JP2019205615A - Production method and production machine of microbubble mixture water - Google Patents

Abstract

To provide a production method and a production machine of microbubble mixture water in which a user can be bathed in carbonated microbubble shower, even if it is a shower head where a carbonated bath agent cannot be put therein.SOLUTION: A production method of carbonated microbubble mixture water is characterized by mixing hot water obtained from a hot water outlet 2 in a shower head 3 with microbubble obtained by dissolving a carbonated bath agent 8 in the hot water to thereby obtain microbubble mixture water. The microbubble mixture water receives the carbonated bath agent, and can be obtained from a hot water outlet of an exterior body being wound and mounted to the hot water outlet.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a method for producing a microbubble mixed water that significantly improves the bathing effect of carbonated springs such as blood circulation promotion and also has a microbubble effect, and a production device that can easily obtain the microbubble mixed water.

  Molding a mixture containing bicarbonate (sodium hydrogen carbonate or potassium hydrogen carbonate) and an organic acid by tableting or the like to form a foamable composition (solid) is a cleaning agent, bathing agent, bath water cleaning It is applied to products such as chemicals and fungicides for pools. These products (solids) have the advantage of quickly dissolving while generating carbon dioxide when they react with water, and at the same time increase the commercial value because they give consumers a comfortable feeling of use. In particular, in a bath preparation (sometimes referred to as a bath preparation), the blood circulation promoting effect of the generated carbon dioxide gas is actively used.

  Conventionally, in order to obtain carbonated microbubble shower water using a bath agent, a technique of inserting a carbonate bath agent into a shower head is known (see Patent Documents 1 to 4). The present inventor has also proposed the technique described in Patent Document 4.

JP 2008-241261 A Japanese Patent Laid-Open No. 62-283915 JP 2007-289289 A Japanese Patent No. 6268226

  Since these techniques described in Patent Documents 1 to 4 are configured to set a carbonic acid bathing agent on the shower head, if there is no shower head that can be set, the carbonic microbubble shower by the shower head could not be taken. .

  In particular, even if there was a desire to bathe in carbonated micro bubble shower water while traveling abroad, there were no accommodations such as hotels where a carbonated bathing agent could be set, so we had to give up.

  From the above, the object of the present invention is to provide a method and a device for producing microbubble mixed water capable of bathing a carbonated microbubble shower even if it is a shower head that cannot contain a carbonated bath agent. It is in.

