KR102538016B1 - System of oxygen generator stiker with antibacterial and composition and mrthod thereof - Google Patents

Abstract

The present invention reacts with surrounding carbon dioxide or moisture, but does not react rapidly, reacts slowly, maintains a solid state, releases oxygen, and maintains an antibacterial function in a state where oxygen is released, and an oxygen generating antibacterial sticker manufacturing system, composition, and manufacturing It relates to a method for transporting nonwoven fabric at a uniform speed, a composition applicator for applying the oxygen generating antibacterial sticker composition to the surface at a uniform thickness, and a conveyor for transporting the oxygen generating nonwoven fabric coated with the oxygen generating antibacterial sticker composition on the nonwoven fabric at a uniform speed. A drying unit installed on the upper side of the conveyor unit and drying the oxygenated nonwoven fabric with hot air, and a compression unit for attaching a protective film to the upper side of the oxygenated nonwoven fabric passing through the drying unit and attaching adhesive and release paper to the lower side, and a compression unit that passes through the compression unit. It is made in the form of a sticker by the feature of including a semi-oxygenated nonwoven fabric that is transported at a uniform speed and wound around a semi-finished winding roll, and is easily attached to a selected location, and has a convenient effect of generating oxygen by ambient moisture and carbon dioxide. there is.

Description

Oxygen generating antibacterial sticker manufacturing system, composition and manufacturing method

The present invention relates to an oxygen-generating antibacterial sticker manufacturing system, composition, and manufacturing method, and more particularly, reacts with surrounding carbon dioxide or moisture, but does not react rapidly but reacts slowly while maintaining a solid state, releasing oxygen, and releasing oxygen. It relates to an oxygen-generating antibacterial sticker manufacturing system, composition, and manufacturing method that continue to maintain antibacterial function in the state.

It is included in fine dust naturally generated by sandstorms in desertification areas accelerated by climatic environmental changes such as recent global warming and yellow dust generated in wasteland fields, as well as automobile exhaust and factory exhaust artificially created by industrialization and industrialization. It can be a daily life of modern people to live in air polluted by various harmful substances. Hereinafter, it will be explained and understood that fine dust includes various harmful substances such as nitrogen oxides NOX and sulfur oxides SOX.

The human bronchus is directly exposed to fine dust due to breathing, resulting in respiratory diseases such as cough, asthma, and bronchitis. It is well known that the air in Seoul has a higher concentration of fine dust compared to other large cities due to the influence of yellow dust.

According to the information announced in the 2013 Air Quality Annual Report of the Ministry of Environment, the concentration of fine dust in Seoul among other large cities is 45 μg/m ³ , about 3 times higher than that in London (18 μg/m ³ ), and 30 μg/m ³ in LA. It can be seen that the concentration of fine dust is relatively higher than that of other cities, about 1.5 times higher than that of other cities.

Therefore, it is necessary to protect the human bronchus from fine dust and various harmful substances, and many people are wearing masks when going out due to this need.

The mask protects the respiratory tract from fine dust by blocking the inflow of dust and fine dust suspended in the air (atmosphere) to the respiratory tract. On the other hand, dust masks and masks with high KF numbers have a much higher rate of blocking fine dust than general masks, and in order to reduce the gap through which fine dust enters, a metal implant whose shape is adjusted to fit the curved surface of the face is further provided, and the mask A filter to block the inflow of harmful substances is provided inside or part of the filter to increase the blocking rate of fine dust and harmful substances contained in the outside air.

These masks, dust masks, etc. block the inflow of fine dust contained in the air to breathe with relatively safe air, but the inflow of air is blocked as much as the inflow of fine dust is blocked, making breathing feel stuffy. On the other hand, breathed breath contains moisture, and the concentration of moisture inside the mask increases due to repeated breathing, and the increased humidity makes you feel uncomfortable. In addition to causing skin diseases such as skin diseases, there are problems such as a lack of air flow due to long-term use and lack of oxygen, which causes people with weak lung capacity to complain of anemia.

As a prior art that partially solves these problems, there is a 'outdoor blocking mask' by Korean Patent Registration No. 10-1161848 (2012. 06. 26.).

Figure 1 is according to an embodiment of the prior art and is a block diagram of the outside air mask.

Hereinafter, referring to the accompanying drawings, it is provided with a main body 100 and a hanging band 140 like a general life mask, but an opening is formed in the center of the main body and a plurality of wrinkles are formed on the front surface of the main body to form an inflatable air bag portion. When the expansion member 200 made of 210 is installed and air is blown through the opening from the rear of the main body, the air bag part 210 expands, blocking the inflow of outside air in a fire or the like situation, and the air bag part 210 It has the advantage of breathing using the air filled inside, but breathing is very difficult when the oxygen of the air filled in the air bag part 210 is consumed, so there is a problem that the lack of oxygen and moisture problems due to long-time use are still not solved. .

In addition, as another prior art, there is a 'mask for blocking dust and preventing fogging' according to Korean Patent Registration No. 10-1648577 (2016. 08. 09.). Other prior art has the advantage of blocking external dust from entering the user's respiratory tract and distributing the air discharged from the user's respiratory tract to flow in multiple directions, but the problem of insufficient oxygen and moisture caused by long-term use is still not solved. there is.

And, as another prior art, there is a 'functional dust mask' according to Republic of Korea Publication No. 10-2016-0097619 (August 18, 2016). Another prior art has the advantage of ensuring that the nose pads of the glasses are properly seated, preventing the lenses of the glasses from getting wet, preventing the bridge of the nose and the middle of the forehead from being burned by light and heat, and increasing the wearing comfort, workability and safety, but long-term use There is still a problem that the lack of oxygen and moisture caused by the problem cannot be solved.

Therefore, when using a mask, it removes moisture while not feeling a lack of oxygen, and if you feel a lack of oxygen due to a lot of exercise in an environment without fine dust, more oxygen is supplied smoothly to speed up physical recovery and remove surrounding bacteria. There is a need to develop a technology that includes an antibacterial function.

