JP6523960B2 - Hot spring mist suction facility - Google Patents

Description

  The present invention relates to a hot spring mist suction facility for applying a thermal therapy for warming the body from the core by far infrared radiation and improving blood circulation, and in particular, generating hot water mist containing mineral water Regarding the mist suction facility.

  Hyperthermia is a therapy that warms the body by far infrared rays and improves blood circulation. Thermal therapy is performed in the form of integrated therapy and the accompanying hyperthermia. 70% of the human body is made up of water. The water molecules that make up this moisture have the power to store energy. Therefore, using a thermal wave that reacts to water molecules, the body's ability to recover is greatly improved by warming it from the core with the vibrational energy of water molecules, without just heating the surface only.

  Originally, hyperthermia was a therapy that was developed focusing on the nature of cancer that is susceptible to heat, and is currently attracting attention all over the world. Germany's largest alternative therapy clinic, St. George Hospital, has reported clinical results demonstrating the superior effects of hyperthermia.

  The basic idea of hyperthermia is as follows. When a person is active for one day, cellular energy decreases. The reduced energy is recovered by eating, sleeping, resting and so on. It is necessary to improve recovery ability to maintain health. Therefore, it is necessary to warm up the body from the core and raise metabolism to improve blood circulation.

  Heretofore, several proposals have been made as an apparatus using mist.

  Patent Document 1 proposes a mist sauna private room using an ultrasonic mist generator for a bedrock bath. "I have provided a bedrock fan heater for blowing warm air on the inlet side of the hot air passage space, and the ultrasonic mist generator is a partitioned container having a mist generation tank and a water storage tank, and the mist generation tank An ultrasonic oscillator is provided on the bottom of the unit, and the fine mist of mist generated by the ultrasonic oscillator is sent from the mist tank cover that covers the upper part of the mist generation tank to the upper part of the simple assembly unit via the mist duct. It is proposed to "discharge the room from the provided mist outlet".

  Moreover, in patent document 2, the mist generating apparatus as a facial care apparatus is disclosed. In Patent Document 2, “during generation of mist, the cooling in the cooling unit and the electrolysis in the electrode are parallel to the liquid heated and sterilized by the heating unit or the mist before being discharged from the discharge port. It is characterized by the fact that

  Furthermore, in patent document 3, mist is produced | generated using the sprayer or the sprayer and the ultrasonic transducer together. Subsequently, Patent Document 4 discloses an invention of generating steam in a boiler to generate mist. On the other hand, in Patent Document 5, a water supply container is attached to a soot generator, the stored water is warmed to about 40 ° C. by a heater, two ultrasonic transducers 10 are operated, and the ultrasonic oscillator is fine. A mist of mist is generated. On the other hand, Patent Document 6 discloses the use of an ultrasonic device as a mist or as a vapor to increase the humidity of a circulating flow.

Patent No. 3872501 Patent No. 4915582 Patent No. 5064581 gazette Patent No. 3987502 Utility model registration 3124724 gazette Patent application publication Hei 3-49468 gazette

  By the way, a bedrock bath as shown by patent document 1 is examined. In a bedrock bath using a monolith, the wave is single because the bedrock is a monolith. For this reason, even if this bedrock is heated, the wave motion of the bedrock is single, so that the human body gets used to a single wave, and an antibody against a single wave can be made in the human body, and the far infrared effect is There was a problem that it faded. In addition, on the bedrock, bacteria are easily retained on the surface, and there is a problem in terms of hygiene. For this reason, it is necessary to be able to emit far infrared rays with different waves, and it is necessary to provide a material with less bacterial retention.

  In addition to the effect of far infrared rays in hyperthermia, the provision of minerals has a great cosmetic effect such as having a moisturizing effect on the skin. However, for example, in natural hot spring, the component combination is not blended according to the purpose, but exists at a blending ratio which happens to be present in the natural world, and the component of mineral varies depending on the hot spring. Was thin and not efficient for the purpose of aspirating minerals. For this reason, there is a need for a mineral solution that contains well-balanced minerals at an appropriate concentration and in a well-balanced manner.

  By the way, in the conventional thermal therapy, hot spring water was directly sprinkled to a bedrock etc. with a hose etc., and it evaporated using the heat of floor heating, etc., and raised indoor humidity. The applicants investigated the evaporation of the hot spring water by this method and found that the mass of the mineral is heavier than the water, does not evaporate, precipitates underground, and the component of the generated vapor is water. Yes, it did not contain any minerals. Therefore, the applicants needed to develop a method that can simultaneously evaporate mineral components. Moreover, there is also a problem in the patent document. For example, in the patent document 1, it is necessary to solve the problem about the wave of far infrared rays in the rock bath and the problem about retention of bacteria.

  In patent document 2, there is a need to clarify about control in the bathroom after releasing mist in the bathroom.

  Patent Document 3 needs to clarify how to control the environment and mist of the temperature and humidity in the bathroom from which the mist is released.

  In Patent Document 4, a solution containing a mineral is evaporated at a high temperature and a high pressure, and a method is employed in which sufficient mineral evaporation can not be expected. For this reason, it is necessary to solve the problem about the method of mineral evaporation.

  Patent Document 5 discloses only a method of generating mist, and does not sufficiently disclose a method of evaporating minerals.

  Patent Document 6 also discloses only the method of generating mist, and the method of evaporating minerals is not sufficiently disclosed.

