KR20110049354A - A diet belt - Google Patents

Abstract

PURPOSE: A diet health band is provided to increase a diet effect and immunity through far-infrared radiation and to reduce adult disease and stress. CONSTITUTION: A diet health band is made of fiber textile including conductive acryl fiber. The conductive acryl fiber contains fiber textile(1) and a far-infrared ray emitting layer(3) deposited on the fiber textile. The far-infrared ray emitting layer includes selenium of 30-90 wt.%, titanium of 1-30 wt.%, germanium of 1-30 wt.%, volcanic rock of 1-30 wt.%, tourmaline of 1-30 wt.%, elvan of 1-30 wt.%, yellow soil of 1-30 wt.%, jade of 1-30 wt.%, and tourmaline of 1-30 wt.%.

Description

Diet bag {A DIET BELT}

The present invention relates to a diet bag, which is coated with selenium particles and volcanic or tourmaline on a fabric fabric containing conductive acryl fibers made by adsorbing copper sulfide to acrylic fibers to vitalize the human body through the production of fibers that emit far infrared rays. Give a diet bags that can give a diet effect.

In recent years, most people have become interested in the diet method and various exercises, which are one of the methods, in order to prevent the progress of obesity, which is the main culprit of various adult diseases.

However, in reality, it is best to prevent obesity through continuous exercise, but since it requires a lot of time and effort, it is very difficult to continuously exercise in the position of modern people living busy daily life.

Therefore, some people rely on drugs, which are relatively simpler methods than exercise, in order to expect a dietary effect.

In recent years, a diet band is worn near the user's abdomen and physically presses the abdomen to obtain a diet effect. However, in the case of the existing abdominal pressure, the abdomen occurs when worn for a long time because it compresses the abdomen.

Therefore, in view of the above problems, the present invention increases the diet effect by fabricating a bag using a fiber fabric containing conductive acyl fibers, and far-infrared rays on the fabric fabric using chemical vapor deposition and physical vapor deposition. The purpose of the present invention is to deposit a far-infrared radiation layer emitting radiation to improve immunity through far-infrared radiation, and to provide a dietary bag that is beneficial in relieving stress and fatigue of adult diseases.

In the diet bag according to the present invention for achieving the above object, the conductive acrylic fiber is at least 30% fiber fabric containing; And a far infrared ray emitting layer deposited on the fiber fabric, wherein the far infrared ray emitting layer is 30 to 90 wt% selenium, 1 to 30 wt% titanium, 1 to 30 wt% germanium, 1 to 30 wt% For diet comprising volcanic stone, 1-30 wt% tourmaline, 1-30 wt% elvanite, 1-30 wt% ocher, 1-30 wt% jade, and 1-30 wt% tourmaline Give the bags.

The far-infrared radiation layer may be deposited by physical vapor deposition including vacuum deposition and sputtering or patterned on the fabric by a shadow mask.

It further comprises a laminating paper provided on the far infrared ray emitting layer.

The conductive acrylic fiber is characterized by being produced by adsorbing a copper compound on the acrylic fiber containing 50% by weight or more of acrylonitrile.

In addition, the conductive acrylic fiber according to the present invention comprises the steps of preparing a fiber fabric containing at least 30%; And 30 to 90% by weight selenium, 1 to 30% by weight titanium, 1 to 30% by weight germanium, 1 to 30% by weight volcanic stone, 1 to 30% by weight on the fabric fabric using physical vapor deposition. Forming a far-infrared radiation layer comprising a tourmaline, 1-30 wt% elvanite, 1-30 wt% ocher, 1-30 wt% jade, and 1-30 wt% tourmaline, wherein the far-infrared firm It provides a method for producing a dietary bag, comprising the step of processing the fiber fabric in the form of a bag before or after the step of forming a layer.

Vacuum deposition and sputtering are used as the physical vapor deposition method.

As described above, the present invention can manufacture a bag of conductive fibers and form a far-infrared radiation layer including volcanic and tourmaline on its surface, thereby increasing thermal conductivity and increasing diet effect.

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

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

1 and 2 is a perspective view of the fiber for producing a diet bag according to an embodiment of the present invention.

1 and 2, the fiber for diet bags according to the present embodiment includes a fiber fabric 1 and a far-infrared radiation layer 3 deposited on the fiber fabric 1.

It is effective to use conductive acrylic fibers or at least one of conductive acrylic fibers, natural fibers, recycled fibers and synthetic fibers as the fiber fabric 1. here,

The conductive acrylic fiber is prepared by adsorbing a copper compound to an acrylic fiber containing 50% by weight or more of acrylonitrile. At this time, a conductive acrylic fiber may be prepared by adding a compound which forms a complex with copper divalent ions together with copper sulfate, nickel sulfate, sodium thiosulfate and a Ph adjusting solution in the same reaction tank.

