KR101342457B1 - Antibacterial flexible hose fabric for air conditioning and heating and there of manufacturing method - Google Patents

Abstract

The present invention is easy to be damaged due to the characteristics of the aluminum fabric 30 of the thin film, so that the antimicrobial coating layer 40a is laminated through the process of unwinding the wound reinforcement fabric 10 and the aluminum fabric 30. Air-conditioning for air conditioning and heating to ensure a more hygienic air conditioning facility by preventing the spread of various bacteria contained in warm air, cold air, exhaust gas or indoor air, while making it easy to manufacture antibacterial flexible hose fabric. The present invention relates to an antimicrobial flexible hose fabric and a method of manufacturing the same.

Description

ANTIBACTERIAL FLEXIBLE HOSE FABRIC FOR AIR CONDITIONING AND HEATING AND THERE OF MANUFACTURING METHOD}

The present invention relates to an antibacterial flexible hose fabric for air conditioning and air conditioning and a method for manufacturing the same, and more specifically, an antibacterial flexible hose fabric for air conditioning and heating used as an air conditioning facility through which warm air, cold air, exhaust gas, or indoor air passes. It relates to a manufacturing method.

In general, the hose fabric is used as a material of an air conditioning facility through which warm air, cold air, exhaust gas, or indoor air passes.

For example, as an air conditioning facility, the flexible duct has an advantage of having excellent refractive index and free positioning of wind, and more specifically, an aluminum or stainless steel fabric wound in a bellows form. And those that kept the mold with spiral rings.

선행기술문헌의 종래 기술에 언급된 후렉시블 덕트(50)는 도 1 및 도 2에 도시된 바와 같이 길이방향으로 연속되는 일측 테두리(11) 및 타측 테두리(12)를 지닌 원단(10)과, 이 원단(10)의 타측 테두리(12)를 일측 테두리(11)의 내측에 포개어 겹친부분(13)이 형성되도록 원단(10)을 나선형으로 회전시켜 원통체를 구현하면서 겹친부분(13)의 내주연을 접은 상태로 폭이 넓게 받아들여 압착시키는 스파이어럴 링[20; 서로 마주보는 한글 자음 디귿()자 형상으로 이루어져 폭이 넓음]과, 상기 겹친부분(13)의 접힌공간(14)에 끼워져 스파이어럴 링(20)에 내입되는 서포팅 와이어(30)를 포함하는 구성으로 이루어 진다. 그런데, 선행기술문헌의 종래 기술에 언급된 후렉시블 덕트(50)는 단순히 알루미늄 재질의 원단(10)만을 적용하고 있어 온풍, 냉풍, 배기가스 또는 실내공기 등에 함유된 각종 세균에 대한 대응이 전혀 이루어지지 않아 위생적으로나 건강적으로 많은 우려를 낳고 있다.

The flexible duct 50 mentioned in the prior art of the prior art document has a fabric 10 having one side edge 11 and the other side edge 12 continuous in the longitudinal direction, as shown in FIGS. 1 and 2, and The inner periphery of the overlapped portion 13 while the other edge 12 of the fabric 10 is superimposed on the inner side of one side edge 11 so as to form the overlapped portion 13 by rotating the fabric 10 in a spiral manner. Spiral ring [20; It consists of Hangul consonant dichro () shape facing each other wide; and a support wire 30 is inserted into the folded space 14 of the overlapping portion 13 and embedded in the spiral ring 20 Is done. By the way, the flexible duct 50 mentioned in the prior art of the prior art simply applies only the fabric 10 made of aluminum, so there is no response to various bacteria contained in warm air, cold air, exhaust gas, or indoor air. This is causing hygiene and health problems.

An object of the present invention is easy to be damaged by the characteristics of the aluminum fabric of the thin film, so that the antimicrobial coating layer through the process of laminating the reinforcement fabric and the unwinding of the wound reinforcement fabric and aluminum fabric to provide an antimicrobial flexible hose fabric having an antibacterial function. The present invention provides an antimicrobial flexible hose fabric for air conditioning and heating that can be manufactured more simply and quickly, and a method of manufacturing the same.

It is an object of the present invention to provide an antibacterial flexible hose fabric for air conditioning and heating, and a method of manufacturing the same, for producing an antibacterial flexible hose fabric that can block the propagation of various bacteria contained in warm air, cold air, exhaust gas, or indoor air. Is in.