  Therefore, an object of the present invention is to provide a material that can emit far-infrared rays having different wave motions and has less bacterial retention. In particular, by combining and using a plurality of optional far-infrared emitting materials, the vibration waveform of the far-infrared radiation is such that a plurality of waves overlap to obtain a resonance effect. As a result, far-infrared rays whose penetrability is amplified by the resonance action are rapidly conducted to the inside of the user's body, and an efficient far-infrared effect can be obtained, along with the "symmetry effect of far-infrared rays". The purpose is to realize the effects presented.

  The second object of the present invention is to provide a well-balanced mineral solution.

  Furthermore, the third object of the present invention is to allow bathing by steam containing minerals by sufficiently evaporating the minerals.

  Next, a fourth object of the present invention is to promote the diffusion of mist by introducing outside air when the diffusion of the mist is insufficient in the ultrasonic wave generator.

  Then, the fifth object of the present invention is to introduce the gas from inside the bathroom in order to be affected by the outside air temperature by introducing the outside air when the diffusion of the mist is insufficient in the ultrasonic wave generator. Heat exchange.

  In order to solve the object of the present invention, the hot spring mist suction facility according to the present invention comprises a mineral tank for producing a mineral solution, a mineral supply unit for transporting the mineral solution, and a mist generation for misting the transported mineral solution. It is a hot spring mist suction facility provided with a bathroom including a section, a heating section, and a gravel layer heated to the heating section,

  A mineral mist atmosphere containing minerals is introduced into the bathroom from the upper part of the bathroom as a mist formed in a state containing minerals, and the beaded gravel layer in the bathroom is wetted and then heated by the heating unit. Maintain a constant temperature and constant humidity.

  The mist may be supplied from the upper portion of the bathroom by arranging the mineral supply portion at the upper portion of the bathroom.

  Further, the mist may be supplied into the bathroom by the sending unit, and the air in the bathroom may be supplied into the bathroom by the sending unit.

  Furthermore, the mineral tank that produces the mineral solution may be preheated by the heating unit. Subsequently, the mist outlet in the bathroom may be in the vicinity of the floor in the bathroom.

  By applying the present invention, it is possible to emit far-infrared rays with different waves and to provide a material with less bacterial retention. By combining and using a plurality of optional far-infrared emitting materials, the vibration waveform of the far-infrared radiation is such that a plurality of waves overlap to obtain a resonance effect. As a result, far-infrared rays whose penetrability is amplified by the resonance action are rapidly conducted to the inside of the user's body, and an efficient far-infrared effect can be obtained, along with the "symmetry effect of far-infrared rays". The effect to be achieved can be realized.

  Also, by applying the present invention, a well-balanced blended mineral solution can be provided.

  Furthermore, by applying the present invention, it is possible to allow bathing with steam containing minerals by sufficiently evaporating the minerals.

  Next, by applying the present invention, the diffusion of mist can be promoted by introducing the outside air when the diffusion of the mist is insufficient in the ultrasonic wave generator.

  Subsequently, by applying the present invention, in order to receive the influence of the outside air temperature by introducing the outside air when the ultrasonic wave generator does not sufficiently diffuse the mist, the gas from the inside of the bathroom is introduced. Heat exchange can be performed.

It is a block diagram which shows the outline of the hot spring mist attraction facility of the 1st Embodiment of this invention. It is a block diagram which shows the outline of the hot spring mist suction facility of the 2nd Embodiment of this invention. It is a block diagram which shows the outline of the hot spring mist attraction facility of the 3rd Embodiment of this invention. It is a top view of the hot spring mist suction facility of the 3rd Embodiment of this invention. It is a longitudinal cross-sectional view of the hot spring mist attraction facility of the 3rd Embodiment of this invention. It is a layout drawing of the heating means of the hot spring mist suction facility of the 3rd Embodiment of this invention. It is a block diagram which shows the outline of the hot spring mist attraction facility of the 4th Embodiment of this invention. It is a block diagram which shows the outline of the hot spring mist attraction facility of the 5th Embodiment of this invention. It is a side view of hot spring mist suction facility 502 of a 6th embodiment of the present invention. It is a block diagram of rebar 520 and piping 522 of hot spring mist suction facility 502 of a 6th embodiment of the present invention. It is sectional drawing of AA crucible of hot spring mist attraction facility 502 of a 6th embodiment of the present invention. It is a top view of hot spring mist suction facility 502 of a 6th embodiment of the present invention. It is a top view of hot spring mist suction facility 502 of a 6th embodiment of the present invention. It is sectional drawing of the two-stage type drainage port 510 of the hot spring mist attraction | suction facility 502 of the 6th Embodiment of this invention.

  Next, an embodiment of a hot spring mist suction facility according to the present invention will be described in detail with reference to the drawings.

First Embodiment
FIG. 1 is a block diagram schematically showing a hot spring mist suction facility 2 according to a first embodiment of the present invention.

  In the hot spring mist suction facility 2, a mineral tank 4 for storing a mineral solution sprayed as a mist is disposed. The mineral tank 4 is connected to a faucet 8 via a pipe 6. The faucet 8 may be connected to a water supply, but may be a hot water faucet.

  The mineral tank 4 is provided with an opening 10 into which the mineral stock solution is injected. In the mineral tank 4, the mineral solution to be purified from the mineral stock solution and tap water is extracted directly from the minerals as a mineral-containing aqueous solution, and it is desirable to contain well-balanced minerals that are considered good for the body. The mineral solution (hot spring) to be used is a mineral group solution obtained by dissolving and extracting 20 types of minerals from mineralized vermiculite (VERMICULITE), which is a weathered body of biotite, and contains no organic matter.

  The applicant has found that corroded granite produced from the Abukuma mountain area in Fukushima Prefecture contains dozens of types of mineral components in a well-balanced manner, and the minerals contained become a mineral solution extracted in the form of ions that are easily absorbed by the living body There is.