Here, it is preferable to add 0.1-0.5 g / L of compounds which form a complex with copper divalent ion with respect to the whole process liquid. The compound forming a complex with copper divalent ions is ethylenediamine tetra acetic acid (EDTA), ethylenediamine tetramethylene phosphonic acid (EDDTPO), and nitrilotriacetic acid (NTA). , 1,2-diaminocyclohexane-N, N, N ', N'-tetraacetic acid (1,2-Diaminocyclohexane-N, N, N', N'-tetra acetic acid: DCYTA) or polyvalent amines Can be.

Here, there is a slight difference depending on the compound, but if it is added in excess of 0.5g / ℓ does not dissolve well in water and acts as an excess, when less than 0.1g / ℓ may exhibit an effect.

The compound chelated with the copper divalent ions used in the present embodiment not only stabilizes the reaction but also adsorbs copper sulfide uniformly on the fiber surface, thereby providing uniform conductivity and at the same time excellent conductivity.

In addition, the chelate compound used in the present invention has a difference in complex formation reaction rate depending on pH and concentration, but forms a complex stably between pH 2-4 and concentration 0.1-0.5 g / L.

In addition, when the chelating compound is added, even if sodium thiosulfate is used alone, enough copper ions are uniformly adsorbed on the fiber surface to obtain fibers having extremely excellent conductivity.

The conductive acrylic fiber of the present invention obtained by the above-described manufacturing method can be manufactured in a staple or spun yarn state, and can be mixed with other fibers because the physical properties of the acrylic fiber are maintained as it is.

In addition, in the case of using natural fibers as the fiber fabric (1), cotton fibers, hemp fibers, wool fibers and silk fibers may be used, rayon and acetate may be used as the regenerated fibers, nylon, acrylic as the synthetic fibers , Polyester and polyurethane can be used. Of course, it is also possible to use polyester fibers, glass fibers, aramid fibers and fiber fabrics with heat-resistant insulating functionality.

At this time, as mentioned above

The fiber fabric 1 can be made of 100% conductive acrylic fibers. Of course, the present invention is not limited thereto, and when at least one of other fibers such as natural fibers, recycled fibers, and synthetic fibers is added, the conductive acrylic fibers are preferably added at least 30% or more. If it is smaller than the above range, the diet effect is reduced. At this time, it is preferable that% is weight%. Accordingly, the fiber fabric 1 may include 30 to 100 wt% of conductive acrylic fibers, 0 to 70 wt% of natural fibers, 0 to 70 wt% of regenerated fibers, and 0 to 70 wt% of synthetic fibers, respectively.

The surface of the fiber fabric 1 is coated with a far infrared ray emitting layer (3).

And, in the present embodiment further comprises the step of processing the fiber fabric (1) in the form of a bag. In this case, after the far-infrared radiation layer 3 is coated on the surface of the fiber fabric 1, it may be processed in a bag form, and after the first process in the form of a bag, the far-infrared radiation layer 3 may be coated.

The far-infrared radiation layer 3 uses a method in which the fibrous fabric 1, which is the coating material, is not damaged by using a deposition technique, that is, a coating technique. That is, in this embodiment, physical vapor deposition (PVD), which can perform deposition at low temperature, is used. Such physical vapor deposition methods are sputtering, e-beam evaporation, thermal evaporation, laser molecular beam deposition (L-MBE, laser molecular beam epitaxy), pulsed laser deposition (PLD) ). Preferably, the far infrared radiation layer 3 is formed by vacuum deposition or sputtering. In vacuum deposition, material is evaporated by using resistance heating or electron beam at high vacuum, and vaporization atoms and molecules solidify onto the coating material, thereby forming a wood. Sputtering is an abnormal discharge caused by the voltage between the high electrodes of several KV in an inert gas atmosphere, and inert ions collide with the target, thereby vacuuming the target material in a vacuum to coagulate the coated material.

The far-infrared radiation layer 3 produced through the above-described process includes selenium, titanium, germanium, volcanic stone, and tourmaline. It may further include elvan, loess, jade and tourmaline. At this time, it is preferable to take the highest content of selenium. Here, the far infrared ray emitting layer 3 is 30 to 90% by weight selenium, 1 to 30% by weight titanium, 1 to 30% by weight germanium, 1 to 30% by weight volcanic stone, 1 to 30% by weight tourmaline, 1 To 30 weight percent elvanite, 1 to 30 weight percent ocher, 1 to 30 weight percent jade, and 1 to 30 weight percent tourmaline.

