material on the tent fabric; A middle coating step of forming an infrared reflecting layer by coating an infrared reflecting material on the infrared absorbing layer by a sputtering process; And a top coat coating wet coating on the infrared reflecting layer to form a protective layer protecting the infrared reflecting layer.

Description

A method for manufacturing an infrared shielding tent fabric and a method for manufacturing a railway tent fabric

The present invention relates to an infrared shielding tent fabric manufacturing method and a thermal barrier tent fabric produced thereby.

More specifically, a layer coating is preceded by a coating for effective sputtering of the infrared shielding material on the surface of the tent fabric, the coating of the infrared shielding material by sputtering thereon, and the top coating thereon to protect the intermediate coating layer. The present invention relates to a method for smoothly performing a multi-stage coating process and a thermal barrier tent fabricated by the method.

Recently, various kinds of functional fibers have been released in accordance with the trend of high-end textile products, and as a part of this, research and technology development for thermal barrier fibers have been actively progressed. The thermal barrier fiber is a functional fiber that provides a feeling of comfort by providing a cooling effect under the heat wave in summer by including a material that blocks near infrared rays in the fiber.

In this regard, Japanese Patent Application No. 2002-370319 discloses a heat ray barrier fiber cloth comprising a fiber cloth and a resin layer containing an infrared absorber having a particle diameter of 500 nm or less imparted to at least one side thereof. 2008-075184 discloses a heat-reflecting particle-containing fiber in which a titanium oxide having a particle diameter of 0.2 to 0.7 µm is coated with a metal oxide, and the additives surface-treated with a silane coupling agent are mixed.

In addition, Japanese Patent Application No. 2011-047566 discloses an infrared shielding cloth and a textile product in which a resin containing an infrared reflector such as titanium oxide is partially attached onto at least one side of a knitted fabric.

However, in the related art, only a method of attaching or coating an infrared reflector for blocking infrared rays on a fiber fabric is proposed, and a technique of coating an infrared shielding layer (midway) between the upper and the upper layers as described herein has not been disclosed.

Document 1: Unexamined Patent Publication No. 10-2016-0070262 Document 2: Registration Utility Model Publication No. 20-0391057

The present invention precedes the undercoat in order to effectively sputter the infrared shielding material on the surface of the tent fabric, and a series of coatings on top of the infrared shielding material by sputtering thereon, and the top coating on the protective layer to protect the intermediate coating layer. It is an object to provide a method for carrying out the process.

In addition, the present invention has another object to provide a thermal barrier tent fabric produced by the manufacturing method.

The problem to be solved by the present invention is not limited to the above-mentioned problems, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

According to an object of the present invention, the unwinder to release the dent fabric being wound in the working direction, but released in a decelerated state by the power clutch, pressing the surface of the radar tent fabric wound on the unwinder A raw material supply unit including a member and a cylinder for displacement of the pressing member for displacing the position of the pressing roller of the pressing member;
A fabric transfer unit including an electrostatic scavenging member for spraying an electrostatic scavenger to the fabric of the tent passing through the driving roller while being installed in the body of the transfer unit;
A coater for coating an infrared reflecting solution or a protective solution on the tent fabric, and a coating apparatus including a tilt adjusting member for adjusting a horizontal tilt of the coater based on a rotation axis provided in the coater;
A drying unit drying the coating solution of the tent fabric by warm air; And
An upper and upper coating apparatus including a; a recovery unit including a denser roller coupled to a lower end of the denser roller bracket which is hinged to an upper end of the recovery body and is rotatable by a bracket cylinder; And

Sputtering unit, cathode unit, primary and secondary vacuum pumps and chillers,
The sputtering unit is vacuumed by the first and second vacuum pumps, the process chamber is a sputtering process is performed; A drum rotatably installed inside the process chamber to wind the tent fabric; And a shield plate that partitions the space between the inner surface of the process chamber and the drum into a plurality of spaces to form a plurality of isolated working spaces.
The primary vacuum pump is a low pressure pump for the initial vacuum for evacuating the chamber at atmospheric pressure,
The secondary vacuum pump is a vacuum coating device comprising a middle coating device comprising a cryo, TMP, turbo molecular pump to completely vacuum the inside of each chamber and remove moisture in the chamber together. Tent fabric manufacturing method,

The tent fabrication method comprises a bottom coating step of wet coating an infrared absorbing material on the tent fabric to form an infrared absorbing layer;
A middle coating step of forming an infrared reflecting layer by coating an infrared reflecting material on the infrared absorbing layer by a sputtering process; And
A top coat coating step of wet coating on the infrared reflecting layer to form a protective layer protecting the infrared reflecting layer;
The undercoat coating step,
Installing the tent fabric on the unwinder;
Transferring one end of the tent fabric to a work direction by a driving roller of a fabric conveying unit disposed at a next position of the unwinder;
Coating a primer solution including an infrared absorbing material on a tent fabric by a coater of a coating unit disposed at a next position of the fabric transfer unit;
Passing the primer-coated tender fabric to a drying chamber of a drying unit disposed at a next position of the coating unit, and drying by hot air at a temperature of 50 to 120 ° C .; And
Recovering by winding the fabric of the tender coated with the primer solution onto a roll by a rewinder which is rotated while being disposed at a next position of the drying unit;
The primer is a water-dispersible polyurethane resin, the water-dispersible polyurethane resin is 25 to 29% by weight of aliphatic isocyanate polyol, 0.4 to 1% by weight of triethylamine as a chain extender, N- methyl diethanolamine 2 4 to 4% by weight and 68 to 70% by weight of water are mixed, and 26 to 32% by weight of an alkali copolymer compound, 1 to 3% by weight of alkali polyoxyethylene sulfate, 0.001 to 0.2% by weight of potassium sulfate, and Provided is a tent fabrication method for infrared ray shielding, characterized in that the thickener mixed with the remainder of the water is prepared by mixing and stirring the water-dispersible polyurethane resin with the dispersion water.