It is an object of the present invention to apply an inorganic antimicrobial agent having a high melting point is released to the lower surface of the aluminum fabric during processing to prevent the sticky phenomenon in advance while antimicrobial flexible hose fabric for air conditioning and air conditioning that can maximize the antimicrobial effect and its manufacturing method In providing.

An object of the present invention is to pass the aluminum fabric and the reinforcing fabric between the heating roll and the silicon roll so that the aluminum fabric is easily damaged by being buffered by the silicon roll, and the relatively tough reinforcing fabric is more closely adhered to the aluminum fabric The present invention provides an antimicrobial flexible hose fabric for air conditioning and heating, and a method of manufacturing the same.

An object of the present invention is to provide an antimicrobial flexible hose fabric for air conditioning and heating, which enables the coating adhesive layer to be fixed more quickly while maintaining the spreadability at the interface between the aluminum fabric and the reinforcing fabric by a heating roll maintaining a temperature of 60 to 90 ° C. And to provide a method for producing the same.

The manufacturing method of the antibacterial flexible hose fabric for air conditioning and heating according to the present invention,

Applying a liquid adhesive to the back surface while unwinding the wound reinforcing fabric,

Heating the reinforcing fabric coated with the liquid adhesive to form an adhesive coating layer on the back surface;

Unwinding the wound aluminum fabric while laminating it with the upper surface in contact with the adhesive coating layer of the reinforcing fabric;

Applying a liquid antimicrobial agent to a lower surface of the aluminum fabric laminated to the reinforcing fabric;

It comprises a step of preparing a fabric for the antimicrobial flexible hose by heating the aluminum fabric coated with the liquid antimicrobial agent while being laminated with the reinforcing fabric to form an antimicrobial coating layer on the lower surface.

The manufacturing method of the antibacterial flexible hose fabric for air conditioning and heating according to the present invention,

Applying a liquid antimicrobial agent on the back side while unwinding the wound reinforcing fabric,

Heating the reinforcing fabric coated with the liquid antimicrobial agent to form an antimicrobial coating layer on the back surface;

Applying a liquid adhesive to a surface of the reinforcing fabric;

Heating the reinforcing fabric coated with the liquid adhesive to form an adhesive coating layer on the surface;

And a step of preparing the antimicrobial flexible hose fabric by laminating the wound aluminum fabric while unwinding the upper surface to be in contact with the adhesive coating layer of the reinforcing fabric.

The antibacterial flexible hose fabric for air conditioning and heating according to the present invention is

Reinforcement fabric,

An adhesive coating layer formed on the rear surface of the reinforcing fabric;

Aluminum fabric is fixed to the reinforcing fabric with the adhesive coating layer therebetween,

Including the antimicrobial coating layer formed on the lower surface of the aluminum fabric is a basic feature of the technical configuration.

The antibacterial flexible hose fabric for air conditioning and heating according to the present invention is

Reinforcement fabric,

An antimicrobial coating layer formed on the rear surface of the reinforcing fabric,

An adhesive coating layer formed on a surface of the reinforcing fabric;

The technical feature of the present invention is to include an aluminum fabric adhered to the reinforcing fabric with the adhesive coating layer interposed therebetween.

The present invention is easy to be damaged due to the characteristics of the thin aluminum fabric, so that the antimicrobial coating layer is prepared by laminating the reinforcing fabric and unwinding the reinforcing fabric and the aluminum fabric. It can be effective.

The present invention has the effect of producing a fabric for the antimicrobial flexible hose that can block the propagation of various bacteria contained in warm air, cold air, exhaust gas or indoor air.

The present invention has the advantage of maximizing the antimicrobial effect while preventing the sticking phenomenon by being applied to the lower surface of the aluminum fabric or the back of the reinforcing fabric when processing by applying a high melting point inorganic antimicrobial agent.

The present invention by applying a PET film or a synthetic resin film as a reinforcing fabric not only excellent adhesion to the aluminum fabric of the thin film, but also the effect of maximizing the fixing force when bonding the aluminum fabric and heating between the liquid antimicrobial agent and liquid adhesive. There is.

The present invention has the effect of applying a nonwoven fabric as a reinforcing fabric to relatively compensate for the phenomenon of being easily damaged such as temperature maintenance and noise prevention and furthermore, aluminum fabric.