1 to 30% by weight of ceramic may be further added to the far infrared ray emitting layer 3. This is because the amount of addition may vary depending on the characteristics of the respective elements.

Of course, only one of the above-described volcanic stone and tourmaline may be added. That is, the far infrared ray emitting layer 3 may include selenium, titanium, germanium and volcanic stones, or may include selenium, titanium, germanium, and tourmaline.

However, as mentioned above, it is preferable that the addition amount of selenium is the largest.

Selenium is one of the oxygen group elements belonging to group 6B of the periodic table and is an essential trace element (inorganic substance) in our body. It is a component of the antioxidant enzyme (Glutathione peroxidase), which prevents oxidative damage and is caused by fat peroxidation. Protects cells and membranes from free radicals. Most cells contain this enzyme, so selenium has a wide range of protective actions. That is, because free radicals can damage cells and cause some chronic diseases, our bodies have a defense system that regulates the amount of free radicals, such as antioxidants. Selenium is essential for the normal functioning of this defense, the immune system and the thyroid gland. Selenium has an emissivity (5-20 µm) of 0.904 and an emission energy (W / m 2 · µm, 37 ° C) of 3.49 × 10 ² .

Selenium has ionization action, blood promoting action, upbringing effect, sweating effect and analgesic effect. In addition to this, it has the effect of blocking harmful electromagnetic waves and the effect of blocking water vein waves. Therefore, the addition of selenium to the far-infrared radiation layer (3) is effective in neuralgia, low back pain, arthritis, myalgia discs, etc., and has a good night's sleep, which is good for stress relief and fatigue recovery of modern people and insomnia. In addition, it helps to circulate blood vessels by expanding microcirculation and has a rapid effect in treating adult diseases (hypertension, kidney disease, diabetes, heart disease, etc.).

In addition, by adding volcanic stones and tourmaline they can be reacted by the lower fiber fabric (1) and the human body heat to increase the diet effect. In addition, since the production of alpha waves is increased, it is possible to activate the metabolism of the human body.

Figure 3 is a graph of the results of measuring the wavelength emitted from the diet belly band according to this embodiment.

As shown in FIG. 3, it can be seen that the radiation dose of alpha (α) waves is higher than that of theta (θ) waves in the diet belly according to the present embodiment. At this time, the alpha wave radiation was 92.5%, beta wave was 5%, and theta wave was 2.5%. As such, the amount of alpha waves that make the human body feel more metabolized and comfortable increases the body movement of the abdominal region. This may increase the diet effect. In addition, metabolism may also be enhanced by far-infrared radiation emitted from the far-infrared radiation layer.

In addition, in the present embodiment, the fiber fabric 1 is made of conductive acrylic fibers, and the thermal conductivity can be increased by placing volcanic stones and / or tourmaline in the far-infrared radiation layer 3 coated on the upper side thereof. This makes it possible to concentrate heat in the vicinity of the bag, thereby further increasing the far-infrared radiation amount of the far-infrared radiation layer 3. In addition, due to the concentration of heat there is an advantage that can slowly burn fat near the abdomen by heat. Therefore, the effect of losing fat near the abdomen can be seen.

The far-infrared radiation layer 3 described above may be made of a plurality of layers. And, although not shown, the far infrared ray emitting layer 3 may be formed on the upper side and the lower side of the fiber fabric (1). In FIG. 1, the far-infrared radiation layer 3 is formed on the entire fiber fabric 1. However, the present invention is not limited thereto, and the far infrared ray emitting layer 3 may be formed on the fiber fabric 1 in a predetermined pattern form. In this case, in order to form the far-infrared radiation layer 3 on the fiber fabric 1 in a predetermined pattern shape, forming the far-infrared radiation layer 3 on the fiber fabric 1 by using a shadow mask during vacuum deposition or sputtering process. desirable. That is, when a shadow mask having an opening for pattern formation to be manufactured is disposed on the fabric fabric 1 and then the far infrared ray emitting layer 3 is formed by physical vapor deposition, the far infrared ray emitting layer 3 is formed in a desired pattern. Can be made.

In addition, the far-infrared radiation layer 3 of a present Example is not limited to this and can be manufactured using a printing method. That is, it can be produced by coating a separate coating material and then coating it on the fiber fabric (1).

In addition, as shown in FIG. 2, the far-infrared radiation layer 3 may be coated with a laminating paper 5. In this way it is coated with a laminating paper (5) to have durability and chemical resistance and flame retardancy even in the washing operations such as water washing or dry cleaning.