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Preferably, the intermediate coating step, the step of introducing a cathode of the cathode module into the process chamber of the sputtering unit; The first vacuum pump and the second vacuum pump are operated in order to vacuum the loading chamber of the loading unit, the process chamber of the sputtering unit, and the inside of the unloading chamber of the unloading unit, and the vacuum degree of the process chamber is 5 × 10 ^-5 Torr. Evacuating to Injecting an inert gas such as Ar gas into the process chamber so that the internal vacuum of the process chamber is 3 × 10 ⁻³ to 5 × 10 ⁻³ Torr; The infrared reflecting material of the target mounted on the cathode is deposited on the primer-coated surface of the tent fabric by sputtering action of powering the cathode while driving the tent fabric mounted over the loading chamber, the process chamber and the unloading chamber. Doing; And recovering the tent fabric in which the deposition is completed.

Preferably, the infrared reflecting material may include at least one selected from Al, Cr, Sus, Silver, and Ni / Cr alloys.

Preferably, the top coat coating step, the step of installing the tent fabric through the uncoated coat and the middle coat step; Transferring one end of the tent fabric to a work direction by a driving roller of a fabric conveying unit disposed at a next position of the unwinder; Coating a protective solution including a waterproofing material, a barrier material, and a flame retardant material of a tent fabric by a coater of a coating unit disposed at a next position of the fabric transfer unit; Passing through the tent fabric coated with the protective solution to a drying chamber of a drying unit disposed at a next position of the coating unit and drying by hot air at a temperature of 50 to 120 ° C .; And rewinding the tent fabric coated with the protective solution onto a roll by a rewinder which is rotated while being disposed at a next position of the drying unit.

Preferably, the protective solution includes at least one selected from a dispersed titanium liquid, a dispersed silica liquid, a urethane-based primer, an acrylic primer, an epoxy-based primer, a nylon-based primer, and a silicone-based primer, wherein the waterproofing agent is polyacrylic or polyurethane-based , Polysilicon-based one or more selected, the anti-corrosive agent 8-hydroxyquinoline Cu-acetate (8-hydroxyquinoline copper acetate), trimethylol melamine (trimethylol melamine), dimethylol ethylene urea, organic silver (organic silver) ), Silicon-based quaternary ammonium salts, silicon tetrahydride, tetra benzyl tin, dibutyl laurate includes at least one selected from the group, the flame retardant polyaryl phosphate ester type, alkylated polyaryl phosphate ester type, alkylaryl phosphate Ester-based, trialkylphosphate esters, One or more selected from hexabromocyclododecane may be included.

According to another object of the present invention, a thermal barrier tent fabric is provided by sequentially stacking an infrared absorbing layer, an infrared reflecting layer and a protective layer on the tent fabric by the method of claim 1.

The present invention can provide a method for effectively coating an infrared shielding material (infrared absorbing and reflecting material) on the tent fabric can increase the infrared shielding performance by increasing the coating completeness of the infrared shielding material, the coating agent The additional components included also have the effect of waterproofing, burial and flame retardant.

1 is a block diagram illustrating a method for manufacturing an infrared shielding tent fabric according to the present invention.
Figure 2 is an overall configuration diagram of the undercoat and top coat coating apparatus for manufacturing an infrared shielding tent fabric according to the present invention
3 is a detailed view of the fabric supply unit
4 is a detailed view of the fabric transfer unit
5 is a detailed view of the coating unit
6 is a detailed view of the drying unit
7 is a detailed view of the recovery unit
Figure 8 is an overall configuration of the intermediate coating device for manufacturing the infrared ray shielding tent fabric according to the present invention
9 is a top view of FIG. 8
10 is a front view of FIG. 8
11 is a detailed cross-sectional view of the sputtering unit
12 is a cross-sectional view of the tent fabric according to the present invention

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like elements throughout the specification.

Throughout the specification, when a part is said to be "connected" with another part, it includes not only "directly connected" but also "indirectly connected" with another member therebetween. In addition, when a part is said to "include" a certain component, this means that it may further include other components, except to exclude other components unless otherwise stated.

Terms used in the present invention are terms defined in consideration of functions in the present invention, which may vary according to a user's intention or an operator's intention or custom, and thus, definitions of these terms are intended to be consistent with the technical matters of the present invention. It should be interpreted as and concepts.

In addition, the optional terms in the following embodiments are used to distinguish one component from another component, and the component is not limited by the terms. In the following description, detailed descriptions of related well-known technologies that may unnecessarily obscure the subject matter of the present invention will be omitted.

Hereinafter, specific embodiments of the present invention will be described.

1 is a block diagram illustrating a method for manufacturing an infrared shielding tent fabric according to the present invention.

According to Figure 1, one embodiment of the present invention, after coating the primer containing the infrared absorbing material under the pretreatment step for sputtering the infrared reflecting material on the tent fabric or glamping fabric or tent fabric, A method of manufacturing an infrared shielding tent fabric is coated on top of the infrared shielding material by sputtering, and the top coat is coated to protect the intermediate coated portion thereon. FIG. 12 is a cross-sectional view of the tent fabric manufactured by the method.

The undercoat coating step (S100) is started from the step (S101) of installing the tent fabric on the roll unwinder.

Next, the step (S102) of transferring the one end of the tent fabric 10 in the working direction by the driving roller of the fabric transfer unit disposed at the next position of the unwinder.

Next, the step (S103) of coating the infrared absorbing solution on the tent fabric 10 by the coater of the coating unit disposed at the next position of the fabric transfer unit.

Here, the infrared absorbing solution, the primer, the solvent and the powder for absorbing infrared rays are added to a mixer (not shown), stirred for 30 minutes or more for even dispersion and then supplied to the coater, the viscosity of the infrared absorbing solution is tent Depending on the type of fabric can be adjusted within the range of 20 ~ 2000cps.

In addition, the infrared absorption powder includes at least one selected from Sendust, Ferrite, ATO, CNT, Carbon, WO ₃ , Zno, Ceramics, Silica, Titanium, Graphite, ITO, AZO, MgO. can do.

