KR101555231B1 - Mirror-type quantum energy irradiation device - Google Patents

Abstract

In the present invention, a mirror-type quantum energy irradiating device capable of easily carrying and storing, capable of controlling a power source only by physical contact without any separate operation, and capable of cell activation, blood circulation promotion, blood waste, fat and cholesterol removal Lt; / RTI >
In one aspect of the present invention, there is provided a mirror-type quantum energy irradiating apparatus including a healing portion and a frame portion surrounding the healing portion, wherein the healing portion includes a first quantum energy irradiation board having a heating portion on one surface thereof and a second quantum energy irradiation board covering one surface of the first quantum energy irradiation board, Wherein the second quantum energy irradiation board includes a plurality of holes, and the second quantum energy irradiation board includes a plurality of holes.

Description

[0001] MIRROR-TYPE QUANTUM ENERGY IRRADIATION DEVICE [0002]

The present invention relates to a mirror-type quantum energy irradiation apparatus.

Quantum energy is absorbed and absorbed deeply into a human body or substance, resonating with the intrinsic wavelength of a human body or material, and is activated by resonance. These quantum energies have the effects of accelerating the growth of plants and animals, activating water, maintaining freshness of food, increasing taste, deodorizing and aging. Especially in the human body, temperature increase of subcutaneous layer, expansion of microvessels, promotion of blood circulation, And an increase in reproduction ability.

Korean Patent Registration No. 10-0975857 (Aug. 16, 2010)

The present invention relates to a mirror type quantum energy irradiation device capable of easily controlling the power source only by physical contact without any separate operation and capable of cell activation, promotion of blood circulation, removal of blood waste, fat and cholesterol, Lt; / RTI >

A mirror type quantum energy irradiating apparatus according to the present invention is a mirror type quantum energy irradiating apparatus including a healing portion and a frame portion surrounding the healing portion. The healing portion includes a first quantum energy irradiation board having a heating portion formed on one surface thereof, And a second quantum energy irradiation board covering one side of the board, wherein the second quantum energy irradiation board may be formed with a plurality of holes.

Here, the frame portion may be formed so as to surround the remainder of the healing portion except one side.

And one side of the healing portion may be formed so as to be covered with a mesh.

Further, the heat generating portion may be formed of a heat generating coil.

Further, a knob including a switch for controlling power of the healing portion may be further formed at the lower end of the frame portion.

Further, the switch may be formed of a capacitive touch sensor.

In addition, the first and second quantum energy irradiation boards may be formed of ore structures having a plurality of pores.

Also, the ore structure having a plurality of pores comprises 60 to 95 wt% (wt%) of an ore structure and 5 to 40 wt% (wt%) of an inorganic binder, and 5 to 20 wt% ) Coloring agent may be further included.

As the inorganic binder, a glaze or a frit may be used.

The mirror-type quantum energy irradiating device according to the present invention has effects of cell activation, promotion of blood circulation, removal of blood waste, fat and cholesterol, and also has a shape of a hand mirror so as to facilitate portability and storage, It is possible to operate the power easily by only touching the body by applying it.

1 is a front view of a mirror-type quantum energy irradiation apparatus according to an embodiment of the present invention.
2 is a cross-sectional view of a mirror-type quantum energy irradiation apparatus according to an embodiment of the present invention.
3 is a perspective view of an ore structure having a plurality of pores forming first and second quantum energy irradiation boards.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings, so that those skilled in the art can easily carry out the present invention.

1 is a front view of a mirror-type quantum energy irradiation apparatus according to an embodiment of the present invention. 2 is a cross-sectional view of a mirror-type quantum energy irradiation apparatus according to an embodiment of the present invention.

Referring to FIGS. 1 and 2, a mirror-type quantum energy irradiation apparatus 100 according to an embodiment of the present invention includes a healing portion 120 and a frame portion 110 surrounding the healing portion 120. Here, the healing portion 120 is surrounded by the frame portion 110 and exposes only one side to the outside, and one side of the exposed healing portion 120 may be covered with the net 130. A handle 115 including a switch 116 for controlling power of the healing unit 120 is further formed at the lower end of the frame unit 110.