1. It is a method for producing carbonated microbubble mixed water to obtain microbubble mixed water by mixing hot water obtained from a hot water outlet in a shower head and microbubbles obtained by dissolving a carbonate bath in the hot water,
The microbubble mixed water is obtained from a hot water jet of an exterior body that contains the carbonated bathing agent and is wound around and attached to the hot water jet.
2. The outer body is a storage container that contains a carbonate bath and is wound around a hot water outlet, and the pores or nets of the storage container are microbubble mixed water hot water outlets. 2. The method for producing carbonated microbubble mixed water according to 1.
3. The exterior body is a storage container that contains a carbonated bathing agent and is wound around and attached to a hot water outlet, and has a pore or a mesh part. 2. The method for producing carbonated microbubble mixed water according to 1 above, which is an outlet.
4). An exterior body wound around and attached to a hot water outlet in a shower head is mixed, and hot water obtained from the outlet is mixed with microbubbles obtained by dissolving a carbonic acid bathing agent in the hot water. To obtain carbonated microbubble mixed water production equipment
The said exterior body has the accommodating part of the said carbonate bathing agent, and also has a spout of the carbonated microbubble mixed water, The manufacturing apparatus of the carbonated microbubble mixed water characterized by the above-mentioned.
5. The outer body is a storage container that contains a carbonate bath and is wound around a hot water outlet, and the pores or nets of the storage container are microbubble mixed water hot water outlets. 5. A device for producing carbonated microbubble mixed water according to 4.
6). The exterior body is a storage container that contains a carbonated bathing agent and is wound around and attached to a hot water outlet, and has a pore or a mesh part. 5. The device for producing carbonated microbubble mixed water according to 4 above, which is an outlet.
7). The carbonated microbubble mixed water according to any one of 4 to 6 above, wherein the storage container for the carbonated bathing agent is mounted between a hot water outlet of the exterior body and a hot water outlet of the shower head. Manufacturing machine.
8). It is a microbubble mixed water producing device having an outer body wound around and attached to a hot water outlet in a shower head,
The outer packaging body has a carbonate bath containing portion and a jet of carbonated microbubble mixed water, and a carbonated microbubble mixed water producing device.
9. The outer body is a storage container that contains a carbonate bath and is wound around a hot water outlet, and the pores or nets of the storage container are microbubble mixed water hot water outlets. 8. A device for producing carbonated microbubble mixed water according to 8.
10. The exterior body is a storage container that contains a carbonated bathing agent and is wound around and attached to a hot water outlet, and has a pore or a mesh part. 9. The apparatus for producing carbonated microbubble mixed water according to 8 above, which is an outlet.
11. 11. The carbonated microbubble mixed water according to any one of the above 8 to 10, wherein the storage container for the carbonated bathing agent is mounted between a hot water outlet of the exterior body and a hot water outlet of the shower head. Manufacturing machine.
12 12. The device for producing carbonated microbubble mixed water according to any one of 4 to 11 above, wherein the storage container for carbonated bathing agent is a container for accommodating one or more carbonated bathing agents.
13. 13. The carbon microbubble mixed water producing apparatus according to claim 12, wherein the storage container has pores or nets for dissolving the carbonate bath agent in hot water.
14 12. The container according to the above 12, wherein the storage container is a container for storing one or more carbonated bathing agents in a direction parallel or perpendicular to the flow direction of the hot water obtained from the hot water outlet of the shower head. Or the manufacturing apparatus of carbonic acid microbubble mixed water of 13.
15. 15. Said 13 or 14 characterized by the pore provided in the said storage container being provided in the surface which exists in the direction which is the same direction as the flow direction of the hot water obtained from the hot water jet nozzle of a shower head, or a orthogonal direction. Carbonated microbubble mixed water making device.

  According to the inventions shown in the above 1, 4 and 8, there is no need for a showerhead having a special structure capable of incorporating a carbonated bathing agent, and a carbonated microbubble shower can be bathed as long as there is a general showerhead.

  According to 2, 3, 5-7 and 9-11, since a storage container having a pore or a net is used, regardless of the shape of the shower head, by wrapping around a wide shower head, Carbonated microbubble shower water can be bathed.

  According to the inventions shown in 12 and 13, by using the storage case for storing the carbonated bath agent, the carbonated bath agent can be easily wrapped around the hot water outlet of the shower head, and the carbonated bath agent is completely removed. It can be used effectively until it is completely dissolved, and a carbonated microbubble shower can be bathed for a long time.

  According to the inventions shown in the above 14 and 15, a carbonic microbubble shower bath can be performed for a longer time.

  In the present invention, “hot water” refers to so-called water, warmed or heated hot water, or a mixture of both. “Microbubble” refers to what is called a fine bubble. In the present invention, “amount” represents “mass” unless otherwise specified, “%” represents “mass%” unless otherwise specified, and “part” represents “part by mass” unless otherwise specified. Represents.

The side view which shows an example of the shower head which wound and mounted | worn the storage container used for the manufacturing apparatus of the carbonated microbubble mixed water which concerns on this invention. The perspective view which shows an example of the storage container used for this invention. The perspective view which similarly shows another example. Furthermore, the perspective view which shows another example.

  Hereinafter, a method for producing microbubble mixed water according to the present invention (hereinafter sometimes simply referred to as a production method) and a device for producing microbubble mixed water (hereinafter also simply referred to as a manufacturer) will be described with reference to the drawings. explain.

  The present invention is a method for producing microbubble mixed water having both a carbonated spring bathing effect and a microbubble effect, and a production device for easily obtaining the microbubble mixed water, and a device for producing hot water in which carbon dioxide components and microbubbles are mixed. This is a technique that can be expected to have a health promotion effect such as a cleaning effect and blood circulation promotion by discharging from the discharge port (shower discharge).