For reference, the sendust is a magnetic material which is an iron-silicon-aluminum-based alloy, has a high permeability, Si 5-11%, Al 3-8%, and is very hard as the remaining Fe, and is used as a weak casting, and a magnetic shield In addition to the magnetic core of communication equipment, it is also used for powder magnetic core. μ0 = 35, 100, μm = 116, 500, W / 15 = 25erg / cm 2 / cycle, Hc = 0.022Oe, p = 81μΩ-cm.

The ferrite is a general term for magnetic ceramics containing iron oxide. Magnetic tapes, computer storage materials, magnets and the like are widely used.

ATO and ITO are thermal barrier nanodispersions

The CNT is a carbon nanotube, a new material in which carbon is connected like a honeycomb to form a bundle. It is 1 nanometer (1/10 million of hair), 100 times stronger than steel, and 1000 times more electricity than copper. have. CNT has a perfect structure, mechanical, physical, electrical and thermal properties, and its application in a wide range of fields such as electrical, electronics, telecommunications, energy, biotechnology, aerospace, etc. Research is being done.

WO ₃ is tungsten (IV) or tungsten trioxide, which is an intermediate step in the extraction of tungsten from minerals.

The infrared absorption powders exemplified above are all materials that block and absorb infrared rays, thereby absorbing infrared rays to prevent infrared heat from passing through. Therefore, when it is applied to the fabric of the tent, by absorbing the ultraviolet rays can block the heat passing through the tent fabric can see the thermal insulation effect.

On the other hand, one element of the infrared absorption solution is prepared using a water-dispersible polyurethane resin. The water-dispersible polyurethane resin is 25 to 29% by weight of aliphatic isocyanate polyol, 0.4 to 1% by weight of triethylamine as a chain extender, 2 to 4% by weight of N- methyldiethanolamine and 68 to 70% by weight of water The composition is mixed. A water-dispersible polyurethane resin comprising 26 to 32% by weight of an alkali copolymer compound, 1 to 3% by weight of alkali polyoxyethylene sulfate, 0.001 to 0.2% by weight of potassium sulfate, and a thickener mixed with water. It is prepared by mixing and stirring with dispersed water.

Here, the water-dispersible polyurethane resin is 5 to 15% by weight, the thickener is 0.001 to 0.01% by weight, the balance is mixed with dispersion water to form a primer. If the content of the water-dispersible polyurethane resin is less than 5% by weight, the resin particles are not fixed to the tent fabric 10, so that the surface of the fabric is not smooth, while if the content of the water-dispersible polyurethane resin is more than 15% by weight, Since the viscosity is high, the uniform coating is not made, causing a problem of bending.

Next, a step (S104) of passing the tent fabric 10 coated with the solution to the drying chamber of the drying unit in which the coating unit is disposed at the next position is followed.

Here, the tent fabric 10 can be dried by directly blowing hot air of 50 ~ 120 ℃, alternatively to form the internal atmosphere temperature of the drying chamber to 50 ~ 120 ℃ and to pass through the tent fabric 10 to dry It is also possible to make it.

Finally, the step S105 of recovering the tent fabric 10 coated with the solution onto the roll by the rewinder being rotated while being placed in the next position of the drying unit.

Accordingly, the tent fabric 10, which has been coated with the undercoat, may serve as UV shielding as the UV absorbing material is coated, and the infrared absorbing layer 11 also serves as a binder for the secondary coating.

Then, the intermediate coating step (S200) is first started from the step (S201) of introducing a cathode module into the process chamber of the sputtering unit. In other words, the cathode of the cathode unit is introduced into the process chamber of the sputtering unit, and the cathode unit, which is spaced apart from the process chamber, is introduced into the process chamber using a moving pulley.

Next, the first vacuum pump and the second vacuum pump are operated in order to vacuum the loading chamber of the loading unit, the process chamber of the sputtering unit, and the inside of the unloading chamber of the unloading unit, and the vacuum degree of the process chamber is 5 × 10 ^−. Vacuuming to reach ⁵ Torr (S202) is followed.

Next, step S203 is performed to inject an inert gas such as Ar gas into the process chamber so that the internal vacuum degree of the process chamber is 3 × 10 ⁻³ to 5 × 10 ⁻⁵ Torr.

Next, while driving the tent fabric 10 mounted over the loading chamber, the process chamber, and the unloading chamber, the nanoparticles for infrared reflection of the target mounted on the cathode are spun by the sputtering action by applying power to the cathode. Subsequently, the step S204 of depositing the surface of the undercoat layer 11 of 10) is continued. That is, when power is supplied to the target, emitting electrons having energy equal to the voltage applied to the target are emitted from the target surface. These electrons collide with the inert gas injected into the process chamber and the inert gas gases collide with the target surface again.

In this process, ionized particles are first adsorbed on the target and then adsorbed, causing ion implantation to change the structure of the target, or ion scattering reflected from the target surface. In addition to the atoms sputtered by the particles, the emission electrons also come out.

Then, they collide with the inert gas gases again, causing a chain reaction to generate plasma, and the sputtered particles are deposited on the tent fabric 10.

Finally, the step (S205) of recovering the tent fabric 10 is completed. This is to rotate the unloading roller to wind the tent fabric 10 on the surface to recover the roll.

Accordingly, the tent fabric 10 of which the intermediate coating is completed may double the infrared shielding efficiency by coating the intermediate coating layer 12, which is an infrared reflecting material, on the undercoat coating layer 11, which is an infrared absorbing material. In addition, since the undercoat coating layer 11 serves as a base when sputtering the intermediate coating layer 12, it is very effective to easily coat the intermediate coating layer 12.

In addition, the top coat coating process (S300) is to form a top coat layer 13 to protect the mid coat layer by wet coating on the mid coat layer 12, and the top coat process is performed in the same manner as the above coat process. .

That is, starting from the step (S301) to install the tent fabric 10 is finished uneven winder and midway coating.

Next, the step (S302) of transferring the one end of the tent fabric 10 in the working direction by the driving roller of the fabric transfer unit disposed at the next position of the unwinder is followed.

