KR100439842B1 - Method for manufacturing farinfrared ray emitting fiber products - Google Patents

Abstract

The present invention relates to a method for manufacturing a far-infrared radioactive fiber product, the method comprising: irradiating a fiber product with visible light having a wavelength of 525-550 nm, irradiating the fiber product with an infrared ray having a wavelength of 3,000-15,000 nm, and It consists of the step of irradiating the fiber product body by vortexing the infrared ray with a wavelength of 1,045 ~ 1,155nm with an infrared band screw, according to the present invention, the fiber product irradiated with visible light and infrared rays effectively emits far infrared rays for a long time.

Description

Method for manufacturing far-infrared radioactive fiber products {Method for manufacturing farinfrared ray emitting fiber products}

The present invention relates to the production of far-infrared radioactive fiber products, and more particularly, to a method for manufacturing a far-infrared radioactive fiber product by applying a specially designed optical energy to the fiber product so that the fiber product exhibits far-infrared radiation characteristics for a long time.

Conventionally, in order to impart far-infrared radiation characteristics to textile products such as socks, gloves, underwear, bedding, etc., minerals such as loess, elvan, mica, javasite, feldspar, silica, kaolin and those with far-infrared radiation characteristics are contained. A method of coating or impregnating an object with a far infrared radioactive composition has been used.

However, this method is not only complicated to impart far-infrared radiation characteristics to the target product, it is not only high in production cost, but also insignificant in radioactivity at room temperature, the far-infrared radiation coating damages the feel and appearance of the fiber, and the far-infrared radiation coating is easily peeled off. There is a disadvantage in that there are many restrictions to the application.

Accordingly, an object of the present invention is to provide a method capable of imparting efficient far-infrared radiation characteristics to a textile product by a simpler method.

In order to solve the above problems, the present inventors have completed the present invention by discovering the surprising fact that treated fiber products emit far-infrared radiation for a long time when irradiated with visible and infrared rays specially designed for textile products. .

1 is an apparatus diagram schematically showing a preferred example of a system for producing a far infrared radioactive fiber product according to the present invention;

Figure 2 is a view showing a planar arrangement of the visible light irradiation member in the visible light irradiation apparatus in the apparatus of Figure 1,

3 shows a planar arrangement of the first and second infrared irradiation members in the infrared irradiation device in the apparatus of FIG. 1;

4 is a schematic longitudinal sectional view of the visible light irradiation member in the apparatus of FIG. 1;

5 is a schematic longitudinal cross-sectional view of a second infrared irradiation member in the apparatus of FIG. 1;

6 is a schematic longitudinal sectional view of the first infrared irradiation member in the apparatus of FIG. 1;

* Brief description of symbols for the main parts of the drawings *

A: visible light irradiation device

B: infrared irradiation device

C: feeder

1: visible light irradiation member

2: mounting member of the visible light irradiation member

3: first infrared irradiation member

4: second infrared irradiation member

5: mounting member of the infrared irradiation member

11: light source

12: visible filter

13: dimming cap

31: light source

32: infrared filter

33: dimming cap

41a, 41b, 41c: light source

42a, 42b, 42c: Infrared filter

43: infrared band screw

44: dimming cap

Therefore, according to the present invention, in the method for producing a far-infrared radioactive fiber product, the fiber product has a wavelength of 1,045-1,155 nm which is vortexed with visible light having a wavelength of 525-550 nm, infrared rays having a wavelength of 3,000-15,000 nm, and an infrared screw. Provided is a method for producing a far-infrared radioactive fiber product, characterized by irradiating infrared light sequentially.

Hereinafter, the present invention will be described in more detail.

As used herein, terms such as a visible filter, an infrared filter, an infrared screw, and the like are used in the literature. [Reference: Korean, English, Japanese Electrical and Electronic Glossary, Ph.D. Mogiakira, Ph.D., Edited by Daeguk Bookstore, Published May 10, 2000, p105, p1117].

According to the present invention, a method for producing a far-infrared radioactive material includes irradiating visible light having a wavelength of 525 to 550 nm to a fibrous product (step I), irradiating infrared light having a wavelength of 3,000 to 15,000 nm (step II), and a wavelength of 1,045 to It mainly consists of vortexing infrared rays of 1,155 nm with infrared screws and focusing and irradiating them (step III).

