JP2018176155A - Hydrogen generating shower - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a shower capable of discharging hydrogen water containing hydrogen with a safe and simple configuration.SOLUTION: There is provided a hydrogen generating shower 10 including a hydrogen supplying part 20 provided in the middle of a water passage 15 extending from a faucet 17 to a discharge port 32. The hydrogen supplying part 20 comprises: an aspirator 50 having a water flow passage inlet 51 to which the upstream side of the water passage 15 where water or warm water is supplied is connected, a water flow passage outlet 52 to which the downstream side of the water passage 15 is connected, a negative pressure generation chamber 53 provided between the water flow passage inlet 51 and the water flow passage outlet 52, generating a negative pressure with the water flow, and an external inflow port 54 through which liquid and gas flow from the outside to the negative pressure generation chamber 53; a hydrogen generation tank 60 provided outside of the water passage 15 and housing therein water and a hydrogen generating agent 61 reacting with the water to generate hydrogen; and a transport passage 80 connecting the hydrogen generation tank 60 and the external inflow port 54, through which the liquid containing hydrogen flows from the hydrogen generation tank 60 to the negative pressure generation chamber 53.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a shower capable of discharging hydrogen water.

  According to Non-Patent Documents 1 and 2 below, which are the papers published by the present inventors, the elasticity of the skin is improved, the smoothness and hair of the hair are improved by touching the hydrogen water in which the hydrogen is dissolved in the water. It has been disclosed to increase the gloss of the skin and to raise the core temperature.

  Further, Patent Document 1 below discloses a technique using a hydrogen generating agent as a bath agent, because reduced water such as hydrogen water contributes to the prevention of aging of the skin and the like.

  In addition, in Patent Document 2 below, since drinking water such as hydrogen water is expected to have an anti-aging effect such as improvement of gastrointestinal symptoms and removal of active oxygen, electrolyzed water is electrolyzed by electrolyzing water. Techniques for generating are disclosed.

WO 2007/55146 A1 Patent No. 5639724 gazette

Y. Kurita, K. Umeda, S. Ikeda, O. Urushibata & S. Okouchi (Akira Kurita, Ikki Umeda, Shigeo Ikeda, Osamu Lacquerta, Shoichi Ohkawachi), "Effects of Magnesium Hydride as a Reductive Bath Additive on the Skin (Effect of magnesium hydride as a reducing hydrogen bath agent on skin), J. Hot Spring Sci. (Hot Spring Science), Vol. 63, No. 4, p. 317-327 Ohkawachi Shoichi, Ohnami Hideyuki, Shoji Miku, Ohno Keisuke, Ikeda Shigeo, Aishi Hiroyuki, Shinohara Tomoaki, Suzuki Toru, "Effects of Electrolytically Reduced Hot Spring Water on Skin and Hair", Hot Spring Science, Vol. 55, Second, p. 55-63

  Patent Document 1 mentioned above discloses the use of a hydrogen generating agent as a bath agent, but does not disclose the application of this agent to a shower.

  Moreover, when producing hydrogen water by electrolysis which is disclosed by said patent document 2, it is necessary to provide comparatively large-scale electricity-related installation.

  Therefore, an object of the present invention is to provide a shower capable of discharging hydrogen water containing hydrogen with a simple configuration and safety.

In order to solve the above problems, the hydrogen generation shower 10 according to the present invention is a hydrogen supply capable of continuously supplying hydrogen to the middle of the water passage 15 from the faucet 17 to the discharge port 32 of the shower head 30. With the unit 20,
The hydrogen is characterized in that the hydrogen generating agent 61 that generates hydrogen by reacting with water is generated by reacting with water.

  The hydrogen generating agent 61 may be detachably accommodated in the hydrogen supply unit 20. Here, “removable” means that the hydrogen generating agent 61 can be accommodated, replenished, or removed from the outside in the hydrogen supply unit 20. In this case, in order to prevent the hydrogen generating agent 61 from unnecessarily reacting with the water remaining in the hydrogen supply unit 20 when the shower is not used, the hydrogen supply is provided upstream of the hydrogen supply unit 20. It is desirable to have a drainage port 29B for draining the water accumulated in the inside of the section 20.

  Alternatively, the hydrogen supply unit 20 may be capable of continuously supplying hydrogen using the water pressure of the water flow.