Next, a step (S303) of coating the top coat layer 13, which is a protective layer for protecting the intermediate coating layer 12 of the tent fabric 10, by the coater of the coating unit disposed at the next position of the fabric transfer unit is followed. .

Here, the top coat layer 13 is mixed with at least one selected from a dispersed titanium liquid, a dispersed silica liquid, a urethane primer, an acrylic primer, an epoxy primer, a nylon primer, a silicone primer, and waterproof, anti-rust, flame retardant It is made, the viscosity of this protective solution can be adjusted within the range of 20 ~ 2000cps depending on the type of tent fabric (10).

The waterproofing agent may include one or more selected from polyacryl, polyurethane, and polysilicon.

The anti-corrosive agent is 8-hydroxyquinoline Cu-acetate (8-hydroxyquinoline copper acetate), trimethylol melamine, dimethylol ethylene urea, organic silver, silicon-based quaternary ammonium salt, silicon tetrahydride, One or more selected from tetra benzyl tin and dibutyl laurate may be included.

The flame retardant may include one or more selected from polyaryl phosphate esters, alkylated polyaryl phosphate esters, alkylaryl phosphate esters, trialkyl phosphate esters, and hexabromocyclododecane.

Next, a step (S304) of drying the top coat layer 13 by passing the tent fabric 10 to the drying chamber of the drying unit in which the coating unit is disposed at the next position is followed.

Here, the tent fabric 10 can be dried by directly blowing hot air of 50 ~ 120 ℃, alternatively to form the internal atmosphere temperature of the drying chamber to 50 ~ 120 ℃ and to pass through the tent fabric 10 to dry It is also possible to make it.

Finally, the step of recovering the tent fabric 10 coated with the top coat layer 13 coated on the roll by the rewinder is disposed in the next position of the drying unit (S305).

On the other hand, Figures 2 to 7 is a coat and top coat coating apparatus for implementing the above method, Figure 2 is an overall configuration diagram of the bottom coat and top coating apparatus for fabricating the tent fabric for infrared shield according to the present invention, Figure 3 is a fabric supply Figure 4 is a detailed view of the unit, Figure 4 is a detailed view of the fabric transfer unit, Figure 5 is a detailed view of the coating unit, Figure 6 is a detailed view of the drying unit, Figure 7 is a detailed view of the recovery unit.

According to these drawings, the undercoat and top coat coating apparatus 100 provides a fabric supply unit 200 for automatically releasing and supplying the tent fabric 10 on a roll, and a tent fabric 10 supplied to the fabric supply unit. The fabric transfer unit 300 forcibly transferring to the next section by the power to be, the coating unit 400 for coating the ultraviolet absorbing solution on the tent fabric 10 transferred from the fabric transfer unit, and the solution is coated It may include a drying unit 500 for drying the tent fabric 10 and a recovery unit 600 for recovering the dried tent fabric 10 transferred from the drying unit on a roll.

The fabric supply unit 200, which is a part of the coating apparatus 100, includes a supply unit body 210, an unwinder 220, a lead guide roller 230, a press member 240, and a press member displacement cylinder. 250.

The supply unit body portion 210 serves as a frame of the fabric supply unit 200 and supports each component of the fabric supply unit.

The unwinder 220 has a bobbin shape, which is wound around the tent fabric 10 to be coated in a roll shape. The unwinder 220 is rotatably installed on the supply unit body 210, and is decelerated by the power clutch 221. In this state, the tent fabric is rotated in the unwinding direction (left side in the drawing).

Here, the power clutch 221 is to provide an appropriate braking force to prevent the unwinder 220 is rotated by the inertia force when pulling the tent fabric 10 in the fabric transfer unit 300. .

The take-out guide roller 230 serves to guide the tent fabric 10 in the discharge direction, and is released from the unwinder 220 while being rotatably supported by the supply unit body 210. Guide the tent fabric 10 in the withdrawal direction. For example, the withdrawal guide roller 230 is composed of a pair of upper and lower, it can be mounted to the tent fabric 10 in the s-shape.

The pressing member 240 serves to press the surface of the radar tent fabric 10 so that the tent fabric 10 wound around the unwinder 220 is not released, and the unwinder 220 It is disposed between the extraction guide roller 230.

The pressing member 240 is a pin is coupled to the upper end of the supply unit body portion 210 and the lower end of the roller bracket 241 that can be rotated in a direction that is closer or distant to the unwinder 220, and the roller bracket It may be composed of a pressing roller 242 is coupled to the lower end to press the surface of the tent fabric wound on the unwinder 220.

The pressing member displacement cylinder 250 is for rotating the roller bracket 241. The lower end is pin-coupled to the supply unit body 210, and the rod is coupled to the upper part of the roller bracket 241. The roller bracket is rotated in accordance with the advance and retreat movement of the roller to eventually displace the position of the pressing roller 242.

For example, as shown in the lower figure of FIG. 3, when the volume of the tent fabric 10 wound around the unwinder 220 is reduced from the dashed line to the solid line, the rod of the pressing member displacement cylinder 250 is advanced. In operation, the lower end of the roller bracket 241 is rotated counterclockwise in the drawing. Accordingly, the press roller 242 coupled to the lower end of the roller bracket 241 is reduced in the tent of the unwinder 220. Press the surface of the fabric (10).

The fabric transfer unit 300, which is a part of the coating apparatus 100, as shown in Figure 4, the transfer unit body portion 310, the entry side guide roller 320, the driving roller 330, driven roller 340 ), A driven roller bracket 350, a driven roller displacement cylinder 360, an electrostatic erasing member 370 and a horizontal holding member 380.

The transfer unit body portion 310 serves as a frame of the fabric transfer unit 300, and each component of the fabric transfer unit is supported.

The entry side guide roller 320 serves to guide the tent fabric 10 to enter the transfer unit body while being rotatably installed on the entry side of the transfer unit body 310. More precisely it serves to guide the drive roller 330.

