JP2008212276A - Blood flow increasing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a blood flow increasing apparatus capable of economically increasing a blood flow amount and demonstrating a medicinal effect. <P>SOLUTION: By the blood flow amount increasing apparatus 39, in an artificial carbonated spring improvement unit 4, carbon dioxide nanobubbles are contained in bathtub water by the nanobubble generator 42 of a first tub 6. Calcium carbonate minerals 16 filled in a second tub 7 are dissolved by the carbon dioxide nanobubbles contained in the bathtub water, and dissolution of calcium ions and magnesium ions is accelerated. Thus, there is the effect of improving the generation efficiency of nanobubbles. Since the bathtub water containing the carbon dioxide nanobubbles is introduced from the artificial carbonated spring improvement unit 4 to a bathtub 1, a blood flow amount increasing action by the carbon dioxide nanobubbles is demonstrated by bathing in the bathtub 1. Medicinal components of galenicals 22 in a third tub 8 are dissolved in the bathtub water and various kinds of medicinal actions by the medicinal components are demonstrated. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a blood flow increasing device, and, for example, relates to a blood flow increasing device that is effective for various diseases by increasing the blood flow rate using extremely fine bubbles of carbon dioxide gas.

  Conventionally, there is a medical finding that carbonated springs increase blood flow. Hot springs containing about 1000 ppm of carbon dioxide gas typified by carbonated springs exist in Europe, particularly in Germany, and have long been used as carbonated springs for various medical treatments.

  In Japan, there are no hot springs that contain about 1000 ppm of carbon dioxide, so it is possible to cope with any disease, that is, there are no hot springs that can be medically treated, but MRC Home Products Co., Ltd. An apparatus for producing bathtub water (artificial carbonated spring) containing carbon dioxide at a high concentration of 1000 ppm or more has been developed. The structure and function of this device is a device that dissolves carbon dioxide gas in bathtub water using a semipermeable membrane that allows only gas to pass through without passing through water, and a multilayer composite hollow fiber membrane.

  In Japan, it is said that there are about 8 million diabetic patients whose blood flow is poor. When diabetic complications lead to kidney artificial dialysis or gangrene caused by blood flow deterioration near the end of the foot. There are cases of amputation.

  Here, as a method of improving when the blood flow of a person's foot has deteriorated, a bathtub system that increases the blood flow by generating a micro-nano bubble by installing a large number of swirl flow micro-nano bubble generators can be considered. . As a specific example, there is an experimental example in which ten swirling flow type micro-nano bubble generators are installed in order to exert an effect of increasing a desired blood flow rate.

  However, in this type of bathtub system, it is necessary to install as many as 10 micro / nano bubble generators. This adds to the problem of bathtub space and increases the cost of the bathtub, which is not a realistic system.

  By the way, as a utilization method and apparatus of nanobubbles as a conventional technique, there is one described in Japanese Patent Application Laid-Open No. 2004-121962.

  This technology utilizes the characteristics of nanobubbles such as reduction of buoyancy, increase of surface area, increase of surface activity, generation of local high-pressure field, and surface active action and bactericidal action by realizing electrostatic polarization. More specifically, by interlinking them, various objects can be washed with high functionality and low environmental load by the adsorption function of dirt components, the high-speed washing function of the object surface, and the sterilization function. It discloses that purification can be performed.

  Moreover, the production method of nanobubbles as a conventional technique is described in Japanese Patent Application Laid-Open No. 2003-334548 (Patent Document 2).

  In this technique, in a liquid, (1) a step of cracking and gasifying a part of the liquid, (2) a step of applying ultrasonic waves in the liquid, or (3) a step of cracking and gasifying a part of the liquid and It is comprised from the process of applying an ultrasonic wave.

  Also, a waste liquid treatment apparatus using ozone microbubbles as a prior art is described in Japanese Patent Application Laid-Open No. 2004-321959 (Patent Document 3).

  In this technology, ozone gas generated from an ozone generator is supplied to the micro / nano bubble generator, and waste liquid extracted from the lower part of the treatment tank is supplied to the micro / nano bubble generator via a pressure pump. Further, the generated ozone microbubbles are ventilated into the waste liquid in the treatment tank through the opening of the gas blowing pipe.

  Conventionally, a technique for applying microbubbles using carbon dioxide is described in Japanese Patent Application Laid-Open No. 2006-320675 (Patent Document 4). In this technique, a carbon dioxide gas container and a pressure reducing valve are arranged, and carbon dioxide gas is supplied to the intake air intake system of the microbubble generator at a certain pressure and flow rate.

However, there is a problem that even if the technology using the existing bubbles using the above four technologies as an example is referred to, it is economically impossible to ask for a device that has a particularly favorable influence and effect on the human body.
JP 2004-121962 A JP 2003-334548 A JP 2004-321959 A JP 2006-320675 A

  Accordingly, an object of the present invention is to provide a blood flow increasing device that can increase blood flow and exhibit pharmacological effects economically. Another object of the present invention is to provide a blood flow increasing device capable of economically generating carbon dioxide nanobubbles in a large amount. Another object of the present invention is to provide a blood flow increasing device that exerts particularly favorable influences and effects on the human body.

In order to solve the above problems, a blood flow increasing device of the present invention has a water tank filled with calcium carbonate mineral and a herbal medicine and produces bathtub water containing carbon dioxide nanobubbles, and the bathtub water is added to the water tank. An artificial carbonated spring improvement unit that flows in,
And a bathtub portion into which the bathtub water is introduced from the artificial carbonated spring improvement unit.

  According to the blood flow increasing device of the present invention, in the artificial carbonated spring improvement unit, the calcium carbonate mineral filled in the water tank can be dissolved with the carbon dioxide nanobubbles contained in the bath water, and the dissolution of calcium ions and magnesium ions can be promoted. Therefore, there is an effect of increasing the generation efficiency of nanobubbles. Moreover, since the bathtub water containing carbon dioxide nanobubbles is introduced into the bathtub portion from the artificial carbonated spring improvement unit, the blood flow increasing action by the carbon dioxide nanobubbles is exhibited by bathing in the bathtub portion. Moreover, the medicinal component of the herbal medicine is dissolved in the bath water, and various pharmacological actions by the medicinal component are exhibited, thereby realizing a multifunctional blood flow increasing device. The carbonated spring refers to bathtub water containing carbon dioxide gas. In addition, examples of herbal medicines include various kinds such as yellowfin, elderberry, elephant, mugwort, saxifrage, mugwort, red pine leaf, matababi, aloe, and sugar beet. As other herbal medicines, Inokozu root and psyllium seed are selected for diabetes treatment. In addition, for arteriosclerosis, Auren, Mishima psycho and ginseng are selected.

  As calcium carbonate minerals, oyster shells and corals are common, but natural calcium carbonate that can be mined from mountains in the Chugoku region (cold stone as a product) can also be mentioned. Since oyster shells and corals are products from the sea, when dissolved, they contain many inorganic ions such as calcium and magnesium, so that nanobubbles are easily generated in the bath water.

  In one embodiment of the blood flow increasing device, the water tank is filled with a humectant.

  According to the blood flow increasing device of this embodiment, the moisturizing agent is dissolved in the bath water, and the bath water gives a moist feeling to the human body due to the moisturizing agent, thereby providing a more multifunctional blood flow increasing device.