The frame part 110 is formed to surround the healing part 120 to be described later. Particularly, the frame part 110 may be formed to surround the remainder of the healing part 120 except for one side. That is, the frame unit 110 exposes only one side of the healing unit 120 to the outside. The frame part 110 serves to firmly hold the healing part 120, and the material of the frame part 110 may be wood, metal, and plastic. However, these materials do not limit the present invention.

The handle 115 is further formed at the lower end of the frame part 110. By forming the knob 115, the user can conveniently use the mirror-type quantum energy irradiation apparatus 100 by holding the knob 115. In addition, the switch 116 may be formed on the side surface of the handle 115 to control the power supply of the mirror-type quantum energy irradiation device. Here, the switch 116 may be a capacitive touch sensor. The capacitive touch sensor operates by detecting the change in capacitance caused when the body touches. Therefore, when the user's hand touches the switch 116 by holding the knob 115, the mirror-type quantum energy irradiating apparatus according to the embodiment of the present invention is operated by the change in the electrostatic capacity generated at this time. Even if the user places the mirror-type quantum energy irradiating apparatus 100 adjacent to another object after temporarily stopping use or terminating use, the user's body and the switch 116 are not in contact with each other, The operation can be stopped. Therefore, it is possible to easily control the power source without any special operation, and in particular, when the short instantaneous use is stopped, the heat due to the quantum energy irradiated from the apparatus can be prevented from being transmitted to other adjacent objects. Although the switch 116 is preferably a capacitive touch sensor, the switch 116 may be formed by a contact type switch.

The handle 115 may be made of wood, metal, or plastic, like the frame 110, and thus the present invention is not limited thereto. 1, the switch 116 is formed to be positioned on the side surface of the handle 115. However, the present invention is not limited thereto. For convenience, the switch 116 may be formed to surround a part or the whole of the handle 115 Also,

A power supply line 117 is formed on the lower end of the handle 115, that is, on the opposite side of the contact area between the handle 115 and the frame 110. The mirror type quantum energy irradiating apparatus 100 according to an embodiment of the present invention is connected to an external power source by the power source supply line 117 and is operated by receiving power from an external power source.

The healing portion 120 includes a first quantum energy irradiation board 121 having a heating portion 121a formed on one surface thereof and a second quantum energy irradiation board 125 covering one surface of the first quantum energy irradiation board 121 And a plurality of holes 126 are formed in the second quantum energy irradiation board 125.

The first quantum energy irradiation board 121 is formed to include a heat generating unit 121a at the center of one surface thereof. The heating portion 121a may be a heating coil. Also, the heating coil is connected to the power supply line 117. Accordingly, the heat generating coil of the heat generating unit 121a generates heat by the electric power supplied from the power supply line 117.

The first quantum energy irradiation board 121 is formed of an ore structure having a plurality of pores to be described later, and is an amorphous rock having a property of rapidly expanding in a high temperature environment. The amount of energy (far infrared ray energy) from the first quantum energy irradiation board 121 is increased by heating the ore structure having a plurality of pores, that is, the first quantum energy irradiation board 121 is heated by the heat generating unit 121a, .

The second quantum energy irradiation board 125 is formed to cover one surface of the first quantum energy irradiation board 121. That is, the second quantum energy irradiation board 125 is formed to cover the heat generating unit 121a formed on one surface of the first quantum energy irradiation board 121. Accordingly, since the heat generating portion 121a is not directly exposed to the outside, the user and the heat generating portion 121a come into contact with each other due to the hot heat of the heat generating portion 121a, for example, carelessness, .

The second quantum energy irradiation board 125 is formed of an ore structure having a plurality of pores like the first quantum energy irradiation board 121. Accordingly, the second quantum energy irradiation board 125 receives heat from the heat generating unit 121a, and thus the quantum energy (far-infrared energy) is irradiated from the second quantum energy irradiation board 125.

Meanwhile, a plurality of holes 126 are formed in the second quantum energy irradiation board 125. The quantum energy generated in the first and second quantum energy irradiation boards 121 and 125 may be transferred to the user through the holes 126 without being accumulated in the healing unit 120. [ In addition, since the heat of the heat generating portion 121a can be discharged through the holes 126, it is possible to prevent accumulation of excessive heat. The shapes and the numbers of the holes 126 shown in the drawings are for explaining the embodiments of the present invention and are not intended to limit the present invention.

