KR100713616B1 - Method for producing far-infrared ray emitting cement-base product curied body - Google Patents

Abstract

The present invention relates to a method for manufacturing a cement mortar curing product and a cement mortar secondary product curing product that emits far-infrared rays. Irradiating visible light to the cement mortar, cement mortar component, or cement secondary component material, and (II) filtering the light with an infrared filter to obtain infrared rays of a specific wavelength, Swirling with an external screw and concentrating and irradiating the cement mortar, cement mortar component, or cement secondary product component subjected to visible light irradiation in step I, and (III) the cement mortar treated as described above. On the walls of the building or by curing the secondary products using cement secondary product components Since far infrared rays are directly emitted from cotton, wall or cement secondary products for a long time, it can be expected not only to improve the health function but also to remove cement toxicity. Furthermore, deodorizing effect, anti-mildew effect, and In addition to the antimicrobial effect, it is possible to obtain an improved effect on heat and heat storage.

Description

Method for producing far-infrared ray emitting cement-base product curied body

Figure 1a is a flow diagram illustrating one embodiment of a method for producing a cement mortar curing body that emits far infrared rays in accordance with the present invention.

FIG. 1B is a flow chart showing another embodiment distinguished from the embodiment according to FIG. 1A.

FIG. 2A is a flow diagram illustrating one embodiment of a method of treating one or more components of a cement constituent to produce a cement mortar curing body that emits far infrared rays in accordance with the present invention. FIG.

2b is a flow chart showing another embodiment which is distinguished from the embodiment according to FIG. 2a;

3A is a flow diagram illustrating one embodiment of a method of treating one or more of the components of a cement secondary product to produce a cement secondary product curing body that emits far infrared rays in accordance with the present invention.

3b is a flow chart showing another embodiment which is distinguished from the embodiment according to FIG. 3a;

4A is a schematic diagram of a preferred example of an apparatus used to produce cement mortar in accordance with the present invention.

Figure 4b is a schematic diagram of a preferred embodiment of the apparatus for treating the cement mortar curing agent, the cement admixture used to prepare the cement secondary product curing product that emits far infrared rays according to the present invention.

5 shows a planar arrangement of the visible light irradiation member in the visible light irradiation apparatus in the apparatus of FIGS. 4a and 4b.

6 shows a planar arrangement of the first and second infrared irradiation members in the infrared irradiation device in the apparatus of FIGS. 4A and 4B.

7 is a schematic longitudinal cross-sectional view of the visible light irradiation member in the apparatus of FIGS. 4A and 4B.

8 is a schematic longitudinal cross-sectional view of a second infrared irradiation member in the apparatus of FIGS. 4A and 4B.

9 is a schematic longitudinal cross-sectional view of the first infrared irradiation member in the apparatus of FIGS. 4A and 4B.

Fig. 10 is a schematic longitudinal sectional view illustrating another form of the first infrared irradiation member.

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

A: visible light irradiation device B: infrared light irradiation device

Con: Conveyor M: Maltar

W, C, S: water, cement, sand TC: transparent container

CA: Cement Admixture 1: Visible Light Irradiation Member

2: mounting member of visible light irradiation member 3: first infrared irradiation member

4: second infrared irradiation member 5: mounting member of infrared irradiation member

11: light source 12: visible filter

13: Illumination cap 31, 31a, 31b, 31c: light source

32, 32a, 32b, 32c: infrared filter 33: infrared screw

34: dimming cap 41: light source

42: infrared filter 43: light control cap

100, 200, 300: stage I (visible light irradiation stage)

110, 210, 310: step I-a (irradiating irradiated with arsenic)

120, 120a, 220, 220a, 320, 320a: Phase II (infrared vortex irradiation)

330: step III (step of mixing the cement secondary product constituents with the remaining cement secondary product constituents to form a cement secondary product constituent mixture)

340: Step IV (forming and curing the cement secondary product component material mixture to form a cement secondary product curing body)

The present invention relates to the production of far-infrared radiation cement products, and more specifically, to the cement mortar curing material that emits far-infrared radiation by applying specifically designed light energy to cement mortar, cement mortar component material, or cement secondary product component material. Or a method of manufacturing a cement secondary product such as a brick, ready-mix concrete or concrete pipe product, and a method of using a cement admixture to produce a cement mortar or cement secondary product that emits far infrared rays. will be.