Moreover, in the blood flow increasing device of one embodiment, the artificial carbonated spring improvement unit includes:
A first tank in which a nanobubble generator is attached and the bath water contains carbon dioxide nanobubbles;
A second tank filled with calcium carbonate mineral while bath water from the first tank flows in;
A third tank in which the bath water from the second tank flows and filled with herbal medicines;
A fourth tank filled with a humectant as the bathtub water from the third tank flows in;
And a fifth tank in which a dissolved carbon dioxide meter or a pH meter is installed while bath water from the fourth tank flows in,
The bathtub water is circulated between the artificial carbonated spring improvement unit and the bathtub section.

  According to the blood flow increasing device of this embodiment, since the bathtub water is circulated between the bathtub and the artificial carbonated spring improvement unit, the calcium carbonate nanobubbles contained in the bathtub water in the second tank cause calcium to flow from the calcium carbonate mineral to the bathtub water. By elution, the generation efficiency of nanobubbles can be increased. Moreover, in the 3rd tank filled with the crude drug, the medicinal component from the crude drug can be eluted in the bath water, and the pharmacological effect by the medicinal component can be expected. Moreover, in the 4th tank with which the moisturizing agent was filled, a moisturizing component can be eluted in bath water, and a moist feeling with respect to a human body can be obtained. Moreover, the dissolved carbon dioxide gas density | concentration installed in the 5th tank can detect the dissolved carbon dioxide gas density | concentration of bathtub water directly or indirectly.

  In addition, as a crude drug of the said 3rd tank, the root of a medicinal plant which is a medicinal plant and the seed of psyllium are selected as an example especially for diabetes treatment. In addition, for arteriosclerosis, Aureen, Mishima psycho and ginseng are selected as herbal medicines. In any case, the third tank is filled with medicinal plants according to the purpose and the water temperature of the bathtub water is 38 ° C. to 42 ° C., for example. A pharmacological effect can be exerted by absorption in blood. Further, the moisturizing agent in the fourth tank is a material that moisturizes the skin with the moisturizing component, and moisturizing the skin makes the skin moist and moisturized after taking a bath. As a specific example, olives, various seaweeds, soybeans, etc. that have been approved by the “Japan Bathing Agents Association”, “Components and Types of Bathing Agents” are selected.

  Moreover, in the blood flow increasing device of one embodiment, warm water containing 1000 ppm or more of carbon dioxide gas is supplied from the artificial carbonated spring device to the first tank of the artificial carbonated spring improvement unit.

  According to the blood flow increasing device of this embodiment, hot water containing carbon dioxide at a high concentration (1000 ppm or more) is supplied from the artificial carbonated spring device to the first tank. Carbon dioxide nanobubbles can be produced by introducing into the generator. In addition, the carbon dioxide gas contained in the carbonated spring is recognized as having an effect of improving blood flow by promoting the expansion action of blood vessels by being absorbed into the body.

  Moreover, in the blood flow increasing device of one embodiment, the nanobubble generator installed in the first tank of the artificial carbonated spring improvement unit includes carbon dioxide-containing hot water from the artificial carbonated spring device and bathtub water from the bathtub unit. Both are supplied as a gas-liquid mixture.

  According to the blood flow increasing device of this embodiment, carbon dioxide nanobubbles can be efficiently contained in bathtub water by the nanobubble generator in the first tank.

Moreover, in the blood flow increasing device of one embodiment, a dissolved carbon dioxide meter that is installed in the fifth tank of the artificial carbonated spring improvement unit and measures the dissolved carbon dioxide concentration of the bathtub water in the fifth tank,
A dissolved carbon dioxide regulator installed outside the fifth tank and receiving a signal representing the dissolved carbon dioxide concentration from the dissolved carbon dioxide meter,
The dissolved carbon dioxide gas controller controls the operation of the nanobubble generator by outputting a control signal to the nanobubble generator based on the signal.

  According to the blood flow increasing device of this embodiment, the operation of the nanobubble generator is controlled by the control signal of the dissolved carbon dioxide gas regulator based on the signal from the dissolved carbon dioxide gas regulator of the fifth tank. Therefore, the carbon dioxide gas concentration in the fifth tank can be controlled by the operation of the nanobubble generator, and the constantly stable carbon dioxide gas concentration in the bathtub water can be maintained.

  Moreover, in the blood flow increasing device of one embodiment, the operation of the nanobubble generator and the operation of the artificial carbonated spring device are linked.

  According to the blood flow increasing device of this embodiment, when the carbon dioxide containing hot water from the artificial carbonated spring device is introduced into the first tank, the nanobubble generator is immediately operated in conjunction with the carbon dioxide from the carbon dioxide containing hot water. Gas divergence and dissipation can be minimized.

  In one embodiment, the nanobubble generator of the carbonated spring improvement unit is a gas-liquid mixed gas shearing nanobubble generator.

  According to the blood flow increasing device of this embodiment, carbon dioxide nanobubbles can be reliably produced by the first step of gas-liquid mixing and the second step of gas shearing by the gas-liquid mixed gas shearing type nanobubble generator. .

Moreover, in the blood flow increasing device of one embodiment, a pH meter that is installed in the fifth tank of the artificial carbonated spring improvement unit and measures the pH of the bathtub water in the fifth tank,
A pH controller installed outside the fifth tank and receiving a signal representing pH from the pH meter;
The pH controller outputs a control signal to the nanobubble generator based on the signal to control the operation of the nanobubble generator.

  According to the blood flow increasing device of this embodiment, instead of the dissolved carbon dioxide gas meter and the dissolved carbon dioxide gas regulator, a general-purpose pH meter and pH regulator are adopted, so there are many usage results, Reliability can be improved. That is, instead of directly measuring the dissolved carbon dioxide gas, the dissolved carbon dioxide gas concentration in the bath water is indirectly measured by measuring the pH.

Moreover, in the blood flow increasing device of one embodiment, the nanobubble generator of the carbonated spring improvement unit,
A gas-liquid mixing circulation pump having a microbubble generating unit;
A gas shearing section for generating nanobubbles by shearing microbubbles produced by the gas-liquid mixing circulation pump;
A needle valve that adjusts the amount of gas supplied to the microbubble generator;
The gas-liquid mixing circulation pump, the gas shearing section, and a pipe connecting the needle valve.

  According to the blood flow increasing device of this embodiment, a highly reliable nanobubble generator can be constructed, and the carbon dioxide nanobubbles contained in the bath water in this nanobubble generator are absorbed from the skin, and the blood flow increasing action by the carbon dioxide gas Can be made more reliable.

  In addition, the gas-liquid mixing circulation pump which has a microbubble generation part is a pump with which a pump main body can generate a micro nano bubble. In general, the pump and the generator are separate, but the gas-liquid mixing circulation pump 33 has a microbubble generator. The nanobubble generator as an overall system generates and produces microbubbles with a gas-liquid mixing and circulation pump having a microbubble generator at the first stage, and gas shearing at the second stage. Generate nanobubbles in the part. Further, as necessary, the air amount is accurately adjusted by controlling the opening of the needle valve. Moreover, when more accurate control is required, a system for controlling the rotation speed of the gas-liquid mixing circulation pump may be constructed.

  In one embodiment, the carbonated spring improvement unit includes a micro / nano bubble generator.

