JP4838105B2 - Bathtub equipment - Google Patents

Description

The present invention relates to a bath equipment, in particular, micro-nano bubble generator, about the tub equipment utilizing blowing agents and fillers.

  Conventionally, a bathtub using a micro / nano bubble generator has a small generation amount of micro / nano bubbles and a narrow size range of the micro / nano bubbles, and the influence of the micro / nano bubble bubbles on the human body, particularly blood flow, has been small.

  Specifically, there are many diabetic patients in Japan, and in diabetic patients, it may even be necessary to cut the leg by gangrene caused by blood flow deterioration near the end of the foot.

  Here, as an improvement method effective when the blood flow of a person's foot is deteriorated, a large number of swirl flow micro-nano bubble generators are installed in the bathtub system (as currently known, 10 There is a method of generating a large amount of micro-nano bubbles in the bathtub water by installing a micro-nano bubble generator of a swirl flow system.

  However, this method is expensive in terms of electricity costs for operating a large number of micro / nano bubble generators and the initial cost of a large number of micro / nano bubble generators. Not right.

  That is, in the bathtub apparatus, it has been found that micronanobubbles of a wide range of sizes can be generated in the size of micronanobubbles, and if a large amount of micronanobubbles is generated, it has a positive effect on the human body. In particular, a bathtub apparatus that can generate micro-nano bubbles in a wide range of sizes and generate a large amount of micro-nano bubbles and a method for creating bathtub water have not been found.

  Micro-nano bubbles also have a cleaning effect on the human body. However, conventional bathtub devices using micro-nano bubbles have a bath water solution as a measure to prevent stains on the bathtub water from the human body generated as a result of the cleaning of the human body. There was only a replacement.

  In detail, as a method and an apparatus using nanobubbles, there is one described in Japanese Patent Application Laid-Open No. 2004-121962 (Patent Document 1).

  This device and method take advantage of the characteristics of nanobubbles such as reduced buoyancy, increased surface area, increased surface activity, generation of local high-pressure fields, and interfacial activity and bactericidal action by realizing electrostatic polarization. . More specifically, by correlating them with each other, it is possible to realize a high-performance and low-environmental load cleaning of various objects by a dirt component adsorption function, an object surface high-speed cleaning function, and a sterilization function. It discloses that water purification can be performed.

  Conventionally, as a method for generating nanobubbles, there is one described in Japanese Patent Application Laid-Open No. 2003-334548 (Patent Document 2). This method includes a step of decomposing and gasifying a part of the liquid in the liquid, a step of applying ultrasonic waves in the liquid, or a step of decomposing and gasifying part of the liquid and applying ultrasonic waves. Has been.

  Conventionally, as an apparatus for treating waste liquid using ozone microbubbles, there is one described in Japanese Patent Application Laid-Open No. 2004-321959 (Patent Document 3).

  This processing apparatus supplies the microbubble generator with ozone gas generated from the ozone generator and the waste liquid extracted from the lower part of the processing tank 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.

However, even with reference to the existing technology using micro-nano bubbles such as the above-described technology using three micro-nano bubbles, a wide variety of micro-nano bubbles can be generated economically and a large amount of micro-nano bubbles can be generated. It is difficult to efficiently obtain an effect that does not generate nanobubbles and has a positive effect on the human body.
JP 2004-121962 A JP 2003-334548 A JP 2004-321959 A

An object of the present invention is to provide a bath equipment which can generate economically wide range of sizes and a large amount of micro-nano bubbles.

In particular, the present invention is a micro-nano bubble that has a significant effect on the human body, that is, has a diameter of about 10 μm to several hundred nm, and a wide variety of micro-nano bubbles in a range of sizes. it is to provide a bath equipment which can be manufactured.

  In particular, the present invention is a micro-nano bubble that exhibits a beneficial effect on the human body, that is, has a diameter of about 10 μm to several hundred nm, and a wide variety of micro-nano bubbles in the size range. An object of the present invention is to provide a bathtub apparatus that can be produced in a large amount and that has only one micro-nano bubble generator and that has low operation and manufacturing costs.

In order to solve the above problems, the bathtub apparatus of the present invention is
A bathtub water storage container for storing at least part of the bathtub water;
A micro / nano bubble generator for generating micro / nano bubbles in the bathtub water in the bathtub water storage container;
And a injection device for injecting at least one of the foamed agent and bath salts in the bath water container,
The injection device is
A mineral oil scale container containing mineral oil;
A bath salt scale container for storing bath salt,
A first control valve disposed in the course of the flow of mineral oil from the mineral oil scale container to the bath water container;
A second control valve disposed in the course of the bathing agent flow from the bathing agent graduated container to the bath water storage container;
A control device for controlling the opening and closing of the first control bubble and for controlling the opening and closing of the second control valve;
Have
The micro-nano bubble generator is a submersible pump type micro-nano bubble generator arranged in the bathtub water storage container,
It has a blower that sends air to the submersible pump type micro / nano bubble generator,
The control unit is characterized that you have to control the timing for sending the air to the water pump-type micro-nano bubble generator from the blower, the amount of air sent to the water pump-type micro-nano bubble generator from the blower .