Far-infrared rays are known to have effects on the human body: heat action (temperature regulation), maturation (growth promotion), oily action (calcium absorption rate strengthening), body temperature maintenance, neutralization (body waste removal), resonance (Balance of nutrition).

Existing far-infrared radiation products are mainly made to emit far-infrared rays by containing minerals such as ocher, elvan, mica, javasite, feldspar, quartzite and kaolin which have far-infrared radiation characteristics. In addition, in order to allow the cement mortar to emit far-infrared rays, a method is known in which ceramic raw materials such as elvan are mixed with cement and applied to a wall. In addition, in the case of constituting a cement secondary product containing cement, such as brick, ready-mixed concrete, concrete pipe products, it can be said that it is common to mix ceramic raw materials with cement first.

However, such a conventional method has not only complicated the process of imparting far-infrared radiation characteristics to a target product itself, but also has a problem of having to use a ceramic material which is expensive due to limited resources and limited product application. The limits have been shown.

Therefore, in order to solve the above problems, the present invention provides a simpler method to prepare cement mortar or cement secondary products that can emit far-infrared rays in comparison with the method of directly using a ceramic raw material such as elvan. And to provide a cement admixture used for this is a technical problem.

In order to solve the above problems, the amount of cement mortar treated by irradiating visible and infrared rays specially designed according to the present invention with respect to all cement mortars prepared in general, including processed or unprocessed cement and stone components The present invention provides a very simple method for causing a living body to emit far infrared rays.

In addition, the present invention is a cement mortar curing material formed by mixing these materials after irradiating visible and infrared rays specially designed according to the present invention to any one or more of the material constituting the cement mortar, water, sand, cement It provides a method for emitting far infrared rays.

In addition, the present invention is a cement 2 formed by mixing these materials after irradiating visible and infrared rays specially designed according to the present invention to any one or more constituent materials of water and cement, which are the most basic materials constituting the cement secondary products, and then molding them. It provides a method for causing a tea product to emit far infrared rays.

Furthermore, the present invention is a cement admixture added to the material constituting the cement mortar or cement secondary product, the visible light and infrared rays specifically designed in accordance with the present invention so that the cement mortar or cement secondary product emits far infrared rays. A method of using a cement admixture to be treated by irradiation is provided.

According to the present invention, in the method for producing a cement mortar curing body that emits far infrared rays, (I) the visible light obtained by adjusting the wavelength to the color by means of a visible filter and controlling the energy density as the brightness of cement mortar (II) filtering the light with an infrared filter to obtain infrared light in a specific wavelength band, vortexing the infrared light with an infrared light screw, and converging the infrared light onto the cement mortar irradiated with visible light in step I. It provides a method for producing a far-infrared cement mortar curing comprising the step of irradiating, and (III) curing the cement mortar to form a cement mortar curing body.

In addition, according to the present invention, in the method for producing a cement mortar curing body that emits far infrared rays, (I) the visible light obtained by adjusting the wavelength to the color by the visible band filter and controlling the energy density as the luminance, Irradiating at least one component of water, sand, or cement, which is a material constituting the cement mortar, (II) filtering light with an infrared filter to obtain infrared rays of a specific wavelength, and swirling the infrared light with an infrared screw. And then focusing and irradiating the cement mortar constituent material subjected to visible light irradiation in the step I, (III) mixing the cement mortar constituent material and the remaining cement mortar constituent material which have undergone the step II to form cement mortar. And (IV) curing the cement mortar to form a cement mortar curing body. The cement mortar both in vivo method of producing the far-infrared emitting, it characterized in that there is provided.