  In particular, the present invention is a normal shower head that does not have a carbonated bath additive storage part, and is equivalent to or more than a shower head that discharges carbonated microbubble mixed water and has a conventional carbonated bath additive storage part. It is a technology that can exert health promotion effects such as cleaning effects and blood circulation promotion.

  According to the inventor's research, the effect of the present invention is that, in the case of a shower head having a conventional carbonated bath additive storage section, hot water contacted with the carbonated bath additive is equivalent to running water in tap water, However, the hot water contacted with the carbonate bath in the present invention is a microbubble mixed water in which bubbles obtained from the hot water outlet in the shower head are mixed, and this microbubble mixed water. This is presumed to be for obtaining carbonated microbubble mixed water by bringing a carbonate bathing agent into contact with and dissolving.

  In addition, the present invention has an advantage that even when traveling abroad, as long as there is an ordinary shower head, the carbonated microbubble mixed water by the carbonate bathing agent can be easily bathed.

  Hereinafter, in an embodiment of the present invention, a shower device 1 around which a storage container of the present invention is wound is provided with a shower head 3 having a hot water outlet 2 and a shower body 4 which becomes a handle of a handle when used. The thing of the structure which illustrates is shown, and hot water shall be supplied from the hose 5 connected to the shower trunk | drum 4. FIG.

  However, the shower head 3 and the shower body 4 may be integrally formed, or may be formed by connecting or combining separately formed ones. Alternatively, the shower head 3 may be connected directly or indirectly to the shower body 4 so that the direction and angle of the shower head 3 can be changed, and at least the shower head 3 having the hot water outlet 2 is provided. It only has to be.

  The manufacturing device according to the present invention is exemplified in FIG. 2 as an example of the storage container 6 wound around the hot water outlet 2 in the shower head 3.

  As shown in FIG. 2, the storage container 6 has a storage portion for the carbonated bathing agent 8 between the hot water jet 2 of the shower head 3 and the hot water jet 7 constituting the jet of the carbonated microbubble mixed water. 9.

  For example, after storing one or two or more of the carbonated bath agent 8 in the storage portion 9 of the storage container 6 illustrated in FIGS. 2 to 4, the storage container 6 is wrapped around the shower head 3 using the rubber hand 11. Good. In addition, when using the 2 or more carbonic acid bath agent 8, it is preferable to accommodate | superimpose.

  That is, the storage container 6 includes, for example, a so-called magic tape male 12 </ b> A provided at the tip of each of the rubber bands 11, 11 attached to the attachment parts 20, 20 provided on the side wall 19 that forms the cylindrical container body 13. The female mold 12B is wrapped around the back head 10 of the shower head 3.

  Any known means for attaching the rubber bands 11, 11 to the attachment portion 20 may be employed. For example, the end portions of the rubber bands 11, 11 are passed through the attachment portion 20 to sew the rubber bands 11, 11 together, or an insertion member is provided at the end portions of the rubber bands 11, 11 to be fitted and fixed to the attachment portion 20. .

  As shown in FIG. 2, the container main body 13, in the case of the container main body 13 without a lid, contains the carbonated bathing agent 8, and then the opening 14 without the lid is brought into contact with the hot water outlet 2 of the shower head 3. What is necessary is just to wrap and attach to the shower head 3 in a state. The container body 13 is provided with a large number of shower pores 15.

  As shown in FIG. 3, the container body 13 can be exemplified by a container body 13 shown in FIG. 2 that is covered with a lid 17 having a large number of shower pores 16.

  In this case, the lid 17 may be provided with a protrusion 18 in order to make a gap between the lid 17 and the jet port 7. In this example, the structure which can accommodate the some carbonated bath agent 8 in piles is shown.

  In the example shown in FIGS. 2 and 3, shower pores can be provided on the side wall 19 of the container body 13 instead of or simultaneously with the shower pores 15 and 16. When it is provided on the side wall 19 in place of the shower pores 15 and 16, the dissolution time of the carbonic acid bathing agent 8 can be greatly extended. Moreover, it can also be set as the storage container 6 which used the structure of FIG.2 and FIG.3 together.