On the other hand, it is necessary to develop a technique for supplying oxygen simply, quickly, and relatively cheaply in the case of weak lung capacity, severe exercise, or when it is necessary to supply high oxygen concentration due to various other reasons.

Republic of Korea Patent Registration No. 10-1161848 (2012. 06. 26.) ‘Outdoor air blocking type mask’ Republic of Korea Patent Registration No. 10-1648577 (2016. 08. 09.) ‘Mask for blocking dust and preventing fogging’ ‘Functional dust mask’ according to Republic of Korea Publication No. 10-2016-0097619 (August 18, 2016)

The present invention, which was devised to solve the problems and needs of the prior art as described above, is made in the form of a sticker, which is easily attached to a necessary position around the user and generates oxygen by the surrounding moisture and carbon dioxide. An oxygen generating antibacterial sticker manufacturing system and It is an object to provide a composition and manufacturing method.

In addition, the present invention is an oxygen-generating antibacterial sticker that is attached to the user's surroundings or mask in the form of a sticker and stably releases oxygen for a long time by moisture and carbon dioxide contained in the breath, thereby eliminating headaches caused by lack of oxygen and rapidly recovering physical strength. It is an object to provide manufacturing systems and compositions and manufacturing methods.

On the other hand, the present invention provides an oxygen-generating antibacterial sticker manufacturing system, composition, and manufacturing method in which oxygen is slowly and stably generated to prolong the use time and has an antibacterial function to prevent bacteria or infectious pathogens from propagating in a damp mask. that is its purpose

In addition, the present invention is an oxygen generating antibacterial sticker manufacturing system that increases the efficiency of oxygen generation while being used cleanly because the material for generating oxygen in the form of a sticker does not melt due to moisture, etc., and quickly recovers physical strength consumed by exercise, etc. And it is its purpose to provide a composition and manufacturing method.

The oxygen-generating antibacterial sticker manufacturing composition of the present invention, which was devised to solve the above objects and needs, can be composed by mixing 10 to 30 parts by weight of a porous inorganic material with respect to 100 parts by weight of the oxygen generator.

The binder may be further mixed in an amount of 1 to 5 parts by weight based on 100 parts by weight of the oxygen generator.

2 to 8 parts by weight of the antibacterial composition may be further mixed with respect to 100 parts by weight of the oxygen generator.

The oxygen generating agent may be made of any one or more than one selected from potassium superoxide (KO2), sodium peroxide (NaO2), and calcium peroxide (CaO2).

The porous inorganic material may be made of any one or more than one selected from zeolite, alumina, silica and diatomaceous earth.

The antimicrobial composition may be composed of a mixture of cyclosilicate and phyllosilicate, any one selected from illite, silver, zinc, and platinum, or a mixture of any one or more.

The antimicrobial composition may further include titanium dioxide.

The mixture of cyclosilicate and phyllosilicate may be made by mixing cyclosilicate and phyllosilicate in the same weight ratio.

The binder may be prepared by mixing a cured resin and rosin.

The cured resin and rosin may be mixed in a weight ratio of 1:9 to 4:6.

The zeolite, alumina, silica, and diatomaceous earth may be formed of particles having a diameter of 5 to 10 micrometers.

The rosin, cyclosilicate, phyllosilicate, illite, silver, zinc, and platinum may be formed of particles having a diameter of less than 1 micrometer.

The titanium dioxide may be formed of particles having a diameter of less than 100 nanometers.

The curing resin may be made of any one or more than one selected from urethane acrylate, epoxy acrylate and polyester acrylate.

The binder may further include 1 to 10 parts by weight of the antimicrobial composition based on 100 parts by weight of the cured resin.

The cured resin may further include 10 to 30 parts by weight of a reactive monomer diluent based on 100 parts by weight.

The diluent is 2-ethylhexyl (meth) acrylate, 2-dicaprolactone ethyl acrylate, cyclohexyl (meth) acrylate, phenoxyethyl (meth) acrylate, isobornyl (meth) acrylate, acryloyl Sunsetporin, N-vinylpyrrolidone, N-vinylcaprolactam, dimethylaminoethyl (meth)acrylate, tripropylene glycoldi (meth)acrylate, cyclopentenyl (meth)acrylate, tricyclodecanedimethanoldi ( It may consist of any one or more than any one selected from meta) acrylate and trimethylolpropane tri(meth)acrylate.

The silver, zinc, and platinum may be formed of any one or a mixture of any one or more selected.

The antimicrobial composition includes a mixture of the cyclosilicate and the phyllosilicate in a weight ratio of 70 to 90%, and the illite in a weight ratio of 5 to 25%, and any one selected from silver, zinc, and platinum, or a mixture of any one or more. can

The silver, zinc, and platinum may be mixed in an equal weight ratio.

The silver, zinc, and platinum may each be composed of ions.

The oxygen generating antibacterial sticker manufacturing system of the present invention, which was devised to solve the above objects and needs, transfers the nonwoven fabric 1010 at a uniform speed and applies the oxygen generating antibacterial sticker composition 1020 to the surface at a uniform thickness. Composition application unit 1000; a conveyor unit 2000 for conveying the oxygen-generating antibacterial sticker composition 1020 applied to the non-woven fabric 1010 at a uniform speed; a drying unit 3000 installed on an upper side of the conveyor unit 2000 to dry the oxygenated nonwoven fabric 1030 with hot air; a compression unit 4000 for attaching a protective film to the upper side of the oxygenated nonwoven fabric 1030 passing through the drying unit 3000 and attaching an adhesive and a release paper to the lower side; a semi-finished oxygen nonwoven fabric 5000 that passes through the compression unit 4000 and transports the semi-finished oxygen nonwoven fabric 5010 at a uniform speed and winds it around a semi-finished product winding roll 5020; can include

An unwinding unit 6000 that unwinds the semi-oxygenated nonwoven fabric 5010 wound around the semi-made winding unit 5000 at a uniform speed; a slit cutting unit 7000 for cutting the semi-oxygenated nonwoven fabric 5010 unwound at a uniform speed from the unwinding unit 6000 into a uniform width along the longitudinal direction; A sticker mold unit 8000 that separates the semi-oxygenated nonwoven fabric 5010 that has passed through the slit cutting unit 7000 into a sticker shape of a specific size and shape; A finished winding unit 9000 that winds the semi-oxygenated nonwoven fabric 5010 passing through the sticker mold unit 8000 at a uniform speed; may further include.