And according to the present invention, in the method for producing a cement secondary product curing body that emits far-infrared rays, (I) visible light obtained by adjusting the wavelength to the color by the visible filter and controlling the energy density as the luminance Irradiating to the constituent material of at least one of water and cement, which are the materials constituting the cement secondary product, (II) filtering the light with an infrared filter to obtain infrared light in a specific wavelength band, and converting the infrared light into the infrared screw. Vortexing and concentrating, irradiating the cement secondary product constituent material subjected to visible light irradiation in the step I, (III) the cement secondary product constituent material and the remaining cement secondary product composition Mixing the materials to form a cement secondary product constituent mixture, and (IV) molding and curing the cement secondary product constituent mixture There is also provided a method for producing a cement secondary product curing material that emits far-infrared rays comprising the step of forming a cement secondary product curing product.

In addition, the present invention is a cement admixture (for example, AE agent, water reducing agent, AE water reducing agent, high performance water reducing agent, fluidizing agent, super-delay agent, water-based concrete admixture, shrinkage added to the constituent materials constituting the cement mortar or cement secondary products Reducing agent or the like), the visible light obtained by adjusting the wavelength to the color by the visible band filter and the energy density as the luminance is irradiated to the cement admixture, and the specific wavelength band obtained by filtering the light with the infrared band filter. It provides a cement admixture, characterized in that the vortex infrared rays obtained by vortexing infrared rays with infrared rays and then focusing are irradiated to the cement admixture.

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

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.

In the present specification, the term cement mortar refers to a cement, including various special cements as well as general cements such as portland cement, and a predetermined fluidity before mixing and sand and water are mixed at a ratio suitable for use. In the case of cement secondary products, cement secondary water other than cement mortar containing sand is referred to collectively including cement and water as basic constituent materials.

According to the present invention, a method for preparing a cement mortar curing body that emits far infrared rays includes step I (100), which is a step of irradiating filtered visible light to cement mortar, as shown in FIG. Step II (120), which is a step of irradiating infrared rays (infrared vortex), and step III (130) of curing cement mortar to form a cement mortar curing body.

Preferably, in the visible light irradiation step of the step I (100), the visible light obtained by adjusting the wavelength to the color by the visible filter and the energy density as the brightness is irradiated to the cement mortar. As a result of the experiment, when the cement mortar is irradiated with visible light before the vortex infrared radiation is irradiated, the vibration state and the energy transition of the cement mortar material molecules are effectively changed in the subsequent vortex infrared radiation, resulting in cement mortar curing This is because the far-infrared emission effect of is maximized.

The visible light irradiated in the step I (100) is appropriate that the wavelength range of 360 ~ 760nm. In particular, the visible light of the wavelength range 580-590 nm is especially effective among the visible light of the said wavelength range.

In step II 120, the infrared rays in the wavelength range of 760 to 1,000,000 nm are vortexed or irradiated, or two or more infrared rays of different wavelength bands are synthesized and the synthesized infrared rays are vortexed and irradiated.

In this case, even if the infrared ray is not used, the far infrared emission effect of the cement mortar curing product may be deteriorated when the infrared ray is not used in the limited wavelength range.

Infrared vortex is achieved by infrared band screw. Infrared screws are already known in the optical arts as a mechanism configured to perform horizontal and vertical rotational motions, and are generally composed of a motor and a ball screw. Infrared screws twist and vortex the infrared rays passing through them. The infrared rays twisted by the infrared region screw are absorbed by the cement mortar to effectively change the vibration state and energy transition of the cement mortar material molecule to maximize the far-infrared emission effect of the cement mortar curing body.