  In the case of the example shown in FIGS. 2 and 3, one or more carbonated bathing agents 8 used in the present invention are accommodated in a direction orthogonal to the flowing direction of the hot water discharged from the hot water outlet 2.

  The present invention is not limited to the above, and the carbonated bathing agent 8 may be configured to accommodate one or more in a direction parallel to the flowing direction of the hot water discharged from the hot water outlet 2.

  That is, for example, as shown in FIG. 4, the storage container 6 has a partition wall (side wall) 19 erected in parallel, and one or more of the carbonated bathing agent 8 is fixed between the partition walls (side wall) 19. In this state, the hot water outlet 2 may be wound and attached as shown in FIG. 1 as in the case of the example shown in FIG.

  Shower pores 15 are provided on the lower surface of the partition wall 19. A partition body 21 such as a mesh body may be provided on the side of the partition wall 19.

  In this case, the carbonated bath agent 8 may be set in either the same direction or a direction orthogonal to the flowing direction of the hot water obtained from the hot water outlet 2 of the shower head 3.

  The size of the storage container 6 that stores the carbonated bath agent 8 is only required to accommodate at least one carbonated bath agent 8. However, it is not limited to this, It is preferable to set it as the magnitude | size which can accommodate two or more.

  Further, the size of the surface of the storage container 6 facing the shower outlet 7 is such that it is wound around and attached to a part of the shower outlet 7 as shown in FIG. The size may be equal to the size, or may be larger than the shower outlet 7.

  The outer shape of the storage container 6 may be a cylindrical shape as shown in FIGS. 2 and 3, or may be a rectangular shape as shown in FIG. Any part or all of the squirting hot water from the water can be brought into contact with the carbonic acid bathing agent 8 contained in the storage container 6, and any structure can be used as long as it is ejected from the hot water jet 7.

  Next, the operation of the present invention will be described.

  First, one or two or more carbonated bathing agents 8 are accommodated in the accommodating portion 9 of the accommodating container 6 according to the present invention, the accommodating container 6 is made to face the shower hot water outlet 2, and the rubber hands 11 and 11 are placed on the shower head 10. The storage container 6 containing the carbonic acid bathing agent 8 is wound around the shower head 3 and attached thereto.

  If the shower apparatus 1 is operated in this state, the hot water discharged from the shower hot water outlet 2 is mixed with microbubbles obtained by dissolving the carbonic acid bathing agent 8 incorporated in the storage container 6, and microbubble mixing Water will be ejected from the hot water spout 7.

  This shower bath with the microbubble mixed water is continued until the carbonate bathing agent 8 is completely dissolved.

  Even if the shower bath is temporarily stopped, as long as the carbonic acid bathing agent 8 remains in the storage container 6, the shower device 1 can be operated again to obtain a shower bath with microbubble mixed water.

  The carbonic acid bathing agent in the present invention may be any publicly known and publicly used one.

  Examples of the carbonic acid bathing agent (bathing agent) preferably used in the present invention include those described in Japanese Patent No. 6268332 previously proposed by the present inventor, and are exemplified below.

  Preferred bath preparations for the present invention include organic acid (citric acid, succinic acid, malic acid, fumaric acid, etc.) after granulating bicarbonate with polyethylene glycol (hereinafter sometimes referred to as “PEG”) or the like. , Citric acid is most preferred) and PEG are mixed or granulated, and each is mixed under conditions within a certain ratio, and the following excipients are added to form a tablet by compression molding. By designing the pH to be in the following range, when water penetrates into the tablet, it reacts so that carbon dioxide gas foams vigorously and uniformly, and the generated carbon dioxide bubbles are long as micro-sized fine carbon dioxide gas. The tablet continues to foam micro-sized bubbles until dissolution is complete, before the bubbles volatilize in the air, neutralized in water and dissociated into bicarbonate ions, resulting in high concentrations of bicarbonate ions. The pH of water is designed to be 5.5 to 9.0, preferably 6.0 to 8.5, especially 6.3 to 8.0, so that the effect of the present invention is maximized. Is done.

  Furthermore, since the mixture of bicarbonate is a granulated product prepared by coating with PEG using a fluidized bed, the effects of the present invention such as continuous and uniform reaction in tablets can be exhibited. Greatly demonstrated.