(First aspect)
Specifically, as the first aspect, the hydrogen supply unit 20 is connected to the water channel inlet 51 to which the upstream side of the water channel 15 to which water or hot water is supplied is connected, and the water channel outlet to which the downstream side of the water channel 15 is connected. 52, a negative pressure generating chamber 53 located between the water channel inlet 51 and the water channel outlet 52 and generating negative pressure by the water pressure of the water flow, liquid and gas from the outside flow into the negative pressure generating chamber 53 An aspirator 50 having an external inlet 54
A hydrogen generating tank 60 provided outside the water channel 15 and containing water and the hydrogen generating agent 61 therein;
A transport path 80 connecting the hydrogen generation tank 60 and the external inlet 54 and flowing the hydrogen-containing liquid from the hydrogen generation tank 60 into the negative pressure generation chamber 53;
It is characterized by having.

  In this embodiment, the aspirator 50 provided in the middle of the water channel 15 generates negative pressure by the water pressure of the water flow. The negative pressure is generated in the negative pressure generating chamber 53, and the transport path 80 is connected to the negative pressure generating chamber 53 through the external inlet 54. The transport path 80 is in communication with the hydrogen generation tank 60. The hydrogen generating agent 61 contained in the hydrogen generating tank 60 reacts with water to generate hydrogen. The generated hydrogen is sucked by the negative pressure generated by the aspirator 50 together with the aqueous solution in which the hydrogen generating agent 61 has reacted, and flows into the negative pressure generation chamber 53 from the external inlet 54 through the transport path 80. Then, it joins with the water channel 15 and passes through the water channel outlet 52 and is discharged from the discharge port 32. During the discharge, the reaction with the dissolved hydrogen generating agent 61 proceeds, and the discharged water or hot water contains a large amount of hydrogen.

(Second aspect)
Further, as a second aspect, the hydrogen supply unit 20 is formed as a hollow outer cylinder 20 provided in the middle of the water channel 15 and as a hollow inner cylinder 60 mounted inside the outer cylinder 20. Having a hydrogen generation tank 60 provided,
At the upstream end side of the inner cylinder 60, a water flow valve 65 for introducing a part of the water flow from the upstream of the water channel 15 into the inner cylinder 60 and preventing backflow of liquid is provided.
On the downstream end side of the inner cylinder 60, there is provided a gas discharge unit 70 for discharging only gas from the inside of the inner cylinder 60 to the water channel on the downstream side,
The hydrogen generating agent 61 is accommodated in the inner cylinder 60.

  In the present embodiment, the hydrogen supply unit 20 provided in the middle of the water channel 15 has a double cylindrical structure. That is, the inner cylinder 60 is located in the outer cylinder 20.

  Although the hydrogen generating agent 61 is accommodated in the inner cylinder 60, the water flow valve from the upstream side is introduced by the water flow valve 65 provided on the upstream side thereof. It is designed to prevent backflow. Thus, the hydrogen generating agent 61 in the inner cylinder 60 does not leak out through the water flow valve 65.

  In addition, the liquid inside the inner cylinder 60 is not permeated by the gas discharge unit 70 provided on the downstream side of the inner cylinder 60, and only hydrogen generated inside the inner cylinder 60 is made downstream by the water pressure of the water flow. It is possible to transmit.

  The hydrogen that has permeated the gas discharge unit 70 is discharged into water or warm water that has flowed inside the outer cylinder 20 and outside the inner cylinder 60, and is discharged from the discharge port 32 as a shower by the water channel 15. The discharged water or hot water is hydrogen water containing a large amount of hydrogen.

  Here, as the gas discharge part 70, it is possible to use a gas permeable membrane 71 which allows the passage of gas and the passage of liquid.

  Further, as the gas discharge part 70, a vent valve 74 which allows gas to pass and liquid can not be used can be used.

(Hydrogen generating agent)
Here, the hydrogen generating agent 61 contained in the hydrogen generating tank 60 may be any chemical substance capable of generating hydrogen by reacting with water, and in particular, sodium borohydride (NaBH ₄ ), hydrogen Preferably, it is selected from the group consisting of magnesium fluoride (MgH ₂ ) and metallic magnesium (Mg).

  Here, when the hydrogen generating agent 61 is metallic magnesium, 1 mol of hydrogen is generated per 1 mol according to the following reaction formula.

Mg + 2 H ₂ O → Mg (OH) ₂ + H ₂

  When the hydrogen generating agent 61 is magnesium hydride, 2 moles of hydrogen are generated per mole according to the following reaction formula.

MgH ₂ + 2H ₂ O → Mg (OH) ₂ + 2H ₂

  Furthermore, when the hydrogen generating agent 61 is sodium borohydride, 4 moles of hydrogen are generated per mole according to the following reaction formula.