Infrared rays, which are used to generate infrared vortex, usually range from 760nm to 1,000,000nm, a kind of electromagnetic waves, which have longer wavelengths than visible light and shorter wavelengths than microwaves. In general, the criteria for distinguishing infrared rays by wavelength bands are variously defined according to a field or a person using infrared rays. For example, 760 to 4,000 nm can be classified as near infrared, 4,000 to 400,000 nm as far infrared, near infrared 740 to 1,400 nm, mid infrared 1,400 to 3,000 nm, far infrared at 3,000 to 1,000,000 nm, and near infrared 750 to 1,500 nm. It is also classified into mid-infrared 1,500-15,000nm, far-infrared 15,000-1,000,000nm, and also classified into near-infrared 750-3,000nm, mid-infrared 3,000-6,000nm, far-infrared 6,000-15,000nm, ultra-infrared 15,000-1,000,000nm.

Although not particularly limited, the preferable wavelength range of the infrared ray irradiated in step II is 950 to 990 nm.

According to the present invention, the cement mortar curing body irradiated with the vortex infrared ray in step II (120) emits far infrared rays for a certain period of time, which is caused by the change of the vibration state of the cement mortar material molecule by the vortex infrared ray and the cement mortar. It is presumed that the energy of the material molecules is due to a transition.

Preferably, as shown in Figure 1b, between the step I (100)) and the step II (120), irradiating the cement mortar by focusing the infrared rays obtained by filtering the light with an infrared filter without swirling Step I-a 110 may be additionally included. According to the experimental results, the cement mortar through stage I (100), stage I-a (110) and stage II (120) has far-infrared emission effect than the cement mortar curing through stage I (100) and stage II (120) only. It can be seen that the further increase, which is the action of removing the non-sintering infrared rays of the step I-a (110) to the factors that prevent the swirling infrared rays change the vibration state and energy of the cement mortar material molecules Presumably because

Preferably, the infrared rays irradiated onto the cement mortar in the step I-a (110) is preferably an infrared ray having a wavelength of 3,000 to 15,000 nm.

Since this method uses the energy system of material molecules, the cement mortar curing body can be designed to emit appropriate infrared rays by appropriately controlling the light rays to be irradiated.

In addition, by performing the steps according to the present invention for any one or more of the constituent materials constituting the cement mortar constituting the cement mortar considering the curability of the cement mortar, the present invention as shown in Figure 2a In other words, in the method for manufacturing a cement mortar curing material that emits far-infrared rays, (I) visible light obtained by controlling the wavelength of light with color by a visible filter and controlling the energy density as luminance Irradiating at least one component material of water, sand, and cement, constituting cement mortar (200) and (II), filtering light with an infrared filter to obtain infrared rays in a specific wavelength band, The cement mortar composition was subjected to visible light irradiation in the step I (200) by vortexing and converging with an external screw Irradiating material 220 (III) to form cement mortar by mixing the cement mortar constituent material and the remaining cement mortar constituent material which has undergone the step II (220) (230), and (IV) the cement A method may be provided that includes curing 240 mortar to form a cement mortar curing body.

In the case of this embodiment as well, as shown in FIG. 2B, between the phase I 200 and the phase II 220, the infrared rays obtained by filtering the light with an infrared filter are not vortexed. Focusing on, irradiating the cement mortar constituent material subjected to visible light irradiation in the step I (200) (step I-a) 210, and the step II (220), Infrared filter is used to obtain infrared light in a specific wavelength band, and the infrared light is swirled with an infrared light screw and focused, and irradiated with visible light in step I (200) and the non-swirl state in step Ia (210). More preferably, the step of irradiating the cement mortar constituent material subjected to infrared irradiation of 220a.

In addition, even in this embodiment, it has the same preferred wavelength range of irradiation light as the embodiments according to FIGS. 1A and 1B described above, and the method of forming an infrared vortex with an infrared screw is also the same.