The mineral solution used for the hot spring mist suction facility according to the present invention is a single substance, and the chemical classification is sulfated of various minerals. The components and standard contents (g / L) of Fe are 10.5 (g / L) (however, as Fe ₂ (SO ₄ ) ₃ ), Al is 9.2 (g / L) (however, Al ₂ ) (As SO ₄ ) ₃ ), Mg is 3.7 (g / L) (as MgSO ₄ ), K is 1.9 (g / L) (but as K ₂ SO ₄ ), H ₂ SO ₄ is 51. 1 (g / L) and contains dozens of other minerals.

  It also contains dozens of other minerals (see the component analysis table). Statistical item number (HS No.): 3824, 90-900 (chemical industry product), standard international commodity classification (SITC): 523-19 (inorganic chemical product), UN number: Item No. 66 UN No. 2796 (A substance containing a low concentration of sulfuric acid).

  Minerals are also classified as aqueous solutions containing acidic minerals and the hazard is not corrosive to human skin due to low free sulfuric acid (approximately 5%). Harm is harmless. Contains no harmful heavy metals (see component analysis chart). The environmental impact is a water purification agent and does not affect any natural environment. This has been demonstrated in toxicity tests on white medaka.

  In addition, physical / chemical properties, appearance is a brown liquid. The specific gravity is 1.15 to 1.16, the pH is 0.5 to 1.0, the boiling point is 100 ° C., the freezing point is −10 ° C., and the solubility (water) is It is 100% (10 ° C.).

  Furthermore, as the hazard data, there is no explosion point (for aqueous solution), no flammability (for aqueous solution), no flammability (for aqueous solution), no explosive (for aqueous solution), no dust explosive (for aqueous solution) Per aqueous solution).

  In addition, as harmful data, none is corrosive to the skin, and irritation is irritating to the damaged skin. On the other hand, no sensitivity, no acute toxicity, no quasi-acute toxicity, no chronic toxicity, no carcinogenicity, no mutagenicity and no teratogenicity.

  Furthermore, in environmental data, degradability is none, accumulation is none. Next, Table 1 shows the content of each component.

  Also, the toxicity to fish is none (but it is necessary to be careful of pH for acidity).

The analytical method adopted is atomic absorption spectrometry for K, Na, Li, BaSO ₄ weight method after oxidation with bromine, and others, using high frequency inductively coupled plasma emission spectrometry (ICP) It is done.

  In addition, in the content of harmful heavy metals (inspection results of the Tokyo Metropolitan Food Sanitation Association), arsenic is not detected, nor is it detected for lead. In addition, cadmium is not detected. Other than that, total mercury is not detected.

  The mineral tank 4 containing the mineral solution is connected to the mineral supply unit 14 through the connecting pipe 12.

  The mineral supply unit 14 is a normal pump, and is an apparatus for supplying the mineral solution in the mineral tank 4 to the mist generation unit 18.

  The mist generation unit 18 is connected to the mineral supply unit 14 via the connection pipe 16. The mist generation unit 18 is connected to the bathroom 30 via the mist pipe 28. Here, when the mist generation part 18 is arrange | positioned in the upper part of the bathroom 30, supply of mist can be performed by shortest distance. Also, mist can be released from the top of the bathroom 30.

  The mist generating unit 18 includes a mineral solution bowl 20 inside.

  The mineral solution reservoir 20 stores the mineral solution delivered via the connection pipe 16. The storage volume of the mineral solution of the mineral solution bowl 20 is controlled by the float switch 22. The float switch 22 is floated in the mineral solution bowl 20, and when the amount of the mineral solution falls below a predetermined amount, the float switch 22 is turned on and transmitted to the mineral supply unit 14 connected by the signal line 24 to mineral the mineral solution. The supply to the solution tank 20 is started. Conversely, when the mineral solution exceeds a predetermined amount, the float switch 22 is turned off and transmitted to the mineral supply unit 14 connected by the signal line 24, and the supply of the mineral solution to the mineral solution tank 20 is stopped.

  The vibrator 26 is disposed at the bottom of the mineral solution bowl 20. The vibrator 26 incorporates a piezoelectric ceramic element or the like therein, and is set to vibrate around 2 MHz, whereby the mineral solution can be misted while containing minerals. The misted mineral solution is supplied to the bathroom 30 through the mist tube 28.

  In conventional facilities, hot spring water containing minerals was directly sprayed on gravel with a hose, and the room humidity was raised by using the heat of floor heating to elevate the indoor humidity, but the mass of mineral is heavier than water Deposited underground, most of the components of the steam were water.

  In order to solve this problem, the applicant has applied the principle of ultrasonic humidification to refine the mineral solution to several microns and developed a technology to feed it directly into the room with a fan.

  When a piezoelectric ceramic vibrator is placed on the bottom of mineral solution pot 20 and a high frequency AC voltage is applied to it, the generated vibrational energy is transmitted to the water surface, and under certain conditions, part of the water surface is raised. , A fine mist is generated from there. The mist generating unit 18 of the present invention generates fog since the resonance frequency is extremely high.

  The optimal conditions such as size, thickness, frequency, sound pressure, and water depth of the piezoelectric vibrator are determined, and the piezoelectric vibrator is set to maximize atomization efficiency by installing the vibrator not horizontally but slightly. There is.

