JP2013233409A - Washing system, drinking water producing system, foot bath system, and jet bath system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an apparatus which can generate hydrogen-dissolved water with a simple structure for improving health and beauty.SOLUTION: A washing system 1 includes a hydrogen-generating system 2 for generating hydrogen by electrolyzing an electrolyte 12 and a washing unit 30 constituted for receiving a face and can store water inside. The washing unit 30 includes a mixing rotodynamic pump 40 for agitating and mixing hydrogen supplied from the hydrogen-generating system 2 and water stored in the washing unit 30 in a casing 41 by the rotation of an impeller 50, and a water-flow forming rotodynamic pump 70 forming a water flow in the washing unit 30 by the rotation of the impeller 50.

Description

  The present invention relates to a technique for generating and using water in which hydrogen is dissolved.

  As a method of dissolving hydrogen in water, nitrogen and oxygen dissolved in water are removed using a gas diffusion semipermeable membrane and a reduced pressure, and then hydrogen is added using high pressure hydrogen and a gas diffusion semipermeable membrane. Can be dissolved in water. According to this method, hydrogen can be efficiently dissolved in water, but a complicated apparatus is required for its implementation.

  Patent Document 1 below describes a gas-dissolved water production apparatus that produces hydrogen-dissolved water by dissolving hydrogen generated by electrolysis in water. In this manufacturing apparatus, since hydrogen-dissolved water is used for a cleaning operation in a semiconductor manufacturing process, only hydrogen out of hydrogen and oxygen generated by water electrolysis is extracted and dissolved in pure water.

Japanese Patent Laid-Open No. 11-244677

  By the way, water in which hydrogen is dissolved (hereinafter referred to as hydrogen-dissolved water) is said to have an antioxidant action that neutralizes active oxygen in the human body, and has attracted attention as a health functional water in medical societies and medical institutions. ing. There is a desire to promote human health and beauty by generating hydrogen-dissolved water having such effects at home and using it.

  Then, although using the gas-dissolved water manufacturing apparatus of patent document 1 is also considered, since the said manufacturing apparatus is a structure which extracts only hydrogen among the hydrogen and oxygen which generate | occur | produced by the electrolysis of water, apparatus is It is complicated and unsuitable for home use. In addition, as in the technique described in Patent Document 1, it is relatively easy to dissolve hydrogen in pure water that does not contain any nitrogen or oxygen. However, in household devices, pure water is used. It is difficult to do. In household devices, it is necessary to generate hydrogen-dissolved water by mixing hydrogen with relatively easily available water such as mineral water and tap water. In addition, household devices are required to generate hydrogen-dissolved water with a relatively simple configuration.

  An object of the present invention is to provide an apparatus that can generate hydrogen-dissolved water with a simple configuration and promote health and beauty using the hydrogen-dissolved water.

  The washing system of the present invention includes a hydrogen generator that generates hydrogen by electrolyzing an electrolytic solution, a washing unit that is configured to receive a face and can store water therein, and the washing unit. A turbo pump for mixing that mixes the hydrogen supplied from the hydrogen generator and water stored in the wash unit in the casing by rotation of the impeller, and is provided in the wash unit. The gist of the present invention is to provide a water flow forming turbo pump for forming a water flow in the wash unit by the rotation of the impeller.

  The said wash system WHEREIN: The said wash unit shall be comprised so that attachment or detachment is possible with respect to the basement to which the said hydrogen generator was fixed.

  In the above wash system, the wash unit is configured to receive a face so that the inner diameter increases toward the vertical upper side, and the wash unit is provided vertically below the wash unit. The mixing turbo pump and the water flow forming turbo pump may be provided on the support.

  In the washing system, the mixing turbo pump may be provided at the bottom of the support unit and at the bottom of the washing unit, the blade of the mixing turbo pump. The vehicle may include a magnet, and the basement is provided with an electric motor in which at least one of attractive force and repulsive force is coupled to the rotor and coupled to the rotor. can do.

  The said wash system WHEREIN: The said turbo flow pump for water flow formation shall be provided in the cylindrical wall which is a substantially cylindrical wall body among the said support parts.

  In the washing system, the water flow forming turbo pump may be arranged such that the suction port faces the mixing turbo pump.

  In the above washing system, the water flow forming turbo pump may be arranged such that water discharged from a discharge port forms a flow along the cylindrical wall.

  The drinking water production system of the present invention includes a hydrogen generator that generates hydrogen by electrolyzing an electrolyte, a beverage container capable of storing water therein, the beverage container, and the hydrogen container. The gist of the invention is to provide a mixing turbo pump that mixes hydrogen supplied from the generator and water stored in the beverage container in the casing by rotation of the impeller.

  In the drinking water manufacturing system, the beverage container may be configured to be detachable from a basement to which the hydrogen generator is fixed.

  Furthermore, the foot bath system of the present invention is configured to be able to receive both legs up to below the knee, a foot bath unit capable of accumulating hot water inside, and the foot bath unit, and the electrolytic solution is electrolyzed. A hydrogen generator for generating hydrogen by the operation, a hydrogen provided in the foot bath unit, supplied from the hydrogen generator, and hot water stored in the foot bath unit by a rotation of an impeller. The gist of the invention is to provide a mixing turbo pump to be mixed inside.

  In the foot bath system, a hot water reservoir is provided at the bottom of the foot bath unit via a slat member, an electric heater is provided in the hot water reservoir, and the mixing reservoir is provided at one end of the hot water reservoir. The blowout port of the turbo pump can be connected.

  In addition, the jet bath system of the present invention is a jet bath unit that is installed on the wall surface in the bathtub by an adsorbing member, and the inside of the jet bath unit is sealed. And a hydrogen generator provided in the jet bath unit, and hydrogen supplied from the hydrogen generator and hot water sucked from the bathtub are mixed in the casing by rotation of an impeller, and the nozzle is connected to the bathtub. The gist is to include a jet water flow pump to be discharged into the inside.

  The jet bath system may include an air valve for supplying air to the suction port of the mixing turbo pump to generate bubbles.

  According to the present invention, it is possible to generate hydrogen-dissolved water with a simple configuration at home and promote health and beauty using the hydrogen-dissolved water.

It is sectional drawing of the washing system of 1st Embodiment. It is sectional drawing which shows the surrounding structure of the turbo pump for mixing of 1st Embodiment. It is sectional drawing which shows the structure of the periphery of the impeller of the turbo pump for mixing of 1st Embodiment, and is an expanded sectional view of FIG. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a component diagram showing the entirety of a water flow forming turbo pump according to a first embodiment. It is an expanded sectional view of the impeller periphery of the turbo flow pump for water flow formation shown in FIG. It is a schematic diagram explaining the arrangement | positioning of the water flow formation turbo pump of 1st Embodiment, and the flow direction of the water which the said water flow formation turbo pump discharges. It is sectional drawing of the drinking water manufacturing system of 2nd Embodiment. It is a top view of the foot bath system of a 3rd embodiment. It is sectional drawing of a foot bath system. It is a figure which shows an example of a hydrogen generator, (a) is a front view, (b) is a side view. It is a figure which shows an example of a jet water flow pump, (a) is sectional drawing, (b) is a suction port side front view. It is a figure which shows the jet bath system of 4th Embodiment, (a) is a top view, (b) is a front view, (c) is a side view, (d) is a rear view. It is a figure which shows the internal structure of a jet bath system. It is a figure which shows an example of the wall-mounted type controller of a jet bath system.