The net 130 is formed to cover one exposed surface of the healing portion 120, that is, one surface exposed to the outside of the second quantum energy irradiation board 125. Therefore, it is possible to prevent the healing portion 120 from being in direct contact with the outside by the mesh 130. [ That is, damage that may be caused by the direct transfer of the hot heat of the healing portion 120 to the outside by the net 130 can be prevented.

3 is a cross-sectional view of a mirror-type quantum energy irradiation apparatus according to another embodiment of the present invention. Portions having the same configuration and operation as those of the above-described embodiment are denoted by the same reference numerals, and differences from the foregoing embodiment will be mainly described below.

Referring to FIG. 3, the mirror-type quantum energy irradiation apparatus according to another embodiment of the present invention includes a healing unit 220 and a frame unit 110 surrounding the healing unit 220. Here, the heeling portion 220 is formed such that the frame portion 110 surrounds the remainder of the heel except for a relatively large first surface and a second surface opposite to the first surface. That is, the heeling portion 220 is surrounded by the frame portion 110 and exposes only the first and second surfaces to the outside, and the exposed first and second surfaces may be covered with the mesh 230. A handle 115 including a switch 116 for controlling the power of the healing unit 220 is further formed at the lower end of the frame unit 110.

The healing unit 220 includes a first quantum energy irradiation board 121 having a heating part 121a formed on a first surface thereof and a second quantum energy irradiation board 121 covering one surface and the opposite surface of the first quantum energy irradiation board 121. [ And an investigation board 225. That is, the second quantum energy irradiation board 225 may be symmetrically formed on both sides with reference to the first quantum energy irradiation board 121. Therefore, since the second quantum energy irradiation board 225 is formed to cover the heat generating unit 121a, the hot heat generating unit 121a is not directly exposed to the outside, so that the damage caused by carelessness can be reduced. In addition, since the second quantum energy irradiation board 225 is formed on both sides of the first quantum energy irradiation board 121, the quantum energy generated from the first quantum energy irradiation board 121 is transmitted to the healing unit 220, it is possible to smoothly escape to the outside. That is, excessive accumulation of heat in the healing portion 220 can be prevented. A plurality of holes 226 are formed in the second quantum energy irradiation board 225 so that the quantum energy generated in the first and second quantum energy irradiation boards 121 and 225 is not accumulated in the healing unit 120 And to be delivered to the user.

Here, the first and second quantum energy irradiation boards 121 and 225 are made of ore structures having a plurality of pores. In addition, the shapes and the numbers of the holes 226 shown in the drawings are for illustrating the embodiments of the present invention, and the present invention is not limited thereto, and the shapes and the numbers thereof may be different according to convenience.

The net 230 is formed to cover the exposed first and second surfaces of the healing portion 220 so that the healing portion 220 is directly in contact with the outside so that the hot heat of the healing portion 220 It is possible to prevent direct delivery to the outside.

As described above, the mirror-type quantum energy irradiating apparatus according to the embodiment of the present invention includes first and second quantum energy irradiation boards formed of ore structures having a plurality of pores, heat generated on one surface of the first quantum energy irradiation board And a healing portion including the portion. The heat generating unit generates heat by receiving power from a power supply line. At this time, quantum energy is generated in the first and second quantum energy irradiation boards by the heat of the heat generating unit.

The quantum energy generated from the mirror-type quantum energy irradiation device according to the embodiment of the present invention penetrates deeply into the skin, thereby facilitating cell activation, promoting blood circulation, and exhibiting an effect of removing blood waste, fat and cholesterol. Therefore, the user can obtain the healing effect by positioning the healing portion of the mirror-type quantum energy irradiation device adjacent to a desired portion.

In the mirror-type quantum energy irradiating apparatus according to the embodiment of the present invention, the switch formed on the handle is formed of a capacitive touch sensor, and the power of the mirror-type quantum energy irradiating device is controlled It is possible to perform a simple operation.

In addition, the mirror-type quantum energy irradiating device according to the embodiment of the present invention has a shape of a hand-held mirror, and has a merit that the size thereof is greatly reduced, the portability is excellent, and the storage is easy.

Hereinafter, an ore structure having a plurality of pores forming the first and second quantum energy irradiation boards of the mirror-type quantum energy irradiation apparatus according to an embodiment of the present invention will be described.

4 is a perspective view of an ore structure 10 having a plurality of pores forming the first and second quantum energy irradiation boards.