NaBH ₄ + 2H ₂ O → NaBO ₂ + 4H ₂

  Among them, sodium borohydride is particularly desirable as the hydrogen generating agent 61 because the number of moles of hydrogen generation per unit number of moles is large. Here, sodium borohydride also has the effect of promoting the reaction of decomposition of hypochlorous acid (HClO) contained in tap water according to the following formula. In the following formula, "O" is an oxygen radical.

  HClO → HCl + O

Therefore, in view of the effect, it is more preferable to use sodium borohydride as the hydrogen generating agent 61. In addition, NaBO ₂ which is a product of a reaction in which hydrogen is generated from sodium borohydride is also a metaboric acid of a hot spring component.

  Preferably, an organic acid is also added to the hydrogen generating agent 61. The organic acid is added to increase the generation rate of hydrogen, and examples thereof include carboxylic acids, and among them, citric acid is particularly desirable.

  The hydrogen generating agent may be formed by dispersing the hydrogen-containing metal compound in fats and oils at room temperature and solid. In other words, the hydrogen-containing metal compound may be molded in a state of being coated with a solid-state fat or oil. In addition, dispersing a hydrogen-containing metal compound in fats and oils at normal temperature solid and coating, or coating a hydrogen-containing metal compound with fat and oil at normal temperature solid and molding in the state means heat-dissolving fat and oil at normal temperature. The thing which mixed and disperse | distributed the hydrogen-containing metal compound to what was cooled is solidified again, and it says that it shape | molds.

  The normal temperature solid fats and oils are obtained by heating and mixing polyoxyethylene fats or polyoxyethylene fatty acid esters obtained by reacting fats or oils or fatty acids with polyethylene glycol or polyoxyethylene and esterifying them with a hydrogenated metal compound and cooling them. It may be molded. In addition, as fats and oils as used herein, any natural oil or synthetic oil or a mixture thereof may be used as long as it has a solid property at normal temperature, and hydrogenated castor oil is particularly preferable. Moreover, as a fatty acid here, a stearic acid etc. are mentioned.

  A hydrogen-containing metal compound is a metal compound containing a hydrogen atom, which reacts with water to generate hydrogen, and includes the sodium borohydride and the magnesium hydride. Among these, sodium borohydride is particularly preferred.

  At the time of molding of this hydrogen generating agent, the above-described polyoxyethylene fat or oil or polyoxyethylene fatty acid ester obtained by reacting the fat or oil or fatty acid with polyethylene glycol or polyoxyethylene and esterified is heated as a fat coating agent. It is desirable that the powder is mixed with hydrogen-containing metal compound and then cooled to room temperature or lower. In addition, oils and fats or fatty acids and polyethylene glycol or polyoxyethylene may be reacted separately from those prepared as materials to produce polyoxyethylene oil or fat or polyoxyethylene fatty acid ester, or ester in advance. It is also possible to use polyoxyethylene fats and oils or polyoxyethylene fatty acid esters which are made as materials. In addition, “esterification” as referred to herein means not only when only one of the terminal hydroxyl groups of polyethylene glycol or polyoxyethylene is esterified with fat or oil or fatty acid, but both of the terminal hydroxyl groups are esterified to form a diester. Also includes the case. Such diesters include, for example, polyoxyethylene distearate.

  That is, the hydrogen-containing metal compound containing sodium borohydride is the above-described polyoxyethylene fat or oil or polyoxyethylene fatty acid ester obtained by reacting the fat or oil or fatty acid as the fat or oil coating agent with polyethylene glycol or polyoxyethylene and esterifying it The oil coating is carried out by this, whereby the contact between the hydrogen metal compound and the water is delayed, so that hydrogen is generated gradually and over a relatively long period of time. For this purpose, the film coated with oil or fat is dissolved at 50 to 95 ° C., and the amount of dissolution in a shower time of 10 minutes may be 1 g or less.

  Since the shower according to the present invention is configured as described above, hydrogen can be continuously supplied to water or hot water in the channel by joining the channel containing the hydrogen sucked by the aspirator to the channel. . Alternatively, hydrogen can be continuously supplied to the water or hot water in the water channel by supplying the liquid containing hydrogen generated in the hydrogen supply unit to the water channel. Therefore, according to the shower according to the present invention, the water or hot water spouted from the shower can be made into hydrogen water containing hydrogen, and a shower user can take hydrogen water.