Hereinafter, embodiments of the present invention (hereinafter referred to as embodiments) will be described in detail with reference to the drawings. In addition, this invention is not limited to the following embodiment, A various change is possible in the range which does not deviate from the summary.
[First embodiment]

  First, the outline of the structure of the washing system of this embodiment is demonstrated using FIG. FIG. 1 is a cross-sectional view of the washing system of this embodiment. As shown in FIG. 1, the washbasin system 1 generates hydrogen dissolved water by dissolving hydrogen generated in the hydrogen generator 2 that generates hydrogen by electrolyzing an electrolytic solution 12 and water generated in the hydrogen generator 2. And a wash unit 30 for washing the face and the like. The hydrogen generator 2 is fixedly provided vertically above the basement 20. On the other hand, the wash unit 30 is detachably provided above the basement 20.

  The hydrogen generator 2 has an electrolytic cell 5 for electrolyzing the electrolytic solution 12. The electrolytic cell 5 includes a substantially cylindrical wall body (hereinafter referred to as a cylindrical wall) 6 whose axial center extends in the vertical direction, and a bottom 7 that extends in the horizontal direction from the vertical lower edge of the cylindrical wall 6. And have. In addition, the electrolytic cell 5 has a lid 8 that closes the opening on the vertical upper side of the cylindrical wall 6. The lid 8 is configured to be detachable from the cylindrical wall 6, and a sealing member 9 for sealing the inside of the electrolytic cell 5 is provided between the cylindrical wall 6 and the lid 8. . For the seal member 9, for example, an O-ring is used. With the lid 8 opened, the electrolytic solution is poured into the electrolytic cell 5 from the opening vertically above the cylindrical wall 6, the lid 8 is attached to the cylindrical wall 6, and the electrolytic cell is sealed.

  As the electrolytic solution filled in the electrolytic bath 5, for example, an aqueous solution in which an electrolyte is dissolved in water such as distilled water or ion-exchanged water is used. As the electrolyte, a carboxylic acid that is not toxic even if it enters the human body by mistake and is safe to handle is used. In this embodiment, an aqueous solution of citric acid having a mass concentration of 5% is used as the electrolytic solution. Sodium citrate is used because it is less decomposed and altered by electrolysis, has good ionic conductivity even at low concentrations, and is inexpensive.

  In the above-described embodiment, sodium citrate is used as the electrolyte used to make the electrolyte of the hydrogen generator 2. However, the electrolyte is not limited to this. As the electrolyte, in addition to sodium citrate, citric acid, malic acid, tartaric acid, or the like may be used.

  From the bottom 7 of the electrolytic cell 5, two electrodes 10 and 11 for electrolyzing the electrolytic solution, specifically, the anode 10 and the cathode 11 extend vertically upward with a predetermined interval. The anode 10 is electrically connected to the anode terminal 24 in the basement 20. Similarly, the cathode 11 is electrically connected to the cathode terminal 25 in the basement 20. In the basement 20, the anode terminal 24 and the cathode terminal 25 are connected to a power source (not shown) and receive power supply from the power source.

  The anode 10 and the cathode 11 are preferably a pair of platinum-plated titanium electrodes. This is because the platinum-plated titanium electrode can withstand long-time electrolysis. Note that the anode 10 and the cathode 11 are not limited to titanium electrodes, but platinum-plated titanium electrodes are suitable as they can withstand long-time electrolysis.

  In the electrolytic cell 5, the electrolytic solution is filled so that the whole of the anode 10 and the cathode 11 is immersed. When a DC voltage of 12 V is applied between the anode 10 and the cathode 11, the electrolytic cell 5 electrolyzes the electrolyte to generate oxygen from the anode 10 side and hydrogen from the cathode 11 side. Let In this way, the hydrogen generator 2 generates hydrogen by electrolyzing the electrolytic solution.

  In addition, the hydrogen generator 2 is provided with a housing 15 that covers the electrolytic cell 5 so that the electrolytic cell 5 does not directly touch a human hand. The housing 15 has a substantially cylindrical shape, is provided with a support portion 17 that covers the periphery of the cylindrical wall 6 of the electrolytic cell 5, and a vertical upper side of the support portion 17, and has a substantially dome shape. 5 and a lid portion 18 that covers the periphery of the lid 8. That is, an air layer is formed between the electrolytic cell 5 and the housing 15. The lid portion 18 is formed with a vent hole 19 that allows the air layer in the housing 15 and the outside air to communicate with each other. By configuring the housing 15 in this way, when the electrolytic solution is electrolyzed in the electrolytic cell 5 and the electrolytic cell 5 is heated, the heat can be dissipated to the outside air through the vent hole 19. And it can prevent that a human hand touches the electrolytic cell 5 directly.

  The electrolytic cell 5 is provided with a hydrogen introduction pipe 22 that guides hydrogen in the electrolytic cell 5 toward the washing unit 30. The hydrogen introduction pipe 22 extends vertically upward from the bottom 7 of the electrolytic cell 5 and extends to the vicinity of the lid 8. The hydrogen introduction pipe 22 passes through the bottom 7 and extends inside the basement 20 toward the washing unit 30. The hydrogen introduction pipe 22 introduces oxygen and hydrogen generated by electrolysis of the electrolytic solution into the electrolytic bath 5 and guides them toward the washing unit 30. The hydrogen introduction pipe 22 is connected to the hydrogen supply pipe 28 via connectors 60 and 65 described later (see FIG. 2).

  The washbasin unit 30 is connected to a bottomed substantially cylindrical portion (hereinafter referred to as a support portion) 32 and a vertically upper portion of the support portion 32 so as to receive a human face. And a portion (hereinafter referred to as a “washing surface portion”) 35 formed so that the inner diameter becomes larger as it goes to. In other words, the wash unit 35 has a general washbasin shape, and is configured to receive a human face and wash the face. The support unit 32 is provided with respect to the wash unit 35. It is provided vertically below. The support part 32 and the washing part 35 are manufactured as separate parts. The vertical upper edge of the support part 32 and the vertical lower edge of the wash part 35 are connected to form the wash unit 30. The connection portion is hereinafter referred to as a connection portion 36.