The present invention allows the reinforcing fabric to pass through the adhesive coating heating chamber and the antimicrobial coating heating chamber to receive the heating heat, thereby continuously utilizing the unwinding, that is, the unwinding process of the reinforcing fabric wound in a roll type, as an antimicrobial flexible hose. There is an effect that the fabric can be produced more quickly (maximum productivity by guaranteeing workability).

According to the present invention, the aluminum fabric and the reinforcing fabric are passed between the silicon roll together with the heating roll so that the fragile aluminum fabric is protected while being buffered by the silicon roll, and the relatively tough reinforcing fabric can be more closely adhered to the aluminum fabric. It is effective.

The present invention has the effect of allowing the coating adhesive layer to be more quickly fixed while maintaining the spreadability at the interface between the aluminum fabric and the reinforcing fabric by a heating roll maintaining a temperature of 60 ~ 90 ℃.

According to the present invention, the antimicrobial flexible hose fabric is embedded in the aging room so that the diluent is volatilized, thereby maintaining the antimicrobial coating layer firmly and further increasing the adhesion of the adhesive coating layer.

1 is a perspective view showing a flexible duct mentioned in the prior art of the prior art document.
Figure 2 is a cross-sectional view showing a flexible duct mentioned in the prior art of the prior art document.
Figure 3 is a process chart showing a manufacturing method for the antibacterial flexible hose for air conditioning air conditioning according to the first embodiment of the present invention.
Figure 4 is a process chart showing a manufacturing method for the antibacterial flexible hose air-conditioning and air conditioning according to a second embodiment of the present invention.

A preferred embodiment of the antimicrobial flexible hose fabric for air-conditioning and air conditioning according to the present invention and a manufacturing method thereof will be described with reference to the drawings, and a plurality of the embodiments may exist, and through this embodiment, an object of the present invention. Better understanding of features and benefits.

3 is a process chart showing a method for manufacturing an antibacterial flexible hose fabric for air conditioning and air conditioning according to a first embodiment of the present invention.

According to the first embodiment of the present invention, a method for manufacturing an antibacterial flexible hose fabric for air-conditioning and air conditioning is applied to a liquid adhesive 20 on the back surface 11 while unwinding a wound reinforcing fabric 10 as shown in FIG. 3. (S10), the reinforcing fabric 10 to which the liquid adhesive 20 is applied is heated so that an adhesive coating layer 20a is formed on the back surface 11 (S20), while unwinding the wound aluminum fabric 30. The upper surface 31 is laminated in contact with the adhesive coating layer 20a of the reinforcing fabric 10 (S30), the liquid antimicrobial agent (3) on the lower surface 32 of the aluminum fabric 30 laminated to the reinforcing fabric 10 40 is applied (S40), and laminated with the reinforcing fabric 10 while heating the aluminum fabric 30 coated with the liquid antimicrobial agent 40, the antimicrobial flexible hose to form an antimicrobial coating layer (40a) on the lower surface (32) It consists of the step (S50) which prepares the fabric 50 for dragons.

The present invention is easy to be damaged due to the characteristics of the aluminum fabric 30 of the thin film, so that the antimicrobial coating layer 40a is laminated through the process of unwinding the wound reinforcement fabric 10 and the aluminum fabric 30. The antimicrobial flexible hose fabric (50) can be easily prepared to prevent the spread of various germs contained in hot air, cold air, exhaust gas, or indoor air in advance, thereby ensuring a more hygienic air conditioning facility. .

At this time, the liquid antimicrobial agent 40 may include zeolite, calcium phosphate, zirconium phosphate or silica gel.

The antimicrobial agent is classified into organic and inorganic type according to the material. When using an organic antimicrobial agent having a low melting point, the antimicrobial agent is released to the lower surface 32 of the aluminum fabric 30 during processing, so it is easy to cause an appearance defect such as stickiness. In addition to the deterioration of the antimicrobial power over time, there is a problem that the organic antimicrobial agent harmful to the human body is introduced along the hose in the present invention is to use an inorganic antimicrobial agent such as zeolite, calcium phosphate, zirconium phosphate or silica gel having a high melting point.

Furthermore, inorganic antimicrobial agents such as zeolite, calcium phosphate, zirconium phosphate or silica gel have high stability compared to organic antimicrobial agents, such as high heat resistance, no volatilization and decomposition, and the antimicrobial effect is expressed by active oxygen ions. It has the advantage of long persistence and does not generate resistant bacteria can be more easily applied to the present invention.