  The mineral solution supplied from the mineral tank 4 to the mist generation unit 18 is kept at a constant water level by the float switch 22, and a vibrator 26 is installed at the bottom of the mineral solution crucible 20. When a high frequency voltage is applied from the drive circuit, the piezoelectric vibrator functions as an ultrasonic vibrator, and its vibrational energy is concentrated on the water surface, the water column stands up, and the surface of the water column has significantly reduced surface tension Splashes. This is sent out as a mist of minerals by the air flow of a blower fan (not shown). The mist particles of the mist generating portion 18 are extremely fine, such as several microns (μm), so that the thermal effect of the present invention makes it possible to effectively penetrate pores into the capillary and the body in which metabolism is activated. .

  The bathroom 30 is provided with an opening of a mist tube 28 at the top so as to release a mist containing a mineral. On the other hand, a heating unit 34 is provided on the floor portion which is the lowermost end of the bathroom 30. The heating unit 34 is provided with an electric heater or a pipe for hot water, and is configured to be able to heat the inside of the bathroom 30 so that the room temperature is 40 ° C. to 50 ° C., preferably 45 ° C.

  A ball gravel layer 32 is provided in the upper layer of the heating unit 34. A faucet 36 is provided in a part of the bathroom 30, and water is sprayed from the surface to the extent that the surface of the gravel layer 32 gets wet from there, the water evaporates from the surface of the gravel layer 32, and the humidity is combined with the mist containing minerals. Is set to be 70% to 90%, more preferably 80%.

  Further, a temperature sensor 38 is provided on the inner wall of the bathroom 30. The temperature sensor 38 is connected to the heating source unit 42 by a wire 40. The heating unit 34 and the heating source unit 42 are connected by a connecting unit 44. If the heating unit 34 is an electric heater, the heating source unit 42 is a power supply, and the connection unit 44 is a conductive wire. On the other hand, if the heating unit 34 is a hot water pipe, the heating source unit 42 is a water heater and the connecting unit 44 is a pipe. Here, assuming that the set temperature is 45 ° C., the heating source portion 42 is set to heat the heating portion 34 when it is lower than the room temperature 45 ° C. When the heating source portion 42 is higher than the room temperature 45 ° C. Stop heating. That is, when the heating unit 34 is an electric heater, the power source is controlled to be driven and stopped by the value of the temperature sensor, and if the heating unit 34 is a hot water pipe, the water heater heats the water heater by the value of the temperature sensor. And stop controlled.

  Here, the bedrock bath using the conventional monolith has the problem that the body gets used to the wave due to the stone with a single wave, the antibody is made, and the far-infrared effect becomes thin. Was. In addition, bacteria are easily retained on the bedrock and there is also concern from the viewpoint of hygiene.

  Therefore, the applicants made it possible to prevent habituation to the body by emitting far-infrared rays of different waves by graveling the rock and blending different stones according to each feature. In addition, it is possible to exert excellent effects from the viewpoint of hygiene because the whole gravel can be washed with a high pressure washer. Furthermore, the bather lays buried in a pebble gravel, so he was able to achieve the comfort of sleeping with the effect of pressing the acupressure on the body properly.

  Far infrared radiation is a type of electromagnetic wave, and is defined as having a wavelength of 4.0 to 25 μm (micrometer).

  Far infrared is not heat. Far-infrared rays are easily absorbed by organic matter by radiative transfer, and vibration energy is given to the molecules of the organic matter to move and heat is generated by the heat of the molecules themselves. Far-infrared rays are also called "growing rays", and have the feature that they penetrate the deep subcutaneous layers of the human body and cause cells to resonate to warm the body mildly, and also make it difficult to cool. When the temperature rises, capillaries are expanded, blood circulation is improved, and the natural healing power inherent to the human body such as cell metabolism and increased immune power is enhanced.

  In addition, the jade gravel layer 32 is, as jade gravel, a boiled stone, radium ore, tourmaline, diorite, basalt volcanic rock, germanium ore, Takachihoishi / amaterite, atenjuite, senchaite and fossil ocher, or part of them Or use all combinations.

  Specifically, in the case of barley-boiled stone, a mineral that has been greatly affected by energy of crustal movement about 70 to 50 million years ago is formed with the force of ultra-high pressure and ultra-high temperature added. Because of the special formation of barley stone, it is mined at only a few places around the world and is a very rare and valuable natural ore. Because it is porous, it is a stone that adsorbs the calcium component (chlorine) and bacteria of tap water, dissolves abundant mineral components, and has a strong far-infrared radiation intensity.

  Radium ore is a rock containing radium, which is an alkaline earth metal and was discovered in 1898 by the Curie and wife. There is no stable isotope, and all four isotopes are radioactive elements, of which the longest half-life radium 226 alpha decays to radon 222 (gas).

  The color of radium ore is silver white and is included in rocks and hot springs. A hot spring that contains radioactive elements such as radium, radon and tron in the hot spring component is called a radiation spring. It is called radium hot spring, radon hot spring, etc. depending on the radioactive element content of the hot spring.

  Tourmaline is a Japanese name called tourmaline, and weak heat flows when heat and pressure are applied from the outside. Unlike tourmaline which has lost its shape, tourmaline which retains its crystalline form is called a polar crystalline body, and is provided with a negative electrode on one side and a positive electrode on the other side.

  In other words, because it is a crystal body equipped with this electrode, it works efficiently for the electrical action.

  Ikuishi is a natural ore that is produced with the bottom sediment containing the ingredients in the sea and has appeared on the ground by crustal movement after a long time. It is rich in porosity and contains a good balance of high-quality mineral components, among which 33% of soluble silica is contained, and when this silica dissolves, minerals also dissolve together. It is most suitable for improving water quality and producing reduced water, and is also used as a raw material for water purifiers of various companies. Further, in recent years, far infrared radiation, mineral elution and reduction action are expected.

  The basaltic volcanic rock is excellent in adsorption of moisture and harmful substances, adsorption of odors, soundproofing and heat resistance.