4 shows an ore structure 10 having a plurality of pores in a substantially plate-shaped board. However, it is also possible to use a hexahedral block, a columnar block, or equivalent block thereof in accordance with a mold , But the form is not limited thereto.

The ore structure 10 having such a plurality of pores may be composed of an ore structure 1 having pores 2 and an inorganic binder 5 for integrating such ore structure 1. Of course, in addition to the ore structure 1 and the inorganic binder 5 in the manufacturing process, water and an organic binder are used, but these water and organic binder are dried or removed during the manufacturing process, so they are not shown in the drawings. Further, although the ore structure 1 is shown almost circular in the figure, such an ore structure 1 has a very irregular shape which is actually close to a circular shape. Moreover, the pores (2) of the ore structure (1) are shown in closed form, but may actually be in open form.

The ore structure 1 may have a structure in which a coating material such as a ceramic glaze or a glass frit is coated on the surface of the ore structure body 1 in advance. However, the present invention is not limited thereto. In addition, the ore structure 10 having a plurality of pores may further include a coloring agent (for example, a coloring agent for ceramics). The ore structure 10 having a large number of pores according to the present invention can have various colors by such a coloring agent.

The structure of the ore structure having a plurality of pores according to the present invention will be described in more detail.

The ore structure 1 may be made by processing obsidian, perlite, and tillage rock or a mineral equivalent thereof. For example, after the mineral is crystallized and heated rapidly at a high temperature of about 870 DEG C or higher, the ore crystal structure 1 having a large number of pores 2 is formed while the crystal water therein is vaporized. The ore structure 1 contains a number of micropores 2 in the particles, and thus has a light characteristic. The ore structure 1 used in the present invention has chemical components as shown in Table 1, but the present invention is not limited to these chemical components.

ingredient SiO ₂ Al ₂ O ₃ K ₂ O Na ₂ O Fe ₂ O ₃ CaO MgO Content (%) 72-78 10 to 15 2.5 to 4.5 2.5 to 4.5 0.2 to 1.2 0.1 to 0.5 0.1 to 0.3

In addition, the ore structure 1 has physical properties substantially as shown in [Table 2]. However, these physical properties do not limit the present invention.

Density (g / cm3) pH Thermal conductivity (kcal / mh ° C) Usable temperature (℃) color 0.03 to 0.25 6.5 to 7.5 0.03 to 0.05 -250 to 1000 White, grayish white

Referring to [Table 1] and [Table 2], the ore structure has light weight because it contains many pores. In addition, the ore structure is a chemically neutral, natural mineral composed solely of inorganic materials, and has a low incidence of the risk of generation of noxious gases in case of fire. In addition, the solid conductance of the ore structure itself is very small due to the point contact between the ore structure powder due to many pores, and since the fine particles are filled in the pores between the ore structure particles, convection is prevented and the particles are white There is a good heat insulating property. In addition, as shown in [Table 2], the ore structure can be used as a thermal insulation and insulation in a wide temperature range.

The ore structure 1 may be about 60 to 95 wt% (wt%) based on the ore structure 10 having a plurality of pores of 100 wt% (wt%). If the ore structure 1 contains less than 60 wt%, the lightweight or adiabatic properties of the ore structure 10 having many pores may be degraded, whereas the ore structure 1 may contain less than 95 wt% (wt%), the weight of the following inorganic binder 5 is relatively reduced, so that the improvement of the strength may be insufficient.

The inorganic binder 5 may be selected from glazes (for example, glazes for ceramics), frit (for example, glass frit) or materials equivalent thereto. However, the material of the inorganic binder 5 is not limited thereto.

The glaze is a lye of a glassy material and can be variously classified according to the melting temperature, the surface condition, the coloring state, the production method, the firing method, and the firing result. According to the molten state, it can be classified into low-quality glazes combined with borax, optical surface, soda, frit and silicate, and high-quality glazes mainly composed of lime feldspar and silicate. Also, depending on the surface condition of the glaze, it can be classified into transparent oil, opaque oil, gloss oil, matte oil, crystalline oil, crack oil and the like. It can also be classified into blue, white, black oil, crude oil, wire oil, cobalt oil, oil per oil, iron oil, and oil remover depending on the coloring state. Also, according to the production method and the firing method, it is possible to classify the crude oil, the frit oil, and the salt water channel. Finally, it can be classified as pottery oil, magnetic oil, stoneware oil according to the result of firing. These glazes for ceramics add strength to the ore structure and serve to prevent contamination of the ore structure with many pores. Also, when ceramic glazes are mixed, resistance to water or chemicals may be increased due to the low glaze properties of the glaze.