More specifically, zeolite is a generic term for minerals that are aluminum silicate hydrates of alkali and alkaline earth metals. The color is colorless transparent or white translucent, and has the highest antibacterial effect. 1670 ℃, specific gravity 3.14, insoluble in water, but insoluble in strong acid, antibacterial effect, zirconium phosphate is colorless crystal, used as inorganic ion exchanger, antimicrobial effect, silica gel reaction of sulfuric acid and sodium silicate It is made of silicate particles of a strong net structure made by a wide surface area is very excellent in the ability to absorb water or alcohol, etc., because it is widely used as a dehumidifying agent has an antimicrobial effect will be able to be applied to the present invention.

Preferably, the liquid antimicrobial agent 40 may include 10-30 wt% zeolite and 70-90 wt% diluent.

In the present invention, zeolite, an inorganic antimicrobial agent, is less than 10% by weight of antimicrobial activity, and when it exceeds 30% by weight, the physical properties are remarkably lowered. It is prepared as a liquid antimicrobial agent 40.

Furthermore, the liquid adhesive 20 may contain 10-35 weight% adhesive, 1-10 weight% hardening | curing agent, and 60-85 weight% diluent.

When the adhesive is less than 10% by weight, the adhesive strength is weakened, and when it is 35% by weight or more, the viscosity is excessive and the interface spreadability between the reinforcing fabric 10 and the aluminum fabric 30 is lowered. In addition, by including 1 to 10% by weight of the curing agent to be quickly cured by the adhesive coating layer (20a) during heating, further comprising 60 to 85% by weight of the diluent to the reinforcing fabric 10 as a liquid adhesive (20) Allow to be applied quickly.

Preferably, the reinforcing fabric 10 may be applied to any one of a PET film, a synthetic resin film, a nonwoven fabric.

PET film or synthetic resin film not only has excellent adhesion with the aluminum fabric 30 of the thin film, but also maximizes the adhesive strength when combined with the aluminum fabric 30 and heating with the liquid antibacterial agent 40 and the liquid adhesive 20 interposed therebetween. The nonwoven fabric is particularly preferable because it can relatively compensate for the phenomenon that the aluminum fabric 30 is easily damaged by temperature maintenance and noise prevention.

Further, the step S20 is heated while passing the reinforcing fabric 10, the liquid adhesive 20 is applied into the adhesive coating heating chamber 61 having a temperature of 100 ~ 140 ℃ by heating the adhesive coating layer ( 20a) is formed, and the step S50 is laminated to the reinforcing fabric 10 while the aluminum fabric 30 to which the liquid antimicrobial agent 40 is applied is coated in the antimicrobial heating chamber 62 having a temperature of 100 to 150 ° C. Heated while passing through the antimicrobial coating layer 40a can be formed on the lower surface (32).

As such, the reinforcing fabric 10 passes through the adhesive coating heating chamber 61 and the antimicrobial coating heating chamber 62 to receive the heating heat, thereby unwinding the reinforcing fabric 10 wound in a roll shape. By continuously utilizing the annealing process, it is possible to maximize the productivity by guaranteeing workability in terms of manufacturing the antimicrobial flexible hose fabric 50 together with the aluminum fabric 30 more quickly.

Furthermore, the step S30 is to pass through between the heating roll 71 and the silicon roll 72 while pressing the adhesive coating layer 20a of the aluminum fabric 30 and the reinforcing fabric 10 so as to be laminated together, The heating roll 71 can maintain the temperature of 60-90 degreeC.

By passing the aluminum fabric 30 and the reinforcing fabric 10 between the heating roll 71 and the silicon roll 72, the aluminum fabric 30, which is easily damaged, is protected while being buffered by the silicon roll 72. , The relatively tough reinforcing fabric 10 may be more closely adhered to the aluminum fabric (30).

Furthermore, the coating adhesive layer can be more quickly fixed while maintaining the spreadability at the interface between the aluminum fabric 30 and the reinforcing fabric 10 by the heating roll 71 maintaining the temperature of 60 ~ 90 ℃.

On the other hand, after the step S50 further comprises a step (S60) for rewinding the antimicrobial flexible hose fabric 50 in a roll shape to facilitate storage and movement of the antimicrobial flexible hose fabric 50, and the S60 After the step, the roll-type antimicrobial flexible hose fabric 50 is embedded in an aging room (Aging Room) 80 at 45 to 65 ° C. for 35 to 55 hours, thereby including a step (S70) to volatilize the diluent, thereby preventing the antibacterial coating layer 40a. Of course, it is possible to maximize the firmness of the adhesive coating layer (20a) as well as maintaining a solid.