  According to the blood flow increasing device of this embodiment, the carbonated spring improvement unit is provided with a micro / nano bubble generator having a low initial cost compared to the nano bubble generator instead of the nano bubble generator. But if the effect fits, it becomes an economical device.

  Further, in the blood flow increasing device according to an embodiment, the organic matter as a stain (red) from the human body generated in the bathtub portion is caused by microorganisms propagated on the calcium carbonate mineral filled in the water tank of the carbonated spring improvement unit. Process.

  According to the blood flow increasing device of this embodiment, the stain (red) from the human body as organic matter generated in the bathtub can be treated with the microorganisms propagated in the calcium carbonate mineral filled in the water tank of the carbonated spring improvement unit. . Therefore, replacement of bathtub water is unnecessary, and as an example, the system is effective when applied to a 24-hour facility or the like. In addition, organic substances can be decomposed by the oxidizing action of nanobubbles. In particular, organic substances can be strongly oxidized by the free radicals of nanobubbles, that is, negative charges.

Moreover, in the blood flow increasing device of one embodiment, the fourth tank of the carbonated spring improvement unit is
A filler filled in a net-like container;
A discharge unit for discharging carbon dioxide nanobubble water from the nanobubble generator from below the filler is provided.

  According to the blood flow increasing device of this embodiment, the component contained in the filler can be eluted into the bath water by carbon dioxide nanobubble water. Further, when microorganisms are propagated on the filler, the propagated microorganisms can be activated by carbon dioxide nanobubble water discharged from the discharge portion. In addition, the same phenomenon can be said in humans that carbon dioxide activates microorganisms. That is, in the human body, when carbon dioxide nanobubbles are absorbed from the skin and enter the capillary blood vessels, and the concentration of carbon dioxide in the blood increases, the blood flow around the whole body also increases and the activity increases. Similarly, microorganisms that are a part of organisms also show physiological activity by carbon dioxide nanobubbles, and further, activation of all organisms can be expected.

  Moreover, the diabetes treatment apparatus of one Embodiment has the said blood flow rate increase apparatus.

  According to the diabetes treatment apparatus of this embodiment, the blood flow volume is increased with at least one of the carbon dioxide micro-nano bubbles or the carbon dioxide nano bubbles contained in the bathtub water with respect to a human body bathed in the bathtub section using the blood flow increasing device. Can be increased. This increase in blood flow can greatly improve the symptoms of diabetes.

  In addition, in the treatment of diabetes, it is very effective when the treatment by the diabetes treatment apparatus of the present invention and the administration of a hypoglycemic agent such as a sulfonylurea agent or a biguanite agent are performed in combination. The synergistic effect of the treatment with the diabetes treatment apparatus of the present invention and the administration of the hypoglycemic agent is very large, and the above-mentioned synergistic effect can improve the symptoms of diabetes in a short period of time.

  Moreover, the beauty apparatus of one Embodiment has the said blood flow rate increase apparatus.

  According to the beauty device of this embodiment, beauty can be effectively promoted by the blood flow increasing effect of the blood flow increasing device.

  Moreover, in the hair growth promotion apparatus of one Embodiment, it has the said blood flow rate increase apparatus.

  According to the hair growth promoting device of this embodiment, hair growth can be effectively promoted by the blood flow increasing effect of the blood flow increasing device.

  Moreover, the central nervous system disease treatment apparatus of one Embodiment has the said blood flow rate increase apparatus.

  According to the central nervous system disease treatment apparatus of this embodiment, the symptoms of the central nervous system disease can be improved by the blood flow increasing effect of the blood flow increasing apparatus. This central nervous disease includes Alzheimer's disease and dementia.

  Moreover, the cardiovascular disease treatment apparatus of one Embodiment has the said blood flow rate increase apparatus.

  According to the cardiovascular disease treatment apparatus of this embodiment, the symptoms of cardiovascular disease can be improved by the blood flow increasing effect of the blood flow increasing device. This cardiovascular disease includes chronic heart failure, hypertension, cerebral infarction, myocardial infarction and the like.

  Moreover, the metabolic disorder disease treatment apparatus of one Embodiment has the said blood flow rate increase apparatus.

  According to the metabolic disorder disease treatment apparatus of this embodiment, the symptoms of metabolic disorder can be improved by the blood flow increasing effect of the blood flow increasing device. This metabolic disorder includes obesity, hyperlipidemia and the like.

  Moreover, the digestive system disease treatment apparatus of one Embodiment has the said blood flow rate increase apparatus.

  According to the digestive organ disease treatment apparatus of this embodiment, the symptoms of digestive organ disease can be improved by the blood flow increasing effect of the blood flow increasing device. This gastrointestinal disease includes gastric ulcer, hypofunction of the liver and the like.

  Moreover, the musculoskeletal disease treatment apparatus of one Embodiment has the said blood flow rate increase apparatus.

  According to the musculoskeletal treatment apparatus of this embodiment, the symptoms of musculoskeletal diseases can be improved by the blood flow increasing effect of the blood flow increasing device. This musculoskeletal disease includes rheumatoid arthritis, arthritis and the like.

  Moreover, the dermatological field disease treatment apparatus of one Embodiment has the said blood flow rate increase apparatus.

  According to the dermatological region disease treatment apparatus of this embodiment, the symptoms of dermatological region disease can be improved by the blood flow increasing effect of the blood flow increasing device. This dermatological disease includes skin aging, hair loss and the like.

  According to the blood flow increasing device of the present invention, in the artificial carbonated spring improvement unit, the calcium carbonate mineral filled in the water tank can be dissolved with the carbon dioxide nanobubbles contained in the bath water, and the dissolution of calcium ions and magnesium ions can be promoted. Therefore, there is an effect of increasing the generation efficiency of nanobubbles. Moreover, since the bathtub water containing carbon dioxide nanobubbles is introduced into the bathtub portion from the artificial carbonated spring improvement unit, the blood flow increasing action by the carbon dioxide nanobubbles is exhibited by bathing in the bathtub portion. Moreover, the medicinal component of the herbal medicine is dissolved in the bath water, and various pharmacological actions by the medicinal component are exhibited, thereby realizing a multifunctional blood flow increasing device.

  Hereinafter, the present invention will be described in detail with reference to the illustrated embodiments.

(First embodiment)
FIG. 1 is a diagram schematically showing a blood flow increasing device 39 according to the first embodiment of the present invention. This blood flow increasing device 39 includes a bathtub 1 as a bathtub section and an artificial carbonated spring improvement unit 4.

  In FIG. 1, the capacity of the artificial carbonated spring improvement unit 4 is expressed to be about twice the capacity of the bathtub 1, but this is because the details of the equipment of the artificial carbonated spring improvement unit 4 are shown in detail. The capacity of the bathtub 1 is 8 times or more compared with the capacity of the artificial carbonated spring improvement unit 4.

  As bathtub 1, various bathtubs correspond, a bathtub for homes, a hospital, a hotel, an inn, and a hot spring bathtub correspond, and the material is various. Generally, the household bathtub 1 is manufactured from various materials such as synthetic resin.

  This bathtub 1 is generally used in the following first and second steps.

(First step)
New hot water is supplied to the bathtub 1 or the hot water from the bathtub is reused by reusing the bathtub water used the day before. Since bath water drops in water temperature, hot water is high-temperature hot water. Moreover, the bathtub water after use the day before contains dirt as an organic substance.