  The support unit 32 of the washbasin unit 30 includes a substantially cylindrical wall body (hereinafter referred to as a cylindrical wall) 33 and a bottom portion (hereinafter referred to as “horizontal”) extending from a vertical lower edge of the cylindrical wall 33. , Referred to as the unit bottom). That is, the unit bottom 34 is the bottom of the support 32 and the bottom of the wash unit 30. A mixing turbo pump 40 for mixing the hydrogen generated by the hydrogen generator 2 with the water stored in the washing unit 30 is provided at the unit bottom 34 of the support 32. On the other hand, in the middle of the cylindrical wall 33 of the support portion 32, a water flow forming turbo pump 70 that forms a water flow in the water stored in the wash unit 30 is provided.

  In the following description, among the members constituting the basement 20, a member closest to the wash unit 30 side, that is, a member (wall body) in contact with the unit bottom 34 is referred to as a “top wall” and denoted by reference numeral 21.

  Next, the peripheral structure of the mixing turbo pump 40 will be described with reference to FIG. FIG. 2 is a cross-sectional view showing a peripheral structure of the mixing turbo pump.

  As shown in FIG. 2, a mixing turbo pump 40 for mixing hydrogen and water is provided at a portion of the unit bottom 34 through which the cylindrical axis of the cylindrical wall 33 passes, that is, at the center of the unit bottom 34. Is provided. The mixing turbo pump 40 is a centrifugal pump having an impeller 50 and a casing 41 that houses the impeller 50. The casing 41 is provided with an impeller housing portion 43 that is coupled to the unit bottom portion 34 and houses the impeller 50, and extends vertically upward from the impeller housing portion 43, and is connected to the hydrogen supply pipe 28 for electrolysis. It has a supply pipe connecting part 45 that guides hydrogen supplied from the tank 5 into the impeller accommodating part 43.

  Note that a space inside the impeller housing portion 43 for rotating and stirring the impeller 50 to mix hydrogen and water is referred to as a “stirring chamber” in the following description. Is denoted by C.

  A nipple 46 to which the hydrogen supply pipe 28 is connected is formed on the uppermost vertical side of the supply pipe connecting portion 45. The hydrogen supply pipe 28 is configured by a flexible hose or the like, and one end thereof is inserted into the nipple 46. The other end of the hydrogen supply pipe 28 is connected to the connector 60.

  A connector (hereinafter referred to as a bottom side connector) 60 for guiding hydrogen from the electrolytic cell 5 to the hydrogen supply pipe 28 is fixed to the unit bottom portion 34 radially outside the mixing turbo pump 40. A check valve 63 is provided inside the bottom connector 60. In the state attached to the unit bottom portion 34, a nipple 61 is formed vertically above the bottom side connector 60, and the end of the hydrogen supply pipe 28 is inserted into the nipple 61. A passage 62 is formed in the bottom connector 60, and the passage 62 is connected to a check valve 63. Details of the check valve 63 will be described later.

  On the other hand, a connector (hereinafter referred to as a top wall side connector) 66 for guiding hydrogen from the electrolytic cell 5 to the hydrogen supply pipe 28 is also fixed to the top wall 21 of the basement 20. A passage 66 is formed inside the top wall connector 65. The passage 66 communicates with the hydrogen introduction pipe 22 described above and receives supply of hydrogen from the electrolytic cell 5 (see FIG. 1). As shown in FIG. 2, the top wall side connector 65 and the bottom side connector 60 are connected in a state where the wash unit 30 is installed on the basement 20, that is, in a state where the unit bottom 34 is in contact with the top wall 21. At this time, the passage 66 of the top wall connector 65 can communicate with the passage 62 of the bottom connector 60 and the passage in the hydrogen supply pipe 28 with the check valve 63 interposed therebetween.

  The check valve 63 of the bottom-side connector 60 allows a flow from the hydrogen introduction pipe 22 (see FIG. 1) of the electrolytic cell 5 toward the hydrogen supply pipe 28 for supplying hydrogen to the mixing turbo pump 40, and in the reverse direction. Configured to stop the flow of That is, the check valve 63 is configured to stop the flow from the mixing turbo pump 40 toward the electrolytic cell 5. By providing the check valve 63 on the unit bottom 34 of the wash unit 30, when the wash unit 30 is removed from the basement 20, the water stored in the wash unit 30 is mixed with the mixing turbo pump 40 and the hydrogen. The supply pipe 28 is prevented from flowing back and leaking out of the wash unit 30.

  The wash unit 30 configured in this manner is configured to be able to store water in the inside thereof, that is, the support unit 32 and the wash unit 35, and is configured to be able to receive a face in the wash unit 35. ing. The wash unit 30 is configured to be detachable from the basement 20 to which the hydrogen generator 2 is fixed.

  Next, the structure around the impeller 50 of the mixing turbo pump 40 will be described with reference to FIG. FIG. 3 is a cross-sectional view showing the structure around the impeller of the mixing turbo pump, and is an enlarged cross-sectional view of FIG.

  As shown in FIG. 3, the mixing turbo pump 40 includes an impeller 50 whose blades 55 agitate and mix water and hydrogen, and the impeller 50, and is supplied from the hydrogen supply pipe 28. And a casing 41 for guiding the generated hydrogen toward the impeller 50. The casing 41 is coupled to the unit bottom 34 by screws or the like. A shaft 47 extending in the vertical direction and rotatably supporting the impeller 50 is provided at a substantially center of the unit bottom 34, that is, a portion of the unit bottom 34 through which the axis of the casing 41 passes. The impeller 50 rotates around 47. The rotation center axis of the impeller 50 of the mixing turbo pump 40 is indicated by a one-dot chain line B in the figure. The rotation center axis of the impeller 50 coincides with the axis of the shaft 47.

  The impeller 50 is provided so as to cover the periphery of the shaft 47, has a portion 52 (hereinafter referred to as a shaft portion) in contact with the shaft, and a substantially annular shape centering on the shaft 47. And a portion 53 (hereinafter referred to as an annular portion). The shaft portion 52 and the annular portion 53 are integrally coupled. A vertically upper end (hereinafter referred to as a shaft end) 51 of the shaft portion 52 is rotatably supported by a bearing 48 provided in the casing 41. Thereby, the impeller 50 can be rotated around the shaft 47 without being displaced in the vertical direction.

  The bearing 48 is configured to allow hydrogen supplied from the hydrogen supply pipe 28 to pass through the stirring chamber C. For example, it is also preferable to provide a through hole (not shown) that allows the hydrogen supply pipe 28 and the stirring chamber C to communicate with each other. Moreover, the bearing 48 can also be comprised with the porous member which can let hydrogen pass.