  In addition, if an organic acid, particularly citric acid, is added to the hydrogen generating agent used in the present invention, the chemical reaction for generating hydrogen can be efficiently performed. In particular, the decomposition of hypochlorous acid in tap water by sodium borohydride can also be promoted. Alternatively, hydrogen is supplied to water or hot water in a water channel for a relatively long period of time by storing a hydrogen generating agent in which a hydrogen-containing metal compound is dispersed and formed in fats and oils at room temperature and solid state in a hydrogen supply unit. Can.

It is a general view of a shower concerning a 1st embodiment of the present invention. It is a schematic sectional drawing of the hydrogen generation tank in 1st Embodiment. It is a schematic sectional drawing of the hydrogen supply part in 1st Embodiment. It is a graph which shows a time-dependent change of the hydrogen concentration in the discharge water from the discharge port in a 1st embodiment. It is a graph which shows a time-dependent change of the dissolved chlorine concentration in the discharge water from the discharge outlet in a 1st embodiment. It is a general view of a hydrogen generation shower concerning a 2nd embodiment of the present invention. It is a schematic cross section of the hydrogen generation part in a 2nd embodiment. It is a schematic cross section of the hydrogen generation part in the 3rd Embodiment of this invention. It is a graph which shows a time-dependent change of hydrogen concentration in discharge water from a discharge mouth in a 2nd embodiment. The whole figure of the hydrogen generation shower concerning a 4th embodiment of the present invention is broken and shown in part. It is a graph which shows a time-dependent change of the hydrogen concentration in the discharge water from the discharge outlet in a 4th embodiment, and boron concentration. It is a graph which shows the time-dependent change of the chlorine concentration in the discharge water from the discharge port in a 4th embodiment.

(1) First Embodiment A hydrogen generation shower 10 according to a first embodiment of the present invention, as shown in FIG. 1, includes a shower hose 40 connecting a faucet 17 and a shower head 30, and a shower A hydrogen supply unit 20 provided in the middle of the hose 40 and a hydrogen generation tank 60 connected to the hydrogen supply unit 20 via a transport path 80 are provided.

  In the hydrogen generation shower 10 according to the present embodiment, the portion from the faucet 17 through the shower hose 40 to the discharge port 32 of the shower head 30 is the water channel 15 where water or warm water flows.

  The hydrogen generation tank 60 is a tank which accommodates water inside, as shown in FIG. To this water, powdery sodium borohydride as the hydrogen generating agent 61 is added, and further, citric acid as the organic acid is added. In the hydrogen generation tank 60, sodium borohydride reacts with water to generate 4 moles of hydrogen per mole according to the above equation, but this reaction is promoted by the added citric acid.

  The hydrogen supply unit 20 is a portion for supplying the hydrogen generated in the hydrogen generation tank 60 to the water channel 15, and an aspirator 50 is housed therein as shown in FIG.

  On the upstream side of the aspirator 50, a water channel inlet 51 into which water or hot water from the faucet 17 flows is provided. Specifically, an upstream shower hose 40 is connected to the water channel inlet port 51.

  On the other hand, on the downstream side of the aspirator 50, a channel outlet 52 through which water or hot water flows toward the shower head 30 is provided. Specifically, the downstream side shower hose 40 is connected to the water channel outlet 52.

  In the middle of the water channel inlet 51 and the water channel outlet 52, a diameter reducing piece 55 for reducing the diameter of the flow path is inserted. A space around the reduced diameter piece 55 is a negative pressure generating chamber 53, and the inner diameter gradually increases from the downstream side to the water passage outlet 52.

  In the negative pressure generating chamber 53, an external inlet 54 is opened at a right angle to the water channel 15. Note that this angle may not necessarily be at right angles. The transport path 80 described above is connected to the external inlet 54. A backflow prevention valve 56 is inserted inside the external inflow port 54.

  When water or hot water flows into the water channel 15 with a certain amount of force, it flows into the water channel inlet 51, and the flow velocity is increased by the water pressure in the diameter reducing pieces 55, whereby negative pressure is generated in the negative pressure generating chamber 53. The negative pressure causes the backflow prevention valve 56 to be opened, and the liquid and gas are sucked from the hydrogen generation tank 60 to the negative pressure generation chamber 53 through the transport path 80. This liquid contains hydrogen as described above. When the liquid joins the water channel 15 in the negative pressure generation chamber 53, hydrogen is added to water or hot water, and the water or hot water delivered from the water channel outlet 52 to the shower head 30 is discharged from the discharge port 32. .