The composition application unit 1000 includes a fabric roll unit 1040 in which the nonwoven fabric 1010 is wound and fixed in a rotating state; an unwinding roller 1050 for unwinding the nonwoven fabric 1010 wound around the fabric mole part 1040 at a uniform speed; An oxygen generating antibacterial sticker composition 1020 injected into an upper portion of the unwinding roller 1050; An application knife 1060 for manufacturing an oxygen non-woven fabric 1030 by applying the oxygen generating antibacterial sticker composition 1020 to a uniform thickness on the upper surface of the non-woven fabric 1010; can include

The conveyor unit 2000 includes a guide roller 2010 for guiding the transport direction of the oxygenated nonwoven fabric 1030; An endless track belt unit 2020 that transports the oxygenated nonwoven fabric 1030 transported by the guide roller 2010 in one direction; Transfer pins 2030 that are repeatedly installed on the surface of the belt unit 2020 at uniform widths and intervals to smoothly transport the oxygenated nonwoven fabric 1030; can include

The compression unit 4000 includes a protective film roll unit 4020 in which a protective film 4010 attached to the upper surface of the oxygen nonwoven fabric 1030 is wound; An adhesive release film roll unit 4040 wound with an adhesive release film 4030 for sequentially and simultaneously attaching an adhesive and a release paper to the lower surface of the oxygen nonwoven fabric 1030; an upper pressure roller 4050 installed on the upper surface of the oxygen nonwoven fabric 1030 and pressing and bonding the protective film 4010 to the upper surface of the oxygen nonwoven fabric 1030; a lower pressure roller 4060 installed on the lower surface of the oxygen nonwoven fabric 1030 and bonding the adhesive release film 4030 to the lower surface of the oxygen nonwoven fabric 1030 by pressing it; can include

The slit cutting unit 7000 is a width cutting blade unit 7010 that receives the semi-oxygenated nonwoven fabric 5010 at a uniform speed and cuts the semi-oxygenated nonwoven fabric 5010 to a uniform width on the upper side of the semi-oxygenated nonwoven fabric 5010 along the lengthwise direction. ; a cutting pressure roller 7020 installed on the lower side of the width cutting blade 7010 to pressurize the semi-oxygenated nonwoven fabric 5010 to be smoothly cut; can include

The sticker mold unit 8000 includes a cutting mold unit 8010 that receives the semi-oxygenated nonwoven fabric 5010 at a uniform speed, prints a specific pattern while moving in an up and down direction, and cuts the semi-oxygenated nonwoven fabric 5010 to be separated into stickers of a specific shape; a mold supporting part 8020 installed on the lower side of the cutting mold means 8010 to support smooth printing and cutting; can include

The oxygen generating antibacterial sticker manufacturing method of the present invention, which was devised to solve the above objects and needs, includes a material preparation step of preparing an oxygen generating agent, a porous inorganic material, a binder, and a material for an antimicrobial composition; A composition preparation step of mixing an oxygen generating antibacterial composition using the material prepared in the material preparation step; A roll installation step of preparing a protective film, an adhesive, a release paper, and a nonwoven fabric for application, attachment, and coating of the oxygen generating antibacterial composition in roll units and installing them in a manufacturing system; A semi-finished coating step of applying an oxygen-generating antibacterial composition to the non-woven fabric, drying it, and then press-coating a protective film, an adhesive, and a release paper to produce a semi-oxygen non-woven fabric; A finished winding step of cutting the semi-oxygenated nonwoven fabric produced in the semi-finished coating step into a uniform width in the longitudinal direction, separating it from printing into a specific sticker shape, and winding it up; can include

The drying may be performed by staying for 1 minute or more in an environment in which air at a temperature of 40 degrees Celsius or higher is forced convection.

In the material preparation step, 10 to 30 parts by weight of the porous inorganic material, 1 to 5 parts by weight of the binder, and 2 to 8 parts by weight of the antimicrobial composition may be prepared based on 100 parts by weight of the oxygen generator.

The adhesive release film 4030 may be formed by sequentially and simultaneously attaching an adhesive, Velcro, and a release paper protecting the surface of the Velcro to the lower surface of the oxygen nonwoven fabric 1030.

The present invention having the configuration as described above is made in the form of a sticker, and has the advantage of being easily attached to a necessary position around the user and generating oxygen by ambient moisture and carbon dioxide.

In addition, the present invention is easily attached to the selected and necessary position of the mask, and since oxygen is stably released for a long time by moisture and carbon dioxide contained in respiration, it has the advantage of eliminating the occurrence of headaches due to lack of oxygen and speeding recovery of physical strength. .

On the other hand, the present invention has the advantage of preventing bacteria or infectious pathogens from propagating in a mask with a lot of moisture by providing an antibacterial function while extending the use time by slowly and stably generating oxygen.

In addition, since the oxygen generating material in the form of a sticker does not melt due to moisture or the like, the present invention has the advantage of being used cleanly, increasing the oxygen generation efficiency, and allowing the physical strength consumed by exercise to recover quickly by supplying clean oxygen.

1 is a configuration diagram of an external air blocking mask according to an embodiment of the prior art;
2 is a semi-finished product manufacturing configuration diagram of an oxygen generating antibacterial sticker manufacturing system according to an embodiment of the present invention;
Figure 3 is according to an embodiment of the present invention, and a finished product manufacturing configuration of the oxygen generating antibacterial sticker manufacturing system,
4 is a detailed configuration diagram of a composition application unit according to an embodiment of the present invention;
5 is a detailed configuration diagram of a conveyor unit according to an embodiment of the present invention;
6 is a detailed configuration diagram of a compression unit according to an embodiment of the present invention;
7 is a flowchart of a method for manufacturing an oxygen generating antibacterial sticker according to an embodiment of the present invention;
8 is a diagram illustrating antibacterial sterilization and deodorization ability and environmental improvement ability of a nanoparticle-sized photocatalyst according to an embodiment of the present invention;
and
9 is an explanatory view of a state in which a photocatalyst affects antibacterial and deodorizing properties for explaining the present invention.