The bath agent is preferably used in the present invention as the tablet hardness is 15 kg or more, preferably 25 kg or more, particularly preferably 30 kg or more. That is, for example, a continuous and stable reaction of a chlorine neutralizing compound can be obtained, and the chlorine neutralization reaction inside the tablet is suppressed, and the dissolved part of the tablet is molded with high hardness so that chlorine can be removed quickly in hot water. It is preferable.
The higher the chlorine removal effect, the greater the effect of promoting health such as blood circulation promotion and body temperature rise even when taking a shower.

  The bath agent has a tablet friability of 10.0 wt% or less, particularly preferably 5.0 wt% or less, and more preferably 3.0 wt% or less. In addition to maximizing the chlorine neutralization reaction efficiency inside the bath agent, it is possible to exert health promotion effects such as blood circulation promotion and body temperature rise even when taking a shower.

  Examples of the organic acid include citric acid, fumaric acid, succinic acid, malic acid, and the like. In particular, when citric acid is used as the organic acid, the neutralization reaction in the bath agent is suppressed and the chlorine removal ability in hot water is increased. Fine carbon dioxide foaming can be realized.

  When granulating at least one of bicarbonate or organic acid in a fluidized bed to obtain a granulated product, if a mechanical fluidized bed granulator that does not substantially use air as a stirring action is used, The reaction can be improved efficiently. As the fluidized bed of the mechanical stirring method, the powder is fluidized using mechanical blades such as a propeller without using air for stirring. In this case, it does not absorb moisture brought in from humid air during granulation, it can also be evacuated with a vacuum pump during granulation, and it can be granulated by lowering the amount of PEG. It is preferably used because the effect of extremely reducing the diameter of foaming bubbles can be exhibited while making the reaction more active.

  A preferred method for producing the bath is to granulate sodium bicarbonate with a fluidized bed granulator using PEG and a mechanical stirring method, and to the granulated product a certain amount of organic acid, anhydrous sodium carbonate and PEG. In addition, after mixing, compression molding is performed at a high pressure to obtain a bath agent.

  The ratio of PEG to 100 parts by weight of the mixture A of bicarbonate (sodium bicarbonate or potassium bicarbonate) (may be granulated product A) is 1/100 to 1/5, particularly preferably 1/100. If the ratio of PEG is less than the above amount, it will be difficult to obtain a sufficiently high hardness, or it will be difficult to obtain a sufficiently low friability, and the diameter of carbon dioxide bubbles will increase, resulting in a foaming time. However, if the amount of PEG is higher than the above, the amount of carbon dioxide bubbles generated is suppressed, and the amount of bicarbonate dissolved in water is the same. The amount of carbonate ions may be reduced.

  Further, after obtaining a granulated product A or PEG mixture A of bicarbonate, and adding organic acid or organic acid granulated product B or PEG organic acid mixture B, anhydrous sodium carbonate, anhydrous potassium carbonate or the like is added. By adding the product, the effect of increasing the amount of foaming and maintaining it for a long time can be obtained while making the bubble diameter of the carbon dioxide gas small.

  As the above anhydride, the effect of the present invention can be exhibited more preferably when anhydrous sodium carbonate or anhydrous potassium carbonate is added.

  In addition, the organic acid is not granulated, and PEG is added to the organic acid and mixed with at least one selected from C6 to C18 alkane sulfonate, olefin acid sulfonate, sucrose fatty acid ester, sodium sulfate, and magnesium sulfate. As a result, when the mixture A is compression-molded to form a bath agent, the micro-sized foam of the present invention can be foamed for a long time, and the carbon dioxide component dissolved in the hot water can be increased.

  Meanwhile, the organic acid is mixed with PEG and C6-18 alkane sulfonate, olefin acid sulfonate and sucrose fatty acid ester, sodium sulfate, magnesium sulfate, or granulated. Also, when mixing and compression molding with the mixture A at a constant temperature, a bath agent capable of foaming micro-sized foam for a long time, maximizing the carbon dioxide component dissolved in water, and stably maintaining the chlorine removal ability to the end. Can be obtained.