  In the first embodiment, the result of measuring the concentration of dissolved hydrogen in the water discharged from the discharge port 32 is shown in the graph of FIG. A drip bag containing 300 mL of water was prepared as the hydrogen generating tank 60, and 2 g or 3 g of sodium borohydride as the hydrogen generating agent 61 and 2 g of citric acid were added thereto. Then, warm water with a water temperature of 40 ° C. was discharged at a shower flow rate of 6 L / min, and the dissolved hydrogen concentration in the discharged water was measured over time.

  As a result, when the amount of the hydrogen generating agent 61 was 3 g, it reached 100 ppb immediately after the discharge start, and the dissolved hydrogen concentration remained above 50 ppb even after 20 minutes. On the other hand, when the hydrogen generating agent was 2 g, the dissolved hydrogen concentration did not exceed 50 ppb by 20 minutes after the discharge start. By the way, while the hydrogen concentration for which improvement in skin elasticity has been confirmed is 50 ppb or more, and the average shower time of Japanese is about 10 minutes, in the present embodiment, the hydrogen concentration for 50 ppb or more is continued for 20 minutes. Because it was possible, it will be more than this.

  In addition, when the dissolved chlorine concentration in discharge water was also measured simultaneously, as shown in FIG. 5, the remarkable fall was recognized in 10 minutes-20 minutes after discharge start time. Thus, sodium borohydride was also found to have the effect of reducing dissolved chlorine.

(2) Second Embodiment As shown in FIG. 6, a hydrogen generation shower 10 according to a second embodiment of the present invention includes a shower hose 40 connecting a faucet 17 and a shower head 30, and a shower And a hydrogen supply unit 20 provided in the middle of the hose 40.

  In the hydrogen generation shower 10 according to the present embodiment, the portion from the faucet 17 through the shower hose 40 to the discharge port 32 of the shower head 30 is the water channel 15 where water or warm water flows. The hydrogen supply unit 20 is a hollow, substantially cylindrical member provided in the middle of the water channel 15, and is formed as an outer cylinder 20 constituting a portion exposed to the outside as shown in FIGS. 7 and 8. The inner cylinder 60 as the hydrogen generation tank 60 accommodated in the inside of this outer cylinder 20 is provided.

  The outer cylinder 20 is located on the upstream side (the side on which the faucet 17 is located, the lower side in FIGS. 7 and 8; the same applies hereinafter) and the downstream side (on the side on which the shower head 30 is located). 7 and FIG. 8, the front portions 26 located on the upper side (the same applies hereinafter) are screwed together to form a substantially cylindrical shape.

  The inner cylinder 60 has a substantially cylindrical shape in which a cap 63 located on the downstream side is screwed into the accommodation portion 62 located on the upstream side.

  An inner cylinder fixing plate 21 is provided at a substantially middle portion of the outer cylinder 20 to divide the inside back and forth. An inner cylinder holding hole 23 for holding the inner cylinder is provided at the center of the inner cylinder fixing plate 21. The inner cylinder 60 is inserted through the inner cylinder holding hole 23 and screwed and held with each other. In addition to this, the inner cylinder fixing plate 21 is provided with a plurality of water passage holes 22 communicating the front and the back.

  An inlet 24 is provided at the upstream end of the rear portion 27 of the outer cylinder 20, and water or hot water from the upstream side flows into the outer cylinder 20 from here. The inflowing water or warm water passes through the water flow holes 22 of the inner cylinder fixing plate 21 and reaches the front portion 26. On the other hand, an outlet 25 is provided at the downstream end of the front portion 26 of the outer cylinder 20, and water or hot water inside the outer cylinder 20 flows out to the downstream side from here.

  The powdery sodium borohydride as the hydrogen generating agent 61 is accommodated in the accommodating portion 62 of the inner cylinder 60, and citric acid as an organic acid is also added thereto. A water flow valve 65 is provided at the rear end of the housing portion 62. The water flow valve 65 allows water flow in the downstream direction but does not flow in the opposite direction. That is, although water or hot water flows from the outside to the inside of the inner cylinder 60, the outflow of the liquid from the inside to the outside of the inner cylinder 60 is prevented. Therefore, the hydrogen generating agent 61 contained inside the inner cylinder 60 does not leak from the water flow valve 65 to the outside of the inner cylinder 60.