(Second step)
The bathtub water in the bathtub 1 is transferred to the first tank 6 via the pipe 37 by the bathtub transfer circulation pump 2. The bathtub water newly introduced into the first tank 6 by transferring the bathtub water to the first tank 6 is a natural flow method, and in order, the second tank 7, the third tank 8, the fourth tank 9, Move to the fifth tank 10. Finally, the bathtub water overflows from the fifth tank 10 and returns to the bathtub 1 via the return pipe 38.

  Moreover, when the bathtub water after the previous day's use is reused, the bathtub water of the previous day contains the dirt as an organic substance that the water temperature is falling.

  As countermeasures for lowering the water temperature, heat is newly provided by piping or boiler equipment in a separate system (not shown). As a measure against dirt (red) as an organic substance contained in the bath water, by circulating between the bath 1 and the first tank 6 to the fifth tank 10, in particular, the second tank 7 is filled. By the microorganisms propagated on the calcium carbonate mineral 16, the organic matter is strongly oxidatively decomposed by microorganisms activated by microorganisms.

  That is, the bathtub water is transferred from the first tank 6 to the tenth tank using the bathtub transfer circulation pump 2 by the overflow method, and the active ingredients are eluted in the water tanks 6 to 10. Then, the tanks are sequentially overflowed and finally returned to the bathtub 1. In addition, the bathtub water circulates between the bathtub 1 and the water tank 10.

  Next, the first to fifth tanks 6 to 10 will be described in detail.

  The first tank 6 is provided with a nanobubble generator 42 composed of several devices dispersed inside and outside the first tank 6. The nanobubble generator 42 is supplied with hot water containing carbon dioxide from the water heater 12 and the high-concentration artificial carbonated spring device 11, and produces carbon dioxide nanobubbles having an effect of increasing blood flow from the hot water containing carbon dioxide.

  Here, the high concentration artificial carbonated spring device 11 will be described. The high-concentration artificial carbonated spring device 11 is a device that can produce hot water containing 1000 ppm or more of carbon dioxide gas from hot water supplied from the water heater 12. As a specific example of the high-concentration artificial carbonated spring device 11, a large number of products from manufacturers such as MRC Home Products Co., Ltd. and Foam Co., Ltd. are sold. As an example of this product, in the case of MRC Home Products Co., Ltd., as an artificial carbonated spring production device, there is a product name “Soda Bath” for general use and “Carbocera” for medical use. Carbonate springs produced by these products, “Soda Bath” and “Carbocera”, are not carbon dioxide nanobubbles, and as described above, they have an effect of increasing blood flow compared to carbon dioxide nanobubbles absorbed in large amounts from the skin. Especially not enough.

  But the said artificial carbonated spring manufacturing apparatus 11 has the capability to supply the hot water whose density | concentration as a carbon dioxide gas is 1000 ppm or more. In the first tank 6, the amount of carbon dioxide-containing hot water introduced from the artificial carbonated spring manufacturing apparatus 11 is adjusted by the valve 14, and the amount of bathtub water from the bathtub 1 is adjusted by the valve 13. It is introduced into the water tank 6.

  As described above, the nanobubble generator 42 installed in the first tank 6 sucks bathtub water, which is a mixture of bathtub water and carbon dioxide-containing hot water, from the pipe hole 5 of the suction pipe 3.

  The nanobubble generator 42 includes a gas / liquid mixing / circulation pump 33, a microbubble generation unit 34 attached to the gas / liquid mixing / circulation pump 33, and a gas shear connected to the microbubble generation unit 34 through a water pipe. It is comprised from the part 35, the nano bubble discharge port 29 connected with this gas shearing part 35, and the needle valve 36 connected to the micro bubble generating part 34 by air piping.

  The nanobubble generator 42 including the needle valve 36, the gas-liquid mixing circulation pump 33 having the microbubble generator 34, the gas shearing portion 35, and the nanobubble discharge port 29 is housed in a stainless steel container as a specific example. Sold as a unit.

  The microbubble generating unit 34 opens the needle valve 36 so that air is supplied from the suction side of the gas-liquid mixing circulation pump 33. The microbubble generator 34 has a special casing structure as an example. The microbubble generator 34 mixes, stirs, and pressurizes the liquid and air as gas to generate microbubbles. And the produced | generated microbubble is introduce | transduced into the gas shear part 35 through water piping. The gas shearing unit 35 generates nanobubbles from the microbubbles by shearing the microbubbles by fluid motion.

  The mechanism of the nanobubble generation will be described in more detail by the first and second steps.

(First step)
By controlling the pressure hydrodynamically in the microbubble generating part 34, gas is sucked from the negative pressure forming part and is moved at high speed fluid to form the negative pressure part and generate microbubbles. To make it easier to understand, the first step is to produce micro-bubble cloudy water by effectively self-sufficiency, mixing, dissolving and pumping water and air.

(Second step)
Next, the microbubbles generated by the above-described high-speed fluid motion and the formation of the negative pressure portion are introduced into the gas shearing portion 35 through the water pipe and sheared as fluid motion, thereby generating nanobubbles from the microbubbles.

  In this embodiment, the nanobubble-containing bathtub water generated by the nanobubble generator 42 is distributed to the first tank 6, the third tank 8, and the fourth tank 9 by the liquid gas mixing pipes 30 and 28. The By adjusting the valves 32 of the mixing pipe 30, the valves 31, 17 and 20 of the mixing pipe 28 in the distribution water by the liquid gas mixing pipes 30 and 28, the tanks 6, 8, and 9 can be adjusted. What is necessary is just to adjust the flow volume of nanobubble containing bathtub water according to the objective.

  In the first tank 6, the bathtub water containing nanobubbles is then introduced into the second tank 7. A partition plate 24A partitions the first tank 6 and the second tank 7 from each other. In the second tank 7, a calcium carbonate mineral 16 (an oyster glass as an example) is filled in the net-like container 15A.

  By containing carbon dioxide as nanobubbles in the bath water, the pH of the bath water is inclined to 5.0 and acidic. For this reason, the calcium carbonate mineral 16 (for example, oyster shells) is dissolved, and the main components of calcium and magnesium are dissolved. Thus, nanobubbles are more efficiently generated in the nanobubble generator 42 by the dissolution of calcium and magnesium into the bath water. For example, since seawater contains a large amount of inorganic ions, it has been demonstrated in oyster and oyster shell culture that micro-nano bubbles are efficiently generated. In fact, when inorganic ions were added to the bath water, micro-nano bubbles and nano-bubbles were efficiently generated.

  Since the oyster shell as an example of the calcium carbonate mineral 16 is a natural product, microorganisms propagate on its surface, and these microorganisms are activated especially by carbon dioxide nanobubbles. Therefore, the organic matter contained in the bath water can be biologically decomposed by the propagated and activated microorganisms. In addition, the dirt as organic matter contained in the bath water is oxidatively decomposed by the strong oxidizing action of the carbon dioxide nanobubbles, and the bath water is always rationally purified.

  Subsequently, the bath water is introduced into the third tank 8 from the upper part of the second tank 7. This third tank 8 is introduced into the third tank 8 in which a herb 22 as a medicinal plant is filled in the net-like container 15A.