Since the present invention can apply various transformations and have various embodiments, specific embodiments will be illustrated in the drawings and described in detail in the detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all conversions, equivalents, or substitutes included in the spirit and scope of the present invention. In describing the present invention, if it is determined that a detailed description of related known technologies may obscure the gist of the present invention, the detailed description will be omitted.

Hereinafter, the antibacterial agent will be described as including a fungicide function.

Figure 2 is a semi-finished product manufacturing configuration of an oxygen generating antibacterial sticker manufacturing system according to an embodiment of the present invention, Figure 3 is a finished product manufacturing configuration of an oxygen generating antibacterial sticker manufacturing system according to an embodiment of the present invention, Figure 4 is a detailed configuration diagram of a composition application unit according to an embodiment of the present invention, Figure 5 is a detailed configuration diagram of a conveyor unit according to an embodiment of the present invention, Figure 6 is according to an embodiment of the present invention It is a detailed configuration of the compression unit, and Figure 7 is a flow chart of an oxygen generating antibacterial sticker manufacturing method according to an embodiment of the present invention.

Hereinafter, referring to the accompanying drawings, an oxygen generating antibacterial sticker manufacturing system according to an embodiment of the present invention will be described. , It is a configuration including a semi-product winding unit 5000, an unwinding unit 6000, a slit cutting unit 7000, a sticker mold unit 8000, and a finished winding unit 9000.

The composition application unit 1000 transfers the nonwoven fabric 1010 at a uniform speed and applies the oxygen generating antibacterial sticker composition 1020 to the surface at a uniform thickness.

The composition application unit 1000 includes a fabric roll unit 1040 in which the nonwoven fabric 1010 is wound and fixed in a rotating state, and an unwinding roller 1050 for unwinding the nonwoven fabric 1010 wound around the fabric mallet unit 1040 at a uniform speed. The oxygen generating antibacterial sticker composition 1020 and the oxygen generating antibacterial sticker composition 1020 injected into the upper part of the unwinding roller 1050 are applied to the upper surface of the nonwoven fabric 1010 in a uniform thickness to form the oxygen nonwoven fabric 1030. It is a configuration including an application knife 1060 to be manufactured.

The composition application unit 1000 is configured to transport the nonwoven fabric 1010 at a speed of 1 to 3 meters per second, but at a speed of 2 meters per second, so that the oxygen generating antibacterial sticker composition 1020 is continuously applied but has the advantage of being uniformly applied. there is. At this time, the thickness of the oxygen generating antibacterial sticker composition 1020 applied to the nonwoven fabric 1010 is applied to a thickness of 2 to 4 millimeters, but preferably applied to a thickness of 3 millimeters, and when applied to a thickness of 3 millimeters, an average thickness of 2.5 millimeters after drying Since it maintains the state attached to the nonwoven fabric 1010 is maintained well, there is an advantage in reducing the occurrence of defects during the handling process.

The conveyor unit 2000 transports the oxygen-generating antibacterial sticker composition 1020 coated on the non-woven fabric 1010 at a uniform speed. The conveyor unit 2000 is configured to transport the nonwoven fabric 1010 at a speed of 1 to 3 meters per second and at a speed of 2 meters per second.

The conveyor unit 2000 includes a guide roller 2010 for guiding the transport direction of the oxygen nonwoven fabric 1030 and an endless track belt unit 2020 for transporting the oxygen nonwoven fabric 1030 transported by the guide roller 2010 in one direction. and a transfer pin unit 2030 that is repeatedly installed on the surface of the belt unit 2020 at uniform widths and intervals to facilitate the transfer of the oxygen nonwoven fabric 1030. The transfer pin part 2030 is uniformly arranged at 10 millimeter intervals on the front, rear, left and right sides, and has a diameter of 1 millimeter protruding from the surface at a height of 1 millimeter, and the oxygen generating antibacterial sticker composition 1020 is applied on the lower surface of the oxygen nonwoven fabric 1030 It is configured to accurately transport the oxygen nonwoven fabric 1030 at a constant speed without deformation.

The drying unit 3000 is installed on the upper side of the conveyor unit 2000 to dry the oxygen nonwoven fabric 1030 with hot air, but has a closed structure in which the hot air is not arbitrarily discharged to the outside.

The drying unit 3000 is configured so that the oxygen nonwoven fabric 1030 stays in a hot air of 40 degrees Celsius for at least 5 to 20 seconds, and the applied oxygen generating antibacterial sticker composition 1020 is dried and cured at a humidity of 5% or less. It is quite natural that the temperature and heating time of the hot air can be adjusted if the curing can be performed with a humidity of 5% or less as needed.

The drying unit 3000 is configured to circulate and transport hot air at 40 degrees Celsius at a speed of 1 to 2 meters per second, and to circulate and transport hot air in a horizontal direction along the transport direction of the oxygenated nonwoven fabric 1030. The circulation conveying rate of the hot air can be increased to 3 to 4 meters per second due to the need for faster drying. However, drying too quickly can cause nodules. On the other hand, if necessary, the hot air may be circulated and transported from the upper side to the lower side.

The compression unit 4000 attaches a protective film 4010 to the upper side of the oxygenated nonwoven fabric 1030 that has passed through the drying unit 3000, and attaches an adhesive and a release paper or an adhesive and a Velcro and a release paper to the lower side, but adheres to it by a compression method. and attach it The adhesive is made of a double-sided adhesive and is composed of an adhesive release film 4030 prepared in a state in which it is sequentially adhered to the release paper. Alternatively, the adhesive is made of a double-sided adhesive, and the velcro bonded to the fiber layer is sequentially connected to the release paper that protects the surface of the velcro from foreign substances. Hereinafter, the adhesive release film 4030 will be described, described, and understood as being any one of a configuration consisting of double-sided adhesive + release paper or double-sided adhesive + Velcro + release paper.