  Ordinary bubbles (bubbles) are bubbles that rise in water and eventually disappear on the surface when they pop off.

  Microbubbles have a bubble diameter of 10 to several tens of μm at the time of their generation, and are bubbles of 50 microns (μm) or less in diameter, shrinking in water and disappearing over time (complete dissolution) ) Or changes to a bubble having a diameter of about 10 μm to several hundred nm.

  Nanobubbles are bubbles that are even smaller than microbubbles (those with a diameter of several hundred nm or less (particularly, with a diameter of 100 to 200 nm)) and are thought to be able to exist in water indefinitely. is there.

  In this specification, the micro / nano bubble is defined as a bubble having a diameter of several tens of μm or less, that is, a bubble (including a micro bubble) having a diameter of a micro bubble or less. For this reason, the micro / nano bubbles in this specification may be composed of only nano bubbles.

  It is said that there are 8 million diabetic patients, and there is no low-cost and effective method for preventing “numbness” in the feet of diabetic patients at present.

  The present inventor has found that it is effective for diabetic patients if a large amount of micro-nano bubbles of various sizes are contained in bath water. This is presumed to be due to the fact that micro-nano bubbles adhering in large quantities to the skin surface of the gaps enter the skin when humans rub the skin with their hands in the bathtub and affect the blood flow. Is done.

According to the present invention, a micro-nano bubble generator for generating a micro-nano to the bath water bath water storage container, and an injection device for injecting at least one of the foamed agent and bath salts in bath water container Since it is provided, a large number of micro-nano bubbles of various sizes can be generated in a bathtub in which a person enters. Therefore, the blood circulation of the bathed person can be improved, and the health condition of the bathed person can be improved.

  In addition, since micro-nano bubbles can be generated efficiently, the number of micro-nano bubble generators can be greatly reduced compared to the conventional case, for example, the number of micro-nano bubble generators can be reduced to one. The operation cost of the bathtub device can be greatly reduced.

  Moreover, in one Embodiment, the said injection | pouring apparatus inject | pours mineral oil or mineral oil, and a bath agent into the said bathtub water storage container.

The present inventors, when injected with mineral oil Among foamed agent to the bath water container was found by efficiently experimentally that it is possible to generate micro-nano bubbles,
According to the said embodiment, since mineral oil is inject | poured into a bathtub water storage container, a micro nano bubble can be generated efficiently.

  Moreover, in one Embodiment, the filler is arrange | positioned in the said bathtub water storage container.

  According to the above embodiment, microorganisms can be propagated in the filler, and organic matter such as red pepper in the bath water can be decomposed by the microorganisms propagated in the filler. Therefore, the bathtub water can be kept clean, and at the same time, the bathtub water can be used many times to save water.

  In one embodiment, the filler is a ring-type polyvinylidene chloride filler.

  According to the said embodiment, the organic substance as red can be physically adhered to the ring-type polyvinylidene chloride filler, and bath water can be kept clean. In addition, microorganisms can be propagated and cultured in a ring-type polyvinylidene chloride filler as a filler, and organic matter such as red can be biologically decomposed to keep the bath water clean.

  In one embodiment, the filler is a string-type polyvinylidene chloride filler.

  According to the said embodiment, the organic substance as red can be physically adhered to the string-type polyvinylidene chloride filler, and bath water can be kept clean. Also, microorganisms can be propagated and cultured in a string-type polyvinylidene chloride filler as a filler, and organic matter such as red can be biologically decomposed to keep the bath water clean.

  In one embodiment, the filler is a nylon filler.

  According to the above embodiment, microorganisms can be propagated and cultured in a nylon filling material, and organic matter such as red can be biologically decomposed to keep the bath water clean.

  In one embodiment, the filler is activated carbon.

  According to the said embodiment, the dissolved organic substance can be made to adsorb | suck to activated carbon, or decoloration of bath water can be carried out. Also, microorganisms can be propagated on the activated carbon, and organic matter that is biologically dissolved can be microbially decomposed to keep the bath water clean.

Further , according to the present invention , a desired micro / nano bubble can be efficiently generated at a desired timing by incorporating a program according to use in advance in the control device. Moreover, the bathtub apparatus with easy operation can be constructed.

  Moreover, in one Embodiment, the said micro nano bubble generator is a nano bubble generator which generate | occur | produces only a nano bubble.

  Since nanobubbles can last considerably longer than microbubbles in bathtub water, the action of nanobubbles can be sustained. For example, nanobubbles can last longer than 10 days, depending on size.

  In addition, since nanobubbles have a greater effect on the human body than microbubbles, various effects and effects on the human body can be expected.

  Moreover, since the nanobubble has the activation effect with respect to microorganisms much more than a microbubble, the microorganism treatment effect of bath water can be anticipated.

  According to the above embodiment, since the micro-nano bubble generator is a nano-bubble generator that generates only nano-bubbles, various beneficial effects on the human body can be efficiently caused, and the microbial treatment capacity of bathtub water can be improved. it can.

  Moreover, in one Embodiment, the said bathtub water storage container accommodates a part of bathtub water.