Furthermore, cement secondary comprising cement and water used to construct cement secondary products (e.g. concrete comprising cement, water, gravel (coarse aggregate) or curable paste containing cement and water without aggregate), etc. With respect to the product constituent material, the present invention may be implemented as in the embodiment as shown in FIG. 3A, that is, in the method for producing a cement secondary product curing body that emits far infrared rays, (I) light (300) irradiating visible light obtained by adjusting wavelength with color by means of a visible filter and controlling energy density as luminance to at least one component of water or cement, which is a material constituting the cement secondary product (300), ( Ⅱ) Filter the light with an infrared filter to obtain infrared light in a specific wavelength band, swirl the infrared light with an infrared screw, and focus Irradiating to the cement secondary product constituent material subjected to visible light irradiation in step I (300) (320), (III) the cement secondary product constituent material and the remaining cement secondary product which passed through step II (320) Mixing the constituent materials to form a cement secondary product constituent material mixture (330), and (IV) forming and curing the cement secondary product constituent material mixture to form a cement secondary product constituent (340) It may be provided a method comprising a.

In the case of this embodiment as well, as shown in FIG. 3B, between the phase I 300 and the phase II 320, the infrared rays obtained by filtering the light with an infrared filter are not vortexed. Focusing on, further comprising irradiating the cement secondary product constituent material subjected to visible light irradiation in step I (300) (step I-a) (310), and step II (320), Filter the light with an infrared filter to obtain infrared light in a specific wavelength band, vortex the infrared light with an infrared screw, and then focus it, irradiating visible light in step I (300) and the ratio in step Ia (310). More preferably, the step 320a of irradiating the cement secondary product constituent material subjected to the vortex infrared irradiation.

Of course, the embodiment shown in FIGS. 3A and 3B also has the same preferred wavelength range of irradiation light as the embodiments according to FIGS. 1A and 1B described above, and the method of forming an infrared vortex with an infrared screw is also the same. Can be said.

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

The apparatus illustrated in FIG. 4A includes a visible light irradiation device A for irradiating visible light to cement mortar M and an infrared irradiation device B for irradiating infrared light to cement mortar M to which visible light is irradiated. ) And a conveying means (Con) provided in the conveying passage (S1) of the visible light irradiation device (A) and the conveying passage (S2) of the infrared irradiation device (B), and the apparatus (A, B, The operation of the controls is controlled by the control box. Although not shown, the irradiation device (A, B) is provided with an object detection sensor to detect when the cement mortar (M) is located in the light irradiation area in the transport passage (S1, S2) and the irradiation device (A, B) is It is desirable to design to initiate light irradiation, and designing such a device is a common technique that is well known in the art. In addition, when the cement mortar (M) in the light-transmissive container (TC) to carry out the treatment steps according to the present invention it will be possible to obtain higher energy efficiency.

In the accompanying drawings, although FIG. 4A shows cement mortar (M) as a treatment object, water (W) and cement (C) instead of cement mortar (M), as indicated by (W, C, S) using parentheses in the drawing. ), Sand (S) or a mixture of two. In addition, it can also be said that it can be a component of the cement secondary product as described in Figures 3a and 3b.

And, as shown in the accompanying drawings, Figure 4b, in the case of the cement admixture (CA), which is usually provided in a liquid phase, using the transparent container TC, the present invention using the same apparatus as shown in Figure 4a It can be implemented.

As shown in FIGS. 4A, 4B, and 5, the visible light irradiation device A includes a plurality of visible light irradiation members 1, and the irradiation member 1 is installed, cement mortar (M) and cement. It is composed of a mounting member (2) formed with a mortar constituent material (W, C, S), a cement secondary product constituent material, or a conveying passage (S1) of cement admixture (CA), as shown in Figs. As described above, the infrared irradiation device B includes a plurality of first infrared irradiation members 3, a plurality of second infrared irradiation members 4 positioned upstream of the first infrared irradiation member 3, and the infrared irradiation. Mounting member in which the members 3 and 4 are installed and a cement mortar (M), cement mortar components (W, C, and S), cement secondary product materials, or a conveying passage (S2) of cement admixture (CA) are formed. It consists of (5).