The present invention is not limited thereto, and may provide a product made of various textile fabrics. Fiber fabrics and articles made from these fabrics, such as garments or shoes. As described above, the fiber fabric 1 in which the far-infrared radiation layer 3 is deposited on the surface of the fiber fabric 1 produces an outer coating material including the far-infrared radiation layer 3 that generates far-infrared rays such as jade, germanium, and ceramics to give the human body a breath force. Can be. And, by coating with laminating paper (5) has a durability and chemical resistance as well as a fire-proof function even in washing operations such as water washing or dry cleaning.

By using the above-mentioned diet bags, the body temperature of the abdominal muscles that make up the stomach band is raised, thereby increasing the diet effect.

To this end, five experimenters each of the diet bags and the general bags according to the present embodiment described above were measured for changes in weight after wearing 60 hours for 8 hours each day. Experimental Examples 1 to 5 are the results of wearing the diet bags of this embodiment, and 6 to 10 are the results of wearing the general bags. The experimental results are summarized in Table 1 below.

Initial weight 15 days past 30 days elapsed 45 days passed 60 days passed Weight loss Experimental Example 56.3Kg 56.1Kg 55.8Kg 55.2Kg 54.8Kg 1.5Kg Experimental Example 73.2Kg 72.8Kg 72.6Kg 72.0Kg 71.5Kg 1.7Kg Experimental Example 89.3Kg 88.9 Kg 88.5Kg 88.2Kg 88.0Kg 1.3Kg Experimental Example 4 58.6Kg 58.5Kg 58.3Kg 58.1 Kg 57.4Kg 1.2Kg Experimental Example 68.9 Kg 68.3Kg 68.0Kg 67.5Kg 67.2 Kg 1.7Kg Experimental Example 6 78.1Kg 78.3Kg 78.0Kg 78.2Kg 78.0Kg 0.1Kg Experimental Example 61.3Kg 61.1Kg 61.2Kg 61.0Kg 60.8 Kg 0.5Kg Experimental Example 55.9Kg 55.3 Kg 55.2Kg 54.9Kg 54.9Kg 1.0Kg Experimental Example 80.6Kg 80.4Kg 80.1Kg 79.8Kg 79.7 Kg 0.9Kg Experimental Example 71.2Kg 71.2Kg 70.9Kg 70.6Kg 70.4Kg 0.8Kg

As shown in the above table, in the case of the fiber fabric 1 including the conductive acrylic fiber of the present embodiment and the diet band with the far-infrared radiation layer 3 deposited thereon, the weight loss averaged 1.48 Kg in all the experimental groups. However, in the experimental group using the normal bags, the decrease was 0.66 Kg. As such, when using the diet bag of the present embodiment, it can be seen that the weight reduction effect of about 2 times.

1 and 2 are a perspective view of the fiber for producing a diet bag according to an embodiment of the present invention.

Figure 3 is a graph of the results of measuring the wavelength emitted from the diet belly band according to this embodiment.

DESCRIPTION OF THE REFERENCE NUMERALS

1: textile fabric

3: far infrared ray emitting layer

5: laminating paper

Claims (6)

In the diet bag, Conductive acrylic fibers include at least 30% of the fiber fabric containing; And A far infrared ray emitting layer deposited on the fiber fabric, The far infrared ray emitting layer is 30 to 90% by weight selenium, 1 to 30% by weight titanium, 1 to 30% by weight germanium, 1 to 30% by weight volcanic stone, 1 to 30% by weight tourmaline, 1 to 30% by weight Elvan, 1 to 30% by weight of ocher, 1 to 30% by weight of jade, and 1 to 30% by weight of tourmaline comprising a dietary bag. The method of claim 1, The far-infrared radiation layer is deposited by physical vapor deposition including vacuum deposition and sputtering, or patterned on the fiber fabric by a shadow mask characterized in that the diet. The method of claim 1, Dietary bags, characterized in that it further comprises a laminating paper provided on the far-infrared radiation layer. The method of claim 1, The conductive acrylic fiber is manufactured by adsorbing a copper compound to the acrylic fiber containing at least 50% by weight of acrylonitrile. Preparing a fibrous fabric containing at least 30% conductive acrylic fibers; And 30-90 wt% selenium, 1-30 wt% titanium, 1-30 wt% germanium, 1-30 wt% volcanic stone, 1-30 wt% tourmaline on the fabric fabric using physical vapor deposition Forming a far-infrared radiation layer comprising 1 to 30% by weight of elvan, 1 to 30% by weight of ocher, 1 to 30% by weight of jade, and 1 to 30% by weight of tourmaline, Method of manufacturing a bag for a diet, characterized in that the step of processing the fiber fabric in the form of a bag before or after the step of forming the far-infrared superior layer. The method of claim 5, Far infrared radiation fiber manufacturing method characterized in that the vacuum vapor deposition and sputtering by the physical vapor deposition method.

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