  According to the said embodiment, the bathtub apparatus excellent in transport capability is realizable.

Moreover, according to this invention, the bathtub water containing the ideal micro nano bubble can be created.

  Moreover, in one Embodiment, a filler is accommodated in the said bathtub water storage container, and a microorganism is propagated on the said filler located in the water of the water in the said bathtub water storage container.

  According to the embodiment, since microorganisms are propagated in the filler, organic matter such as red pepper in the bath water can be decomposed, and the bath water can be kept clean. In addition, the bathtub water can be reused, and water saving can be realized.

Further, in one embodiment, the water of the bath water storage container, in conjunction with the inclusion of micro-nano bubbles in water, the bath water storage container, injecting and the foamed agent bath agent.

  According to the above embodiment, the foaming agent and the bathing agent are injected in conjunction with the operation of the micro / nano bubble generator (for example, the foaming agent and the bathing agent are automatically coupled with the operation of the micro / nano bubble generator. The micro / nano bubbles can be efficiently generated from an early point in time with the operation of the micro / nano bubble generator.

  Moreover, in one Embodiment, a micro nano bubble consists only of nano bubbles.

  Since nanobubbles can last considerably longer than microbubbles in bathtub water, the action of nanobubbles can be sustained. For example, nanobubbles can last longer than 10 days, depending on size.

  In addition, since nanobubbles are much more effective against the human body than microbubbles, various actions and effects on the human body can be expected.

  Moreover, since the nanobubble has the activation effect with respect to microorganisms much more than a microbubble, the microorganism treatment effect of bath water can be anticipated.

  According to the said embodiment, beneficial to a human body can enlarge an effect.

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

(First embodiment)
Drawing 1 is a figure showing typically bathtub apparatus 1 of a 1st embodiment of the present invention.

  The bathtub device 1 includes a bathtub 38 and a device unit 39. In a state where the bathtub apparatus 1 is installed at a predetermined position, the upper part 40 of the bathtub apparatus 1 is configured only by the upper part of the equipment part 39, and the upper part of the equipment part 39 includes the mineral oil scale container 10 and the bathing agent scale container 11. And have. Hereinafter, when the expression of the vertical direction and the expression of the horizontal direction as above and below are used, it is assumed that it is an expression in a state where the bathtub apparatus 1 is installed at a predetermined position.

  The device unit 39 has a filling material container 50. The filler container 50 is disposed below the mineral oil scale container 10 and the bath salt scale container 11 in the vertical direction. The bathtub 38 and the filling material container 50 constitute a bathtub water container. The filler container 50 is filled with a ring-type polyvinylidene chloride filler 24. The mineral oil scale container 10 and the filler container 50 are connected by a pipe 14, and the automatic diaphragm valve 12 that connects or blocks the mineral oil scale container 10 and the filler container 50 in the middle of the pipe 14. Is arranged. Moreover, the bathing agent scale container 11 and the filler accommodating container 50 are connected by a pipe 15, and an automatic diaphragm that communicates or blocks the bathing agent scale container 10 and the filler accommodating container 50 in the middle of the pipe 15. A valve 13 is arranged. The device unit 39 has a control panel 43. When the automatic diaphragm valve 12 and the automatic diaphragm valve 13 are opened based on a signal from the control panel 43 as a control device, the mineral oil as an example of the foaming agent and the bathing agent are vertically moved by gravity. It moves and is added to the filling material container 50.

  When at least one of the mineral oil and the bathing agent is reduced, at least one of the mineral oil and the bathing agent is replaced with at least one of the mineral oil scale container 10 and the bathing agent scale container 11 from the uppermost part of the device unit 39. It is designed to supply to one side.

  A part of the upper side surface of the device unit 39 is a bathing agent insertion port 9. The bathing agent insertion port 9 can be swung in the vertical direction shown by an arrow a in FIG. When checking the remaining amount of at least one of mineral oil and bathing agent, the bathing agent insertion port 9 is swung upward. In this way, at least one scale of the mineral oil scale container 10 and the bath salt scale container 11 can be confirmed from the horizontal direction.

  In order to generate micro-nano bubbles in the lower part 41 of the bathtub apparatus 1 at the beginning of bathing, a predetermined amount of mineral oil and a predetermined amount of bathing agent are required. The automatic diaphragm valve 12 is opened only for a time for adding a predetermined amount of mineral oil, and a predetermined amount of mineral oil is added into the lower portion 41 of the bathtub apparatus 1. Further, the automatic diaphragm valve 13 is opened only for a time for adding a predetermined amount of bathing agent, and a predetermined amount of input agent is added into the lower portion 41 of the bathtub apparatus 1.

In this embodiment, both mineral oils and bath salts of a foamed material, but is adapted to be added to the filler container 50, in the present invention, of the foamed agent and bath salts Only one of them may be added to the filling container.

  Here, micro-nano bubbles will be described.