  In addition, the impeller 50 is provided with vanes 55 for stirring water and hydrogen. The blade 55 is provided so as to protrude vertically upward from the annular portion 53 of the impeller 50. When the impeller 50 rotates, the blade 55 stirs the water stored in the wash unit 30 and the hydrogen supplied from the hydrogen supply pipe 28 in the stirring chamber C, and mixes the hydrogen with the water. The impeller 50 of the present embodiment is provided with four blades 55 at equal intervals in the circumferential direction of the shaft 47. A vertical upper edge 55 a of the blade 55 is set to face the slit 44 in the radial direction of the shaft 47.

  On the other hand, the impeller housing portion 43 of the casing 41 is formed with a slit 44 that allows the stirring chamber C in the casing 41 to communicate with the outside of the casing 41. The slit 44 is configured such that its longitudinal direction is along the vertical direction. The slit 44 is provided so as to face the edge 55a on the vertical upper side of the blade 55 of the impeller 50. Similar to the blades 55, four slits 44 are provided at equal intervals in the circumferential direction of the shaft 47. The slit 44 allows the inside and outside of the casing 41 to communicate with the blade 55 of the impeller 50 at a portion radially outside the rotation center axis B. Water in the washing unit 30 flows into the stirring chamber C from the slit 44. The water that has flowed into the stirring chamber C is mixed with hydrogen by the rotation of the impeller 50, and then discharged from the slit 44 to the outside of the casing 41 again.

  The mixing turbo pump 40 has an electric motor 58 for rotating the magnet 59 to rotate the impeller 50. A magnet 59 having a substantially cylindrical shape is coupled to a rotor (not shown) of the electric motor 58. The magnet 59 has N and S poles alternately formed in the circumferential direction of the rotation center axis. Similarly, the magnet 54 of the impeller 50 is alternately formed with N poles and S poles in the circumferential direction of the rotation center axis. Between the magnet 59 of the electric motor 58 and the magnet 54 of the annular portion 53 of the impeller 50, the force attracting each other with the top wall 21 of the basement 20 and the unit bottom 34 of the wash unit 30 interposed therebetween (so-called attractive force). And at least one of the forces (so-called repulsive forces) that generate energy with each other acts. With this action, when the magnet 59 of the electric motor 58 is rotationally driven, the impeller 50 including the magnet 54 is driven and rotated. In this way, the mixing turbo pump 40 is configured to be able to rotationally drive the impeller 50 by powering the electric motor 58.

  As shown in FIGS. 1 to 4, the mixing turbo pump 40 configured as described above is supplied to the stirring chamber C with the hydrogen received from the electrolytic cell 5 by the rotational drive of the impeller 50 by the electric motor 58. A certain amount of water is stirred in the stirring chamber C. Thus, the mixing turbo pump 40 mixes water and hydrogen in the stirring chamber C to generate hydrogen-dissolved water. The hydrogen-dissolved water generated in the stirring chamber C is discharged from the slit 44 of the mixing turbo pump 40. The hydrogen-dissolved water discharged from the slit 44 diffuses into the water stored in the support portion 32 and the wash surface portion 35 of the wash unit 30. As described above, in the washing unit 30, the mixing turbo pump 40 uses the impeller 50 to supply the hydrogen supplied from the hydrogen generator 2 and the water stored inside (that is, the support part 32 and the washing part 35). The hydrogen dissolved in the water is mixed by mixing the hydrogen supplied from the hydrogen generator 2 with the water stored inside.

  Next, a water flow forming turbo pump 70 that forms a water flow in the water stored in the support portion 32 and the wash surface portion 35 in the wash unit 30 will be described with reference to FIGS. 1 and 4 to 6. FIG. 4 is a component diagram showing the entire water flow forming turbo pump according to the first embodiment. FIG. 5 is an enlarged cross-sectional view in which the periphery of the impeller of the water flow forming turbo pump shown in FIG. 4 is enlarged. FIG. 6 is a schematic diagram for explaining the arrangement of the water flow forming turbo pump and the flow direction of water discharged from the water flow forming turbo pump.

  As shown in FIG. 1, the water flow forming turbo pump 70 is a centrifugal pump having an impeller 80 and a casing for housing the impeller 80. The water flow forming turbo pump 70 is provided on the cylindrical wall 33 of the support portion 32 of the wash unit 30. As shown in FIG. 6, the water flow forming turbo pump 70 is provided in the middle of the cylindrical wall 33 in the circumferential direction of the rotation center axis (indicated by a point B in the figure). In the washing system 1, the water flow forming turbo pump 70 is arranged to face the hydrogen generator 2 (that is, the electrolytic cell 5) with the mixing turbo pump 40 interposed therebetween.

  As shown in FIG. 4, the water flow forming turbo pump 70 includes an impeller 80, an electric motor 88 for rotating the impeller 80, and a magnet 89 that is rotationally driven by the electric motor 88. doing. In addition, the rotation center axis | shaft of the impeller 80 of the turbo pump 70 for water flow formation is shown with the dashed-dotted line D in a figure.

  The casing of the water flow forming turbo pump 70 has a wall body (hereinafter referred to as an impeller housing wall) 73 that houses an impeller 80 and a wall body (hereinafter referred to as an impeller housing wall) 73 that houses a magnet 89 that is driven to rotate by an electric motor 88. 76, and a wall body that is provided between the impeller housing wall 73 and the magnet housing wall 76 and separates the space that houses the impeller 80 and the space that houses the magnet 89. (Hereinafter referred to as a partition wall) 75. The casing of the water flow forming turbo pump 70 has a tubular portion 79 (hereinafter referred to as a suction pipe) extending from the impeller housing wall 73 toward the suction side opening 74. These are integrally joined to form a casing (73, 75, 76, 79). The said casing (73,75,76,79) is fixed to the cylindrical wall 33 of the support part 32 of the wash unit 30 (refer FIG. 1). The detailed arrangement of the water flow forming turbo pump 70 will be described later.

  With reference to FIG. 5, the peripheral structure of the impeller 80 of the water flow forming turbo pump 70 will be described. A portion of the partition wall 75 of the casing (73, 75, 76, 79) that passes through the rotation center axis (indicated by a one-dot chain line D in the figure) extends vertically downward from the partition wall 75, and the impeller 80 A shaft 77 is provided for rotatably supporting the shaft. The impeller 80 rotates around the shaft 77. That is, the rotation center axis of the impeller 80 coincides with the axis of the shaft 77.

  The impeller 80 is provided so as to cover the periphery of the shaft 77, and has a portion (hereinafter referred to as a shaft portion) 82 covering the periphery of the shaft 77 and a substantially annular shape centering on the shaft 77. A portion (hereinafter referred to as an annular portion) 83 having a magnet 84. The shaft portion 82 and the annular portion 83 are integrally coupled. A vertically lower end (hereinafter referred to as a shaft end) 81 of the shaft portion 82 is rotatably supported by a bearing 78 provided so as to protrude from the suction pipe 79 to the rotation center axis D side. Thereby, the impeller 80 can be rotated around the shaft 77 without being displaced in the vertical direction.