  In this inner cylinder 60, sodium borohydride as the hydrogen generating agent 61 reacts with water to generate 4 moles of hydrogen per mole according to the above equation, but this reaction is based on the citric acid added Promoted by

  Here, as shown in FIG. 7, a cap 63 is attached to the downstream side of the housing portion 62 of the inner cylinder 60. A transmission hole 64 is formed at the center of the cap 63. A gas discharge unit 70 having a structure in which a gas permeable membrane 71 is sandwiched between a membrane support layer 72 formed of two sheets of mesh between the cap 63 and the housing portion 62 has packings 73 on both sides. It is worn while wearing. The gas permeable membrane 71 has a structure that allows gas to permeate from the inside to the outside of the inner cylinder 60 but does not allow liquid and solids to permeate.

  The hydrogen generated as described above in the inner cylinder 60 floats in the downstream direction, passes through the mesh of the membrane support layer 72 on the upstream side, and reaches the gas permeable membrane 71. Here, water pressure from the water flow from the downstream side is always applied to the inside of the inner cylinder 60 through the water flow valve 65, and this water pressure promotes permeation of hydrogen through the gas permeable membrane 71. There is.

  The hydrogen that has permeated the gas permeable membrane 71 passes through the mesh of the membrane support layer 72 on the downstream side and joins with the water flow from the permeation holes 64 of the cap 63, and the water channel on the downstream side from the outlet 25 of the outer cylinder 20 Then, it is discharged from the discharge port 32 of the shower head 30 as hydrogen water.

(3) Third Embodiment On the other hand, in the third embodiment of the present invention shown in FIG. 8, a cap 63 is attached to the downstream side of the housing portion 62 of the inner cylinder 60. At the center of the cap 63, a vent valve 74 as a gas discharge unit 70 is provided. The vent valve 74 has a structure that allows gas to pass from the inside to the outside of the inner cylinder 60 but does not allow liquid and solids to pass.

  The hydrogen generated as described above in the inner cylinder 60 floats in the downstream direction and reaches the vent valve 74. Here, water pressure is always applied by the water flow from the downstream side through the water flow valve 65 inside the inner cylinder 60, and this water pressure is to promote the passage of the hydrogen vent valve 74. .

  The hydrogen that has passed through the vent valve 74 joins the water stream, exits to the water channel 15 downstream of the outlet 25 of the outer cylinder 20, and is discharged as hydrogen water from the outlet 32 of the shower head 30.

  The graph of FIG. 9 shows the result of measuring the concentration of dissolved hydrogen in the water discharged from the discharge port 32 in the second embodiment. The volume of the inner cylinder 60 was 30 mL, and 1 g, 2 g or 3 g of sodium borohydride as the hydrogen generating agent 61 and 2 g of citric acid were added thereto. Then, warm water with a water temperature of 40 ° C. was discharged at a shower flow rate of 6 L / min, and the dissolved hydrogen concentration in the discharged water was measured over time.

  As a result, when the amount of the hydrogen generating agent 61 was 3 g, although it rapidly reached 400 ppb immediately after the discharge start, it dropped sharply after that and fell below 50 ppb after 10 minutes. Moreover, when the hydrogen generating agent 61 was 2 g, it rose to almost 100 ppb immediately after the discharge start, maintained 100 ppb until 15 minutes after that, and the dissolved hydrogen concentration remained above 50 ppb even after 20 minutes . On the other hand, when the hydrogen generating agent was 1 g, the dissolved hydrogen concentration did not exceed 50 ppb by 20 minutes after the start of discharge. By the way, while the hydrogen concentration for which improvement in skin elasticity has been confirmed is 50 ppb or more, and the average shower time of Japanese is about 10 minutes, in the present embodiment, the hydrogen concentration for 50 ppb or more is continued for 20 minutes. Because it was possible, it will be more than this.

(4) Hydrogen Generator In addition, as the hydrogen generator 61 in each said embodiment, what was formed as follows can be used.

The components in Table 1 above are mixed, stirred at 150 ° C., cooled to normal temperature or lower, and solidified to obtain a hydrogen generating agent 61. When an appropriate amount of the hydrogen generating agent 61 is coated and coated with a fiber such as a non-woven fabric to the hydrogen supply unit 20 or the hydrogen generation tank 60 in each embodiment, the hydrogen supply unit 20 or the hydrogen supply unit 20 is In the hydrogen generation tank 60, it reacts with water or warm water to generate hydrogen.
Here, in this hydrogen generating agent 61, powdered sodium borohydride as the hydrogen-containing metal compound is produced by polyoxyethylene hydrogenated ethylene glycol as the oil, which is formed by polyoxyethylenating polyethylene glycol with hydrogenated castor oil. Because it is covered with hardened castor oil, the entire reaction does not come in contact with water or warm water at one time, and the reaction with water continues gradually, and when the shower is not used, the reaction does not proceed, resulting in a relatively long period of time Hydrogen can be supplied along with the shower water or hot water.