  In germanium ore, germanium is a semiconductor located between metal and nonmetal, and it becomes a conductor that conducts electricity at 32 ° C. or higher due to the effects of energy such as light and heat. The germanium electrons that have become conductors become free electrons and become actively active, and work as negative when the other is positive electricity and as positive when the other is negative electricity. In humans, a very weak current, which is a biocurrent, flows, and germanium efficiently works on this biocurrent.

  In Takachihoishi / Amaterite, Takachihoishi's radiant energy is a kind of far infrared rays with an electromagnetic wave of 4 to 14 microns. It has been found that this works very effectively for the growth of animals and plants and the physiological activity of life.

  In particular, the content of silicon dioxide is high, causes quartz (oscillation) like quartz and quartz, resonates the water molecules in our body by resonance, improves the metabolic function by promoting blood circulation, and raises the body temperature by raising the immune system. It is said to be Furthermore, treatment of atopic dermatitis, improvement of cold, bathing materials, etc. are widely used.

  Tenjuseki is a natural stone from Korea, and the area with Mt. Moonguksan in Korea has valleys and lakes, and is a magnificent area full of natural beauty. Tennjuseki is produced from the stratum of this area, and mineral As well as being superior in components, it is used in various fields because the far infrared emissivity is high, and in particular the wave number is exceptionally superior.

  Chiakashi is a natural stone produced from the soil at the foot of the Peacock Mountain in Korea, and is known as an ore with excellent far infrared emissivity and wave numbers. In addition, the water that has flowed through this rock is used as water with excellent mineral balance.

  Fossil yellow soil is a natural ore which is excellent in humidity control and adsorption of harmful substances and has a far-infrared effect, and is most frequently used in far-infrared saunas.

  The operation of the present invention in the above configuration will be described.

  The water supplied from the faucet 8 is introduced into the mineral tank 4 through the pipe 6 and mixed with the mineral stock solution injected from the opening 10 at a predetermined mixing ratio to generate a mineral solution. Ru.

  The mineral solution is introduced into the mist generation unit 18 by the mineral supply unit 14. The mineral supply unit 14 introduces the mineral solution into the mineral solution vessel 20 in detail, but supplies it according to the signal from the float switch 22 provided in the mineral solution vessel 20. The float switch 22 transmits a supply-necessitating signal to the mineral supply unit 14 when the amount of mineral solution in the mineral solution tank 20 falls below a predetermined amount, and the mineral supply unit 14 delivers the mineral solution.

  The mineral solution introduced into the mineral solution crucible 20 is misted by the vibrator 26.

  The generated mist is introduced into the bathroom 30 via the mist tube 28. In the bathroom 30, the gravel layer 32 is heated by the heating unit 34 and is heated by thermal radiation by far infrared rays. The temperature adjustment is adjusted by feedback of the temperature sensor 38 and its signal to the heating source unit 42.

  On the other hand, with regard to the humidity, the water from the water faucet 36 wets the gravel layer 32, and as a result, the water evaporates to be humidified, and the humidity is controlled to be 80%.

  By operating as described above, it is possible to easily introduce mist into the bathroom 30 without using power.

Second Embodiment
FIG. 2 is a block diagram schematically showing a hot spring mist suction facility 102 according to a second embodiment of the present invention.

  The same reference numerals as those in the first embodiment denote the same two lower digits as those in the first embodiment, and a description of the same will be omitted.

  The second embodiment will be described focusing on differences from the first embodiment. The second embodiment is an embodiment in which the mineral tank 104, the mineral supply unit 114, and the mist generation unit 118 are disposed not in the upper part of the bathroom 130 but in an adjacent place or the like. In this case, in order to transfer the mist over a long distance, a certain pressure is required to generate the mist flow. Therefore, in the second embodiment, the air flow pipe 150 is joined to the mist pipe 128, and the mist flow is sent out from the opening end 129 provided on the upper wall of the bathroom 130.

  For this reason, as a configuration, the introduction pipe 146 for the outside air is connected to the blower unit 148, and the blower unit 148 is connected to the blower pipe 150. The blast tube 150 may be connected to the mist tube 128 using a wye to reduce pressure loss. In addition, since the pressure of the blowing unit 148 can be used, the mist generated by the mist generating unit 118 can be transferred to the bathroom 130.

Third Embodiment
FIG. 3 is a block diagram schematically showing a hot spring mist suction facility 202 according to a third embodiment of the present invention.

  The same reference numerals as in the second embodiment denote the same two lower digits in the instruction number, and a description of the same components will be omitted.

  The third embodiment is different in that the air blown from the outside air in the second embodiment is introduced from the windbreak chamber 252 adjacent to the bathroom 230. When the outside air temperature is used to blow the mist when the outside air temperature falls in winter, two problems occur because the mist temperature is lowered. The first issue is the reduction of the temperature of the bathroom 230. It interferes with maintaining the room temperature at 45 ° C. The second point is an increase in the vapor component in the mist. Since the amount of saturated water vapor decreases due to the decrease in temperature, the steam component increases.

  Therefore, in the same waterproof state as the bathroom 230, a windbreak chamber 252 is provided adjacent to the passage to the bathroom 230, and is separated by the door 254. For this reason, the inside of the windbreak chamber 252 is extremely close to the room temperature of the bathroom 230. For this reason, it is possible to minimize the decrease in the temperature of the mist and to reduce unnecessary steam components.

  FIG. 4 shows a top view of the hot spring mist suction facility in the third embodiment. In particular, the details of the heating unit 234 will be described.