The driving roller 330 is forcibly rotated by the driving motor M on the upper side of the transfer unit body 310 to convey the special fabric 10 entered by the entry-side guide roller 320 in the withdrawal direction. It plays a role.

The driven roller 340 is installed closely to the lower portion of the drive roller 330 serves to bring the special fabric 10 in close contact with the drive roller. Accordingly, the tent fabric 10 can be firmly gripped and transported by the driving roller 330 and the driven roller 340.

In addition, the driven roller 340 may be installed to enable the position displacement in the direction close to and distant from the drive roller 330. Here, the positional displacement is based on the driven roller bracket 350 and the driven roller displacement cylinder 360.

The driven roller bracket 350 is hinged to one end of the transfer unit body portion 310, and the other end is rotatable about the one end. Then, the driven roller 340 is rotatably coupled to the intermediate portion.

The driven roller displacement cylinder 360 has a lower end pin coupled to the transfer unit body portion 310, and the rod is coupled to the other end of the driven roller bracket 350 to form a driven roller bracket according to the movement of the rod. It rotates and serves to displace the position of the driven roller 340 coupled thereto.

The reason for displacing the position of the driven roller 340 is to easily mount the special fabric 10 between the driving roller 330 and the driven roller 340.

In addition, the transfer unit body portion 310 may be provided with a handle-type fine positioning member 391 for finely adjusting the driven roller 340 toward the driving roller 330. The fine positioning member 391 may be usefully used when it is necessary to finely adjust the distance between the driving roller 330 and the driven roller 340 according to the thickness or type of the tent fabric (10).

The electrostatic scavenging member 370 serves to spray the electrostatic scavenger to remove static electricity from the tent fabric 10 passing through the driving roller 330 while being installed in the transfer unit body 310. The electrostatic eliminating member 370 is fixed to the side of the transfer unit body portion 310 by a bracket 371, the long hole is formed in the bracket 371, the electrostatic eliminating member 370 within the length range of the long hole You can correct the position of.

The horizontal holding member 380 is provided in the transfer unit body portion 310, and serves to maintain a horizontal state of the special fabric 10 entering the transfer unit body portion. Special fabric 10 has a wide width may cause problems such as tilting or crushing in the process of passing from the fabric supply unit 200 to the fabric transfer unit 300, horizontal holding member 380 In order to prevent this, by supporting the bottom surface of the tent fabric 10 at the top end, a horizontal stand 381 is configured to maintain the horizontal state by correcting the slanted or crushed fabric. In addition, the horizontal bar 381 is supported by the support bar 382, the support bar 382 has a configuration coupled to the roulette portion 383 to which the transfer unit body portion 310 is coupled. . Here, the angle is adjustable to the roulette portion 383 of the support bar 382, the joint portion 382a is configured in the middle portion of the support bar 382 to adjust the installation angle of the horizontal stand (381) Can be.

The coating unit 400, which is a part of the coating apparatus 100, has a coating body 410, a guide roller 420, a vertical rail 430, a coater 440, and a tilt adjusting member as shown in FIG. 450 and the coater elevating cylinder 460.

The coating body 410 serves as a frame of the coating unit 400, and each component of the coating unit is supported.

The guide roller 420 is disposed in the horizontal to the coating body portion 410, it is composed of a plurality of serving as a guide to the horizontal horizontally guide the tent fabric 10 drawn from the fabric transfer unit 300. .

The vertical rail 430 is installed vertically to the coating body 410, and serves as a guide when positioning the entirety of the relevant parts including the coater 440 up and down.

The coater 440 is installed to be elevated along the vertical rail 430, and serves to spray coating the infrared reflecting solution (the bottom) or the protective solution (the top) on the tent fabric 10. The infrared reflecting solution or the protective solution to the coater 440 is provided from the solution supply unit 470. The solution supply unit 470 may include a solution storage tank 471 and a supply pump 472 for supplying a solution of the tank to the coater 440.

The inclination adjustment member 450 is used to adjust the horizontal inclination of the coater based on the rotation shaft 441 provided in the coater 440. The inclination adjustment member 450 includes a handle 451 and the handle. Consists of a gearbox 452 that is operated by rotation, the gearbox 452 is connected to the shaft 441 of the coater 440 may adjust the inclination of the coater 440.

The core lifting cylinder 460 serves to elevate the coater 440, and when the coater 440 is spaced apart from the special fabric 10, or the spaced coater 440 is separated from the tent fabric 10. This is useful when approaching).

On the other hand, when replacing or cleaning the coater 440 may be used ceiling crane (C) is installed on the ceiling of the workplace.

The drying unit 500, which is one part of the coating apparatus 100, as shown in Figure 6, the lower member 510, the guide roller 520, the drive belt gear 530, the power transmission belt 540 and the upper Member 550.

The lower member 510 serves as a drying die.

The guide roller 520 is configured to horizontally guide the special fabric 10 transferred from the coating unit 400 while being horizontally disposed in the longitudinal direction of the lower member 510.

The drive belt gear 530 is installed to be rotationally driven by the drive motor M at the center of the lower member 510.

The power transmission belt 540 connects the drive belt gear 530 and the roller gear 560 provided at each guide roller 520, so that the rotational power of the drive belt gear 530 is rotated by each roller gear 560. It serves to be delivered. Therefore, when the drive belt gear 530 is rotated by the drive motor M, each guide roller 520 connected by the power transmission belt 540 is interlocked.

The upper material 550 is installed to be elevated by the cylinder 570 on the lower member 510, the warm air from the warm air supply unit 580 is provided to be connected to the upper material 550 to the internal chamber By receiving the air to blow the warm air toward the tent fabric 10 is to dry the tent fabric 10 in a solution coated state.

The recovery unit 600, which is a part of the coating apparatus 100, as shown in Figure 7, the recovery body 610, the entry-side guide roller 620, the denser roller 630, the driving roller 640, The driven roller 650, the auxiliary roller 660, bracket 670, the auxiliary roller displacement cylinder 680 and the rewinder 690.

The recovery body 610 serves as a frame of the recovery unit 600, and each component of the recovery unit is supported.