Figure 4 is a process chart showing a manufacturing method for the antibacterial flexible hose for air conditioning and air conditioning according to a second embodiment of the present invention.

Fabrication method for the antibacterial flexible hose for air conditioning and heating according to the second embodiment of the present invention as shown in FIG.

While unwinding the wound reinforcing fabric 10, the liquid antimicrobial agent 40 is applied to the back surface 11 (S100), and the antibacterial agent 40 is applied to the back surface 11 by heating the reinforcing fabric 10 to which the liquid antimicrobial agent 40 is applied. The coating layer 40a is formed (S200), the liquid adhesive 20 is applied to the surface 12 of the reinforcing fabric 10 (S300), and the heating of the reinforcing fabric 10 to which the liquid adhesive 20 is applied. In order to form an adhesive coating layer 20a on the surface 12 (S400), while unwinding the wound aluminum fabric 30, the upper surface 31 is brought into contact with the adhesive coating layer 20a of the reinforcing fabric 10. It is made of a step (S500) for preparing the antimicrobial flexible hose fabric 50 by laminating in a state.

The present invention is easy to be damaged due to the characteristics of the aluminum fabric 30 of the thin film, so that the antimicrobial coating layer 40a is laminated through the process of unwinding the wound reinforcement fabric 10 and the aluminum fabric 30. The antimicrobial flexible hose fabric (50) can be easily prepared to prevent the spread of various germs contained in hot air, cold air, exhaust gas, or indoor air in advance, thereby ensuring a more hygienic air conditioning facility. .

At this time, the liquid antimicrobial agent 40 may include zeolite, calcium phosphate, zirconium phosphate or silica gel.

The antimicrobial agent is classified into organic and inorganic type according to the material. When using an organic antimicrobial agent having a low melting point, the antimicrobial agent is liberated on the back surface 11 of the reinforcing fabric 10 during processing, so it is easy to cause appearance defects such as stickiness. In addition to the deterioration of the antimicrobial power over time, there is a problem that the organic antimicrobial agent harmful to the human body is introduced along the hose in the present invention is to use an inorganic antimicrobial agent such as zeolite, calcium phosphate, zirconium phosphate or silica gel having a high melting point.

Furthermore, inorganic antimicrobial agents such as zeolite, calcium phosphate, zirconium phosphate or silica gel have high stability compared to organic antimicrobial agents, such as high heat resistance, no volatilization and decomposition, and the antimicrobial effect is expressed by active oxygen ions. It has the advantage of long persistence and does not generate resistant bacteria can be more easily applied to the present invention.

More specifically, zeolite is a generic term for minerals that are aluminum silicate hydrates of alkali and alkaline earth metals. The color is colorless transparent or white translucent, and has the highest antibacterial effect. 1670 ℃, specific gravity 3.14, insoluble in water, but insoluble in strong acid, antibacterial effect, zirconium phosphate is colorless crystal, used as inorganic ion exchanger, antimicrobial effect, silica gel reaction of sulfuric acid and sodium silicate It is made of silicate particles of a strong net structure made by a wide surface area is very excellent in the ability to absorb water or alcohol, etc., because it is widely used as a dehumidifying agent has an antimicrobial effect will be able to be applied to the present invention.

Preferably, the liquid antimicrobial agent 40 may include 10-30 wt% zeolite and 70-90 wt% diluent.

In the present invention, zeolite, an inorganic antimicrobial agent, is less than 10% by weight of antimicrobial activity, and when it exceeds 30% by weight, the physical properties are significantly lowered. In the present invention, 70 to 90% by weight of a diluent and 10 to 30% by weight of zeolite are mixed. It is prepared as a liquid antimicrobial agent 40.

Furthermore, the liquid adhesive 20 may contain 10-35 weight% adhesive, 1-10 weight% hardening | curing agent, and 60-85 weight% diluent.

When the adhesive is less than 10% by weight, the adhesive strength is weakened, and when it is 35% by weight or more, the viscosity is excessive and the interface spreadability between the reinforcing fabric 10 and the aluminum fabric 30 is lowered. In addition, by including 1 to 10% by weight of the curing agent to be quickly cured by the adhesive coating layer (20a) during heating, further comprising 60 to 85% by weight of the diluent to the reinforcing fabric 10 as a liquid adhesive (20) Allow to be applied quickly.