As shown in FIG. 6, the light source 11 and the visible filter 12 are sequentially disposed in the dimming cap 13 having a cylindrical body and a funnel-shaped flange at the bottom thereof. do. The visible light irradiation member 1 is located downstream of the light source 11 when the light source 11 is turned on by electric operation, and the visible light filter 12 emits light from the light source 11 that controls the wavelength by color and controls the energy density as luminance. Cement mortar (M) and cement mortar composed of cement visible in the predetermined wavelength band from the light to be filtered, and the filtered visible light is focused in the dimming cap 13, the conveying device (C) to the conveying passage (S1) It functions to irradiate visible light to the material (W, C, S), the cement secondary product component, or the cement admixture (CA).

As shown in FIG. 7, the light source 41 and the infrared filter 42 are sequentially disposed in the dimming cap 43 in the second infrared irradiation member 4. When the light source 41 is turned on by the electrical operation, the second infrared ray irradiation member 4 filters the infrared rays of the predetermined wavelength band from the light emitted from the light source 41 downstream of the infrared filter 42, Cement mortar (M), cement mortar constituent materials (W, C, S), which are infrared rays are focused in the dimming cap 43 and conveyed from the conveying passage (S1) to the conveying passage (S2) by the conveying apparatus (Con), It functions to irradiate filtered infrared rays to cement secondary product components, or cement admixtures (CA). Although it is effective to install such a second infrared irradiation member 4 upstream of the first infrared irradiation member 3, it is possible to produce far-infrared radioactive cement mortar, cement secondary product, or cement admixture without installing it. .

5 and 8, the first infrared irradiation member 3 has three light sources 31a, 31b, 31c in the dimming cap 34, and three enemies for filtering infrared rays in different wavelength bands. The outer filter 32a, 32b, 32c and one infrared screw 33 are sequentially arranged. The light sources and infrared filters here are arranged one each in three cylindrical housings. The first infrared irradiation member 3 shown in the drawing is for synthesizing and irradiating infrared rays of different wavelength bands. When the light sources 31a, 31b and 31c are turned on by electrical operation, they correspond to the respective light sources downstream of the first infrared irradiation member 3. Infrared filters 32a, 32b, and 32c filter infrared rays of a predetermined wavelength from light emitted from light sources 31a, 31b, and 31c, and infrared rays of different filtered bands are infrared screw 33 Cement mortar (M) and cement mortar components (W, C, S), which are synthesized while passing through the vortex, are concentrated at the dimming cap 34 and then conveyed to the conveying passage (S2) by the conveying device (Con). ), Cement secondary product components, or cement admixtures (CA). By operating any one of the light sources 31a, 31b, 31c in the first infrared irradiation member 3, a single infrared ray can be obtained, and by operating any two of these light sources, a synthetic infrared ray that becomes two infrared rays can be obtained. By operating all of the light sources, you can get synthetic infrared light that is three infrared rays.

FIG. 10 illustrates another form of the first infrared irradiation member 3 and is intended to swirl and irradiate infrared rays in a single wavelength band. In the illustrated first infrared irradiation member 3, one light source 31, one infrared filter 32, and one infrared screw 33 are sequentially disposed in the dimming cap 34.