  In addition, as a fats-and-oils coating agent, it is not restricted to the polyoxyethylene hydrogenated castor oil produced | generated as mentioned above, It is also possible to use another vegetable oil or what esterified fatty acid with polyethyleneglycol or polyoxyethylene. Such a fats-and-oils coating agent is considered to be usable as a component of the hydrogen generating agent 61 if the amount of dissolution per 10 minutes in water at 42 ° C. is 1 g or less.

(5) Fourth Embodiment A hydrogen generation shower 10 according to a fourth embodiment of the present invention is, as shown in FIG. 10, a shower hose 40 connecting a faucet 17 and a shower head 30, and a shower And a substantially cylindrical hydrogen supply unit 20 provided in the middle of the hose 40.

  In the hydrogen generation shower 10 according to the present embodiment, the portion from the faucet 17 through the shower hose 40 to the discharge port 32 of the shower head 30 is the water channel 15 where water or warm water flows. The hydrogen supply unit 20 is a hollow substantially cylindrical member provided in the middle of the water channel 15, and has a structure in which a downstream front portion 26 and an upstream rear portion 27 are detachably screwed together.

  In the inside of the shower head 30, a space partitioned by the mesh 28 on the upstream side and the downstream side is formed, and the hydrogen generating agent 61 is accommodated therein. The hydrogen generator 61 has the components of Table 1 above. The mixture is heated, stirred and mixed as described in the item (4) above, and after cooling and solidifying, it is divided into 13 g portions and each is coated with a non-woven fabric.

  The above-mentioned mesh 28 is provided for the purpose of preventing the hydrogen generating agent 61 itself from flowing out to the water channel 15, and provided at the position shown in the figure if it meets the purpose. It does not have to be. For example, it may be provided at a location where water or warm water flows into hydrogen supply unit 20, and a location where water or warm water flows out from hydrogen supply unit 20.

  Further, the above-mentioned hydrogen generating agent 61 does not have to be formed in a lump as shown in the figure, and for example, it is formed in a granular form as shown in the first to third embodiments. May be accommodated in the hydrogen supply unit 20. In this way, when the hydrogen generating agent 61 is consumed and its volume is reduced, it is easy to appropriately replenish it.

  The hydrogen supply unit 20 of the present embodiment is detachable at the middle portion. In the state where it is removed, the above-mentioned hydrogen generating agent 61 is put in and screwed in again, so that it can be used as a shower. That is, the water or warm water supplied to the hydrogen supply unit 20 through the water channel 15 reacts with the hydrogen generator 61 in this to generate hydrogen. The generated hydrogen is dissolved in water or warm water flowing in the water channel 15 to the discharge port 32, and is discharged from the discharge port 32. In order to prevent the hydrogen generating agent 61 from unnecessarily reacting with the water remaining in the hydrogen supply unit 20 when the shower is not used, the shower from the hydrogen supply unit 20 is performed upstream of the hydrogen supply unit 20. A drainage port 29B is provided for draining water accumulated in the interior up to the head 30, and a drainage lever 29A for opening and closing the drainage port 29B is provided in the vicinity thereof.

  Preferably, the hydrogen supply unit 20 is formed of a transparent or translucent material so that the consumption of the hydrogen generating agent 61 contained therein can be seen at a glance. Further, the position at which the front portion 26 and the rear portion 27 are screwed together does not have to be an intermediate portion of the hydrogen supply unit 20 as shown in the drawing, and may be provided at any position in design.

  In the case of discharge at a shower water temperature of 41 ° C. and a water amount of 8.0 L / min using the hydrogen generation shower 10 of the present embodiment, as shown by the line graph in FIG. A high hydrogen concentration of 600 ppb was observed. Moreover, the elution amount of the fats-and-oils coating agent in shower time 10 minutes was 1 g or less. The boron concentration during this period is as shown by triangles in the figure, and the average concentration was 3.8 ppm, and even at the highest time point, it was 4.1 ppm and could be less than 10 ppm of the drainage standard.

  Here, assuming that the average shower time per person is 10 minutes per day, it means that it can be used for 12 days under the above conditions. The hydrogen concentration can be appropriately adjusted by changing the ratio and amount of sodium borohydride and the oil and fat coating agent to be compounded, the type of the oil and fat coating agent, and the density and thickness of fibers of the non-woven fabric to be coated. . For example, if the hydrogen concentration is adjusted to half, the usable time will be doubled.