The entry-side guide roller 620 is for guiding the tent fabric 10 introduced into the recovery body portion 610 may be composed of a plurality.

The denser roller 630 autonomously measures the tension of the tent fabric 10 guided by the entry-side guide roller, and corrects the tension of the tent fabric 10 to a prescribed value when the measured value is above or below a prescribed value. It helps to maintain a constant tension at all times.

Here, the denser roller 630 is hinged to the upper end is coupled to the recovery body 610, as shown in the lower view of Figure 7, the lower end is coupled to the lower end of the rotatable denser roller bracket 631, The denser roller bracket 631 is rotated by the bracket cylinder 632.

According to this configuration, as the rod of the bracket cylinder 632 is lifted and operated, the denser roller bracket 631 connected thereto is rotated clockwise or counterclockwise in the drawing. Therefore, the tensioner 630 coupled to the lower end of the denser roller bracket 631 may adjust the tension by pulling or releasing the radar shielding fabric 10.

The driving roller 640 is forcibly rotated by the driving motor M while being supported by the recovery body 610 to transfer the tent fabric 10 entered by the entry-side guide roller 620 in the withdrawal direction. It plays a role.

The driven roller 650 is to close to the upper portion of the drive roller 640 to serve to press the radar tent fabric 10 to the drive roller 640. As a result, it is possible to strongly grip the tent fabric 10 passing therebetween by the driving roller 640 and the driven roller 650.

The auxiliary roller 660 is installed at the top of the driven roller 650 so as to be displaced in a direction that is close to and distant from the driven roller. The auxiliary roller 660 is a rubber roller so that the special fabric 10 passed between the driven roller 650 is smoothly transported without slipping.

One end of the bracket 670 is pin-coupled to the recovery body 610, and the other end of the bracket 670 is rotatable based on the pin coupling part, and the auxiliary roller 660 is rotatably installed at an intermediate part thereof.

The auxiliary roller displacement cylinder 680 has a rod coupled to the other end of the bracket 670 while one end is pinned to the recovery body 610 to rotate the other end of the bracket according to the advancing / removing operation of the rod. Play a role. Therefore, the auxiliary roller 660 can be displaced in a direction that is close to or distant from the driven roller 650 by the operation of the auxiliary roller displacement cylinder 680.

The rewinder 690 serves to recover the tent fabric 10 drawn out from the recovery body 610 in the form of a roll, and the rewinder 690 is rotated by the motor M.

Attached Figure 8 is an overall configuration of the intermediate coating apparatus for manufacturing an infrared shielding tent fabric according to the invention, Figure 9 is a plan view of Figure 8, Figure 10 is a front view of Figure 8, Figure 11 is a secondary Detailed cross section of the sputtering unit in the coating apparatus.

8 to 11, the intermediate coating apparatus 700 may include a sputtering unit 800, a cathode unit 900, a primary vacuum pump 1000, a secondary vacuum pump 1100, and a chiller 1200. Include.

The sputtering unit 800, which is a part of the intermediate coating apparatus 700, is a unit for a sputtering process, and includes a loading module 810 for loading the tent fabric 10.

The loading module 810 is evacuated by the primary vacuum pump 1000 and the secondary vacuum pump 1100 and has a loading chamber 811 having an opening at one side thereof.

Here, the opening is opened and closed by the loading chamber door 812 to serve as a doorway for supplying the tent fabric 10 to the loading roller 813 of the loading chamber 811. That is, the loading chamber door 812 opens and closes the opening while sliding along the door guide 812a installed outside the loading chamber 811.

In addition, the loading module 810 is rotatably installed by the driving motor 813a in the loading chamber 811 and has a loading roller 813 on which a special fabric 10 is wound on an outer circumferential surface thereof. The loading roller 813 is rotated in the clockwise direction (see FIG. 11) by the driving motor 813a to release the tent fabric 10 wound on the surface thereof.

In addition, the loading module 810 is a plurality of guide rollers that serve to guide the tent fabric 10 released from the loading roller 813 into the process chamber (to be described later) of the sputtering unit 800 ( 814). Here, the guide roller 814 is preferably arranged in a zigzag shape so that the special fabric 10 can maintain a constant tension.

The sputtering unit 800 includes a sputtering module 820 for coating or depositing gold or silver nanoparticles, which are good for skin care, on the surface of the tent fabric 10 loaded from the loading module 810 by a sputtering process. .

In addition, the sputtering module 820 is vacuumed by the primary vacuum pump 1000 and the secondary vacuum pump 1100 and has a process chamber 821 in which a sputtering process is performed. Here, one side of the process chamber 821 is provided with an opening 821a for introducing or withdrawing the cathode of the cathode unit 900.

In addition, the sputtering module 820 is rotatably installed in the process chamber 821 by the drive motor 822a, the tent fabric 10 is a sputtering object provided from the loading chamber 811 on the outer peripheral surface It has a drum 822 to be wound.

In addition, the sputtering module 820 has a plurality of shield plates 823 partitioning the space between the inner surface of the process chamber 821 and the drum 822 into a plurality of spaces. Here, the plurality of spaces are radially divided along the outer circumferential surface of the drum 822, and each of the divided spaces becomes an individual work space in which a sputtering process is performed. In addition, the shield plate 823 serves as a diaphragm to prevent the sputtering work performed in each work space from being kneaded by isolating each divided work space.

In addition, the sputtering module 820 has a plurality of guide rollers 824 for guiding the tent fabric 10 in the process chamber 821 to the unloading module 830. The guide roller 824 is the main purpose of guiding the tent fabric 10 to the unloading module 830, in particular, the guide roller is disposed on both sides of the top of the drum 822, the tent fabric 10 is The tent fabric 10 serves to tighten the outer circumferential surface of the drum 822 so as to be contacted over the entire outer circumferential surface of the drum 822.

The sputtering unit 800 includes an unloading module 830 for recovering the tent fabric 10 loaded with gold nanoparticles or silver nanoparticles deposited in the sputtering module 820.