  Ordinary bubbles (bubbles) are bubbles that rise in water and eventually disappear on the surface when they pop off. Microbubbles have a bubble diameter of 10 to several tens of μm at the time of their generation, and are bubbles of 50 microns (μm) or less in diameter, shrinking in water and disappearing over time (complete dissolution) ) Or changes to a bubble having a diameter of about 10 μm to several hundred nm. Nanobubbles are bubbles that are even smaller than microbubbles (those with a diameter of several hundred nm or less (particularly, with a diameter of 100 to 200 nm)) and are thought to be able to exist in water indefinitely. is there.

  In this specification, a micro-nano bubble is defined as a bubble having a diameter of several tens of μm or less, that is, a bubble (including a micro-bubble) having a diameter of less than or equal to a micro-bubble. May consist of only).

  The device unit 39 has a small blower 3 at the top and a submersible pump type micro / nano bubble generator 2 at the bottom. The submersible pump type micro / nano bubble generator 2 is disposed in the filler container 50. An upper net 5 is disposed above the submersible pump type micro / nano bubble generator 2 in the filling material container 50, and below the submersible pump type micro / nano bubble generator 2 in the filling material container 50. The lower net 5 is arranged in the front.

  The upper net 5 indicates that the ring-type polyvinylidene chloride filler 24 located above the submersible pump type micro / nano bubble generator 2 is in contact with the submersible pump type micro / nano bubble generator 2 in the filler container 50. The ring-type polyvinylidene chloride filling 24 located below the submersible pump type micro / nano bubble generator 2 is in contact with the submersible pump type micro / nano bubble generator 2 in the filler container 50. To prevent it.

  As the submersible pump type micro / nano bubble generator 2, a Nomura Electronics Co., Ltd. product is adopted. However, the manufacturer is not limited, and any commercially available submersible pump type micro / nano bubble generator can be used in the present invention. What is necessary is just to select a pump type micro nano bubble generator according to the objective.

  The blower 3 supplies air to the submersible pump type micro / nano bubble generator 2. After the automatic diaphragm valve 12 and the automatic diaphragm valve 13 are opened, even when the automatic diaphragm valve 12 and the automatic diaphragm valve 13 are closed, the small blower 3 and the submersible pump type micro / nano bubble generator 2 are It continues to drive and generates micro / nano bubbles at the lower part 41 of the bathtub apparatus 1.

  A control signal generated by the control circuit in the control panel 43 is output to the automatic diaphragm valve 12, the automatic diaphragm valve 13, and the small blower 3 via the signal line 37. In this way, the automatic diaphragm valve 12, the automatic diaphragm valve 13, the small blower 3, and the submersible pump type micro / nano bubble generator 2 are each operated, more specifically, each automatic operation is performed. Yes.

  In addition, it may be determined that sufficient micro / nano bubbles have been generated in some cases when the bathtub apparatus 1 is used, and bathing may be performed with the small blower 3 and the submersible pump type micro / nano bubble generator 2 stopped. Of course.

  In addition, when bathing, in order to increase the effect of bathtub water containing micro-nano bubbles on the human body, the small blower 3 and the submersible pump type micro-nano bubble generator 2 are continuously operated and bathed, while the micro-nano bubbles are bathed. If the effect on the human body of the bath water containing the water is not so much required, the small blower 3 and the submersible pump type micro / nano bubble generator 2 may be stopped and bathed. That is, the person who takes a bath may judge whether the small blower 3 and the submersible pump type micro / nano bubble generator 2 are operated or stopped.

  The blower 3 has an electric cord 22 and a plug 31. The blower 3 is operated when the plug 31 is inserted into the outlet 23. The submersible pump type micro / nano bubble generator 2 receives about 5 liters of air per minute from the small blower 3 through the air pipe 6 and discharges the micro / nano bubbles in the direction of the intermediate net 42. Yes. And the micro nano bubble water flow 16 and 18 containing the micro nano bubble which passed the intermediate part net | network 42 generate | occur | produces in the bathtub 38. FIG.

  The micro / nano bubble water streams 16 and 18 collide with the wall of the bathtub 38. The micro / nano bubble water streams 16 and 18 collide with the wall of the bathtub 38 to form the micro / nano bubble water streams 17 and 19 in the direction opposite to the flow direction of the micro / nano bubble water streams 16 and 18. The submersible pump type micro / nano bubble generator 2 is configured to generate a micro / nano bubble water flow around the entire body of the submersible pump type micro / nano bubble generator 2.

  The submersible pump type micro / nano bubble generator 2 has an electric cord 20 and a plug 33. The plug 33 is connected to the plug receiver 32. Further, the 5 mA earth leakage breaker 21 connected to the plug receiver 32 is inserted into the outlet 23, and the submersible pump type micro / nano bubble generator 2 is electrically connected. It is designed to be used safely.

  When the submersible pump type micro / nano bubble generator 2 leaks in the filling material container 50, it is expected to receive an electric shock. However, since the leakage breaker used is 5 mA, that is, the leakage breaker 21 having a current range that does not affect the human body even when a leakage occurs, the human body may be affected by an electric shock due to the leakage. Absent.

  In general, when a person takes a bath, organic matter as red is liberated from the human body and floats on the surface of the bathtub, giving the person a sense of filth. However, in this embodiment, the ring-type polyvinylidene chloride filling 24 separates the organic matter as red from the bath water and decomposes the microorganisms, so that the organic matter as red floats near the water surface of the bathtub 38. There is almost no.