  The third tank 8 is filled with a crude drug 22 (an example of various medicinal plants) in a net-like container 15B. The herbal medicine 22 has various shapes such as leaves, rhizomes, bark, and seeds of medicinal plants, but the shape of the herbal medicine for efficiently dissolving the target active ingredient in the bath water is selected. And since bath water is operation-managed by 37 to 42 degreeC as an example, the active ingredient of a crude drug is melt | dissolved (it is also called extraction) in bath water, without destroying with heat. In addition, conventionally, it is a known fact that warming the human body by putting herbal medicine in bathtub water, it is a known fact, but in this embodiment the bathtub water contains carbon dioxide nanobubbles, The active ingredient of the herbal medicine can be dissolved more efficiently in the bath water. And according to the said bath water, both the blood circulation promotion effect | action of a crude drug and the blood circulation promotion effect | action of a carbon dioxide nanobubble work, a blood flow rate increases further, and a blood circulation promotion effect | action is strengthened. Specific examples of herbal medicines include mugwort, red pine leaves, matababi, aloe, and toki.

  Further, below the net-like container 15B of the third tank 8, a liquid gas mixing pipe 18 and a discharge port 19 for discharging the nanobubble-containing water are installed as necessary. In the liquid gas mixing pipe 18, the nanobubble amount is adjusted by the valve 17, and nanovalve-containing water is discharged from the discharge port 19. The nanovalve-containing water dissolves the active ingredient from the crude drug 22 in the net-like container 15B.

  Next, the bath water is introduced into the fourth tank 9 from the lower part of the third tank 8. A partition plate 24 </ b> C partitions the third tank 8 and the fourth tank 9. In the fourth tank 9, a moisturizing agent 23 filled in the net-like container 15C is installed. The fourth tank 9 is different from the third tank 8 in that the filler is not the herbal medicine 22 but a moisturizing agent. Accordingly, in the fourth tank 9, as in the third tank 8, a pipe connected to the liquid gas mixing pipe 28 via the valve 20 extends below the moisturizing agent 23. From the discharge port 21 of this pipe, nanobubbles are discharged with the amount adjusted by the valve 20. The moisturizing agent 23 moisturizes the skin and has been approved by the Japan Bathing Agents Association. A specific example of the humectant 23 was selected from seaweed, soybeans, olives, and the like according to the purpose.

  Next, the bath water that has flowed out of the upper part of the fourth tank 9 due to overflow is introduced into the fifth tank 10. A dissolved carbon dioxide gas meter 44 is installed in the fifth tank 10, and this dissolved carbon dioxide gas meter 44 is connected to the dissolved carbon dioxide gas regulator 45 through a signal line 27A. The dissolved carbon dioxide gas regulator 45 is installed outside the fifth tank 10. The dissolved carbon dioxide meter 44 measures the amount of dissolved carbon dioxide in the bath water in the fifth tank 10 and inputs a signal representing the amount of dissolved carbon dioxide to the dissolved carbon dioxide regulator 45 from the signal line 27A.

  Here, the blood flow increasing action is in carbon dioxide nanobubbles as the carbon dioxide component contained in the bath water. Therefore, as a measuring instrument for measuring the dissolved carbon dioxide gas, the measuring system using the dissolved carbon dioxide gas meter 44 and the dissolved carbon dioxide gas regulator 45 is more preferable than the measuring system using the pH meter and the pH controller. It is direct.

  On the other hand, the dissolved carbon dioxide gas meter 44 is not general and has few manufacturers. However, although not as much as a pH meter or a pH controller, a dissolved carbon dioxide meter 44 is sold by several manufacturers. For example, products of Toa DKK Corporation can directly measure the dissolved carbon dioxide concentration in the liquid phase by the diaphragm electrode method. The product of Able Co., Ltd. has a feature that it is a dissolved carbon dioxide meter capable of steam sterilization.

  Here, the nano bubble generator 42 described above is linked to the dissolved carbon dioxide meter 44 that receives a signal from the dissolved carbon dioxide meter 44 installed in the fifth tank 10 via the signal line 27. In other words, the dissolved carbon dioxide gas regulator 45 outputs a control signal to the signal line 27C based on the signal representing the carbon dioxide gas concentration of the bathtub water input from the dissolved carbon dioxide gas meter 44, so that the nanovalve generator 42 Control driving.

  This operation control is performed as follows as an example. That is, when the bath water is first introduced into the first tank 6, the pH of the bath water is about 5.0 due to the carbon dioxide gas of the carbon dioxide nanobubbles. Bathtub water circulates between the artificial carbonated spring improvement unit 4. As a result, the purification of the bath water and the neutralization of the pH of the bath water proceed, and when the pH of the bath water reaches 6.5, all the components of the nanobubble generator 42 are stopped. become.

  The first embodiment has the following effects. That is, according to this 1st Embodiment, carbon dioxide nanobubbles are contained in bathtub water, blood flow with respect to the human body immersed in the bathtub water of bathtub 1 can be increased, and blood circulation can be promoted. In addition, since the function of the living body such as the recovery of immune function is restored by increasing the blood flow rate, taking the drug also has the effect of enhancing the action of the drug, so the same effect can be expected with a small amount of drug. Moreover, the bath water has an effect of synergistically enhancing the action effect of the drug by dissolving the active ingredient from the herbal medicine.

  Moreover, according to the bath water by the blood flow increasing device 39 of this embodiment, the blood flow increasing action with respect to the human body is exhibited, and at the same time, there is a cleaning effect with carbon dioxide nanobubbles on the human skin. Therefore, if this bath water is also used for the face and hair, the face wash, the amount of shampoo, the amount of body soap, etc. can be reduced.

  The set of the gas-liquid mixing / circulation pump 33, the micro-bubble generating unit 34, the gas shearing unit 35, the needle valve 36, and the nano-bubble discharge port 29, which basically constitutes the nano-bubble generator 42, is commercially available. It can be adopted, but it does not limit the manufacturer. As a specific example, products from Kyowa Kikai Co., Ltd. can be used, but many products from other manufacturers are expected to be sold in the future.

  Here, three types of bubbles will be described.

  (i) Normal bubbles (bubbles) rise in the water and eventually disappear on the surface by popping bread.

  (ii) A microbubble is a fine bubble having a diameter of 10 to several tens of microns (μm) at the time of its generation, and partially changes into a micro / nano bubble by contraction movement after the generation.

  (iii) A nanobubble is a bubble having a diameter of several hundreds of nanometers or less (typically 100 to 200 nm with a diameter of 1 micron or less) smaller than a microbubble, and is said to be a bubble that can exist in water indefinitely. ing.

  And a micro nano bubble can be explained as a bubble in which micro bubbles and nano bubbles are mixed.

(Second embodiment)
Next, FIG. 2 shows a blood flow increasing device 49 according to a second embodiment of the present invention. As shown in FIG. 2, the second embodiment differs from the first embodiment in the following points. That is, in the first embodiment described above, the supply of the gas to the needle valve 36 is simply air, but in this second embodiment, the carbon dioxide gas from the liquefied carbon dioxide cylinder 47 is supplied to the needle valve 36. Yes. Therefore, in the second embodiment, not only the carbon dioxide gas is supplied from the high concentration artificial carbonated spring device 11 to the first tank 6 but also the liquefied carbon dioxide cylinder corresponding to the carbon dioxide gas supplied from the high concentration artificial carbonated spring device 11. Carbon dioxide gas from 47 is supplied to the needle valve 36.