The unloading module 830 is evacuated by the primary vacuum pump 1000 and the secondary vacuum pump 1100 and has an unloading chamber 831 having an opening at one side thereof.

Here, the opening is opened and closed by the unloading chamber door 832 to serve as a doorway for recovering the tent fabric 10 of which deposition is completed from the unloading chamber 831. That is, the unloading chamber door 832 opens and closes the opening while sliding along the door guide 832a installed outside the unloading chamber 831.

In addition, the unloading module 830 is rotatably installed in the unloading chamber 831 by a driving motor 833a, and unloading of the tent fabric 10 in which the sputtering work is completed on the outer circumferential surface thereof. It has a roller 833. The unloading roller 833 is rotated in a clockwise direction (see FIG. 11) by the driving motor 833a to wind the tent fabric 10 wound on the surface thereof.

In addition, the unloading module 830 has a plurality of guide rollers 834 for guiding the tent fabric 10 transferred from the sputtering module 820 to the unloading roller 833. Here, the guide roller 834 is preferably arranged in a zigzag shape so that the tent fabric 10 can maintain a constant tension.

Meanwhile, the loading chamber 811, the process chamber 821, and the unloading chamber 831 have a loading chamber 811, a process chamber 821, a process chamber ( The 821 and the unloading chamber 831 are connected in communication with each other by a connecting chamber 841.

In addition, each of the connection chambers 841 is opened and closed by the transfer valve 842, so that the connection chambers are opened when the sputtering process is in progress, and when the process is not in progress, the connection chambers 841 are closed to block the degree of vacuum in the process chamber 821. It could be maintained.

The cathode unit 900, which is a part of the intermediate coating apparatus 700, is introduced into the process chamber 821 of the sputtering module 820 while being disposed inline on one side of the sputtering unit 800, or Withdrawal serves to achieve the sputtering process.

The cathode unit 900 includes a moving pulley 910 which is movably installed to be pulled into or pulled out of the process chamber 821 along the guide rail 911 from the outside of the sputtering module 820; An opening / closing door 920 installed at the moving pulley to open and close an opening of the process chamber 821; It is installed on the surface facing the process chamber 821 of the opening and closing door 920, it may be composed of a plurality of cathodes 930 divided into a plurality to be introduced into each compartment of the process chamber 821.

The cathode unit 900 has the cathode 930 fully introduced into the process chamber 821 so that the opening / closing door 920 blocks the opening 821a of the process chamber 821 so that the cathode unit 930 is completely inserted into the process chamber 821. Sputtering operation is possible.

On the other hand, the cathode unit 900 may be mounted on the mobile pulley 910, a controller 940 for applying power to the cathode 930.

The primary vacuum pump 1000, which is a part of the intermediate coating apparatus 700, is disposed inline on the other side of the sputtering unit 800, and the loading module 810, the sputtering module 820, and the unloading. It serves to primarily vacuum the interior of each chamber 811, 821, 831 of the module 830, and may include a rotary pump 1010 and a booster pump 1020.

The primary vacuum pump 1000 is an initial vacuum pump for evacuating the interior of each chamber at atmospheric pressure. When the high-pressure vacuum is performed immediately, the load is applied to the pump, and thus the primary vacuum pump 1000 is about a low pressure pump. It is for achieving a vacuum.

The secondary vacuum pump 1100, which is a part of the secondary coating apparatus 700, is provided in the loading module 810, the sputtering module 820, and the unloading module 830, respectively. 811,821,831 inside the secondary vacuum, that is, complete vacuum. Along with this, the role of removing the water present in the interior of each chamber is also parallel. The secondary vacuum pump 1100 may be composed of a cryo pump 1110 and a turbo molecular pump (TMP) 1120.

The chiller 1200 serves to supply a coolant to the cooling pipe p provided in the chambers 811, 821, and 831 of the modules 810, 820, and 830. Since each of the chambers 811, 821, and 831 is a space where a sputtering operation is performed, a cooling pipe (p) is installed for cooling thereof since the working heat is accompanied, and the chiller 1200 serves to circulate the cooling refrigerant.

The embodiments and drawings attached to this specification are merely to clearly show some of the technical ideas included in the present invention, and those skilled in the art can easily infer within the scope of the technical ideas included in the specification and drawings of the present invention. It is apparent that all modifications and specific embodiments that can be included in the scope of the technical idea of the present invention.

10: tent fabric 11: undercoat coating layer
12: intermediate coating layer 13: top coating layer
100: primary coating device 200: fabric supply unit
210: supply unit body portion 220: unwinder
230: drawing guide roller 240: pressing member
300: fabric transfer unit 310: transfer unit body
320: guide side guide roller 330: drive roller
340: driven roller 350: driven roller bracket
360: driven roller displacement cylinder 370: static eliminating member
380: horizontal holding member 400: coating unit
410: coating body portion 420: guide roller
430: vertical rail 440: coater
450: tilt adjustment member 460: coater lifting cylinder
470: solution supply unit 500: drying unit
510: lower member 520: guide roller
530: drive belt gear 540: power transmission belt
550: upper material 600: recovery unit
610: retrieval body portion 620: guide side guide roller
630: dancer roller 640: driving roller
650: driven roller 660: auxiliary roller
670: bracket 680: secondary roller displacement cylinder
690: Rewinder
700: sputtering device 800: sputtering unit
810: loading module 811: loading chamber
812: loading chamber door 813: loading roller
820: Sputtering Module 821: Process Chamber
822: Drum 823: Shield
830 unloading module 831 unloading chamber
832: unloading chamber door 833: unloading roller
841: connecting chamber 842: transfer valve
900: cathode unit 910: moving pulley
920: opening and closing door 930: cathode
1000: 1st vacuum pump 1100: 2nd vacuum pump
1200: chiller

Claims (8)