  Specifically, the ring-type polyvinylidene chloride filler 24 has a negative charge, and the organic substance as red is attached to the ring-type polyvinylidene chloride filler 24. From this, organic matter as red can be removed.

  Furthermore, red is not only efficiently removed from the bathtub water as hot water. That is, with the passage of time, microorganisms that can withstand the high temperature of hot water propagate in the ring-type polyvinylidene chloride filler 24. From this, the organic matter as red sticking to the ring-type polyvinylidene chloride filling 24 can be microbially decomposed, and the bath water which is hot water can be purified.

  From this, the bathtub water as hot water can be recycled by the action of microorganisms that can withstand the high temperature. However, in the case where there is a predetermined amount or more of dirt in the bathtub water, that is, organic matter as red, the rate of increase of organic matter as red is larger than the decomposition rate of organic matter due to the purification action of microorganisms, It is considered that a large amount of red is attached on the surface of the ring-type polyvinylidene chloride filler 24. At this time, the ring-type polyvinylidene chloride filling 24 is cleaned as follows.

  That is, a part of the upper part of the side surface of the filler container 50 serves as the upper net outlet 8, and a part of the lower part of the side surface of the filler container 50 serves as the lower net outlet 7. . The upper net take-out port 8 and the lower net take-out port 7 turn up and down. When it is considered that a large amount of red is attached on the surface of the ring-type polyvinylidene chloride filler 24, the ring-type polyvinylidene chloride filler 24 is taken out from the upper net outlet 8 or the lower net outlet 7. Wash with water and then refill.

  Further, a drain pipe 35 is connected to the bottom of the bathtub 38 via a valve 34. When the bathtub water becomes conspicuous, the valve 34 is opened so that the bathtub water can be drained through the drain pipe 35.

  Experimental data that the microorganisms attached to the ring-type polyvinylidene chloride filler 24 are harmful to the human body has not been obtained at present. That is, it is considered that the microorganisms attached to the ring-type polyvinylidene chloride filler 24 are harmless to the human body. This idea is very likely to be correct because the microorganisms attached to the ring-type polyvinylidene chloride filler 24 are naturally occurring microorganisms in the bath water that is hot water. This is because, among currently known microorganisms, most naturally occurring microorganisms are harmless to the human body.

  Conventionally, the idea of filling a ring-type polyvinylidene chloride filler into a bathtub device so as to contact the bathtub water has not existed. Conventionally, there has been no bathtub apparatus with excellent purification ability.

  However, the present inventor fills the ring-type polyvinylidene chloride filling 24 into the bath apparatus 1 so as to contact the bath water, and causes the ring-type polyvinylidene chloride filling 24 to propagate microorganisms at a high concentration. The microorganisms were decomposed by these microorganisms to successfully improve the purification capability in the bathtub apparatus 1. That is, it succeeded in creating the bathtub apparatus 1 which is excellent in purification capacity.

  According to the bathtub apparatus 1 of the said 1st Embodiment, while the submersible pump type micro nano bubble generator 2 is installed and the mineral oil which is a foaming agent, and a bath agent, the filler with which bathtub water is filled Since it can be thrown into the container 50, the submersible pump type micro / nano bubble generator 2 can generate a large amount of micro / nano bubbles in the bath water, thereby improving the bioactivity effect of the micro / nano bubbles on the human body. be able to.

  Moreover, according to the bathtub apparatus 1 of the said 1st Embodiment, since the ring-type polyvinylidene chloride filling material 24 is filled in the filler container 50, the ring-type polyvinylidene chloride having a negative charge is charged. The filling material 24 can physically adsorb dirt substances (red, etc.) in the bath water and purify the bath water.

  Moreover, according to the bathtub apparatus 1 of the said 1st Embodiment, even if it is a situation where many people bathe in the bathtub apparatus 1 and it is a case where dirt of bathtub water is intense, it is a ring periodically. The ring-type polyvinylidene chloride filling 24 is taken out from the equipment unit 39, and the dirt substance adhering to the ring-type polyvinylidene chloride filling 24 is periodically washed to be removed and cleaned. By simply returning the vinylidene chloride filling 24 to the device section 39, the bath water can be purified easily and inexpensively.

  Moreover, according to the bathtub apparatus 1 of the said 1st Embodiment, the red blood from the human body contained in bathtub water can be biologically decomposed | disassembled by the microorganisms which propagated to the ring-type polyvinylidene chloride filling 24. Since it can, the bathtub water can be purified and recycled.

  Moreover, according to the bathtub apparatus 1 of the said 1st Embodiment, since the submersible pump type micro nano bubble generator 2 and the ring type polyvinylidene chloride filling 24 are accommodated in the same filler accommodating container 50. FIG. In addition, a synergistic effect between the submersible pump type micro-nano bubble generator 2 and the ring-type polyvinylidene chloride filler 24 can be realized. For example, microorganisms that are propagated in the ring-type polyvinylidene chloride filler 24 with micro-nano bubbles, Can be activated. Therefore, the purification ability of bathtub water can be improved significantly.