  Therefore, in the second embodiment, the same parts as those in the first embodiment described above are denoted by the same reference numerals and detailed description thereof will be omitted, and parts different from those in the first embodiment will be described.

  In the second embodiment, the carbon dioxide gas from the liquefied carbon dioxide gas cylinder 47 is directly supplied to the microbubble generator 34 of the nanobubble generator 42. Therefore, not only the supply of carbon dioxide gas from the high concentration artificial carbonated spring device 11 to the first tank 6 but also the microbubbles from the liquefied carbon dioxide gas cylinder 47 according to the amount of carbon dioxide supplied from the high concentration artificial carbonated spring device 11 to the first tank 6. Carbon dioxide gas is supplied to the generator 34. Thus, the nanobubble generator 42 discharges carbon dioxide nanobubbles from the nanobubble discharge port 29. Thereby, the dissolved carbon dioxide concentration of the bathtub water in the first water tank 6 can be made 1000 ppm or more in a short time and economically.

  The amount of carbon dioxide supplied from the liquefied carbon dioxide cylinder 47 to the needle valve 36 is, for example, 0.7 liters / minute as a reference. Therefore, carbon dioxide nanobubbles can be efficiently contained in the bath water under conditions where the amount of carbon dioxide used is small. Since the liquefied carbon dioxide cylinder 47 itself has a high pressure, a pressure reducing valve (not shown) is attached to reduce the pressure.

(Third embodiment)
Next, FIG. 3 shows a blood flow increasing device 59 according to a third embodiment of the present invention. The third embodiment is different from the first embodiment in the following points (1) and (2). Therefore, in the third embodiment, the same parts as those in the first embodiment described above are denoted by the same reference numerals and detailed description thereof will be omitted, and parts different from those in the first embodiment will be described.

    (1) In the first embodiment described above, the gas supplied to the needle valve 36 is simply air, but in the third embodiment, the carbon dioxide gas from the liquefied carbon dioxide cylinder 47 is supplied to the needle valve 36.

    (2) In the first embodiment described above, the high concentration artificial carbonated spring device 11 is provided. However, in the third embodiment, since the high concentration artificial carbonated spring device 11 is not provided, only the carbon dioxide gas from the liquefied carbon dioxide gas cylinder 47 is provided. Is supplied to the nanovalve generator 42.

  Therefore, according to the third embodiment, all the carbon dioxide dissolved in the bathtub water of the first water tank 6 is only from the carbon dioxide from the liquefied carbon dioxide cylinder 47, so that the cost is reduced and economical. Can be a thing.

  That is, the high-concentration artificial carbonated spring device 11 included in the first embodiment described above is a system that uses a liquefied carbon dioxide gas cylinder and a multilayer composite hollow fiber membrane that is a semipermeable membrane, and therefore costs such as maintenance related to them are high. appear. On the other hand, in this 3rd Embodiment, since it does not have the high concentration artificial carbonated spring apparatus 11 and carbon dioxide gas is supplied only by the liquefied carbon dioxide gas cylinder 47, those expenses do not generate | occur | produce.

  Moreover, since the carbon dioxide-containing hot water itself from the high-concentration artificial carbonated spring device 11 of the first embodiment described above escapes from the hot water due to the emission of carbon dioxide, the total amount of carbon dioxide cannot be maintained in the bath water. was there. On the other hand, the carbon dioxide gas from the liquefied carbon dioxide cylinder 47 is directly introduced into the nanobubble generator 42 to become carbon dioxide nanobubbles, which lasts for more than a week in the bath water. Therefore, it is economical in terms of carbon dioxide consumption.

  The amount of carbon dioxide supplied from the liquefied carbon dioxide cylinder 47 to the needle valve 36 is, for example, 0.7 liters / minute as a reference. Therefore, carbon dioxide nanobubbles can be efficiently contained in the bath water under conditions where the amount of carbon dioxide used is small. Since the liquefied carbon dioxide cylinder 47 itself is at a high pressure, a pressure reducing valve (not shown) is attached to reduce the pressure.

  Then, carbon dioxide nanobubbles are produced by the nanobubble generator 42 and discharged from the nanobubble discharge port 29 to the first tank 6. The carbon dioxide nanobubbles produced by the nanobubble generator 42 reduce carbon dioxide gas, which has conventionally been absorbed from the skin surface only in a small amount, as much as possible to be absorbed from the skin surface and taken into capillaries. Very fine bubbles. Therefore, according to this blood flow increasing device, the carbon dioxide nanobubbles travel around the whole body together with the blood, and as a result, the therapeutic device is effective for various diseases due to the blood flow increasing and blood circulation promoting actions.

  Further, in this embodiment, the generation state of nano-sized bubbles is accurately controlled by the exact amount of carbon dioxide gas from the needle valve 36 and the rotation speed of the electric motor of the gas-liquid mixing circulation pump 33 according to the bath water conditions. Thus, nanobubbles can be manufactured. That is, it has been found that the effect of increasing the blood flow when bathing in the bathtub 1 is nano-sized, but there is a difference depending on the size of the nano-sized. Therefore, the rotational speed of the motor of the gas / liquid mixing / circulation pump 33 can be accurately adjusted by inputting a control signal from the dissolved carbon dioxide controller 45 to the gas / liquid mixing / circulation pump 33 via the signal line 27C in accordance with the condition of the bath water. To control. Thus, in combination with an accurate amount of carbon dioxide gas from the needle valve 36, the nano-bubble generator 42 can produce nano-sized bubbles in a desired target size.

(Fourth embodiment)
Next, FIG. 4 shows a blood flow increasing device 69 according to a fourth embodiment of the present invention. Compared with the first embodiment, the blood flow increasing device 69 has a pH meter 25 instead of the dissolved carbon dioxide meter 44 and a pH regulator 26 instead of the dissolved carbon dioxide meter 45. Only the point is different from the first embodiment. Therefore, in the fourth embodiment, the same portions as those in the first embodiment are denoted by the same reference numerals, detailed description thereof is omitted, and portions different from those in the first embodiment are described.

  In the fourth embodiment, the dissolved carbon dioxide in the bath water is controlled by the pH meter 25 and the pH controller 26. The control system using the pH meter 25 and the pH controller 26 is a system that is used everywhere in the water treatment field. Therefore, the reliability of the system is high. That is, in the fourth embodiment, the pH meter 25 measures the pH of the bath water in the fifth tank 10, and a signal from the pH meter 25 representing the measured pH is input to the pH controller 26. The pH controller 26 outputs a control signal to the signal line 27 </ b> C based on the signal from the pH meter 25 to control the operation of the nanobubble generator 42.

  In the fourth embodiment, the second tank 7 is filled with the oyster glass as the calcium carbonate mineral 16 in the net-like container 15A. And, when the pH of the bath water is about 1000 ppm in the dissolved carbon dioxide concentration, the pH is inclined to about 5.0 and acidic. Thereby, with the control signal from the control system by the pH meter 25 and the pH adjuster 26, the nanobubble generator 42 is circulated until the pH of the bath water reaches 6.5. That is, the pH of the bath water is neutralized from pH 5.0 to pH 6.5, which means that the calcium carbonate mineral 16 as oyster shells dissolves and the main components of calcium and magnesium are dissolved in the bath water. As a result, the phenomenon is neutralized. Thus, the pH of the bath water rises as calcium and the like dissolve into the bath water. And since calcium and magnesium melt | dissolve in bath water, an inorganic ion increases, In the nano bubble generator 42, a nano bubble can be generated more efficiently.