  As described above, sodium borohydride also has an effect of decomposing and removing hypochlorous acid contained in tap water. That is, as shown in FIG. 12, the chlorine concentration in the shower water can be suppressed to a level as low as less than 0.1 ppm at least until 60 minutes after the high hydrogen concentration is shown in the shower (see FIG. 11). did it. By the way, the chlorine concentration is high again after 120 minutes, but this corresponds to the time when the hydrogen concentration is 0 as shown in FIG. 11, and the efficacy of the hydrogen generating agent 61 at this time Has been shown to be lost.

10 hydrogen generation shower 15 waterway 17 faucet
20 hydrogen supply part (outer cylinder) 21 inner cylinder fixing plate 22 water flow hole
23 inner cylinder holding hole 24 inlet 25 outlet
26 front 27 rear 28 mesh
29A drain lever 29B outlet
30 shower head 32 outlet
40 shower hose
50 aspirator 51 channel inlet 52 channel outlet
53 negative pressure generating chamber 54 external inlet 55 reduced diameter piece
56 Backflow prevention valve
60 hydrogen generation tank (inner cylinder) 61 hydrogen generator 62 storage section
63 cap 64 through hole 65 water flow valve
70 gas exhaust 71 gas permeable membrane 72 membrane support layer
73 packing 74 vent valve
80 transport route

Claims (13)

A hydrogen supply unit capable of continuously supplying hydrogen to the water channel is provided in the middle of the water channel from the faucet to the discharge port of the shower head.
A hydrogen generation shower characterized in that the hydrogen is generated by reacting a hydrogen generating agent which generates hydrogen by reacting with water.   The hydrogen generation shower according to claim 1, wherein the hydrogen generating agent is detachably accommodated in the hydrogen supply unit.   3. The hydrogen generation shower according to claim 2, further comprising: a drainage port upstream of the hydrogen supply unit for removing water accumulated in the hydrogen supply unit.   The hydrogen generation shower according to claim 1, wherein the hydrogen supply unit can continuously supply hydrogen using water pressure of a water flow. The hydrogen supply unit is located between a waterway inlet connected to the upstream side of a waterway to which water or hot water is supplied, a waterway outlet connected to the downstream side of the waterway, the waterway inlet and the waterway outlet. And an aspirator having a negative pressure generating chamber in which a negative pressure is generated by the water pressure of the water flow, and an external inlet through which liquid and gas from the outside flow into the negative pressure generating chamber.
A hydrogen generation tank provided outside the water channel and containing water and the hydrogen generator inside;
A transport path connecting the hydrogen generation tank and the external inlet and flowing a liquid containing hydrogen from the hydrogen generation tank into the negative pressure generation chamber;
The hydrogen generation shower according to claim 4, characterized in that The hydrogen supply unit is formed as a hollow outer cylinder provided in the middle of the water channel and has a hydrogen generation tank provided as a hollow inner cylinder mounted inside the outer cylinder,
The upstream end side of the inner cylinder is provided with a water flow valve for introducing a part of the water flow from the upstream of the water channel into the inner cylinder and preventing backflow of liquid,
The downstream end side of the inner cylinder is provided with a gas discharge unit which discharges only gas from the inside of the inner cylinder to the water channel on the downstream side,
The hydrogen generation shower according to claim 4, wherein the hydrogen generating agent is accommodated inside the inner cylinder.   7. The hydrogen generation shower according to claim 6, wherein the gas discharge part is a gas permeable membrane that allows the passage of gas and does not allow the passage of liquid.   7. The hydrogen generation shower according to claim 6, wherein the gas discharge part is a vent valve through which gas can not pass and liquid can not pass.   The hydrogen generating shower according to any one of claims 1 to 8, wherein the hydrogen generating agent is selected from the group consisting of sodium borohydride, magnesium hydride and metallic magnesium.   The hydrogen generation shower according to claim 9, wherein an organic acid is also added to the hydrogen generator.   11. The hydrogen evolution shower according to claim 10, wherein the organic acid is citric acid.   The hydrogen generating shower according to any one of claims 1 to 8, wherein the hydrogen generating agent is formed by dispersing a hydrogen-containing metal compound in fats and oils at room temperature solid state.   The hydrogen generation shower according to claim 12, wherein the normal temperature solid fat or oil is polyoxyethylene fat or oil or polyoxyethylene fatty acid ester obtained by reacting fat or oil or fatty acid with polyethylene glycol or polyoxyethylene to be esterified.