Preferably, the reinforcing fabric 10 may be applied to any one of a PET film, a synthetic resin film, a nonwoven fabric.

PET film or synthetic resin film not only has excellent adhesion with the aluminum fabric 30 of the thin film, but also maximizes the adhesive strength when combined with the aluminum fabric 30 and heating with the liquid antibacterial agent 40 and the liquid adhesive 20 interposed therebetween. The nonwoven fabric is particularly preferable because it can relatively compensate for the phenomenon that the aluminum fabric 30 is easily damaged by temperature maintenance and noise prevention.

Furthermore, the step S200 is heated while passing the reinforcing fabric 10 coated with the liquid antimicrobial agent 40 into the antimicrobial coating heating chamber 62 having a temperature of 100 ~ 150 ℃ antibacterial coating layer ( 40a) may be formed, and the step S400 may be performed while heating the reinforcing fabric 10 to which the liquid adhesive 20 is applied into the adhesive coating heating chamber 61 having a temperature of 100 to 140 ° C. An adhesive coating layer 20a may be formed at 12.

As such, the reinforcing fabric 10 passes through the adhesive coating heating chamber 61 and the antimicrobial coating heating chamber 62 to receive the heating heat, thereby unwinding the reinforcing fabric 10 wound in a roll shape. By continuously utilizing the annealing process, it is possible to maximize the productivity by guaranteeing workability in terms of manufacturing the antimicrobial flexible hose fabric 50 together with the aluminum fabric 30 more quickly.

Furthermore, the step S500 is to pass through between the heating roll 71 and the silicon roll 72 while pressing the adhesive coating layer 20a of the aluminum fabric 30 and the reinforcing fabric 10 so as to be bonded together, The heating roll 71 can maintain the temperature of 60-90 degreeC.

By passing the aluminum fabric 30 and the reinforcing fabric 10 between the heating roll 71 and the silicon roll 72, the aluminum fabric 30, which is easily damaged, is protected while being buffered by the silicon roll 72. , The relatively tough reinforcing fabric 10 may be more closely adhered to the aluminum fabric (30).

Furthermore, the coating adhesive layer can be more quickly fixed while maintaining the spreadability at the interface between the aluminum fabric 30 and the reinforcing fabric 10 by the heating roll 71 maintaining the temperature of 60 ~ 90 ℃.

On the other hand, after the step S500 further comprises a step (S600) of rewinding the antimicrobial flexible hose fabric 50 in a roll shape to facilitate the storage and movement of the antimicrobial flexible hose fabric 50, and the S600 After the step, the roll-type antimicrobial flexible hose fabric 50 is embedded in an aging room (Aging Room) 80 at 45 to 65 ° C. for 35 to 55 hours, thereby including a step (S700) to volatilize the antimicrobial coating layer 40a. Of course, it is possible to maximize the firmness of the adhesive coating layer (20a) as well as maintaining a solid.

The present invention can be used in the industrial field utilized as a material such as a flexible duct used as an air conditioning facility through which warm air, cold air, exhaust gas, or indoor air passes.

10: reinforcing fabric 11: back side
20: liquid adhesive 20a: adhesive coating layer
30: aluminum fabric 31: upper surface
32: lower surface 40: liquid antimicrobial agent
40a: antimicrobial coating layer 50: fabric for antimicrobial flexible hose
61: heating chamber for adhesive coating 62: heating chamber for antimicrobial coating
71: heating roll 72: silicon roll
80: Aging Room

Claims (27)