Preferably. In the visible light irradiation step (I), irradiated visible light having a wavelength of 525 to 550 nm obtained by adjusting the wavelength with the color of the visible filter and controlling the energy density as the luminance. This is a result of the experiment. When the fiber product is irradiated with visible light before being irradiated with vortex infrared rays, the vibration state and energy transition of the material molecules constituting the fiber product are effectively changed by subsequent vortex infrared irradiation. This is because the far infrared emission effect of the product is maximized.

Preferably, in step II, the fiber product is irradiated without vortexing infrared rays having a wavelength of 3,000-15,000 nm obtained by filtering light with an infrared filter. As a result of the experiment, it was found that the fiber products undergoing the steps I, II, and III have higher far-infrared emission effects than the fiber products undergoing the steps I and III. It is presumed that this is because the infrared rays of step II remove the factors that interfere with changing the energy.

Preferably, in step III, single or synthetic infrared rays having a wavelength of 1,045 to 1,155 nm are vortexed and irradiated. Synthetic infrared rays can be obtained by passing two or more infrared rays belonging to a wavelength range of 1,045-1,155 nm through an infrared region screw.

If the infrared radiation of the wavelength band is not limited to the infrared rays, the infrared emission effect of the irradiated object is inferior, which is considered to be due to the mutual interference caused by the overlapping when the infrared ray is used in the wide wavelength range.

Infrared vortex is achieved by infrared band screw. Infrared screws are well-known in the field of optics, and are usually composed of motors and ball screws. Infrared screws twist and vortex the infrared rays passing through them. The infrared rays twisted by the infrared region screw are absorbed by the irradiated object to effectively change the vibration state and energy transition of the irradiated material molecules to maximize the far-infrared emission effect of the irradiated object.

Infrared is an electromagnetic wave whose wavelength band is usually in the range of 760 nm to 1,000,000 nm, longer than visible light and shorter than microwaves. The division of infrared rays by wavelength band is defined variously according to the person using the infrared rays. For example, 760-4,000nm is classified as near infrared, 4,000-400,000nm is classified as far infrared, near infrared 740-1,400nm, mid-infrared 1,400-3,000nm, far infrared 3,000-1,000,000nm, and near infrared 750-1,500nm, It is classified as mid-infrared 1,500-15,000nm, far-infrared 15,000-1,000,000nm, and also classified as near-infrared 750-3,000nm, mid-infrared 3,000-6,000nm, far-infrared 6,000-15,000nm, and ultra-infrared 15,000-1,000,000nm.

According to the present invention, the irradiated subject irradiated with vortex infrared rays in step III emits infrared rays for a certain period of time, which means that the vibration state of the irradiated substance molecules is changed and the energy of the irradiated substance molecules is changed by the vortex infrared rays. It is assumed that this is because the transition.

Hereinafter, an example of an apparatus for implementing the present method as described above will be described with reference to the drawings.

The apparatus for manufacturing far-infrared radioactive fiber products illustrated in FIGS. 1 to 6 includes a visible light irradiation device A for irradiating visible light to a textile product, and an infrared irradiation device for irradiating infrared rays to a fiber product irradiated with visible light ( B) and the fiber product conveyance means (C) provided in the fiber product conveyance passage (S1) of the visible light irradiation device (A) and the fiber product conveyance passage (S2) of the infrared irradiation device (B), The operation of these devices A, B and C is controlled by the control box. Although not shown, it is preferable that the irradiation apparatuses (A) and (B) be provided with an object detecting sensor to detect when the textile product is located in the light irradiation area of the moving passage and to design the irradiation apparatus to start light irradiation. Device design is a common technique that is well known in the art.

As shown in Fig. 1 and 2, the visible light irradiation device (A) is a mounting member having a plurality of visible light irradiation member (1), the member (1) is installed and the transport passage (S1) of the textile product is formed 1 and 3, the infrared irradiation device B includes a plurality of first infrared irradiation members 3, a plurality of second infrared irradiation members 4, and the members. Fields 3 and 4 are installed, and is composed of a mounting member 5 formed with a conveying passage (S2) of the textile product.

As shown in FIG. 4, the light source 11 and the visible filter 12 are sequentially disposed in the dimming cap 13 having a cylindrical body and having a funnel-shaped flange portion at the bottom thereof. . When the light source 11 is turned on by the electrical operation, the visible light irradiation member 1 has a visible region filter 12 that adjusts the wavelength to the color located downstream and controls the energy density as the luminance. Filters visible light in a predetermined wavelength range from the emitted light and focuses the filtered visible light on the dimming cap 13 to irradiate visible light to the fiber products conveyed to the conveying path S1 by the conveying device C. Do it.