  In addition, in the bathtub apparatus 1 of 1st Embodiment, the bathtub water storage container was comprised from the filler storage container 50 and the bathtub 38, and the bathtub water storage container was the form which accommodates all the bathtub water. Moreover, the bathtub apparatus 1 was composed of an equipment unit 39 and a bathtub 38.

  Here, the device unit 39 may be separable from the bathtub 38 and may be freely attached to the bathtub 38. In this case, it is needless to say that only the device unit 39 can be used as a product. Here, it is necessary to say that the bathtub device of the present invention can be configured only by the device unit 39. That is, when only the device part 38 is considered as the bathtub device of the present invention, the bathtub water storage container is configured only from the filler storage container 50, and the bathtub water storage container is configured to receive a part of the bathtub water. It becomes.

  That is, the apparatus which has the apparatus part 39 and the bathtub 38 is also the bathtub apparatus of this invention, and the apparatus part 39 only becomes the bathtub apparatus of this invention. This also applies to the second to sixth embodiments described below.

(Second Embodiment)
Drawing 2 is a figure showing typically bathtub apparatus 101 of a 2nd embodiment of the present invention.

  The bathtub apparatus 101 of the second embodiment is different from the bathtub apparatus 1 of the first embodiment only in that the ring-type polyvinylidene chloride filler 24 is replaced with a string-type polyvinylidene chloride filler 29.

  In the bathtub apparatus 101 of 2nd Embodiment, the same reference number is attached | subjected to the component same as the component of the bathtub apparatus 1 of 1st Embodiment, and description is abbreviate | omitted. Moreover, in the bathtub apparatus 101 of 2nd Embodiment, description will be abbreviate | omitted about the effect common to the bathtub apparatus 1 of 1st Embodiment, and only about the structure and effect different from the bathtub apparatus 1 of 1st Embodiment. I will explain.

  The second embodiment is different from the first embodiment in that the ring-type polyvinylidene chloride filler 24 in the first embodiment is replaced with a string-type polyvinylidene chloride filler 29. That is, the material of the filler is the same, but the shape of the filler is different.

  The string-like polyvinylidene chloride filler 29 is fixed to the filler container 50 of the device section 139 by fixing brackets 25, 26, 27, and 28.

  According to the bathtub apparatus 101 of the second embodiment, the physical function and biological function of the filler can be realized in the first embodiment, and the string-type polyvinylidene chloride filler 29 is further provided. Is fixed to the filler container 50 by the fixing metal fittings 25, 26, 27, and 28, and therefore, unlike when the ring-type polyvinylidene chloride filler 24 is used, the filler is formed by the micro-nano bubble water streams 17 and 19. It does not flow. Therefore, compared with 1st Embodiment, a microorganism can be propagated stably.

  Moreover, according to the bathtub apparatus 101 of the said 2nd Embodiment, since the string-type polyvinylidene chloride filler 29 with which various goods are marketed is used as a filler, ring type polychlorination is used as a filler. Compared to the case where the vinylidene filler 24 is used, the manufacturing cost of the apparatus can be reduced. That is, the ring-type polyvinylidene chloride filler 24 has a problem that the product scale is small and the cost is high, but the string-type polyvinylidene chloride filler 29 is low in cost and can be easily and inexpensively constructed. Can do it.

(Third embodiment)
Drawing 3 is a figure showing typically bathtub apparatus 201 of a 3rd embodiment of the present invention.

  The bathtub apparatus 201 of the third embodiment is different from the bathtub apparatus 1 of the first embodiment only in that the ring-type polyvinylidene chloride filler 24 is replaced with a nylon filler 30.

  In the bathtub apparatus 201 of 3rd Embodiment, the same reference number is attached | subjected to the component same as the component of the bathtub apparatus 1 of 1st Embodiment, and description is abbreviate | omitted. Moreover, in the bathtub apparatus 201 of 2nd Embodiment, description will be abbreviate | omitted about the effect common to the bathtub apparatus 1 of 1st Embodiment, and only about the structure and effect different from the bathtub apparatus 1 of 1st Embodiment. I will explain.

  In the third embodiment, the ring-type polyvinylidene chloride filler 24 in the first embodiment is replaced with a nylon filler 30. That is, as compared with the first embodiment, the filler material is different and the shape is slightly different.

According to the bathtub apparatus 201 of the said 3rd Embodiment, since the goods 30 made from nylon arrange | positioned at the filler storage container 50 of the apparatus part 239 are sold many goods, and the cost of a filler is low, The apparatus can be constructed at low cost. In addition, although the adhesion and propagation of microorganisms are inferior to the ring-type polyvinylidene chloride filler 24, the nylon filler 30 has high strength, so that damage to the filler can be suppressed.
(Fourth embodiment)
Drawing 4 is a figure showing typically bathtub apparatus 301 of a 4th embodiment of the present invention.

  The bathtub apparatus 301 of the fourth embodiment is different from the bathtub apparatus 1 of the first embodiment only in that the ring-type polyvinylidene chloride filler 24 is replaced with activated carbon 36.