  The use ratio of PEG to organic acid in the above production method is preferably 5 to 15 parts by mass with respect to 100 parts by mass of organic acid.

  The added amount of granulated product B or mixture B to granulated product A or mixture A of bicarbonate is 1/100 to 2/3, preferably 1/50 to 2/3, particularly preferably 1/10 to 1 / 3.

  Further, the anhydride is added to any step during compression molding, such as the step of preparing the granulated product A or the mixture A, or the step of mixing the granulated product A with the mixture B or the granulated product B. It is preferable.

Excipients used for powder mixture and bath preparation are sodium alkane sulfonate having 6 to 18 carbon atoms, sodium olefin sulfonate having 6 to 18 carbon atoms, sucrose fatty acid ester, sodium sulfate, magnesium sulfate, etc. It is. Desirable compounds include sodium n- (normal) octane sulfonate, sodium tetradecene sulfonate, a mixture of C6 to C18 sodium alkane sulfonate, sucrose laurate, sucrose myristic ester, sucrose palmitic acid Ester sodium sodium sulfate is used. Among these, sodium n- (normal) octanesulfonate, sodium tetradecenesulfonate, and sodium n-heptanesulfonate are particularly preferable.
The amount of sodium n- (normal) octane sulfonate, sodium tetradecene sulfonate and sodium n-heptane sulfonate of the present invention is 1/10 to 1/1000 of the organic acid used in the bath. Preferably there is. Similar amounts may be used for other excipients.

  Particularly desirable sodium alkane sulfonates and sodium olefin sulfonates include at least one of a C6 to C18 sodium alkane sulfonate mixture, sodium tetradecene sulfonate, and sodium normal octane sulfonate.

  In the mixture B and the granulated product B, sodium chloride, potassium chloride, dry sodium sulfate, magnesium sulfate, magnesium oxide, anhydrous silicic acid, sodium hydroxide, dextrin, calcium silicate are additives that are preferably used. A fragrance | flavor, a pigment | dye, surfactant, etc. are mentioned as an additive.

  A known compression molding machine can be used for compression molding for preparing the bath without any particular limitation. For example, a hydraulic press machine, a single-shot tableting machine, a rotary tableting machine, a briquetting machine, or the like can be used. it can. The size of the punch used in this tableting machine or the like is preferably 7 mm or more when the punch is circular, and when the punch is a triangle or square, the diameter is 7 mm or more in terms of a circular punch. Those are preferred. The same applies to the thickness of the ridge. When obtaining a round tablet product, the tablet diameter is preferably 7 mm or more, more preferably 10 mm or more, and the thickness is also 7 mm or more, preferably 10 mm or more. In terms of conversion, each of the diameter and thickness is preferably 7 mm or more, particularly 10 mm or more.

  As described above, the bath agent does not necessarily have to be a circular shape having a flat surface, and the shape is not limited at all as long as it is a solid body of 7 mm or more, whether it is an oval shape, a so-called tablet shape or a spherical shape.

  The bath agent preferably causes micro-size foaming slowly in the above-mentioned hardness and friability and a certain size or more of the bath agent, and more efficiently dissolves the carbon dioxide gas in the hot water. Therefore, the hardness is 15 kg or more. Desirably, it is 25 kg or more, particularly preferably 35 kg or more, the friability is 10.0 wt% or less, preferably 5 wt% or less, particularly preferably 3 wt% or less, and the diameter or thickness is particularly preferably 10 mm or more. Generation of carbon dioxide gas in the agent occurs more effectively, so that the carbon dioxide gas is efficiently dissolved in water and the diameter of the bubbles is reduced.

  Hereinafter, the hardness of the bath preparation according to the present invention will be described.

  The hardness as bathing agent breaking strength from the diameter direction was measured.

  In this method, the breaking strength of the bath salt is measured, but the hardness [kg] of the bath salt is measured four times by using a digital tablet hardness meter New Speed Checker TS75NL manufactured by Okada Seiko Co., Ltd. as a hardness measuring method in the diameter direction. It was measured. In this case, the hardness was reproducible and no large variation in value was observed.