As shown in FIG. 5, the light source 31 and the infrared filter 32 are sequentially disposed in the dimming cap 33 in the first infrared irradiation member 3. When the light source 31 is turned on by the electrical operation, the first infrared ray irradiation member 3 filters the infrared rays of a predetermined wavelength band from the light emitted from the light source 31 downstream of the infrared filter 32. The infrared rays are focused on the dimming cap 33 and serve to irradiate the filtered infrared rays to the fiber products conveyed to the conveying passage S2 by the conveying device C.

3 and 6, the second infrared irradiation member 4 includes three light sources 41a, 41b, 41c in the dimming cap 44, and three infrared rays for filtering infrared rays of different wavelength bands. Filters 42a, 42b and 42c and one infrared screw 43 are sequentially arranged. The light sources and infrared filters here are arranged one each in three cylindrical housings. The second infrared irradiation member 4 shown is for synthesizing and irradiating infrared rays of different wavelength bands. When the light sources 41a, 41b, 41c are turned on by electric operation, they correspond to the respective light sources downstream of the second infrared irradiation member 4. Infrared filters 42a, 42b and 43c filter infrared rays of a predetermined wavelength from light emitted from light sources 41a, 41b and 41c, and the infrared rays of the different filtered bands are infrared screw 43 While passing through the synthetic and at the same time vortex is generated and concentrated in the dimming cap 44 is irradiated to the fiber products transported in the conveying passage (S2) by the conveying device (C). By operating only one of the light sources 41a, 41b, 41c in the second infrared irradiation member 4, a single infrared ray can be obtained, and by operating any two of these light sources, a composite infrared ray that becomes two infrared rays can be obtained. By operating all of the light sources, you can get synthetic infrared rays that are three infrared rays.

Although not shown, the visible light irradiating member 1, the first infrared irradiating member 3, and the second infrared irradiating member 4 each emit light emitted from the surface, side, bottom, or two or more of them. It may be arranged to irradiate the light, which is in consideration of the type, size, etc. of the textile product, the shape of the installation member (2, 5) and the visible light irradiation member (1), the first infrared irradiation member (3) and the second infrared ray This can be achieved by changing the installation position or the form of the irradiation member 4. In addition, the number of installations of the visible light irradiation member 1, the first infrared irradiation member 3, and the second infrared irradiation member 4, or the number of installation of the visible light irradiation device A and the infrared irradiation device B are textile products. It can be changed in consideration of the type, size, etc., and the transfer device (C) can also be variously changed to suit this.

Features and other advantages of the present invention as described above will become more apparent from the following examples. However, the present invention is not limited to the following examples.

Example 1

In the apparatus of FIG. 1, the socks were infrared treated after visible light irradiation. At this time, visible light was filtered to irradiate the socks with 530 nm, and the vortex infrared light focused on one of the light sources 31a, 31b, and 31c, and then passed 1,100 nm of infrared light obtained by filtering through an infrared screw. The socks were examined. Far-infrared emissivity was measured before and after treatment (initial and three months later) of the treated socks. The measurement results are shown in Table 1. Emissivity measurement results are shown as the average value after 10 experiments.

Example 2

The same procedure as in Example 1 was repeated except that golf gloves were used instead of socks. The measurement results are shown in Table 1.

division Textile products Visible light (nm) Synthetic Infrared (nm) Far-Infrared Radiation (Unit: None) Before investigation After investigation Early After 3 months Example 1 Amount - say 530 1100 0.78 0.99 0.99 Example 2 Gloves 530 1100 0.79 0.99 0.98

As will be apparent from the above experimental results, according to the present invention, it is possible to produce a fiber product which effectively emits far infrared rays for a long time by irradiating visible light and infrared rays specially designed.

Claims (2)

A method for producing a far-infrared radioactive fiber product, wherein the fiber product is sequentially irradiated with visible light having a wavelength of 525 to 550 nm, infrared rays having a wavelength of 3,000 to 15,000 nm, and infrared rays having a wavelength of 1,045 to 1,155 nm which is vortexed with an infrared band screw. A method for producing a far-infrared radioactive fiber product, characterized in that. The method of claim 1, wherein the visible light is a visible light obtained by adjusting the wavelength of the light to the color by the visible filter and the energy density as a luminance, the infrared light is a single infrared light obtained by filtering the light with an infrared filter or A method for producing a far infrared radioactive fiber product, characterized in that it is a synthetic infrared ray.