Although not shown, the visible light irradiating member 1, the first infrared irradiating member 3, and the second infrared irradiating member 4 transmit light emitted from the cement mortar M and the cement mortar component materials W and C, respectively. , S), the cement secondary product component, or the surface, side, bottom, or two or more of them to the cement admixture (CA), which may be disposed of cement mortar (M), cement mortar component ( W, C, S), the shape of the mounting members 2 and 5, the visible light irradiation member 1, and the first infrared irradiation in consideration of the type and amount of the cement secondary product component material or cement admixture (CA) This can be achieved by changing the installation position or the shape of the member 3 and the second infrared irradiation member 4. Of course, at this time, the cement mortar (M), the cement mortar components (W, C, S), the cement secondary material, or the cement admixture (CA) as shown in Figure 4a and 4b has a light transmissive It may be more preferable to receive and process the container TC. In addition, the installation number of the visible light irradiation member 1, the 1st infrared irradiation member 3, and the 2nd infrared irradiation member 4, and the installation number of the visible light irradiation apparatus A and the infrared irradiation apparatus B are cements. It can be changed in consideration of the type, amount, etc. of the mortar, and can also be changed in various ways to suit this.

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

As shown in Figure 4a, the infrared treatment according to step II was performed after the visible light irradiation step of step I according to the present invention for the mortar mixed with cement, water, sand. At this time, visible light was filtered and irradiated to tartar with 580 to 590 nm, and vortex infrared light passed 950 to 990 nm infrared rays obtained by filtering after only one of the light sources 31a, 31b, and 31c were operated through an infrared screw. After the concentration, the concentration was investigated in Maltar.

According to the result of the test for confirming that the treated mortar emits far infrared rays, the mortars formed from cement, water and sand before the treatment hardly emit far infrared rays (BLUE using FT-IR Spectrometer). As low as about 0.850 to about 0.886 as a result of measuring BODY), the cured product of cement mortar treated in accordance with the present invention can be seen from the following test results (measurement compared to BLACK BODY using FT-IR Spectrometer). It was confirmed that the radiation of a large amount of far infrared rays.

Test results (treat the process according to the invention on mortar) Emissivity (5 to 20 μm) Radiation energy (W / ㎠) 0.912 3.68 x 10 ²

In addition, according to the results of deodorization test using ammonia (NH ₃ ) gas on the mortar treated in this way, the deodorization rate reached about 51% after the elapse of 30 minutes, and the deodorization rate was about 57 after 120 minutes. According to the results of antifungal test, the growth of bacteria was not noticeable during the 4 week culture test period, and in the antibacterial test using Escherichia coli and Pseudomonas aeruginosa, In the case of mortar, the concentration of bacteria increased by three times or more after 24 hours, whereas in the case of the mortar subjected to the treatment according to the present invention, the bacterial reduction rate was about 99% or more after 24 hours.

As another test example, the infrared treatment according to step II after the visible light irradiation step of step I according to the present invention for at least one of the constituent materials constituting the mortar made of cement, water and sand using the apparatus of FIG. 4A Was performed. At this time, visible light was filtered and irradiated with 580-590 nm to any one of the mortar constituent materials, and the vortex-infrared light was irradiated with 950-990 nm infrared light obtained by filtering only one of the light sources 31a, 31b and 31c. What was collected after passing the infrared screw was irradiated to the constituent material.

According to the result of the test for confirming whether the mortar containing the component material treated as described above emits far infrared rays, the cured product of the mortar containing the component material treated according to the present invention is the following test results (FT-IR Spectrometer) As can be seen from the measurement result compared to the used BLACK BODY, it was confirmed that the radiation of a large amount of far infrared rays.

Test results (treat water according to the invention) division Emissivity (5 to 20 μm) Radiation energy (W / ㎠) Water (Treatment) + Normal Sand + Normal Cement 0.911 3.68 x 10 ² General Water + Sand (Treatment) + General Cement 0.910 3.67 x 10 ² Normal Water + Normal Sand + Cement (Treatment) 0.910 3.67 x 10 ²

Although the test results are not shown herein, the same results were obtained even when the treatment according to the present invention was carried out by selecting two kinds of materials constituting the mortar (for example, water and cement).