  The impeller 80 is provided with vanes 85 for forming a water flow. The blade 85 is provided so as to protrude vertically downward from the annular portion 83 of the impeller 80. The impeller 80 of the water flow forming turbo pump 70 of the present embodiment is provided with four blades 85 at equal intervals in the circumferential direction of the shaft 77, similarly to the impeller 50 of the mixing turbo pump 40. .

  The water flow forming turbo pump 70 has an electric motor 88 for rotating the magnet 84 to rotate the impeller 80. The rotor (not shown) of the electric motor 88 has a substantially cylindrical shape, and a magnet 89 is coupled thereto. In the magnet 89, N poles and S poles are alternately formed in the circumferential direction of the rotation center axis D. Similarly, in the magnet 84 of the impeller 80, N poles and S poles are alternately formed in the circumferential direction of the rotation center axis D. Between the magnet 89 of the electric motor 88 and the magnet 84 of the annular portion 83 of the impeller 80, the partition wall 75 is sandwiched between the attractive force (so-called attractive force) and the attractive force (so-called repulsive force). At least one acts. With this action, when the magnet 89 of the electric motor 88 is rotationally driven, the impeller 80 including the magnet 84 is driven and rotated. The electric motor 88 is supplied with electric power from a terminal 87 shown in FIG. As described above, the water flow forming turbo pump 70 is configured to be able to rotationally drive the impeller 80 by controlling the power running of the electric motor 88.

  Next, the arrangement of the water flow forming turbo pump 70 will be described with reference to FIGS. FIG. 6 is a schematic diagram for explaining the arrangement of the water flow forming turbo pump and the flow direction of the discharged water. As shown in FIGS. 1 and 6, the water flow forming turbo pump 70 is disposed so that the suction port 72 faces the mixing turbo pump 40 in a state where the water flow forming turbo pump 70 is attached to the support portion 32 of the wash unit 30. Has been. In more detail, it arrange | positions so that the slit 44 of the casing 41 may be opposed.

  As shown in FIG. 6, when the impeller 80 rotates, the water flow forming turbo pump 70 uses water mixed with hydrogen generated by the mixing turbo pump 40 (that is, hydrogen-dissolved water) as indicated by an arrow in the figure. As indicated by E, the air is sucked from the suction port 72. Then, centrifugal force generated by the rotation of the impeller 80 acts on the sucked hydrogen-dissolved water, and is discharged from the discharge port 71 toward the cylindrical wall 33 as indicated by an arrow G. The discharged hydrogen-dissolved water flow (hereinafter simply referred to as “water flow”) flows along the cylindrical wall 33. As described above, the water flow forming turbo pump 70 is arranged so that the water discharged from the discharge port 71 forms a flow (water flow) along the cylindrical wall 33. The flow along the cylindrical wall 33 reaches the wash surface portion 35 from the support portion 32.

  In the washing system 1 configured as described above, as shown in FIG. 1, the hydrogen generated by the hydrogen generator 2 is supplied to the mixing turbo pump 40. The water stored in the wash unit 30 in the mixing turbo pump 40 and the hydrogen supplied from the hydrogen generator 2 are mixed to generate hydrogen-dissolved water. A water flow forming turbo pump (centrifugal pump) 70 provided in the wash unit 30 sucks hydrogen-dissolved water from the vicinity of the mixing turbo pump 40 and forms a water flow in the wash unit 30. By continuously operating the hydrogen generator 2 and the mixing turbo pump 40, water mixed with hydrogen (hydrogen-dissolved water) reaches the wash unit 30 or is contained in the hydrogen-dissolved water in the wash unit 30. The hydrogen concentration can be increased to saturation.

  In the wash system 1 of the present embodiment, when the hydrogen concentration of water in the wash unit 30 is sufficiently increased, the wash unit 30 in which the hydrogen-dissolved water is collected is removed from the basement 20 and removed. The unit 30 can wash the face and the like. Even when the washing unit 30 is detached from the basement 20, it is possible to form a water flow in the hydrogen-dissolved water in the washing unit 35 by operating the water flow forming turbo pump 70. Can be washed. The anti-oxidant action of hydrogen-dissolved water improves the health and beauty of the washed face.

  As described above, the washing system 1 of the present embodiment is configured to receive the hydrogen generating device 2 that generates hydrogen by electrolyzing the electrolytic solution 12 and the face, and stores water inside. And a wash unit 30 capable of Furthermore, the wash unit 30 agitates the hydrogen supplied from the hydrogen generator 2 and the water stored in the wash unit 30 by the rotation of the impeller 50, and turns the water stored in the wash unit 30 into water. The mixing turbo pump 40 for mixing the supplied hydrogen in the casing 41 and the water flow forming turbo pump 70 for forming a water flow in the wash unit 30 by the rotation of the impeller. By rotating the impeller 50 of the mixing turbo pump 40, the hydrogen supplied from the hydrogen generator 2 can be mixed with the water stored in the wash unit 30 to generate hydrogen-dissolved water. Furthermore, the water flow forming turbo-type pump 70 forms a water flow in the wash unit 30, so that the hydrogen-dissolved water is distributed in the wash unit, and the face can be washed comfortably with the water flow. The anti-oxidant action of hydrogen-dissolved water improves the health and beauty of the washed face. By continuously using the washing system 1 at home, it becomes possible to make the skin glossy and glossy.

  Moreover, in the wash system 1 of this embodiment, the wash unit 30 shall be comprised so that attachment or detachment was possible with respect to the basement 20 to which the hydrogen generator 2 was fixed. When the hydrogen concentration in the water (hydrogen-dissolved water) in the wash unit 30 is sufficiently increased, the face and the like can be washed with the wash unit 30 in which the hydrogen-dissolved water is accumulated removed from the basement 20. The face washing unit 30 can be moved to an arbitrary place to wash the face.

  Further, in the washing system 1 of the present embodiment, the washing unit 30 is configured to receive the face, and the washing unit 35 is formed so that the inner diameter increases toward the upper vertical side. The mixing turbo pump 40 and the water flow forming turbo pump 70 are provided on the support portion 32. The support portion 32 supports the wash surface portion. By generating the hydrogen-dissolved water and forming the water flow in the support portion 32, it is not necessary to provide both the mixing turbo pump 40 and the water flow forming turbo pump 70 in the wash surface portion 35. A sufficient space can be secured for washing the face in the wash face 35.

  In the washing system 1 of the present embodiment, the mixing turbo pump 40 is provided at the unit bottom 34 which is the bottom of the support unit 32 and the bottom of the washing unit 30. The impeller 50 includes a magnet 54, and the basement 20 is provided with an electric motor 58 in which at least one of attractive force and repulsive force acts between the magnet 54 and a rotor. It was supposed to be. By rotating the magnet 59 by controlling the power running of the electric motor, the impeller 50 including the magnet 54 can be rotationally driven following the rotation of the magnet 59. Since it is not necessary to provide the electric motor 58 in the washing unit 30, the washing unit 30 can be reduced in weight compared to the case where the electric motor 58 is provided in the washing unit 30. Thereby, the portability of the washbasin unit 30 improves.