  In the bathtub apparatus 301 of 4th Embodiment, the same reference number is attached | subjected to the same structure part as the structure part of the bathtub apparatus 1 of 1st Embodiment, and description is abbreviate | omitted. Moreover, in the bathtub apparatus 301 of 4th Embodiment, description will be abbreviate | omitted about the effect common to the bathtub apparatus 1 of 1st Embodiment, and only about the structure and effect different from the bathtub apparatus 1 of 1st Embodiment. I will explain.

  In the fourth embodiment, activated carbon 36 is accommodated in the filler container 50 of the device unit 339. That is, as compared with the first embodiment, the filler is replaced with the activated carbon 36 from the ring-type polyvinylidene chloride filler 24, and the material of the filler and the shape of the filler are greatly different.

  According to the bathtub device 301 of the fourth embodiment, although activated carbon 36 is inferior to the ring-type polyvinylidene chloride filler 24 in the attachment and propagation of microorganisms, many products are sold in the activated carbon 36. Since the cost is low, the apparatus can be constructed at low cost.

  Moreover, according to the bathtub apparatus 301 of 4th Embodiment, since a filler is the activated carbon 36, a microorganism can be propagated on the surface of the activated carbon 36, and organic matter can be decomposed | disassembled into microorganisms. Moreover, since activated carbon has an organic substance adsorption | suction capability and a decoloring capability, while being able to deodorize the smell of bathtub water, the color of bathtub water itself can be maintained transparent. In addition, since the microorganisms propagated on the activated carbon 36 are activated by the micro-nano bubbles, the organic matter adsorbed by the activated carbon 36 can be efficiently treated with the activated microorganisms, and the replacement of the activated carbon 36, that is, until the activated carbon 36 is regenerated. Can be lengthened.

(Fifth embodiment)
Drawing 5 is a figure showing typically bathtub apparatus 401 of a 5th embodiment of the present invention.

  In the bathtub forming apparatus 401 of the fifth embodiment, the ring-type polyvinylidene chloride filler 24 is not filled with the filler in the container 150 constituting a part of the lower part of the device unit 439. Different from the first embodiment in which the container 50 is filled.

  In the bathtub apparatus 401 of 5th Embodiment, the same reference number is attached | subjected to the same structure part as the structure part of the bathtub apparatus 1 of 1st Embodiment, and description is abbreviate | omitted. Moreover, in the bathtub apparatus 401 of 5th Embodiment, description is abbreviate | omitted about the effect common to the bathtub apparatus 1 of 1st Embodiment, and it is only about the structure and effect different from the bathtub apparatus 1 of 1st Embodiment. I will explain.

  In 5th Embodiment, since it does not have a filler, the lower part of the apparatus part 439 becomes only the submersible pump type micro nano bubble generator 2. FIG. Therefore, the structure can be simplified and the manufacturing cost can be reduced.

(Sixth embodiment)
Drawing 6 is a figure showing typically bathtub apparatus 501 of a 6th embodiment of the present invention.

  In the bathtub apparatus 501 of the sixth embodiment, the main body of the nanobubble generator 44 is installed outside the filler container 50, and the suction port 45 and the outlet 46 of the nanobubble generator 44 are inside the filler container 50. The arrangement is different from the bathtub apparatus 1 of the first embodiment in which the entire submersible pump type micro / nano bubble generator 2 is installed in the filling material container 50.

  In the bathtub apparatus 501 of 6th Embodiment, the same reference number is attached | subjected to the component same as the component of the bathtub apparatus 1 of 1st Embodiment, and description is abbreviate | omitted. Moreover, in the bathtub apparatus 501 of 6th Embodiment, description is abbreviate | omitted about the effect common to the bathtub apparatus 1 of 1st Embodiment, and it is only about the structure and effect different from the bathtub apparatus 1 of 1st Embodiment. I will explain.

  In the sixth embodiment, the main body of the nanobubble generator 44 is installed outside the filler container 50 and the bathtub 38, and the suction port 45 and the outlet 46 of the nanobubble generator 44 are installed inside the filler container 50. ing.

  According to the bathtub device 501 of the sixth embodiment, since only nanobubbles can be generated from the outlet 46, the bathtub water can be filled with nanobubbles and the filled nanobubbles can be maintained. Thus, many physiological effects beneficial to the human body can be exerted on the human body, such as an increase in blood flow to the human body.

  Unlike the conventional micro / nano bubble generator 2, the nano bubble generator 44 can form nano bubbles by operating a large power pump to ensure high pressure and flow velocity. As a method of the nanobubble generator 43, there is a gas-liquid mixed gas shearing method. It is proved from the measurement data of Beckman Coulter, Inc., a clinical trial company, that the bubble generated by the nanobubble generator 43 is only nanobubbles. In addition, in 6th Embodiment, although the nano bubble generator 44 of Kyowa Kikai Co., Ltd. was employ | adopted as a nano bubble generator, of course, the manufacturer of the nano bubble generator which can be used is not restricted to Kyowa Kikai Co., Ltd. is there.