  For example, in seawater, a large amount of inorganic ions are dissolved, and it has been demonstrated that oysters and oysters are cultivated efficiently, and in fact, inorganic ions are added to the bath water. Then, micro-nano bubbles and nano bubbles were generated efficiently. When the dissolved carbon dioxide gas is about 10,000 ppm or more, the pH is 6.5, calcium ions and the like are dissolved, and the generation efficiency of the nanobubbles of the nanobubble generator 42 reaches the target, the pH meter 25 and the pH adjustment A control signal from the control system by the total 26 is issued, and the nanobubble generator 42 stops operating.

(Fifth embodiment)
Next, FIG. 5 shows a blood flow increasing device 79 according to a fifth embodiment of the present invention. The fifth embodiment is different from the first embodiment in that the high-concentration artificial carbonated spring device 11 is not provided, and a small net-like container 40 is installed in the first tank 6. The point which becomes the structure which can install the carbon dioxide foaming solid agent 41 in 40 differs from 1st Embodiment. Therefore, in the fifth embodiment, the same parts as those in the first embodiment described above are denoted by the same reference numerals and detailed description thereof will be omitted, and parts different from those in the first embodiment will be described.

  In the fifth embodiment, as a carbon dioxide supply structure, a small net-like container 40 is installed in the first tank 6, and a carbon dioxide foaming solid agent 41 can be installed in the net-like container 40. . Therefore, in the fifth embodiment, the carbon dioxide supply structure is a simple device, and the carbon dioxide foamed solid agent 41 is commercialized in large quantities today and is generally inexpensive in terms of cost. This is an embodiment that is easier to implement.

  In addition, as the carbon dioxide foam solid agent 41, there is “Bab” of Kao Corporation as an example of representative products, but various types are also sold from other manufacturers. In either case, the carbon dioxide foam solid agent 41 as a general-purpose product may be filled in the small net-like container 40 of the first tank 6 and used. By the way, as the carbon dioxide foaming solid agent 41, “Bab” (registered trademark) manufactured by Kao Corporation is well known. This produces carbon dioxide microbubbles. It is easy to use with a blood flow increasing device.

  Moreover, in this 5th Embodiment, although the position which installs the small net-shaped container 40 was made into the upper part of the 1st tank 6, the position which installs the container 40 is not limited to this. However, the position where the container 40 is installed is that when the carbonic acid bubble is generated, the carbonic acid bubble is immediately taken into the microbubble generating part 34 of the gas-liquid mixing circulation pump 33 from the pipe hole 5 of the nanobubble generator 42 to remove the microbubble. An installation position that enables manufacture is desirable.

  That is, as long as the carbon dioxide containing water generated by the carbon dioxide foaming solid agent 41 (the carbon dioxide actually generated is said to be small in size and called carbon dioxide microbubbles), the carbon dioxide does not diverge as much as possible. In addition, it is desirable to take into consideration that the microbubble generator 34 of the gas-liquid mixing circulation pump 33 is taken in from the pipe hole 5 of the nanobubble generator 42. For example, an efficient installation position may be finally determined by experiment. Thus, the nanobubble generator 42 discharges carbon dioxide nanobubbles from the nanobubble discharge port 29.

(Sixth embodiment)
Next, FIG. 6 shows a blood flow increasing device 89 according to a sixth embodiment of the present invention. The sixth embodiment has a pH meter 25 in place of the dissolved carbon dioxide meter 44 and a pH regulator 26 in place of the dissolved carbon dioxide regulator 45 as compared with the fifth embodiment described above. Is different from the fifth embodiment described above. Therefore, in the sixth embodiment, the same parts as those in the fifth embodiment described above are denoted by the same reference numerals and detailed description thereof will be omitted, and parts different from those in the fifth embodiment will be described.

  In the sixth embodiment, the dissolved carbon dioxide in the bath water is controlled by the pH meter 25 and the pH controller 26. The control system using the pH meter 25 and the pH controller 26 is a system used everywhere in the water treatment field. Therefore, the reliability of the system is high. That is, in the sixth embodiment, the pH meter 25 measures the pH of the bath water in the fifth tank 10, and a signal from the pH meter 25 representing the measured pH is input to the pH controller 26. The pH controller 26 outputs a control signal to the signal line 27 </ b> C based on the signal from the pH meter 25 to control the operation of the nanobubble generator 42.

  In the sixth embodiment, the second tank 7 is filled with oyster glass as a calcium carbonate mineral 16 in a net-like container 15A. And, when the pH of the bath water is about 1000 ppm in the dissolved carbon dioxide concentration, the pH is inclined to about 5.0 and acidic. Thereby, with the control signal from the control system by the pH meter 25 and the pH adjuster 26, the nanobubble generator 42 is circulated until the pH of the bath water reaches 6.5. That is, the pH of the bath water is neutralized from pH 5.0 to pH 6.5, which means that the calcium carbonate mineral 16 as oyster shells is dissolved and the main components of calcium and magnesium are dissolved in the bath water. As a result, the phenomenon is neutralized. Thus, the pH of the bath water rises as calcium and the like dissolve into the bath water. And since calcium and magnesium melt | dissolve in bath water, an inorganic ion increases, In the nano bubble generator 42, a nano bubble can be generated more efficiently.

  For example, in seawater, a large amount of inorganic ions are dissolved, and it has been demonstrated that oysters and oysters are cultivated efficiently, and in fact, inorganic ions are added to the bath water. Then, micro-nano bubbles and nano bubbles were generated efficiently. When the dissolved carbon dioxide gas is about 10,000 ppm or more, the pH is 6.5, calcium ions and the like are dissolved, and the generation efficiency of the nanobubbles of the nanobubble generator 42 reaches the target, the pH meter 25 and the pH adjustment A control signal from the control system by the total 26 is issued, and the nanobubble generator 42 stops operating.

(Experimental example)
Based on the blood flow increasing device 39 shown in FIG. 1, the capacity of the bathtub 1 is 2 m ³ , the total capacity of the first tank 6, the second tank 7, the third tank 8, the fourth tank 9, and the fifth tank 10. Was 0.2 m ³ , and the blood volume increasing device 39 was manufactured with the specification of the electric motor 3.7 kw of the gas-liquid mixing circulation pump 33. And blood glucose level (fasting) before and after the corresponding treatment with a blood volume increasing device for patients who have been suffering from diabetes for more than 10 years and who have been carrying out pharmacotherapy, diet therapy and exercise therapy. And after meal). As a result of this comparison, on average, the blood glucose level after the corresponding treatment decreased from 30% to 60% of the blood glucose level before the corresponding treatment, although it varied depending on the day.