  The heating unit 234 includes a water heater 242, a pipe 2342 and a pipe 2344, and is disposed at the bottom of the bathroom 230 in a bellows shape. A water supply pipe 2322 and a gas pipe 2324 are disposed in the water heater 242.

  Further, FIG. 4 shows that the windproof chamber 252 adjacent to the bathroom 230 is connected to the air blowing unit 248 by the introduction pipe 246, and the air flow pipe 250 is connected to the mist pipe 228.

  FIG. 5 shows a longitudinal sectional view of the hot spring mist suction facility of the third embodiment. In FIG. 5, the FRP plate 259 is disposed in the lowermost layer, and the urethane 258 is disposed in the upper layer thereof for heat insulation. Reinforcing bars 2352 are arranged in a grid shape in the upper layer of the urethane 258. The pipe 2346 and the pipe 2342 are disposed along the rebar 2352 at the top thereof, and fixed at the grid points at each grid point. All of these are fixed with concrete. After the concrete floor is generated, a gravel layer 232 is placed thereon.

  For the wall surface, a urethane layer 244 is provided inside the outermost layer, a stud layer 249 is provided inside thereof, a plywood 247 is disposed inside thereof, and a kitchen panel is disposed inside thereof.

  In addition, rebar 2352 and piping 2354 and 2346, 2348, 2342, 2344 are arranged in a grid like rebar 2352, while piping is arranged the same as the grid, but piping with only one pipe Rather, it can be seen that a plurality of pipes form a grid-like arrangement.

Fourth Embodiment
FIG. 7 is a block diagram schematically showing a hot spring mist suction facility 302 according to a seventh embodiment of the present invention.

  The same reference numerals as those in the third embodiment denote the same two lower digits in the instruction number, and a description of the same components will be omitted.

  The difference from the third embodiment is that the mineral tank 304, the mineral supply unit 314, and the mist generation unit 318 are embedded in the bead gravel layer 332. In the previous embodiment, the mineral tank 304, the mineral supply unit 314, and the mist generation unit 318 are all disposed outside, and a decrease in temperature is expected in winter. Therefore, by disposing the mineral tank 304, the mineral supply unit 314, and the mist generation unit 318 in the gravel layer 332, the temperature drop of the mineral solution can be minimized.

Fifth Embodiment
FIG. 8 is a block diagram schematically showing a hot spring mist suction facility 402 according to a fifth embodiment of the present invention.

  The same reference numerals as those in the third embodiment denote the same two lower digits in the instruction number, and a description of the same components will be omitted.

  The difference from the fifth embodiment is the position of the open end 456 of the bathroom 430. The ends are open near the floor of the bathroom 430. For this reason, the customer etc. can be directly exposed to the mist containing mineral.

  In another embodiment, a waterproof speaker is provided in the bathroom, connected to an amplifier and a music media playback device, and the bathroom is used by playing music or any sound generated in the actual forest recorded in the forest. You may enhance the healing effect of Specifically, in order to enhance the healing effect by hearing, further effects can be obtained by listening to the sound of the forest live while lying on the bathroom floor with reference to the German Kneipp therapy. As a result, by listening to live forest sounds lively, stress hormones decrease firstly. In addition, parasympathetic activity is enhanced. In addition, sympathetic nerve activity is suppressed. In addition, systolic and diastolic blood pressure and pulse rate decrease. In addition, psychological tension will be relaxed and liveliness will increase. Subsequently, the NK activity is increased and the immunity is raised. Finally, anti-cancer proteins are increased.

Sixth Embodiment
FIG. 9 shows a side view of the hot spring mist suction facility 502 according to the sixth embodiment of the present invention.

  In the hot spring mist suction facility 502, a pillar 508 supports a beam 506 on a base 504. On the base 504, a heat insulator 512 inclined to the two-stage outlet 510 is placed. The upper surface of the heat insulating material 512 is formed with a waterproofed surface (FRP) 514 that is waterproofed, provided with a relay drain 516 of the two-stage drainage port 510, and collected by the waterproofed surface (FRP) 514 Are configured to flow to the relay drain 516. Further, on the upper side of the waterproofed surface (FRP) 514, a heat insulating material 518 in which an admixture and a concrete are mixed is provided. Rebars 520 (not shown) are provided on the top surface of the heat insulator 518, and pipes 522 (not shown) are provided. Details will be described separately. The use of thermal insulation can reduce the escape of heat from the floor. The combination of FRP waterproofing and mixed waterproofing will enhance the waterproofing function. It also serves as a measure against concrete cracks.

  A concrete layer 524 is further placed on the heat insulating material 518, the reinforcing bars 520, and the piping 522. The thickness of the concrete layer is preferably about 7 to 10 cm. A waterproof surface (FRP) 526 is provided on the upper surface of the concrete layer 524, an upper drain 528 of the two-stage drainage port 510 is provided, and the drainage collected on the waterproof surface (FRP) 526 is collected in the upper drain 528. Water is discarded. Therefore, the waterproofed surface (FRP) 526, the concrete layer 524, the reinforcing bars 520, the heat insulating material 518 and the waterproofed surface (FRP) 514 are all 0.1% to 5%, preferably 0.5% to 3% or so It has a slope. For this reason, it is easy to flow sebum dirt etc. The functional gravel 530 is mounted on the waterproof surface (FRP) 526 so that the upper surface is flat. It is also possible to improve the flow of sebum dirt by laying a gauze or wire mesh under the functional bead gravel 530.

  The heat insulating material 532 is provided on the indoor side of the column 508 in the wall surface of the hot spring mist suction facility 502, and two panels 534 are stacked on the indoor side so that their joints do not overlap each other.