  Further, in the washing system 1 of the present embodiment, the water flow forming turbo pump 70 is provided on the cylindrical wall 33 which is a substantially cylindrical wall body in the support portion 32. As described above, the mixing turbo pump 40 is provided on the unit bottom 34 which is the bottom of the support 32 as described above. Therefore, by providing the water flow forming turbo pump 70 on the cylindrical wall 33. The mixing turbo pump 40 and the water flow forming turbo pump 70 can be arranged on the support portion 32.

  Further, in the washing system 1 of the present embodiment, the water flow forming turbo pump 70 is disposed so that the suction port 72 faces the mixing turbo pump 40. The hydrogen-dissolved water generated by the mixing turbo pump 40 is sucked from the suction port 72 by the water flow forming turbo pump 70 to form a water flow and can be diffused well into the wash unit 30.

Further, in the washing system 1 of the present embodiment, the water flow forming turbo pump 70 is arranged so that the water discharged from the discharge port 71 forms a flow along the cylindrical wall 33. By forming the water flow along the cylindrical wall 33 by the water flow forming turbo pump 70, it becomes easy to maintain the strength of the water flow and allow the water flow to reach the wash surface portion 35. According to the washbasin system 1, it is possible to generate hydrogen-dissolved water with a simple configuration at home, and to promote health and beauty using the hydrogen-dissolved water.
[Second Embodiment]

  The structure of the drinking water manufacturing system of this embodiment is demonstrated using FIG.2 and FIG.7. FIG. 7 is a cross-sectional view of the drinking water production system of the present embodiment. In addition, about the structure common to the wash system of 1st Embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  As shown in FIG. 7, the drinking water production system 100 includes a hydrogen generator 2 that generates hydrogen by electrolyzing an electrolyte solution 12, and hydrogen dissolved in water by dissolving hydrogen generated by the hydrogen generator 2 in water. And a beverage container 110 capable of storing drinking water such as water therein. The hydrogen generator 2 is fixedly provided vertically above the basement 20. On the other hand, the beverage container 110 is detachably provided vertically above the basement 20.

  The beverage container 110 has a substantially cylindrical shape with a bottom, and is configured to be able to store a beverage such as water therein. Specifically, the beverage container 110 includes a substantially cylindrical wall body (hereinafter referred to as a cylindrical wall) 113 and a bottom portion (hereinafter referred to as a horizontal portion) extending from the vertical lower edge of the cylindrical wall 113. 114) (denoted as the container bottom). The portion of the container bottom 114 through which the cylindrical axis of the cylindrical wall 113 passes, that is, the center of the container bottom 114 is mixed with hydrogen generated by the hydrogen generator 2 and water stored in the beverage container 110. Therefore, the same mixing turbo pump 40 as that of the first embodiment described above is provided. A pour spout 112 for pouring a beverage from the beverage container 110 to another container such as a cup is formed on the edge of the cylindrical wall 113 on the upper vertical side.

  The mixing turbo pump 40 agitates the hydrogen supplied from the hydrogen generator 2 and the water stored in the beverage container 110 by the rotation of the impeller 50. Thereby, the mixing turbo pump 40 mixes the hydrogen supplied from the hydrogen generator 2 with the water stored in the beverage container 110 to generate hydrogen-dissolved water.

  As shown in FIGS. 2 and 7, the bottom side connector 60 is fixed to the beverage container 110 as in the first embodiment (see FIG. 2), and a check valve 63 is provided in the inside thereof. Is provided. On the other hand, a top wall side connector 65 is also fixed to the top wall 21 of the basement 20, and a passage 66 is formed inside the top wall side connector 65. The passage 66 is supplied with hydrogen from the electrolytic cell 5 of the hydrogen generator 2 described above (see FIG. 7). In a state where the beverage container 110 is installed on the basement 20, the top wall side connector 65 and the bottom side connector 60 are connected. The check valve 63 of the bottom connector 60 is configured to stop the flow from the mixing turbo pump 40 toward the electrolytic cell 5. Therefore, when the beverage container 110 is removed from the basement 20, water stored in the beverage container 110 is prevented from leaking out of the beverage container 110 by flowing backward through the mixing turbo pump 40. . Thus, the beverage container 110 is configured to be detachable from the basement 20 to which the hydrogen generator 2 is fixed.

  In the drinking water production system 100 configured as described above, the hydrogen generated by the hydrogen generator 2 is supplied to the mixing turbo pump 40 as shown in FIG. The water stored in the beverage container 110 in the mixing turbo pump 40 and the hydrogen supplied from the hydrogen generator 2 are mixed to produce hydrogen-dissolved water. By continuously operating the hydrogen generator 2 and the mixing turbo pump 40, water mixed with hydrogen (hydrogen-dissolved water) spreads into the beverage container 110 or is contained in the drinking water in the beverage container 110. The hydrogen concentration can be increased until saturation. In the drinking water production system 100, when the hydrogen concentration of the water in the beverage container 110 is sufficiently increased, the beverage container 110 in which the hydrogen-dissolved water is accumulated is removed from the basement 20 and removed from the removed beverage container 110. The hydrogen-dissolved water can be transferred to other beverage containers such as cups. The antioxidant effect of hydrogen-dissolved water enhances the health and beauty of humans who have consumed hydrogen-dissolved water.

  As described above, the drinking water production system 100 of the present embodiment includes the hydrogen generator 2 that generates hydrogen by electrolyzing the electrolytic solution 12, and the beverage container 110 that can store water therein. Have. The beverage container 110 stirs the hydrogen supplied from the hydrogen generator 2 and the water stored in the wash unit 30 by the rotation of the impeller 50, and converts the hydrogen stored in the beverage container 110 to hydrogen. A mixing turbo pump 40 for mixing the hydrogen supplied from the generator 2 in the casing (73, 75, 76, 79) is provided. By rotation of the impeller 50 of the mixing turbo pump 40, the hydrogen supplied from the hydrogen generator 2 can be mixed with the water stored in the beverage container 110 to generate hydrogen-dissolved water. Drinking hydrogen-dissolved water improves human health and beauty.

In the drinking water production system 100 of the present embodiment, the beverage container 110 is configured to be detachable from the basement 20 to which the hydrogen generator 2 is fixed. When the hydrogen concentration of the water (hydrogen-dissolved water) in the beverage container 110 is sufficiently increased, the beverage container 110 in which the hydrogen-dissolved water is collected is removed from the basement 20 and poured into another beverage container such as a cup. be able to.
[Third embodiment]

  The configuration of the foot bath system according to the present embodiment will be described with reference to FIGS. FIG. 8 is a plan view of the foot bath system of the present embodiment, and FIG. 9 is a cross-sectional view of the foot bath. In addition, about the structure common to the wash system of 1st Embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted.