  When the bubble diameter of carbon dioxide gas generated in hot water, which is a preferred bath preparation condition, is measured visually, the tablet diameter is 7 mm or more, particularly 10 mm or more, and it is uniformly generated without bubbles and the neutralization reaction is completed. Using the 12 samples of 7 lots of the test bath product, 12 kinds of tablets were prepared so that the bath solution reacted until the bath solution was completely dissolved, so that carbon dioxide was neutralized and bicarbonate ions could be efficiently dissolved in hot water. Even when the hardness was measured, if the average value was measured four times, the fluctuation width of the measured value was negligible, and it was confirmed that the bath had a mean hardness of 15 kg or more, particularly 25 kg or more.

Hereinafter, the friability of the bath agent preferably used in the present invention will be described. As for the friability, a bath agent is placed in a tablet friability tester (manufactured by Higaki Medical Science Co., Ltd.) so that the weight of the bath agent is 31 g or more. For example, when the weight of 1 bath agent is 15 g, 3 bath agents are added and rotated for 2 minutes (rotation speed is 25 rotations / minute). After finishing, the powder on the surface of each bath preparation is brushed (braded) with a brush (for example, used for cleaning the chemical balance), and obtained by the following formula.
[(Bath weight before wear (g) Sum-Weight of bath powder after wear (g) Sum) / Bath weight before wear (g) Sum] x 100 = Bath wear rate (wt%)
In addition, for example, when the weight of the bath preparation is 40 g, one tablet is put. When the weight is 60 g, one tablet is put, and when one bath preparation is 16.5 g, two pieces are put.

  When the bath agent friability is 10.0 wt% or less, micro-size foaming in the bath agent is caused slowly, and dissolution of carbon dioxide gas in the liquid can be efficiently controlled. Therefore, the friability is 10.0 wt% or less, more preferably 5.0 wt% or less, and particularly preferably 3.0 wt% or less. In the bath agent having this friability, the generation of carbon dioxide gas in the bath agent occurs more efficiently, particularly after the dissolution of the bath agent starts, and the dissolution of carbon dioxide gas in water is performed efficiently, and The diameter of becomes smaller.

  Although it is desirable to add compounds other than the above as much as possible to a bath agent, an acidic component, an alkali component, a fragrance | flavor component, and one or two or more gorgeous hot spring components etc. can also be added as needed.

  It is preferable to add the pH adjusting agent after adding the above components in a preferable amount ratio, and to adjust the pH in water after dissolution to the above range.

  As the pH adjuster to be used, sodium carbonate and organic acid are preferably used, but any other publicly known and publicly available ones can be used without any particular limitation, and in particular, the pH adjuster as a food additive can be used. Since it may enter the eyes and mouth, it is preferable for safety. For example, trisodium citrate (sodium citrate), disodium citrate, monosodium citrate, potassium gluconate, sodium gluconate, disuccinate Examples include sodium, sodium acetate, DL-sodium tartrate, L-sodium tartrate, potassium carbonate, sodium bicarbonate, sodium carbonate, sodium lactate, DL-sodium malate, and the like.

  The bath agent used in the present invention is, for example, compression molded in the presence of bicarbonate, organic acid, and polyethylene glycol, the diameter and thickness are 7 mm or more, the hardness is 15 kg or more, and the bath agent is dissolved in hot water. Examples thereof include a bath agent in which the pH immediately after is in the range of 5.5 to 8.5, preferably containing an activator such as sodium n- (normal) octane sulfonate, and further, Patent No. 6268332 such as L-ascorbic acid. Containing the chlorine neutralizing compound described in the Japanese Patent Publication.

  Compared with the prior invention of Patent 6267332 previously proposed by the present inventor, the present invention differs from the above in that the carbonated bathing agent is dissolved in hot water obtained from the hot water discharge port in the shower head to obtain carbonated microbubble mixed water. The technical problem of the present invention could be solved, and the same or better effect than the previous invention was obtained.