  A warm water mist machine 536 is disposed on the lower side wall of the upper side wall of the two-stage drainage port 510. A high concentration mineral mist device 538 is disposed immediately above the warm water mist device 536.

  The hot water mist machine 536 is a mist machine capable of controlling the temperature by the hot water supplied and supplied constantly. In order to maintain the room temperature, it is preferable that the supply capacity is higher than that of the high concentration mineral mist machine 538. By directly supplying hot water, it is possible to prevent a drop in room temperature. In addition, since hot water can be supplied, piping can be shared with maintenance faucets and the like. Moreover, since high concentration minerals are not used, the deterioration of the warm water mist machine can be reduced, and the frequency of maintenance can also be reduced.

  The high concentration mineral mist device 538 is a mist device dedicated to high concentration minerals at normal temperature, but constantly generates high concentration mineral mist by replenishing high concentration mineral water adjusted to an appropriate concentration. By using the high concentration mineral mist device 538 as a dedicated device, adjustment and replacement can be freely performed without affecting the hot water mist device 536 even when the high concentration mineral corrodes or degrades the mist device.

  These mist machines are connected to the maintenance faucet 544 from an external water source 540 through a pipe 542. Further, the external water source 540 is connected to the water heater 548 through a pipe 546. The water heater 548 is further connected to the maintenance hot water plug 552 and the hot water mist machine 536 through a pipe 550. That is, one water heater 548 can supply the maintenance hot water plug 552 and the hot water mist machine 536. In addition to the external faucet, a high pressure cleaning device may be provided to improve the efficiency of maintenance.

  In the wall surface different from the two mist machines, the air supply ventilating port 554 and the exhaust air vent 556 are provided at the same height at a position higher than that of the mist machine with a certain interval. The air supply vent 554 supplies external air, and the exhaust air vent 556 exhausts indoor air. Although not shown, the motor of the eye of the fan for ventilation can be provided in a pipe communicating with the ventilation port to facilitate replacement at the time of deterioration due to high concentration mineral. The ventilation fan can prevent temperature drop at the time of air supply and exhaust by being able to control independently by air supply and exhaust.

  Heat exchange may be performed instead of the air supply and exhaust.

  The ceiling 558 is configured to be inclined to the opposite side of the waterproof surface (FRP) 526 to the side opposite to the misting machine. The outer surface of the ceiling 558 is also a waterproofed surface 560 which is waterproofed, a panel 562 is provided on the beam side, and a heat insulator 564 is provided on the inner side of the panel 562.

  Subsequently, the detailed configuration will be described using FIGS. 10 to 14. The configuration of the floor will be described using FIGS. 10 and 11. FIG. 10 shows the configuration of the reinforcing bars 520 and the piping 522, and the reinforcing bars 520 are arranged in a lattice shape on the heat insulating material 518. The pipe 522 is a pipe for heating ball gravel, and is connected to a hot water boiler (not shown) and has a function of heating ball gravel. The pipes 522 are arranged in a bellows shape, provided that the pipes do not intersect with each other. By arranging in this way, it is possible to provide piping that is minimal to maintain temperature. For this reason, the warm water to be supplied to the piping can be minimized, and the fuel cost can be reduced.

  FIG. 11 is a cross-sectional view taken along the line AA ′ ′ of FIG. 10, in which the piping 522 and the reinforcing bars 520 are vertically disposed, the waterproofing surface (FRP) 514 is provided on the heat insulating material 512, and A heat insulating material 518 and a reinforcing bar 520 mixed with each other are provided, and further, a pipe 522 is disposed in the concrete layer 524. A waterproof surface (FRP) 526 is provided on the upper layer thereof, and a functional gravel 530 is provided thereon. Is placed.

  FIG. 12 is a top view of the hot spring mist suction facility 502. A blast chamber 566 is provided adjacent to the bathroom 501. A high concentration mineral mist machine 538 is provided on one side of the bathroom 501, and an air supply vent 554 and an exhaust air vent 556 are provided on the side different from the side. Outside air supplied from the air supply vent 554 circulates in the bathroom 501 and is exhausted from the exhaust air vent 556 as indicated by the arrow. Further, the air chamber 566 is provided with an internal port 568 communicating with the bathroom 501 and an external port 570 communicating with the outside. In the present embodiment, air supply and exhaust are not piped to the air removal chamber. It is possible to prevent the release of high concentration mineral mist from the air blast chamber to the outside and the condensation.

  FIG. 13 is a top view of the hot spring mist suction facility 502. It is a figure especially showing a gravel and a partition.

  The customer space can be clarified by providing a partition 572 such as a board in order to make the space for one person clear with respect to the gravel. Furthermore, it is possible to arrange a plurality of types of gravels 574 and 576 by dividing them by the partition 572 and arrange the gravels according to the preference of the customer. As functional ball gravels, it is also possible to adopt tori, blue stone, radium ball. Furthermore, by providing a panel 578 such as a lattice on the partition, the space of the individual can be further clarified. It is possible to take measures against deterioration by painting glass paint on the partitions. The division space can be divided into a personal space of about 1.8 square meters and a family of about 3.3 square meters for two people and further for a family of about 7 square meters.

  FIG. 14 is a cross-sectional view of the two-stage drain 510. The two-stage drainage port 510 includes a relay drain 516 and an upper drain 528. In the relay drain 516, a dropper 580 of the upper drain 528 is inserted at the center, and a doughnut-shaped relay drain cap 584 in which a plurality of relay drain holes 582 are opened is provided around it. A relay drain 586 is provided under the relay drain cap 584, and a relay dropper 588 opens at a lower portion of the relay drain 586 to communicate with the sewage outlet. The level of the relay drain cap 584 coincides with the waterproof surface (FRP) 514.