Velcro has a property of sticking well to other fiber surfaces, and the total thickness of the Velcro is 0.1 to 0.2 millimeters, and it is highly desirable to maintain flexibility to configure it not to exceed 0.2 millimeters. Velcro is a trademark and company name, but since it is well known as a product with a Velcro function, further detailed description of the Velcro or Velcro will be omitted.

It consists of an adhesive release film 4030 prepared in a state in which it is sequentially adhered to the release paper.

The adhesive is made of a double-sided tape having an adhesive strength or a tensile strength of 200 to 500 grams per cubic centimeter on one side, and the adhesive strength can be increased or decreased as needed so that any one selected can be used. The protective film 4010 can be double attached, and the outermost outer film is completely sealed to block the inflow of moisture, and the protective film attached below has a plurality of holes to allow moisture to flow in in a controlled state. Therefore, it is preferable to form a plurality of projections (embossing) or separation handles so that the outer film can be easily separated and removed during use.

The compression unit 4000 is a protective film roll unit 4020 on which the protective film 4010 attached to the upper surface of the oxygen nonwoven fabric 1030 is wound and an adhesive and a release paper are sequentially and simultaneously attached to the lower surface of the oxygen nonwoven fabric 1030. An upper pressure roller that is installed on the upper surface of the adhesive release film roll unit 4040 and the oxygen nonwoven fabric 1030 around which the release film 4030 is wound, and presses and adheres the protective film 4010 to the upper surface of the oxygen nonwoven fabric 1030. 4050 and a lower pressure roller 4060 installed on the lower surface of the oxygen nonwoven fabric 1030 and bonding the adhesive release film 4030 to the lower surface of the oxygen nonwoven fabric 1030 by pressing it.

The upper pressure roller 4050 and the lower pressure roller 4060 preferably have a configuration in which the surfaces of the rollers are maintained at about 30 to 45 degrees Celsius and an average of 40 degrees Celsius, and a pressure of 100 grams per square meter is applied. It is preferable to transmit pressure to a depth of 2 to 5 mm and to transmit pressure to a depth of 2 mm.

The half-manufactured winding unit 5000 transfers the semi-manufactured oxygen nonwoven fabric 5010 passing through the compression unit 4000 at a uniform speed and winds it around the semi-manufactured winding roll 5020. The half winding unit 5000 winds at an average speed of 2 meters per second, but is configured so that the oxygen nonwoven fabric 1030 discharged from the conveyor unit 2000 is wound in a state where it does not sag.

The unwinding unit 6000 unwinds and unwinds the semi-oxygenated nonwoven fabric 5010 wound in the semi-made winding unit 5000 at a uniform speed. The unwinding unit 6000 is preferably configured so that the semi-oxygenated nonwoven fabric 5010 is constantly unwound at an average speed of 2 meters per second.

The slit cutting unit 7000 cuts the semi-oxygenated nonwoven fabric 5010 unwound at a uniform speed from the unwinding unit 6000 to a uniform width along the longitudinal direction. The width cut by the slit cutting unit 7000 is configured differently according to the shape of the sticker, and is cut to an average width of 25 to 50 millimeters, but may be increased or decreased as necessary. The 25 millimeter interval is relatively preferable since the sticker should be easily attached and easily removed. The slit cutting unit 7000 cuts the adhesive of the oxygen-generating antibacterial sticker composition 1020, the protective film 4010, the nonwoven fabric 1010, and the adhesive release film 4030 that are applied and cured by drying, but the adhesive release film 4030 ) The release paper is configured to remain uncut.

The slit cutting unit 7000 receives the semi-oxygenated nonwoven fabric 5010 at a uniform speed and cuts the semi-oxygenated nonwoven fabric 5010 at a uniform width on the upper side of the semi-oxygenated nonwoven fabric 5010 along the lengthwise direction. It is configured to include a cutting pressure roller 7020 installed on the lower side of the knife portion 7010 to pressurize the semi-oxygenated nonwoven fabric 5010 to be smoothly cut.

The sticker mold unit 8000 cuts or separates the semi-oxygenated nonwoven fabric 5010 that has passed through the slit cutting unit 7000 into a sticker shape of a specific size and a randomly selected shape.

The sticker mold unit 8000 receives the semi-oxygenated nonwoven fabric 5010 at a uniform speed, prints a specific pattern while moving in the vertical direction, and includes a cutting mold means 8010 and a cutting mold means ( 8010) is installed on the lower side and includes a mold supporting part 8020 for supporting printing and cutting to be performed smoothly.

The sticker mold unit 8000 may be configured in a roller shape, and in the drawings, it is shown in a flat press shape for easy understanding, and the cutting depth is applied on the nonwoven fabric 1010 and cured by drying the oxygen generating antibacterial sticker composition. (1020), the protective film 4010, the nonwoven fabric 1010, and the adhesive of the adhesive release film 4030 are cut, but the release paper of the adhesive release film 4030 remains uncut.

The sticker mold unit 8000 can be cut in a separate state as described above at every predetermined length along the longitudinal direction, and can print the selected pattern in color.

The finished winding unit 9000 winds the semi-oxygenated nonwoven fabric 5010 passing through the sticker mold unit 8000 at a uniform speed.

The oxygen generating antibacterial sticker composition 1020 of the present invention is composed of an oxygen generating agent, a porous inorganic material, a binder, and an antibacterial agent composition.

The binder is made by mixing 60 to 90 weight ratio (wt%) of rosin (rosin) with 10w% to 40w% of cured resin. When the mixing ratio of rosin (resin) is less than 60 wr%, there is a disadvantage in that the flexibility of the sticker form is lowered and easily broken in a dry state.