  As shown in FIG. 8 to FIG. 9, the foot bath system 200 has a depth and size that can accommodate both legs up to below the knee, and a hot water bath 201 having an open top for storing hot water w therein. The foot bath unit 202, the hydrogen generator 2 that is provided in the foot bath unit 202 and generates hydrogen by electrolyzing the electrolytic solution 12, and the foot bath unit 202 that is supplied from the hydrogen generator 2. A jet water flow pump 203 comprising a centrifugal pump that mixes hydrogen and hot water w stored in the foot bath unit 202 in the impeller housing portion 43 by the rotation of the impeller 50 is provided.

  The foot bath unit 202 includes a moving wheel 204 on the outer bottom to facilitate movement in a state where hot water w is put. The foot bath unit 202 has a hollow space 205 around it, and the hydrogen generator 2 is installed in the space 205 in front of the foot bath unit 202. In order to facilitate the movement of the foot bath unit 202, a space 207 at the rear of the foot bath unit 202 is provided with a handle 207 for moving operation that is pulled out and used.

  The bottom of the foot bath unit 202 is provided with a hot water reservoir 209 that is a recess for storing a part of hot water via a slat member 208, and the hot water reservoir 209 heats the hot water w to a predetermined temperature. For this purpose, an electric heater 210 is provided, and an outlet of the jet water flow pump 203 is connected to one end of the hot water reservoir 209. The jet water flow pump 203 is attached to the bottom of the foot bath unit 203 sideways. In addition, one end of a drainage hose 211 is connected to the hot water reservoir 209, and a groove-shaped holding part 212 that holds the drainage hose 211 in an upright state is provided on the rear surface part of the foot bath unit 202.

  As shown in FIG. 11, the jet water flow pump 203 includes an impeller accommodating portion 43 that accommodates an impeller 50 of a centrifugal pump, and a magnet 59 on a rotating shaft for rotationally driving the impeller 50 with magnetic force (attraction and repulsion). And a motor accommodating portion 90 that accommodates an electric motor 88 to which is attached. The motor housing 90 is provided with a motor mounting base 92 that also serves as a magnet housing chamber 91 that houses the magnet 59. A partition wall 93 is provided between the impeller housing portion 43 and the magnet housing chamber 91, and a shaft 47 that rotatably supports the impeller 50 is provided on the partition wall 93. The impeller 50 is provided with a magnet 54 that is rotated by a magnet 59.

  A suction port 213 is provided at the axial end of the impeller accommodating portion 43, and a bearing 48 that supports the shaft portion 52 of the impeller 50 is provided at the suction port 213. The suction port 213 is provided with a hydrogen introduction port 214 for introducing hydrogen into the suction port 213. A discharge port 215 for projecting hot water mixed and stirred with hydrogen is provided on one side of the shaft impeller accommodating portion 43.

  As shown in FIG. 10, the hydrogen generator 2 has a rectangular parallelepiped electrolytic cell 5 having a rectangular tube-shaped wall body 6 and a bottom 7, and a lid 8 that closes the upper opening of the electrolytic cell 5. doing. An electrolytic solution 12 is stored in the electrolytic cell 5 and two electrodes 10 and 11 are arranged in parallel in a state where the electrodes 10 and 11 are set up vertically. A lead wire 216 connected to the electrodes 10 and 11 is drawn out at the bottom of the electrolytic cell 5, and a connection port 217 for injecting and discharging the electrolytic solution 12 is provided. The lid 8 of the electrolytic cell 6 is provided with a supply port 218 for hydrogen (including oxygen) and a safety valve 219 that opens at a predetermined pressure. Further, flange portions 220 for attachment are provided on both sides of the electrolytic cell 6.

  One end of a hydrogen supply hose 221 is connected to the hydrogen supply port 218 of the hydrogen generator 2, and the other end of the hydrogen supply hose 221 is connected to the hydrogen inlet port 214. A suction port 222 for sucking and circulating hot water w from the hot water bath 201 is provided on the side wall of the hot water bath 201 of the foot bath unit 202, and the suction port 222 and the suction port 213 of the pump 203 are connected by a connection hose 223. It is connected. A hot water temperature and an operating time are set at the upper edge of the foot bath unit 202, and a controller 224 for controlling the hydrogen generator 2, the jet water flow pump 203, and the electric heater 210 is provided based on the settings. It has been. The space 205 of the foot bath unit 202 is provided with a power supply circuit (not shown) that converts electricity supplied from an AC commercial power source into DC low voltage electricity, and generates hydrogen via the power source circuit. The device 2, the jet water flow pump 203, the heater 210 and the like are supplied with direct current and low voltage electricity.

  According to the foot bath unit 202 configured as described above, the bath has a depth and size that can accommodate both legs up to below the knee, and has a hot water bath 201 that is open at the top to store hot water w. Therefore, the body can be warmed to produce a sweating effect. In addition, the action of hydrogen can be effective in eliminating swelling of feet, rough heels, athlete's foot, and the like. In addition, a hot water reservoir 209 is provided at the bottom of the foot bath unit 202 via a slat member 208, and an electric heater 210 is provided in the hot water reservoir 209, and the jet is provided at one end of the hot water reservoir 209. Since the blowout port 215 of the water flow pump 203 is connected, the hot water w can be forcibly circulated in the hot water tank unit 201, and the massage effect and blood circulation promotion effect by the water flow can be obtained.

Since the foot bath unit 202 includes the wheels 204 and the handle 207, the foot bath unit 202 can be easily moved in a state where hot water w is put, and can be easily moved to a bathroom or the like to drain the hot water w in the hot water bath unit 201. be able to. In this case, since the drainage hose 211 is connected to the hot water reservoir 209, the drainage hose 211 can be easily drained by simply lowering it from the standing state.
[Fourth embodiment]

  The configuration of the jet bath system according to this embodiment will be described with reference to FIGS. 12A is a plan view of the jet bath system of this embodiment, FIG. 12B is a front view, FIG. 12C is a side view, FIG. 12D is a rear view, and FIG. 13 is a diagram showing the internal structure of the jet system. FIG. 14 shows a wall-mounted controller.

  As shown in FIGS. 12 to 13, the jet bath system 230 is provided in the jet bath unit 234, the interior of which is installed on the inner wall surface 232 of the bathtub 231 by the adsorption member 233, and the jet bath unit 234. The hydrogen generator 2 for generating hydrogen by electrolyzing the water, the hydrogen provided in the jet bath unit 234, the hydrogen supplied from the hydrogen generator 2 and the hot water sucked from the bathtub 231 A jet water flow pump 203 that is mixed in the impeller housing portion 43 by rotation and discharged from the discharge port 215 into the bathtub 231 is provided.

