KR102112672B1 - Dustproof screen with enhanced durability for nano fiber layer - Google Patents

Abstract

The present invention relates to a dustproof screen with enhanced durability of a nanofiber layer. More specifically, the present invention provides a dustproof screen with enhanced durability of a nanofiber layer, in which a dustproof screen body is knitted to be intertwined with a support net, the nanofiber layer is spun to be intruded into the dustproof screen body at each mesh of the dustproof screen body where the dustproof screen body has meshes relatively greater than those of the support net, and durability of the nanofiber layer remarkably increases as a protection net is adhered to the dustproof screen body. To achieve the purpose, the present invention provides the dustproof screen with enhanced durability of the nanofiber layer, comprising: the support net (10); the dustproof screen body (20) forming pores therein while being knitted to be integrated with the support net (10); the nanofiber layer (30) formed to be integrated with each of meshes of the dustproof screen body (20) while nanofiber is intruded into the dustproof screen body (20) by melt-spinning; and the protection net (40) adhered to the dustproof screen body (20). The present invention provides the dustproof screen, in which the dustproof screen body is knitted to be supported by a support screen body, the dustproof screen body made by twisting multiple strands has pores therein, and the nanofiber layer is spun to be formed at each of meshes of the dustproof screen body as being intruded into the internal pores and at the same time being connected to each other, thereby enhancing the durability of the nanofiber layer while causing no damage to the nanofiber layer even if applied is external shock like wrinkling, rubbing, shaking and dusting the dustproof screen body.

Description

Dustproof net with enhanced durability of nanofiber layer {DUSTPROOF SCREEN WITH ENHANCED DURABILITY FOR NANO FIBER LAYER}

The present invention relates to an anti-vibration network having enhanced durability of a nanofiber layer, and more specifically, an anti-vibration mesh is knitted on a support net, and the nanofiber layer is radiated to penetrate the inside of the anti-vibration mesh for each body of the anti-vibration mesh. It relates to an anti-vibration network having enhanced durability of the nanofiber layer, which is configured to significantly increase the durability of the nanofiber layer as the protective net is adhered.

In general, screen products in the form of a mesh are fixed to a window frame or a roll screen type of various materials to prevent pests such as insects. However, there has been a disadvantage that micro dust, which is a serious environmental problem in recent years, cannot be prevented.

In recent years, dust-proof nets developed to block fine dust are manufactured by adding a non-woven fabric such as melt-blown to a mesh product, but it is difficult to block ultra-fine dust, and there is a problem in that transparency cannot be seen at all due to poor transparency.

And, instead of a non-woven fabric, a nano-fiber layer has been developed to block the ultra-fine dust and secure transparency by applying a nano-fiber layer with high light transmittance on the mesh. When produced through spinning and applied on a mesh, there is a technical problem in that durability is remarkably deteriorated and the filter function cannot be maintained while not being adhered to the mesh because it has no adhesive property.

In particular, since nanofibers are physically very low in strength, they are easily damaged by external impact or friction, and there is a problem of durability in which the performance of a dustproof network is deteriorated, and thin mesh nanofibers are used to solve the durability problems of these nanofibers. Although the above laminating technology was developed, this also has a problem of increasing the manufacturing cost while increasing the thickness and weight of the dust-proof net, as well as the possibility of damage to the nanofibers during the lamination process of the mesh and nanofibers.

In the following patent document 4, by forming nano-sized dust-proof nets by radiating nanofibers on the existing screens, and firmly fixing them on the surface of the screens, it has not only the function of insect repellent, but also the function of blocking fine dust, but is also breathable and liquid. A nano-vibration screen that can be used as a filter window for a window having excellent function of preventing moisture from entering the water, that is, rainwater, is described.

However, the nano-vibration screen is configured to protect the nanofibers by thermally bonding the nano-sized anti-vibration network between the insect screen and the insect screen using a hot felt resin, but this is also fine as the insect screen and the nanofiber are easily separated by external impact or the like. There are structural problems such as loss of the dust blocking function.

Registered Patent Publication No. 10-1936571 (Dustproof net using nanofiber filter) Patent Publication No. 10-2004-0081398 (Dustproof network using photocatalyst) Registered Patent Publication No. 10-1829175 (Method for manufacturing air-circulating fine dust dust-proof mesh using nanofibers) Published Patent Publication No. 10-2019-0020498 (Nano-vibration screen for blocking ultra fine dust and its manufacturing method)

The present invention has been devised to improve the above-mentioned problems of the prior art, and a nanofiber layer is provided inside the anti-vibration net for each body of the anti-vibration net that is knitted so that the anti-vibration nets are interwoven with each other and has a relatively large body net than the support net. It is intended to provide an anti-vibration network with enhanced durability of the nanofiber layer, which is formed to be radiated to penetrate into the membrane, and is configured to significantly increase the durability of the nanofiber layer while the protective net is adhered to the anti-vibration net.

In order to achieve the object of the present invention, the present invention is a support net; An anti-vibration mesh that is knitted to form an integral part with the support net and forms a void therein; A nanofiber layer integrally formed with each body of the dustproof mesh as the nanofibers penetrate into the dustproof mesh by melt spinning; It provides a dust-proof net having improved durability of the nanofiber layer, characterized in that consisting of; a protective net bonded to the dust-proof body.

The present invention constituted as described above is knitted so that the anti-vibration mesh is supported by the support mesh, and the anti-vibration mesh made by twisting several strands is formed with a void therein, and the nanofiber layer penetrates into the internal air gap of the anti-vibration mesh so that they are connected to each other. As it is radiated, it is created for each body of the anti-vibration mesh and provides a practical effect to enhance the durability of the nano-fiber layer, such as not damaging the nano-fiber layer even if the anti-vibration mesh is crumpled or rubbed or shaken to give an external shock.