The cured resin is urethane acrylate, epoxy acrylate, polyester acrylate, any one or more than 100 parts by weight of a resin mixed with any one or more antibacterial and sterilizing power (sterilizing power) 1 part by weight to 10 parts by weight of an antibacterial agent composition further can be completed, including

The antimicrobial composition comprises a mixture of cyclosilicate and phyllosilicate; illite; A composition comprising any one or a mixture of any one or more selected from among silver, zinc, and platinum ions is used. When one or more of silver, zinc, and platinum ions are included, the same amount may be mixed in a weight ratio, or one selected one may be used alone. Meanwhile, titanium dioxide (TiO 2 ) particles having a size of 100 nanometers (nm) or less are further included as needed.

The reason why a plurality of resins are mixed and used in the curing resin is that, in the case of urethane acrylate, curing is easy due to good reactivity, flexibility can be maintained after curing, and yellowing is relatively small.

In addition, in the case of epoxy acrylate, it has high reactivity, has good hardness and abrasiveness, is easy to cure, has excellent flexibility, and maintains a cured state stably even in contact with oxygen.

In addition, polyester acrylate has excellent reactivity and lower viscosity than urethane acrylate and epoxy acrylate, so it has excellent dispersibility of powder materials for antibacterial and oxygen generation.

In addition, 10 to 30 parts by weight of a reactive monomer diluent is further mixed with the cured resin to adjust the viscosity of the oligomer resin. Hexyl (meth)acrylate, phenoxyethyl (meth)acrylate, isobornyl (meth)acrylate, acryloylmorpholine, N-vinylpyrrolidone, N-vinylcaprolactam, dimethylaminoethyl (meth)acrylate , tripropylene glycol di (meth) acrylate, cyclopentenyl (meth) acrylate, tricyclodecane dimethanol di (meth) acrylate, one or two kinds from the group consisting of trimethylolpropane tri (meth) acrylate Mix and apply the above.

Rosin, which is mixed with hardened resin, is a non-toxic substance and is a sticky liquid substance that comes out when the bark of a pine tree is cut. It is also called rosin or rosin.

Clean rosin is a colorless and transparent liquid, but becomes cloudy and persistent over time, and white solids from resin acids are precipitated.

Resin is mainly produced in North America, and more than 50% of the world's output is produced, and it is produced in Mexico and France. The collection method is to receive the rosin from the wound on the tree with a cup, etc., and a larger amount of rosin can be obtained by spraying sulfuric acid on the wound.

Rosin is soluble in ethanol, chloroform, acetic acid, etc., but insoluble in water, and rosin remains when turpentine is obtained by distillation.

The components of rosin are 70 to 75% of resin (rosin), 18 to 22% of essential oil (turpentine), and 5 to 7% of water and other impurities, of which rosin acid accounts for 60 to 65% of the total, It consists of maric acid, neoabietic acid, and the like. Turpentine is mainly used as a solvent for ointments, paint solvents, leather retainers, shoe polishes, and rubber or waterproofing agents.

Rosin is mainly used for pharmaceuticals such as soap, paint drying agent, insecticide, printing ink, paper additives, and bandages.

The antibacterial and bactericidal substance or antimicrobial composition may comprise a mixture of cyclosilicates and phyllosilicates; illite; A composition comprising a mixture of silver, zinc and platinum ions is used.

Cyclosilicate and phyllosilicate are mixed in the same weight ratio (wt%), cyclosilicate and phyllosilicate are mixed at 70 wt% to 90 wt%, illite are mixed at 5 wt% to 25 wt%, and the rest It consists of silver, zinc and platinum ions. The antimicrobial composition may further include a composition of various combinations as needed. Preferably, titanium dioxide (titanium dioxide, TiO2) may be further included.

The antimicrobial composition is a composition having inorganic antibacterial, antifungal and deodorant functions, and the composition disclosed in Korean Patent Registration No. 10-1303503 (Title of Invention: Inorganic antibacterial, antifungal and deodorant composition and method for preparing the same) is the antimicrobial composition of this embodiment. , and the critical significance of each component can be verified through examples and comparative examples described in the detailed description of the invention described in the specification of Korean Patent Registration No. 10-1303503.

The oxygen-generating antibacterial sticker composition reacts with carbon dioxide or moisture to generate oxygen, and includes an oxygen-generating compound selected from potassium superoxide (KO ₂ ), sodium peroxide (Na ₂ O ₂ ) or calcium peroxide (CaO 2 ), an antibacterial agent composition, and the like After mixing with the powdery porous inorganic material, apply it to the non-woven fabric layer and dry it before use. Oxygen-generating antibacterial sticker composition has the advantage of continuing to maintain the antibacterial function by the antibacterial agent composition in a state in which oxygen is released.

Potassium superoxide (KO ₂ ) or sodium peroxide (Na ₂ O ₂ ) has a good oxygen generation efficiency, and calcium peroxide (CaO2) has a good amount of oxygen generation, respectively. In the present invention, any one or a mixture of potassium superoxide (KO ₂ ) or sodium peroxide (Na ₂ O ₂ ) may be mixed in a weight ratio of 30% and calcium peroxide (CaO 2 ) may be mixed in a weight ratio of 70%.

If the method of manufacturing the oxygen-generating antibacterial sticker is described with reference to all drawings with reference to FIG. 7 attached, when it is determined that the corresponding command for manufacturing the oxygen-generating antibacterial sticker is applied by the material preparation step (S100), the oxygen generator Control and monitor to prepare or prepare materials for the porous inorganic material, binder, and antimicrobial composition (S110).

At this time, 10 to 30 parts by weight of the porous inorganic material, 1 to 5 parts by weight of the binder, and 2 to 8 parts by weight of the antimicrobial composition are prepared based on 100 parts by weight of the oxygen generator.

Using the material prepared in the material preparation step, the oxygen generating antibacterial composition is mixed (S120), and a protective film, adhesive, release paper, and nonwoven fabric for application, attachment, and coating of the mixed oxygen generating antibacterial composition are prepared in roll units to prepare a manufacturing system Installed in (S130).