  The upper drain 528 is provided with a circular upper drain cap 592 in which a plurality of upper drain holes 590 are opened, and an upper drain 594 is provided under the upper drain cap 592. At the center of the upper drain 594, a dropper 580 connected to the relay drain 516 is provided. The level of the upper drain cap 592 coincides with the waterproofed surface (FRP) 526. Providing the waterproof layer in two steps makes it possible to prevent condensation occurring in the heat insulating layer.

  In the above configuration, the operation of the sixth embodiment will be described. The bathroom 501 heats the functional gravel 530 with the hot water circulating in the pipe 522.

  On the other hand, the mist generated by the hot water mist generator 536 is also generated from the hot water to heat the inside of the bathroom 501. On the other hand, the high concentration mineral mist machine 538 generates a normal temperature high concentration mineral mist containing a high concentration of minerals. Since the high concentration mineral mist machine 538 is disposed on the warm water mist machine 536, the warm water mist generated by the warm water mist machine 536 and the high concentration mineral mist mix and fill the room. In this way, the room temperature can be raised without supplying warm water directly to the high concentration mineral mist machine 538, so even if the outside temperature drops in winter, the high concentration mineral is not reduced. Can supply mist. Further, by separately using the high concentration mineral mist machine 538 and the hot water mist machine 536, the load on the mist machine can be reduced and the maintenance load can be reduced.

  Note that room temperature and humidity can be reduced by ventilating with the air supply vent 554 and the exhaust air vent 556 when the room temperature and humidity rise.

DESCRIPTION OF SYMBOLS 2 hot spring mist suction facility 4 mineral tank 6 piping 8 faucet 10 opening part 12 connection pipe 14 mineral supply part 16 connection pipe 18 mist generation part 20 mineral solution 漕 22 float switch 24 signal line 26 vibrator 28 mist pipe 30 bathroom 32 gravel Layer 34 Heating section 36 Water faucet 38 Temperature sensor 40 Wiring 42 Heating source section 44 Connection section 102 Hot spring mist suction facility 104 Mineral tank 114 Mineral supply section 118 Mist generation section 128 Mist pipe 129 Open end 130 Bathroom 146 Introduction pipe 148 Blower section 150 Blower tube 202 Hot spring mist suction facility 228 Mist tube 230 Bathroom 232 gravel layer 234 Heating portion 242 Water heater 246 Introduction tube 244 Urethane layer 249 Stud layer 247 Plywood 248 Blower portion 250 Blow tube 252 Windbreaker room 254 Door 259 FRP plate 258 Urethane 2 42 piping 2344 piping 2322 water supply piping 2324 gas piping 2346 piping 2348 piping 2350 bansen 2352 rebar 2354 piping 302 hot spring mist suction facility 304 mineral tank 314 mineral supply unit 318 mist generation unit 332 ball gravel layer 402 hot spring mist suction facility 430 bathroom 456 opening End 501 Bathroom 502 Hot spring mist suction facility 504 Base 506 Beam 508 Pillar 510 Two-stage outlet 512 Heat insulation material 514 Waterproof surface (FRP)
516 relay drain 518 insulation 520 rebar 522 piping 524 concrete layer 526 waterproof surface (FRP)
528 Upper drain 530 Functional gravel 532 Thermal insulation 534 Panel 536 Hot water mist machine 538 Mist machine 540 for high concentration mineral External water source 542 Piping 544 Maintenance faucet 546 Piping 548 Water heater 550 Piping 552 Hot water faucet 554 Vent for air supply 556 Exhaust vent 558 ceiling 560 waterproof surface 562 panel 564 insulation 566 air vent 568 internal vent 570 external vent 572 divider 574, 576 gravel 578 panel 580 drop outlet 582 drain hole 584 relay drain cap 586 relay drain 588 relay Overhead 590 Upper drainage hole 592 Upper drain cap 594 Upper drainage port

Claims (6)

A hot spring mist suction facility comprising a bathroom including a mineral mist generation unit for forming a mineral solution into a mist, and a heating unit and a pebble layer heated to the heating unit,
The mist solution containing minerals is misted and supplied to the bathroom from the upper part of the bathroom, and after moistening the gravel layer in the bathroom and heating by the heating unit, the mist atmosphere containing minerals has a constant temperature and constant temperature Maintain the humidity,
A mist pipe coupled to the mist generation unit and an air duct coupled to the windbreak chamber adjacent to the bathroom and coupled to the blower unit are coupled to supply mist into the bathroom;
It is further equipped with a hot water mist generator that can be supplied with hot water and whose temperature can be controlled by the hot water,
A hot water mist generator is placed under the mineral mist generator,
The bathroom has an air vent and an air vent inside the bathroom.
A hot spring mist suction facility characterized by providing a waterproofed surface in a bathroom directly below gravel and a first waterproofed surface and a second waterproofed surface under a heating unit .   2. The hot spring mist suction facility according to claim 1, further comprising: a mineral tank that generates a mineral solution; a mineral supply unit that transfers the mineral solution; and a mist generation unit that mists the transferred mineral solution.   The hot spring mist suction facility according to claim 2, wherein the mist is supplied from the upper part of the bathroom by arranging the mineral supply part in the upper part of the bathroom.   The hot spring mist suction facility according to claim 2, wherein the mineral tank for producing the mineral solution is preheated by the heating unit.   The hot spring mist suction facility according to claim 2, wherein the mist outlet in the bathroom is in the vicinity of a floor in the bathroom. The hot spring mist suction facility according to claim 1, wherein a first drain is connected to the first waterproof surface, and a second drain is connected to the second waterproof surface.