Such an inorganic binder 5 may be about 5 to 40 wt% (wt%) of the ore structure 10 having a plurality of pores of 100 wt% (wt%). If the inorganic binder 5 is contained in an amount less than 5 wt% (wt%), the effect of improving the strength of the ore structure 10 having a plurality of pores may be insufficient. When the inorganic binder 5 contains an amount less than 5 wt% (wt%) because the inorganic binder 5 fills the space between the ore structure particles and maintains the bonding force between the particles, the ore structure having a large number of pores So that the bonding force of the base 10 can be weakened. On the other hand, if the inorganic binder 5 is contained in an amount larger than 40 wt% (wt%), the weight may become heavy and may not be suitable for use in the ore structure 10 having a large number of pores requiring light weight And the inorganic binder 5 is relatively hard, cracks may be generated in the ore structure 10 having a plurality of pores. In addition, when the amount is larger than 40 wt% (wt%) in the firing process, the firing process not only expands the thermal expansion but may also be a cost burden.

The ore structure 10 having such a plurality of pores may further include a coloring agent (for example, a coloring agent for ceramics) to realize a natural color. The coloring agent may be contained in an amount of about 5 to 20% by weight (wt%) based on the weight of the inorganic binder (5). When the coloring agent for ceramics is less than 5 wt% (wt%), the color of the ore structure having many pores may be deteriorated. On the other hand, when the coloring agent for ceramics is more than 20 wt% It should be noted that it may adversely affect the bonding or shape of the ore structure with many pores and many bubbles. As described above, by using a coloring agent for ceramics as a coloring agent, natural color can be maintained without discoloring easily even in a high-temperature firing process.

The ore structure having a plurality of pores may be formed by mixing a predetermined amount of water and an organic material binder in the manufacturing process, followed by compression and firing, in order to enhance their formability in the ore structure and the inorganic material. Of course, the water and organic binder is dried or removed in a high-temperature predetermined process, so that it remains in the ore structure having a large number of completed pores.

As described above, the present invention is not limited to the above-described embodiments, but may be applied to other embodiments of the present invention. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.

100; Mirror-type quantum energy irradiator
110; A frame part 115; handle
116; Switch 117; Power supply line
120, 220; Healing section
121; A first quantum energy irradiation board 121a; The heating unit
125, 225; The second quantum energy irradiation board
126, 226; Holes 130 and 230; Mesh

Claims (11)

A mirror type quantum energy irradiation device comprising a healing portion and a frame portion surrounding the healing portion,
A first quantum energy irradiation board having a heating part formed on one surface thereof; And
A second quantum energy irradiation board covering one surface of the first quantum energy irradiation board,
Wherein the second quantum energy irradiation board has a plurality of holes,
Wherein the first and second quantum energy irradiation boards are formed of an ore structure having a plurality of pores,
Wherein the ore structure having a plurality of pores comprises 60 to 95 wt% (wt%) of an ore structure and 5 to 40 wt% (wt%) of an inorganic binder,
Wherein the colorant further comprises 5 to 20% by weight (wt%) of a coloring agent based on the weight of the inorganic binder. The method according to claim 1,
Wherein the frame portion is formed to surround the remainder of the healing portion except the one surface. 3. The method of claim 2,
Wherein one surface of the healing portion is covered with a mesh. The method according to claim 1,
Wherein the frame portion is formed so as to surround the remainder of a surface of the heeling portion which is relatively wide and a second surface that is an opposite surface of the first surface. 5. The method of claim 4,
Wherein the first and second surfaces of the healing portion are covered with a mesh. The method according to claim 1,
Wherein the heating unit comprises a heating coil. The method according to claim 1,
Wherein a handle is further provided at a lower end of the frame portion, the knob including a switch for controlling power of the healing portion. 8. The method of claim 7,
Wherein the switch is formed of a capacitive touch sensor. delete delete The method according to claim 1,
Wherein the inorganic binder is a glaze or a frit.

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