As another test example, after the visible ray irradiation step of step I according to the present invention for the admixture solution, which is a constituent material added in forming the mortar of cement, water and sand using the apparatus of FIG. Infrared treatment was performed. At this time, the visible light was filtered to irradiate the admixture solution of 580 ~ 590nm, and the vortex infrared light was irradiated with infrared rays of 950 ~ 990nm obtained by filtering after operating only one of the light sources (31a, 31b, 31c) After passing through, the concentrated solution was irradiated to the admixture solution. According to the result of the test for confirming that the mortar containing the admixture solution treated as described above emits far infrared rays, the cured product of the mortar containing the admixture solution treated according to the present invention is the following test results (FT-IR Spectrometer) As can be seen from the measurement result compared to the used BLACK BODY, it was confirmed that the radiation of a large amount of far infrared rays.

Test results (treat the process according to the invention on the admixture solution) division Emissivity (5 to 20 μm) Radiation energy (W / ㎠) Water + general sand + general cement + admixture solution (treatment) 0.912 3.68 x 10 ²

As apparent from the above experimental results, according to the present invention, by irradiating specifically designed visible light and vortex infrared light to cement mortar, cement mortar material, or cement secondary product material, or cement admixture, When the treated cement mortar is applied to a wall of a building or molded into a cement secondary product, not only does it emit far-infrared rays for a long time after curing (hardening and solidifying) the cement mortar or cement secondary product, but also the toxicity of the cement. This can be eliminated, and furthermore, in addition to the deodorizing effect, antifungal effect, and antibacterial effect, it is possible to obtain an improved effect on heat and heat storage.

Claims (7)

In the method for producing a cement secondary product curing body that emits far infrared rays, (Ⅰ) Irradiation of 360-760 nm visible light obtained by putting water in a light-transmitting container among the materials constituting the cement secondary product, adjusting the wavelength of light by color using a visible filter, and controlling the energy density as luminance Step 300, (II) filtering the light with an infrared filter to obtain infrared light in the wavelength range of 760 to 1,000,000 nm, vortexing the infrared light with an infrared screw, and condensing the light, and receiving the visible light in step I (300). Irradiating the water contained in the container (320), (III) mixing (330) the cement secondary product component material mixture by mixing the water contained in the light-permeable container passed through step II (320) with the remaining cement secondary product component material; and (IV) forming the cement secondary product component material mixture and curing to form a cement secondary product curing body (340) comprising the far-infrared radiation emitting cement secondary product curing method. The method of claim 1, wherein between the step I 300 and the step II 320, infrared rays of the 760 to 1,000,000 nm wavelength obtained by filtering the light with an infrared filter are focused without vortexing. And irradiating water contained in the light-transmissive container subjected to visible light irradiation at I 300 (step I-a) 310, and In step II 320, the light is filtered with an infrared filter to obtain infrared light in the wavelength range of 760 to 1,000,000 nm, the infrared light is swirled with an infrared screw, and the visible light is collected in step I 300. Irradiating and irradiating the water contained in the light-transmissive container subjected to the irradiated infrared irradiation of the non-swollen state in the step Ia (310) (320a) to manufacture a cement secondary product curing product that emits far infrared rays Way. 3. The method according to claim 1 or 2, wherein the infrared rays irradiated in the step II (320, 320a) are at least two infrared rays of different wavelength bands and are synthesized infrared rays focused after vortexing with an infrared band screw. A method for producing a cement secondary product curing body that emits far infrared rays. The wavelength of visible light irradiated in step I (300) is 580 to 590 nm, and the wavelength of infrared light irradiated in steps (320, 320a) is 950 to 990 nm. A method for producing a cement secondary product curing body that emits far infrared rays. The method of claim 3, wherein the wavelength of the visible light irradiated in the step I (300) is 580 to 590 nm, and the wavelength of the synthetic infrared light irradiated in the step (320, 320a) is 950 to 990 nm. Method of manufacturing a cement secondary product curing machine to spin. The method according to claim 2, wherein the infrared ray irradiated in step I-a (310) has a wavelength of 3,000 to 15,000 nm. delete

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