1 is a photomicrograph illustrating a state in which the anti-vibration mesh is knitted on the support mesh in the anti-vibration network having enhanced durability of the nanofiber layer according to the present invention;
Figure 2 is a photomicrograph illustrating the state in which the nanofiber layer is formed on each eye of the anti-vibration mesh in the anti-vibration network having enhanced durability of the nanofiber layer according to the present invention
3 is a photomicrograph illustrating a state in which a protective net is attached to a dustproof body in a dustproof network having enhanced durability of a nanofiber layer according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

According to an embodiment of the present invention, as shown in FIGS. 1 to 3, the support net 10, the anti-vibration mesh body 20 integrally knitted with the support net 10, and the anti-vibration mesh body 20 ) Is composed of a nanofiber layer 30 formed to be interwoven with each body of the eye, and a protective net 40 adhered to the anti-vibration body 20.

At this time, the anti-vibration mesh 20 according to the present invention is integrally coupled to the support net while being knitted to be woven into the support net 10 as shown in FIG. 1, and a plurality of strands (threads) are loosely twisted It is configured to form voids therein while forming a rope structure.

In particular, the mesh of each body formed while the anti-vibration mesh 20 according to the present invention is knitted on the support net 10 has a size of 81 to 1,089, and 4 to 7 of the mesh mesh of the support net 10. It is configured to have a ship size.

Here, if the mesh of each body in the anti-vibration mesh 20 is less than 81, the size of the body is too large, which may cause the durability of the nanofiber layer 30 to be weakened, and the mesh of each body is 1,089 If it exceeds, the size of the body is too small, leading to structural problems that can deteriorate breathability.

In addition, the nanofiber layer 30 is formed for each body of the anti-vibration mesh 20 by nano-melting spinning, as shown in FIG. 2, in general, nano-melting spinning is polyimide, nylon, polyaramid, poly benziimidazole , Polyetherimide, polyacrylonitrile, polyaniline, polyethylene oxide, piene (polyethylene naphthalate), polystyrene, fib (polyvinyl chloride), polyvinyl alcohol, fibdif (polyvinylidene fluoride), Thermoplastic synthetic fibers such as polyvinylbutylene, PLA (poly L-lactic acid), and PGA (propylene glycol alginate) are extruded in a liquid at a high pressure and high velocity in the air through a spinning nozzle to form a nano-diameter fiber layer. It is known as the spinning method.

At this time, the nanofiber layer 30 according to the present invention, when the liquid thermoplastic synthetic fiber is spun at a high temperature and high pressure through a spinning nozzle, while penetrating or penetrating the dustproof mesh body 20 with a void formed therein while forming a loose fiber rope structure While forming the nanofibers, the nanofibers are configured to be cooled by penetrating the anti-vibration body and being connected to each other or penetrated into the anti-vibration body.

As a result, the nanofiber layer 30 according to the present invention is enlarged in FIG. 2 and as can be seen by looking at FIG. 2, the nanofibers are formed in each body of the anti-vibration mesh while being connected to each other through the anti-vibration mesh 20 or penetrated into the anti-vibration mesh. It is configured to block fine dust and the like.

Here, the nanofiber layer 30 according to the present invention is configured so that the anti-vibration mesh 20 acts as a fixing frame for fixing the nanofibers, its physical durability is significantly increased, and folded or rubbed to remove the adhered fine dust or the like. It ensures mechanical durability that does not cause any damage even when brushing with force.

On the other hand, the protection net 40 according to the present invention is configured to protrude from the anti-vibration mesh while being adhered to the anti-vibration mesh 20 as shown in FIG. 3, while the shape of the body is hexagonal, the size of the mesh is anti-vibration mesh It is configured to be formed in a size of 1/4 to 1/2 of the size of the body of (20).

At this time, the protection net 40 according to the present invention not only acts to support the anti-vibration body 20, but also acts to block the damage caused by the nanofiber layer 30 in contact with the outside.

In short, the nanofiber layer having improved durability of the nanofiber layer according to the present invention penetrates or penetrates the nanofiber through the dustproof mesh body 20 by melt spinning in order to significantly increase the durability of the nanofiber layer 30 blocking fine dust and the like. In the state, the nanofiber layer 30 is formed integrally within each eye of the anti-vibration mesh 20, and furthermore, the anti-vibration mesh is knitted to be knitted integrally with the support net 10 while being adhered to the protection net 40 to the anti-vibration mesh. While supporting the anti-vibration body 20, the technical features will be configured to ultimately protect the nanofiber layer 30.

As described above, although specific embodiments have been described in the detailed description of the present invention, various modifications are possible without departing from the scope of the present invention.

Therefore, the practical scope of the present invention should not be limited by the above-described embodiment, it is natural that it should be determined not only by the claims to be described later, but also by the equivalent configuration with the claims.

10: support net 20: anti-vibration mesh 30: nanofiber layer 40: protective net

Claims (2)

A support net 10;
A dustproof mesh body (20) forming a void therein while being knitted to be integral with the support net (10);
A nanofiber layer 30 integrally formed with each body of the dustproof mesh body 20 as nanofibers penetrate into the dustproof mesh body 20 by melt spinning;
A protective net 40 adhered to the anti-vibration body 20;
It characterized in that the nano-fiber layer has improved durability of the dustproof net. The method according to claim 1,
The anti-vibration network 20 is a dust-proof network having enhanced durability of the nanofiber layer, characterized in that each body is configured to have a mesh of 81 to 1,089.

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