DESCRIPTION OF SYMBOLS 1 Shower apparatus 2 Hot water spout 3 Shower head 4 Shower trunk | drum 5 Hose 6 Storage container 7 Hot water spout 8 Carbonated bath agent 9 Accommodating part 10 Shower head rear head 11 Rubber band 12 Fasteners, such as a magic tape 12A Magic tape male type 12B Magic tape female mold 13 Container body 14 Opening portion 15 Pore 16 Pore 17 Lid 18 Protrusion 19 Side wall 20 Mounting portion 21 Reticulated body

Claims (15)

It is a method for producing carbonated microbubble mixed water to obtain microbubble mixed water by mixing hot water obtained from a hot water outlet in a shower head and microbubbles obtained by dissolving a carbonate bath in the hot water,
The microbubble mixed water is obtained from a hot water jet of an exterior body that contains the carbonated bathing agent and is wound around and attached to the hot water jet. The exterior body is a storage container that contains a carbonated bathing agent and is wound around and attached to a hot water outlet, and the pores or nets of the storage container are hot water outlets of microbubble mixed water. Item 2. A method for producing carbonated microbubble mixed water according to Item 1. The exterior body is a storage container that contains a carbonated bathing agent and is wound around and attached to a hot water outlet, and has a pore or a mesh part. It is an exit, The manufacturing method of the carbonic acid microbubble mixed water of Claim 1 characterized by the above-mentioned. An exterior body wound around and attached to a hot water outlet in a shower head is mixed, and hot water obtained from the outlet is mixed with microbubbles obtained by dissolving a carbonic acid bathing agent in the hot water. To obtain carbonated microbubble mixed water production equipment
The said exterior body has the accommodating part of the said carbonate bathing agent, and also has a spout of the carbonated microbubble mixed water, The manufacturing apparatus of the carbonated microbubble mixed water characterized by the above-mentioned. The exterior body is a storage container that contains a carbonated bathing agent and is wound around and attached to a hot water outlet, and the pores or nets of the storage container are hot water outlets of microbubble mixed water. Item 5. A device for producing carbonated microbubble mixed water according to Item 4. The exterior body is a storage container that contains a carbonated bathing agent and is wound around and attached to a hot water outlet, and has a pore or a mesh part. It is an exit, The manufacturing apparatus of the carbonated microbubble mixed water of Claim 4 characterized by the above-mentioned. The carbonated microbubble mixing according to any one of claims 4 to 6, wherein the storage container for the carbonated bathing agent is mounted between a hot water outlet of the exterior body and a hot water outlet of the shower head. Water maker. It is a microbubble mixed water producing device having an outer body wound around and attached to a hot water outlet in a shower head,
The outer packaging body has a carbonate bath containing portion and a jet of carbonated microbubble mixed water, and a carbonated microbubble mixed water producing device. The exterior body is a storage container that contains a carbonated bathing agent and is wound around and attached to a hot water outlet, and the pores or nets of the storage container are hot water outlets of microbubble mixed water. Item 9. A device for producing carbonated microbubble mixed water according to Item 8. The exterior body is a storage container that contains a carbonated bathing agent and is wound around and attached to a hot water outlet, and has a pore or a mesh part. It is an exit, The manufacturing apparatus of the carbonated microbubble mixed water of Claim 8 characterized by the above-mentioned. The carbonated microbubble mixing according to any one of claims 8 to 10, wherein the storage container for the carbonated bathing agent is mounted between a hot water outlet of the exterior body and a hot water outlet of the shower head. Water maker. 12. The carbonated microbubble mixed water producing apparatus according to any one of claims 4 to 11, wherein the carbonated bathing agent storage container is a container for storing one or more carbonated bathing agents. The said storage container has a pore or a net | network part which dissolves a carbonic acid bath agent in hot water, The carbonated microbubble mixed water manufacturing apparatus of Claim 12 characterized by the above-mentioned. The storage container is a container that stores one or more carbonated bathing agents in a direction parallel or orthogonal to a flowing direction of hot water obtained from a hot water jet outlet of a shower head. A device for producing mixed carbonated microbubble water according to 12 or 13. The pore provided in the said storage container is provided in the surface which exists in the direction which is the same direction as the flow direction of the hot water obtained from the hot water outlet of a shower head, or a direction orthogonal to Claim 13 or 14 characterized by the above-mentioned. A device for producing carbonated microbubble mixed water as described.