Step S10 of applying the liquid adhesive 20 to the back surface 11 while unwinding the wound reinforcing fabric 10,
Step S20 for forming an adhesive coating layer (20a) on the back surface 11 by heating the reinforcing fabric 10 is coated with the liquid adhesive 20,
Step (S30) of laminating in the state that the upper surface 31 is in contact with the adhesive coating layer (20a) of the reinforcing fabric 10 while unwinding the wound aluminum fabric 30,
Step (S40) of applying a liquid antimicrobial agent 40 to the lower surface 32 of the aluminum fabric 30 laminated to the reinforcing fabric 10,
The antimicrobial flexible hose fabric 50 is formed by laminating the reinforcing fabric 10 and heating the aluminum fabric 30 to which the liquid antimicrobial agent 40 is applied to form an antimicrobial coating layer 40a on the lower surface 32. Fabrication method for an antibacterial flexible hose for air conditioning and heating, comprising the step (S50) to provide. The method of claim 1,
The liquid antimicrobial agent 40 is a method for manufacturing a fabric for antibacterial flexible hose for air conditioning and heating, characterized in that it comprises zeolite, calcium phosphate, zirconium phosphate or silica gel. The method of claim 1,
The liquid antimicrobial agent (40) is 10 to 30% by weight of zeolite and 70 to 90% by weight of diluent, characterized in that the manufacturing method for fabric for antibacterial flexible hose for air conditioning and air conditioning. The method of claim 1,
The liquid adhesive (20) comprises 10 to 35% by weight of the adhesive, 1 to 10% by weight of the curing agent, and 60 to 85% by weight of the diluent, characterized in that the air conditioner antibacterial flexible hose fabric manufacturing method. The method according to any one of claims 1 to 4,
The reinforcing fabric 10 is a manufacturing method for the antibacterial flexible hose fabric for air conditioning and heating, characterized in that any one of a PET film, a synthetic resin film, a nonwoven fabric. The method according to any one of claims 1 to 4,
The S20 step is heated while passing the reinforcing fabric 10 coated with the liquid adhesive 20 into the adhesive coating heating chamber 61 having a temperature of 100 ~ 140 ℃ the adhesive coating layer on the back surface 11 Method for producing an antibacterial flexible hose fabric for air conditioning and heating, characterized in that the (20a) is formed. The method according to any one of claims 1 to 4,
The step S50 is laminated on the reinforcing fabric 10 and heated while passing the aluminum fabric 30 coated with the liquid antimicrobial agent 40 into the antimicrobial coating heating chamber 62 having a temperature of 100 ~ 150 ℃. The antimicrobial flexible hose fabric manufacturing method for air conditioning and air conditioning, characterized in that to form the antimicrobial coating layer (40a) on the lower surface (32). The method according to any one of claims 1 to 4,
In step S30, the aluminum fabric 30 and the adhesive coating layer 20a of the reinforcing fabric 10 are brought into contact with each other while passing through the heating roll 71 and the silicon roll 72 so as to be compressed. Fabrication method for antibacterial flexible hose for air conditioning and heating. The method of claim 8,
The heating roll (71) is a method for manufacturing an antimicrobial flexible hose fabric for air conditioning and heating, characterized in that it maintains a temperature of 60 ~ 90 ℃. The method according to any one of claims 1 to 4,
Rewinding the antimicrobial flexible hose fabric (50) after the step S50 in a roll shape step (S60) characterized in that it comprises a step of manufacturing antimicrobial flexible hose fabric for air conditioning air conditioning. The method according to claim 3 or 4,
Rewinding the antimicrobial flexible hose fabric (50) in a roll shape after the step S50 (S60),
After the step S60, the roll-type antimicrobial flexible hose fabric 50 is embedded in the aging room (Aging Room; 80) at 45-65 ° C. for 35 to 55 hours, thereby including a step (S70) to volatilize the diluent. Fabrication method for an antibacterial flexible hose for air conditioning and heating. Step S100 of applying the liquid antimicrobial agent 40 on the back surface 11 while unwinding the wound reinforcing fabric 10,
Step (S200) and the antimicrobial coating layer 40a is formed on the back surface 11 by heating the reinforcing fabric 10 is coated with the liquid antimicrobial agent 40,
Step (S300) for applying the liquid adhesive 20 to the surface 12 of the reinforcing fabric 10,
Step (S400) to heat the reinforcing fabric 10 coated with the liquid adhesive 20 to form an adhesive coating layer (20a) on the surface 12,
Step of preparing the antimicrobial flexible hose fabric 50 by laminating the unwinded aluminum fabric 30 while the upper surface 31 is brought into contact with the adhesive coating layer 20a of the reinforcing fabric 10 (S500). Method of manufacturing a fabric for an air-conditioning and air conditioning antibacterial flexible hose comprising a). 13. The method of claim 12,