An unwinder which releases the dent fabric being wound in the working direction but is decelerated by the power clutch, a pressing member which presses the surface of the radar tent fabric wound on the unwinder, and a pressing roller of the pressing member. Dispersion supply unit including a pressing member displacement cylinder for displacing the position of the;
A fabric transfer unit including an electrostatic scavenging member for spraying an electrostatic scavenger to the fabric of the tent passing through the driving roller while being installed in the body of the transfer unit;
A coater for coating an infrared reflecting solution or a protective solution on the tent fabric, and a coating apparatus including a tilt adjusting member for adjusting a horizontal tilt of the coater based on a rotation axis provided in the coater;
A drying unit drying the coating solution of the tent fabric by warm air; And
An upper and upper coating apparatus including a; a recovery unit including a denser roller coupled to a lower end of the denser roller bracket which is hinged to an upper end of the recovery body and is rotatable by a bracket cylinder; And

Sputtering unit, cathode unit, primary and secondary vacuum pumps and chillers,
The sputtering unit is vacuumed by the first and second vacuum pumps, the process chamber is a sputtering process is performed; A drum rotatably installed inside the process chamber to wind the tent fabric; And a shield plate that partitions the space between the inner surface of the process chamber and the drum into a plurality of spaces to form a plurality of isolated working spaces.
The primary vacuum pump is a low pressure pump for the initial vacuum for evacuating the chamber at atmospheric pressure,
The secondary vacuum pump is a vacuum coating device comprising a middle coating device comprising a cryo, TMP, turbo molecular pump to completely vacuum the inside of each chamber and remove moisture in the chamber together. Tent fabric manufacturing method,

The tent fabrication method comprises a bottom coating step of wet coating an infrared absorbing material on the tent fabric to form an infrared absorbing layer;
A middle coating step of forming an infrared reflecting layer by coating an infrared reflecting material on the infrared absorbing layer by a sputtering process; And
A top coat coating step of wet coating on the infrared reflecting layer to form a protective layer protecting the infrared reflecting layer;
The undercoat coating step,
Installing the tent fabric on the unwinder;
Transferring one end of the tent fabric to a work direction by a driving roller of a fabric conveying unit disposed at a next position of the unwinder;
Coating a primer solution including an infrared absorbing material on a tent fabric by a coater of a coating unit disposed at a next position of the fabric transfer unit;
Passing the primer-coated tender fabric to a drying chamber of a drying unit disposed at a next position of the coating unit, and drying by hot air at a temperature of 50 to 120 ° C .; And
Recovering by winding the fabric of the tender coated with the primer solution onto a roll by a rewinder which is rotated while being disposed at a next position of the drying unit;
The primer is a water-dispersible polyurethane resin, the water-dispersible polyurethane resin is 25 to 29% by weight of aliphatic isocyanate polyol, 0.4 to 1% by weight of triethylamine as a chain extender, N- methyl diethanolamine 2 4 to 4% by weight and 68 to 70% by weight of water are mixed, and 26 to 32% by weight of an alkali copolymer compound, 1 to 3% by weight of alkali polyoxyethylene sulfate, 0.001 to 0.2% by weight of potassium sulfate, and A method for producing a tent fabric for infrared shielding, characterized in that the thickener mixed with water in the remainder is prepared by mixing and stirring the water-dispersible polyurethane resin with the dispersion water.
delete delete The method according to claim 1,
The intermediate coating step,
Introducing a cathode of the cathode module into the process chamber of the sputtering unit;
The first vacuum pump and the second vacuum pump are operated in order to vacuum the loading chamber of the loading unit, the process chamber of the sputtering unit, and the inside of the unloading chamber of the unloading unit, and the vacuum degree of the process chamber is 5 × 10 ^-5 Torr. Evacuating to
Injecting an inert gas such as Ar gas into the process chamber so that the internal vacuum of the process chamber is 3 × 10 ⁻³ to 5 × 10 ⁻³ Torr;
The infrared reflecting material of the target mounted on the cathode is deposited on the primer-coated surface of the tent fabric by sputtering action of powering the cathode while driving the tent fabric mounted over the loading chamber, the process chamber and the unloading chamber. Doing; And
Recovering the tent fabric is completed deposition; infrared shielding tent fabric manufacturing method characterized in that consisting of.
The method according to claim 4,
The infrared reflecting material is a shielding tent fabric manufacturing method comprising at least one selected from Al, Cr, Sus, Silver, Ni / Cr alloy.
The method according to claim 1,
The top coat step,
Installing the tent fabric through the uncoated winder and the intermediate coating step in an unwinder;
Transferring one end of the tent fabric to a work direction by a driving roller of a fabric conveying unit disposed at a next position of the unwinder;
Coating a protective solution including a waterproofing material, a barrier material, and a flame retardant material of a tent fabric by a coater of a coating unit disposed at a next position of the fabric transfer unit;
Passing through the tent fabric coated with the protective solution to a drying chamber of a drying unit disposed at a next position of the coating unit and drying by hot air at a temperature of 50 to 120 ° C .; And
Shielding tent fabric manufacturing method comprising the step of recovering by winding the protective fabric coated the tent fabric on a roll by a rewinder is disposed in the next position of the drying unit.
The method according to claim 6,
The protective solution includes at least one selected from a dispersed titanium liquid, a dispersed silica liquid, a urethane primer, an acrylic primer, an epoxy primer, a nylon primer, and a silicone primer.
The waterproofing agent includes at least one selected from polyacrylic, polyurethane, and polysilicon,
The anti-corrosive agent is 8-hydroxyquinoline Cu-acetate (8-hydroxyquinoline copper acetate), trimethylol melamine, dimethylol ethylene urea, organic silver, silicon-based quaternary ammonium salt, silicon tetrahydride, At least one selected from tetrabenzyl tin and dibutyl laurate,
The flame retardant is a tent material for shielding, characterized in that at least one selected from polyaryl phosphate ester, alkylated polyaryl phosphate ester, alkyl aryl phosphate ester, trialkyl phosphate ester, hexabromocyclododecane Manufacturing method.
A thermal barrier tent fabric made by sequentially stacking an infrared absorbing layer, an infrared reflecting layer, and a protective layer on the tent fabric by the method of claim 1.

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