An oxygen generating antibacterial composition is applied to the front surface of the prepared nonwoven fabric (S140), dried by staying for at least 1 minute in a hot air environment of 40 degrees Celsius (S150), and then a protective film, adhesive, and release paper are press-coated on the nonwoven fabric (b160 ) Semi-oxygenated non-woven fabric is produced.

The manufactured semi-oxygenated nonwoven fabric is cut into a uniform width in the longitudinal direction, separated from printing in a specific sticker shape, and wound (S170).

8 is a view illustrating antibacterial sterilization and deodorization ability and environmental improvement ability of a nanoparticle-sized photocatalyst according to an embodiment of the present invention, and FIG. is also

On the other hand, when described in detail with reference to all accompanying drawings, it is a drawing for explaining the strong oxidizing power of the photocatalyst. Here, the photocatalyst is described based on titanium dioxide (TiO2), and there may be various materials used as the photocatalyst.

A photocatalyst is a combination of photochemistry and catalyst, and refers to a catalyst that is activated by light energy. In general, a catalyst serves to speed up or slow down a chemical reaction without changing the catalyst itself. In the process of a chemical reaction, heat or other energy sources are used. In the case of a photocatalyst, the energy used in a chemical reaction is use light When the catalyst is irradiated with light energy by sunlight or artificial light, the catalyst that absorbs the light energy becomes active and plays a role in oxidizing or reducing organic matter.

When there is a function of a photocatalyst, it is absolutely necessary to absorb light energy. Titanium oxide or titanium dioxide (TiO 2 ), which is a conventional photocatalyst that is widely used, can absorb ultraviolet light with a wavelength of about 380 nm or less. The photocatalytic reaction of titanium oxide occurs only when ultraviolet light is irradiated, as much as the amount of light of ultraviolet light.

In the description of the present invention, titanium oxide, titanium dioxide, and titanium dioxide have the same meaning and are selectively used according to the context.

Titanium dioxide is widely used as a white pigment, high-frequency condenser material, optical material such as low-reflection coating, sensor, and protective material. there is.

Research on the photoactivity of titanium dioxide, a semiconductor material, began with the Honda-Fujishima effect announced by Professor Fujishima in 1972. When light is irradiated on a battery composed of a titanium dioxide electrode and a platinum electrode, water decomposition occurs at about -0.5V, and oxygen is generated on the surface of the titanium dioxide electrode and hydrogen is generated around the platinum electrode. This is a unique phenomenon that occurs at a potential far below +1.23 V, which is the normal oxidation decomposition potential of water. At this time, it was explained that the oxidation of water occurs by the holes generated to generate hydrogen.

Titanium is the ninth most common mineral on Earth, accounting for 0.6% of the leyline and about 1% of the surface.

Band energy inherent in semiconductor photocatalyst materials - in semiconductor materials, it is a linear combination of atomic orbitals called the conduction band (E cb) that is not filled with electrons and the shared band (Valaence Band, E vb) that is filled with electrons. A set of molecular orbitals exists. Accordingly, there exists a forbidden space between these two bands, which cannot be occupied by electrons. This is called band energy (Eg), and its magnitude corresponds to E cb -E vb. A photochemical system in which electrons (e-) and holes (h+) pairs generated after receiving such light energy and electrons (e-) in E vb are excited (excitation) are beneficially used, is a light that can overcome the limitations of the existing reactor design. enables the transmission of

Converting light energy into chemical energy or electrical energy through the process of photochemical reaction means that the generated electrons/holes are adsorbed on the photocatalyst, reduce/oxidize materials in the diffusion layer, or generate current by the configured electrode circuit. It is possible by creating If this is used, it has the advantage of being used for environmental purification by decomposing surrounding organic substances, as well as water decomposition hydrogen production and solar cells.

That is, the photocatalyst is made of nanoparticle-sized titanium dioxide (TiO2). It is used as a food additive and is harmless to the human body. It is also used to improve environmental pollution.

Since the photocatalyst has a strong oxidizing effect on single-celled organisms such as bacteria, fungi, and viruses, it has a sterilizing power that destroys the cell membrane, and it is explained in the accompanying drawings that it has a sterilizing power that is 1.5 times stronger than that of chlorine or ozone.

OH radicals by photocatalytic activation can sterilize various spoilage bacteria by strong oxidation and have relatively excellent purifying ability to decompose and sterilize substances that cause odor, keeping the surrounding environment clean.

As a result of comparison with OH radicals, ozone, hydrogen peroxide, and chlorine, which are other substances that remove contamination of titanium dioxide (TiO2), which is a photocatalyst, eradicate viruses and bacteria, and oxidize and destroy volatile organic compounds and odorous substances, titanium dioxide (TiO2) It is explained that the oxidizing power of the photocatalyst is superior to the destructive power of H radical, ozone, hydrogen peroxide, and chlorine. In addition, the photocatalyst compared the ability to improve the environment by treating various fungi, bacteria, viruses, house dust mites, toxic substances, odors, smoke, volatile organic compounds, and allergens.

In other words, by comparing the environmental improvement ability of known HEPA filters, dust collection filters, ozone, UV rays, and air purifiers with titanium dioxide (TiO2) photocatalysts, titanium dioxide (TiO2), a photocatalyst, is generally very good in all subjects. It explains very well what it is capable of. Since the photocatalyst is well known, further detailed description thereof will be omitted.

Although the present invention has been described in detail with respect to the specific examples described above, it is obvious to those skilled in the art that various changes and modifications are possible within the scope of the technical idea of the present invention, and it is natural that these changes and modifications fall within the scope of the appended claims.