The liquid antimicrobial agent 40 is a method for manufacturing a fabric for antibacterial flexible hose for air conditioning and heating, characterized in that it comprises zeolite, calcium phosphate, zirconium phosphate or silica gel. 13. The method of claim 12,
The liquid antimicrobial agent (40) is 10 to 30% by weight of zeolite and 70 to 90% by weight of diluent, characterized in that the manufacturing method for fabric for antibacterial flexible hose for air conditioning and air conditioning. 13. The method of claim 12,
The liquid adhesive (20) comprises 10 to 35% by weight of the adhesive, 1 to 10% by weight of the curing agent, and 60 to 85% by weight of the diluent, characterized in that the air conditioner antibacterial flexible hose fabric manufacturing method. 16. The method according to any one of claims 12 to 15,
The reinforcing fabric 10 is a manufacturing method for the antibacterial flexible hose fabric for air conditioning and heating, characterized in that any one of a PET film, a synthetic resin film, a nonwoven fabric. 16. The method according to any one of claims 12 to 15,
The step S200 is heated while passing the reinforcing fabric 10 coated with the liquid antimicrobial agent 40 into the antimicrobial coating heating chamber 62 having a temperature of 100 ~ 150 ℃ the antimicrobial coating layer on the back 11 The manufacturing method of the antibacterial flexible hose fabric for air conditioning and air conditioning, characterized in that 40a is formed. 16. The method according to any one of claims 12 to 15,
The S400 step is heated while passing the reinforcing fabric 10 coated with the liquid adhesive 20 into the adhesive coating heating chamber 61 having a temperature of 100 ~ 140 ℃ the adhesive coating layer on the surface 12 Method for producing an antibacterial flexible hose fabric for air conditioning and heating, characterized in that the (20a) is formed. 16. The method according to any one of claims 12 to 15,
Step S500 is characterized in that the aluminum fabric 30 and the adhesive coating layer (20a) of the reinforcing fabric 10 to pass through between the heating roll 71 and the silicon roll 72 to be pressed while being bonded to each other to be laminated. Fabrication method for antibacterial flexible hose for air conditioning and heating. The method of claim 19,
The heating roll (71) is a method for manufacturing an antimicrobial flexible hose fabric for air conditioning and heating, characterized in that it maintains a temperature of 60 ~ 90 ℃. 16. The method according to any one of claims 12 to 15,
Rewinding the antimicrobial flexible hose fabric (50) after the step S500 in a roll shape step (S600), characterized in that the air conditioning air conditioner antimicrobial flexible hose fabric manufacturing method characterized in that it comprises a. 16. The method according to claim 14 or 15,
Rewinding the antimicrobial flexible hose fabric 50 in a roll shape after the step S500 (S600),
After the step S600, the roll-type antimicrobial flexible hose fabric 50 is embedded in the aging room (Aging Room; 80) at 45 to 65 ° C. for 35 to 55 hours, thereby including a step (S700) to volatilize the diluent. Fabrication method for an antibacterial flexible hose for air conditioning and heating. Aluminum fabric 30 fixed to the reinforcing fabric 10 with the reinforcing fabric 10, the adhesive coating layer 20a formed on the back surface 11 of the reinforcing fabric 10, and the adhesive coating layer 20a interposed therebetween. ), And the antimicrobial coating layer 40a formed on the lower surface 32 of the aluminum fabric 30,
The reinforcing fabric 10 is a fabric for antibacterial flexible hose for air conditioning and heating, characterized in that any one of a PET film, a synthetic resin film, a nonwoven fabric. Reinforcing fabric 10, the antimicrobial coating layer 40a formed on the back surface 11 of the reinforcing fabric 10, the adhesive coating layer 20a formed on the surface 12 of the reinforcing fabric 10, and the adhesive coating layer It includes an aluminum fabric 30 is fixed to the reinforcing fabric 10 with the (20a) therebetween,
The reinforcing fabric 10 is a fabric for antibacterial flexible hose for air conditioning and heating, characterized in that any one of a PET film, a synthetic resin film, a nonwoven fabric. delete 25. The method according to claim 23 or 24,
The antimicrobial coating layer (40a) is 10 to 30% by weight of the zeolite, 70 to 90% by weight of the antibacterial flexible hose fabric for air conditioning and air conditioning, characterized in that formed by heating a liquid antimicrobial agent 40 of the diluent. 25. The method according to claim 23 or 24,
The adhesive coating layer 20a is formed by heating a liquid adhesive 20 comprising 10 to 35% by weight of an adhesive, 1 to 10% by weight of a curing agent, and 60 to 85% by weight of a diluent. Fabric for antibacterial flexible hose.

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