This inventor confirmed the effect of this invention using the bathtub apparatus 1 of 1st Embodiment. That is, the capacity of the bathtub water container, that is, the capacity of the filler container 50 and the bathtub 38 is 0.2 m ³ , the capacity of the bathtub part 38 is 0.16 m ^3, and the capacity of the filler container 50 is , 0.04 m ³ , the bath apparatus 1 was manufactured, mineral oil and a bath agent were added, and micro-nano bubbles were ideally generated to create a milk bath state. Then, pure white micro / nano bubbles are generated in the bathtub device 1, and the above-mentioned diabetic patient has a foot bath in the bathtub 38 for about 1 hour in a state where the micro / nano bubble water stream constantly collides with the diabetic patient's foot. After bathing, the feet were observed. Compared to the case where the diabetic patient had foot bath in the bathtub for about 1 hour in a state where the water flow of the bathtub water having the same temperature and no micro-nano bubbles collided with the foot of the diabetic patient. I confirmed that my feet were clearly red. Moreover, when the bathtub apparatus 1 was used for a long period, it was confirmed that a feeling of numbness was temporarily canceled. Also, from a scientific point of view, in one patient, the blood glucose level after fasting and after eating the bathtub apparatus 1 is 10% compared to before using the bathtub apparatus 1, although it varies depending on the day. It was confirmed that the rate dropped dramatically in the range of 30%.

It is a figure which shows typically the bathtub apparatus of 1st Embodiment of this invention. It is a figure which shows typically the bathtub apparatus of 2nd Embodiment of this invention. It is a figure which shows typically the bathtub apparatus of 3rd Embodiment of this invention. It is a figure which shows typically the bathtub apparatus of 4th Embodiment of this invention. It is a figure which shows typically the bathtub apparatus of 5th Embodiment of this invention. It is a figure which shows typically the bathtub apparatus of 6th Embodiment of this invention.

DESCRIPTION OF SYMBOLS 1,101,201,301,401,501 Bath apparatus 2 Submersible pump type micro nano bubble generator 3 Blower 4 Lower net 5 Upper net 6 Air piping 7 Lower net take-out port 8 Upper net take-out port 9 Mineral oil and bath agent insertion port 10 Mineral Oil Scale Container 11 Bath Agent Scale Container 12 Automatic Diaphragm Valve 13 Automatic Diaphragm Valve 14 Piping 15 Piping
16 Micro-nano bubble water flow 17 Micro-nano bubble water flow 18 Micro-nano bubble water flow 19 Micro-nano bubble water flow 20 Electric cord 21 5 mA earth leakage breaker 22 Electric cord 23 Outlet 24 Ring type polyvinylidene chloride filling 25 Fixing fixture 26 Fixing fixture 27 Fixing fixture 28 Fixing fixture 29 String-type polyvinylidene chloride filling 30 Nylon filling 31 Insertion 32 Insertion receptacle 33 Insertion 34 Valve 35 Drainage pipe 36 Activated carbon 37 Signal line 38 Bathtub 39 Equipment part 40 Upper part 41 Lower part 42 Middle part net 43 Control panel 44 Nano bubble generator 45 Suction port 46 Outlet port 50 Filler container

Claims (9)

A bathtub water storage container for storing at least part of the bathtub water;
A micro / nano bubble generator for generating micro / nano bubbles in the bathtub water in the bathtub water storage container;
And a injection device for injecting at least one of the foamed agent and bath salts in the bath water container,
The injection device is
A mineral oil scale container containing mineral oil;
A bath salt scale container for storing bath salt,
A first control valve disposed in the course of the flow of mineral oil from the mineral oil scale container to the bath water container;
A second control valve disposed in the course of the bathing agent flow from the bathing agent graduated container to the bath water storage container;
A control device for controlling the opening and closing of the first control bubble and for controlling the opening and closing of the second control valve;
Have
The micro-nano bubble generator is a submersible pump type micro-nano bubble generator arranged in the bathtub water storage container,
It has a blower that sends air to the submersible pump type micro / nano bubble generator,
The control unit is characterized that you have to control the timing for sending the air to the water pump-type micro-nano bubble generator from the blower, the amount of air sent to the water pump-type micro-nano bubble generator from the blower Bathtub equipment. The bathtub apparatus according to claim 1,
The said injection apparatus inject | pours mineral oil or mineral oil, and a bath agent into the said bathtub water storage container, The bathtub apparatus characterized by the above-mentioned. The bathtub apparatus according to claim 1,
A bathtub apparatus in which a filler is disposed in the bathtub water storage container. In the bathtub apparatus according to claim 3,
The bathtub device is characterized in that the filler is a ring-type polyvinylidene chloride filler. In the bathtub apparatus according to claim 3,
The bathtub device characterized in that the filler is a string-type polyvinylidene chloride filler. In the bathtub apparatus according to claim 3,
The bathtub device characterized in that the filler is a nylon filler. In the bathtub apparatus according to claim 3,
The bathtub device, wherein the filler is activated carbon. The bathtub apparatus according to claim 1,
The micro-nano bubble generator is a nano bubble generator that generates only nano bubbles. The bathtub apparatus according to claim 1,
The bathtub water storage container stores a part of bathtub water.

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