  The jet bath unit 234 has a casing 236 having a sealed structure. In the casing 236, the hydrogen generator 2 and the jet water flow pump 203 are arranged at the upper part and the lower part. Since the hydrogen generator 2 and the jet water flow pump 203 are the same as the hydrogen generator 2 and the jet water flow pump 203 described in the third embodiment, the same reference numerals are given and description thereof is omitted.

  A suction port 237 for sucking hot water w in the bathtub 231 is provided at the lower back portion of the casing 236, and a jet outlet 238 for jetting hot water containing hydrogen is provided at the lower front portion of the casing 236. The suction port 237 is connected to the suction port 213 of the jet water flow pump 203 via a suction hose 239, and the discharge port 215 of the jet water flow pump 203 is connected to the jet port 238 via a discharge hose 240. ing.

  An air valve 241 for supplying air to the suction port 213 of the jet water flow pump 203 to generate bubbles is provided on one upper side of the back surface of the casing 236. The air valve 241 and the suction of the jet water flow pump 203 are provided. An air introduction nozzle 242 provided on the side surface of the port 213 is connected via an air supply pipe 243. Further, on the other side of the upper portion of the back surface of the casing 236, a lead wire 216 for supplying low-voltage direct current electricity to the hydrogen generator 2 and the jet water flow pump 203 and an electric cord lead portion 245 for drawing out the electric cord 244 are provided. ing.

  FIG. 14 shows an example of a wall-mounted controller 246 of the jet bath system. The controller 246 is provided with a power switch 247 that turns on and off the power supply and switches the amount of water discharged from the jet water flow pump 203 and a selection switch 248 that turns on and off the power supply of the hydrogen generator 2.

  According to the jet bath system 230 having the above configuration, by applying a jet stream of hydrogen-dissolved water in which hydrogen is added to hot water w to the body, the body can be warmed to produce a sweating action, By working, it can be effective in relieving swelling of the feet, rough skin, athlete's foot, etc., and can promote health and beauty.

  In the above-described embodiment, the centrifugal pump is used as the mixing turbo pump 40, the water flow forming turbo pump 70, and the jet water flow pump 203. However, the present invention is not limited to this. As the mixing turbo pump 40, the water flow forming turbo pump 70, and the jet water flow pump 203, other types of pumps such as a mixed flow pump and an axial flow pump can be used.

DESCRIPTION OF SYMBOLS 1 Washing system 2 Hydrogen generator 5 Electrolysis tank 10 Electrode (anode)
11 Electrode (cathode)
DESCRIPTION OF SYMBOLS 12 Electrolyte 15 Housing 20 Basement 21 Top wall 22 Hydrogen introduction pipe 28 Hydrogen supply pipe 30 Washing unit 32 Support part 33 Cylindrical wall 34 Unit bottom part 35 Washing part 40 Mixing turbo pump (centrifugal pump)
41 Casing 43 Impeller receiving portion 44 Slit 50 Impeller 54 Magnet 55 Blade 58 Electric motor 59 Magnet 60 Bottom side connector 63 Check valve 65 Top wall side connector 70 Water flow forming turbo pump (centrifugal pump)
71 Discharge port 72 Suction port 73 Impeller housing wall 79 of casing Casing pipe 80 Impeller 84 Magnet 85 Blade 88 Electric motor 89 Magnet 100 Drinking water production system 110 Drinking container 113 Cylindrical wall 114 Container bottom part 200 Foot bath system 201 Hot water bath part 202 Foot bath unit 203 Jet water flow pump 208 Snaw member 209 Hot water reservoir 210 Electric heater 230 Jet bath system 233 Adsorption member 234 Jet bath unit 241 Air valve

Claims (13)

  A hydrogen generator that generates hydrogen by electrolyzing an electrolyte, a face unit configured to receive a face and capable of storing water therein, and provided in the face unit, the hydrogen generator Hydrogen supplied from the apparatus and water stored in the washing unit are mixed in the casing by rotation of the impeller, and the mixing turbo pump is provided in the washing unit, and the rotation of the impeller A washing system comprising a water flow forming turbo-type pump for forming a water flow in a washing unit.   The washing system according to claim 1, wherein the washing unit is configured to be detachable from a basement to which the hydrogen generator is fixed.   3. The washing system according to claim 1, wherein the washing unit is capable of receiving a face and has a washing part formed so that an inner diameter increases toward a vertically upper side, and vertically below the washing part. And a supporting part that supports the washing part, and the mixing turbo pump and the water flow forming turbo pump are provided in the supporting part.   4. The washing system according to claim 3, wherein the mixing turbo pump is provided at a unit bottom that is a bottom of the support and a bottom of the washing unit, and the impeller of the mixing turbo pump. Includes a magnet, and the basement is provided with an electric motor in which at least one of attractive force and repulsive force acts between the magnet and the rotor.   5. The washing system according to claim 4, wherein the water flow forming turbo pump is provided on a cylindrical wall which is a substantially cylindrical wall body in the support portion.   6. The washing system according to claim 5, wherein the water flow forming turbo pump is arranged such that a suction port faces the mixing turbo pump.   The washing system according to claim 6, wherein the water flow forming turbo pump is arranged such that water discharged from a discharge port forms a flow along the cylindrical wall.   A hydrogen generator for generating hydrogen by electrolyzing an electrolyte, a beverage container capable of storing water therein, hydrogen provided in the beverage container and supplied from the hydrogen generator, and the beverage A drinking water production system comprising a mixing turbo-type pump for mixing water stored in a container in a casing by rotation of an impeller.   9. The drinking water production system according to claim 8, wherein the beverage container is configured to be detachable from a basement to which the hydrogen generator is fixed.   A foot bath unit having a depth and size capable of accommodating both legs up to below the knee and having an open bath for storing hot water therein, and the foot bath unit provided with the foot bath unit, A hydrogen generator that generates hydrogen by decomposition, a hydrogen that is provided in the foot bath unit, and that is supplied from the hydrogen generator and hot water stored in the foot bath unit is rotated by rotation of an impeller. A foot bath system comprising a jet water flow pump to be mixed in a casing.   The foot bath system according to claim 10, wherein a hot water reservoir is provided at the bottom of the foot bath unit via a slat member, and an electric heater is provided in the hot water reservoir, and A foot bath system in which a jet outlet of the jet water flow pump is connected to one end.   A jet bath unit in which the interior of the bathtub installed by an adsorbing member is sealed, a hydrogen generator provided in the jet bath unit and generating hydrogen by electrolyzing an electric field liquid, and the jet bath unit And a jet water flow pump that is provided inside and mixes the hydrogen supplied from the hydrogen generator and hot water sucked from the bathtub in the casing by the rotation of the impeller and discharges the hydrogen from the nozzle into the bathtub. Jet bath system.   The jet bath system according to claim 12, further comprising an air valve for supplying air to the suction port of the jet water flow pump to generate bubbles.

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