1000: composition application unit 2000: conveyor unit
3000: drying unit 4000: compression unit
5000: half winding unit 6000: winding unit
7000: slit cutting part 8000: finished winding part

Claims (30)

delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete Composition application unit 1000 for transporting the non-woven fabric 1010 at a uniform speed and applying the oxygen generating antibacterial sticker composition 1020 to a uniform thickness on the surface;
a conveyor unit 2000 for conveying the oxygen-generating antibacterial sticker composition 1020 applied to the non-woven fabric 1010 at a uniform speed;
a drying unit 3000 installed on an upper side of the conveyor unit 2000 to dry the oxygenated nonwoven fabric 1030 with hot air;
a compression unit 4000 for attaching a protective film to the upper side of the oxygenated nonwoven fabric 1030 passing through the drying unit 3000 and attaching an adhesive and a release paper to the lower side;
a semi-finished oxygen nonwoven fabric 5000 that passes through the compression unit 4000 and transports the semi-finished oxygen nonwoven fabric 5010 at a uniform speed and winds it around a semi-finished product winding roll 5020; In the oxygen generating antibacterial sticker manufacturing system comprising a,
An unwinding unit 6000 for unwinding and unwinding the semi-oxygenated nonwoven fabric 5010 wound in the semi-made winding unit 5000 at a uniform speed;
a slit cutting unit 7000 for cutting the semi-oxygenated nonwoven fabric 5010 unwound at a uniform speed from the unwinding unit 6000 into a uniform width along the longitudinal direction;
A sticker mold unit 8000 that separates the semi-oxygenated nonwoven fabric 5010 that has passed through the slit cutting unit 7000 into a sticker shape of a specific size and shape;
A finished winding unit 9000 that winds the semi-oxygenated nonwoven fabric 5010 passing through the sticker mold unit 8000 at a uniform speed; Oxygen generating antibacterial sticker manufacturing system further comprising a.
24. The method of claim 23,
The composition application unit 1000
a fabric roll unit 1040 to which the nonwoven fabric 1010 is wound and fixed in a rotating state;
an unwinding roller 1050 for unwinding the nonwoven fabric 1010 wound around the fabric roll unit 1040 at a uniform speed;
An oxygen generating antibacterial sticker composition 1020 injected into an upper portion of the unwinding roller 1050;
An application knife 1060 for manufacturing an oxygen non-woven fabric 1030 by applying the oxygen generating antibacterial sticker composition 1020 to a uniform thickness on the upper surface of the non-woven fabric 1010; Oxygen-generating antibacterial sticker manufacturing system, characterized in that consisting of a configuration comprising a.
24. The method of claim 23,
The conveyor unit 2000 is
a guide roller 2010 for guiding the transport direction of the oxygen nonwoven fabric 1030;
An endless track belt unit 2020 that transports the oxygenated nonwoven fabric 1030 transported by the guide roller 2010 in one direction;
Transfer pins 2030 that are repeatedly installed on the surface of the belt unit 2020 at uniform widths and intervals to smoothly transport the oxygenated nonwoven fabric 1030; Oxygen-generating antibacterial sticker manufacturing system, characterized in that consisting of a configuration comprising a.
24. The method of claim 23,
The compression unit 4000 is
a protective film roll unit 4020 in which the protective film 4010 attached to the upper surface of the oxygen nonwoven fabric 1030 is wound;
An adhesive release film roll unit 4040 wound with an adhesive release film 4030 for sequentially and simultaneously attaching an adhesive and a release paper to the lower surface of the oxygen nonwoven fabric 1030;
an upper pressure roller 4050 installed on the upper surface of the oxygen nonwoven fabric 1030 and pressing and bonding the protective film 4010 to the upper surface of the oxygen nonwoven fabric 1030;
a lower pressure roller 4060 installed on the lower surface of the oxygen nonwoven fabric 1030 and bonding the adhesive release film 4030 to the lower surface of the oxygen nonwoven fabric 1030 by pressing it; including,
The adhesive release film 4030 is oxygen-generating antibacterial sticker manufacturing system, characterized in that consisting of a configuration consisting of sequentially and simultaneously attaching an adhesive, Velcro, and a release paper that protects the surface of the Velcro to the lower surface of the oxygen nonwoven fabric 1030. System.
24. The method of claim 23,
The slit cutting part 7000
a width cutting blade 7010 that receives the semi-oxygenated nonwoven fabric 5010 at a uniform speed and cuts the semi-oxygenated nonwoven fabric 5010 to a uniform width on the upper surface of the semi-oxygenated nonwoven fabric 5010 along the longitudinal direction;
a cutting pressure roller 7020 installed on the lower side of the width cutting blade 7010 to pressurize the semi-oxygenated nonwoven fabric 5010 to be smoothly cut; Oxygen-generating antibacterial sticker manufacturing system, characterized in that consisting of a configuration comprising a.
24. The method of claim 23,
The sticker mold unit 8000
a cutting mold means 8010 for receiving the semi-oxygenated nonwoven fabric 5010 at a uniform speed, printing a specific pattern while moving in a vertical direction, and cutting the semi-oxygenated nonwoven fabric 5010 to be separated into stickers of a specific shape;
a mold supporting part 8020 installed on the lower side of the cutting mold means 8010 to support smooth printing and cutting; Oxygen-generating antibacterial sticker manufacturing system, characterized in that consisting of a configuration comprising a.
A material preparation step of preparing materials for an oxygen generator, a porous inorganic material, a binder, and an antimicrobial composition;
A composition preparation step of mixing an oxygen generating antibacterial composition using the material prepared in the material preparation step;
A roll installation step of preparing a protective film, an adhesive, a release paper, and a nonwoven fabric for application, attachment, and coating of the oxygen generating antibacterial composition in roll units and installing them in a manufacturing system;
A semi-finished coating step of applying an oxygen-generating antibacterial composition to the non-woven fabric, drying it, and then press-coating a protective film, an adhesive, and a release paper to produce a semi-oxygen non-woven fabric;
A finished winding step of cutting the semi-oxygenated nonwoven fabric produced in the semi-finished coating step into a uniform width in the longitudinal direction, separating it from printing into a specific sticker shape, and winding it up; Oxygen-generating antibacterial sticker manufacturing method comprising a.
The method of claim 29,
The drying is dried by staying for 1 minute or more in an environment in which air of 40 degrees Celsius or higher is forced convection,
In the material preparation step, 10 to 30 parts by weight of a porous inorganic material, 1 to 5 parts by weight of a binder, and 2 to 8 parts by weight of an antimicrobial composition are prepared based on 100 parts by weight of the oxygen generating agent. method.

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