  In addition, according to the diabetes treatment apparatus provided with the blood flow increasing device according to any one of the first to sixth embodiments, the human body bathed in the bathtub using the blood flow increasing device is included in the bath water. The blood flow volume can be increased with at least one of carbon dioxide micro-nano bubbles and carbon dioxide nano-bubbles. This increase in blood flow can greatly improve the symptoms of diabetes. Further, according to the beauty device and the hair growth promoting device provided with the blood flow increasing device, it is possible to promote beauty and hair growth with the blood flow increasing effect, respectively. In addition, a central nervous system disease treatment device, a cardiovascular disease treatment device, a metabolic disorder treatment device, a digestive disease treatment device, a musculoskeletal disease treatment device, a dermatological disease treatment device, a blood, According to the immune disease treatment apparatus, each disease symptom can be improved by the blood flow increase effect. Further, by increasing the blood flow of the human body by bathing in the bathtub of the above blood flow increasing device, it becomes possible to absorb the drugs by taking various drugs through the blood vessels and to further exert the pharmacological effect around the whole body together with the blood.

It is a figure showing typically a 1st embodiment of a blood flow increasing device of this invention. It is a figure which shows typically 2nd Embodiment of the blood flow rate increase apparatus of this invention. It is a figure which shows typically 3rd Embodiment of the blood flow increasing device of this invention. It is a figure which shows typically 4th Embodiment of the blood flow increasing device of this invention. It is a figure which shows typically 5th Embodiment of the blood flow increasing device of this invention. It is a figure which shows typically 6th Embodiment of the blood flow increasing device of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Bathtub 2 Bathtub circulation pump 3 Suction pipe 4 Artificial carbonated spring improvement unit 5 Pipe hole 6 1st tank 7 2nd tank 8 3rd tank 9 4th tank 10 5th tank 11 High concentration artificial carbonated spring apparatus 12 Water heater 13 Valve 14 Valve 15A-15C Net-like container 16 Calcium carbonate mineral 17 Valve 18 Liquid gas mixed discharge pipe 19 Discharge port 20 Valve 21 Discharge port 22 Crude drug 23 Moisturizer 24A-24C Partition plate 25 pH meter 26 pH controller 27A, 27C Signal line 28 Liquid gas mixing pipe 29 Nano bubble discharge port 30 Liquid gas mixing pipe 31 Valve 32 Valve 33 Gas liquid mixing circulation pump 34 Micro bubble generating part 35 Gas shearing part 36 Needle valve 37 Pipe 38 Return pipe 39 to 89 Blood flow increasing device 40 Small net Container 41 Carbon dioxide foaming solid agent 42 Nano bubble generator 4 4 Dissolved carbon dioxide gas meter 45 Dissolved carbon dioxide gas meter 47 Liquid carbon dioxide gas cylinder

Claims (23)

An artificial carbonated spring improvement unit that has a water tank filled with calcium carbonate mineral and herbal medicine and contains carbon dioxide nanobubbles, and the bathtub water flows into the water tank,
A blood flow increasing device, comprising: a bathtub portion into which the bathtub water is introduced from the artificial carbonated spring improvement unit. The blood flow increasing device according to claim 1,
A blood flow increasing device, wherein the water tank is filled with a humectant. The blood flow increasing device according to claim 1,
The artificial carbonated spring improvement unit
A first tank in which a nanobubble generator is attached and the bath water contains carbon dioxide nanobubbles;
A second tank filled with calcium carbonate mineral while bath water from the first tank flows in;
A third tank in which the bath water from the second tank flows and filled with herbal medicines;
A fourth tank filled with a humectant as the bathtub water from the third tank flows in;
And a fifth tank in which a dissolved carbon dioxide meter or a pH meter is installed while bath water from the fourth tank flows in,
A blood flow increasing device for circulating bathtub water between the artificial carbonated spring improvement unit and the bathtub section. The blood flow increasing device according to claim 3,
A blood flow increasing device, characterized in that hot water containing 1000 ppm or more of carbon dioxide gas is supplied from an artificial carbonated spring device to the first tank of the artificial carbonated spring improvement unit. The blood flow increasing device according to claim 3,
The nanobubble generator installed in the first tank of the artificial carbonated spring improvement unit supplies both carbon dioxide-containing hot water from the artificial carbonated spring device and bathtub water from the bathtub as a gas-liquid mixed liquid. A blood flow increasing device. The blood flow increasing device according to any one of claims 3 to 5,
A dissolved carbon dioxide meter that is installed in the fifth tank of the artificial carbonated spring improvement unit and measures the dissolved carbon dioxide concentration in the bathtub water in the fifth tank;
A dissolved carbon dioxide regulator installed outside the fifth tank and receiving a signal representing the dissolved carbon dioxide concentration from the dissolved carbon dioxide meter,
The apparatus for increasing blood flow, wherein the dissolved carbon dioxide gas controller outputs a control signal to the nanobubble generator based on the signal to control the operation of the nanobubble generator. In the blood flow increasing device according to claim 6,
A blood flow increasing device characterized in that the operation of the nanobubble generator and the operation of the artificial carbonated spring device are linked. The blood flow increasing device according to claim 3,
The apparatus for increasing blood flow, wherein the nanobubble generator of the carbonated spring improvement unit is a gas-liquid mixed gas shearing nanobubble generator. The blood flow increasing device according to any one of claims 3 to 5,
A pH meter that is installed in the fifth tank of the artificial carbonated spring improvement unit and measures the pH of the bath water in the fifth tank;
A pH controller installed outside the fifth tank and to which a signal representing the pH from the pH meter is input;
The blood flow increasing device, wherein the pH controller outputs a control signal to the nanobubble generator based on the signal to control operation of the nanobubble generator. The blood flow increasing device according to claim 3,
The nanobubble generator of the carbonated spring improvement unit is
A gas-liquid mixing circulation pump having a microbubble generating unit;
A gas shearing section for generating nanobubbles by shearing microbubbles produced by the gas-liquid mixing circulation pump;
A needle valve that adjusts the amount of gas supplied to the microbubble generator;
A blood flow increasing device comprising the gas-liquid mixing circulation pump, a gas shearing section, and a pipe connecting the needle valve. The blood flow increasing device according to claim 1,
The apparatus for improving blood flow, wherein the carbonated spring improvement unit includes a micro / nano bubble generator. The blood flow increasing device according to claim 1 or 3,
An apparatus for increasing blood flow, characterized in that organic matter generated as a stain (red) from a human body generated in the bathtub portion is treated with microorganisms propagated on calcium carbonate mineral filled in a water tank of the carbonated spring improvement unit. The blood flow increasing device according to claim 3,
The fourth tank of the carbonated spring improvement unit is
A filler filled in a net-like container;
A blood flow increasing device characterized by having a discharge part for discharging carbon dioxide nanobubble water from the nanobubble generator from below the filler.   A diabetes treatment apparatus comprising the blood flow increasing device according to claim 1.   A beauty apparatus comprising the blood flow increasing device according to claim 1.   A hair growth promoting device comprising the blood flow increasing device according to claim 1.   A central nervous system disease treatment device comprising the blood flow increase device according to claim 1.   A cardiovascular disease treatment apparatus comprising the blood flow increasing device according to claim 1.   A device for treating metabolic disorders, comprising the blood flow increasing device according to claim 1.   A gastrointestinal disease treatment apparatus comprising the blood flow increasing device according to claim 1.   An apparatus for treating musculoskeletal disease, comprising the blood flow increasing device according to claim 1.   A dermatological disease treatment apparatus comprising the bathtub device according to claim 1.   A blood and immune disease treatment apparatus comprising the blood flow increasing device according to claim 1.

Images