JP2010119918A - Drinkable radon water storage container and drinkable radon water supply machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a drinkable radon water storage container for inexpensively selling drinkable radon water for domestic use at low cost while maintaining the radon concentration in the captured radon water containing the radon component within the drinkable range. <P>SOLUTION: The drinkable radon water storage container 1 includes a body 3 for storing the captured drinkable radon water 2 containing the radon component, an outlet port 4 for discharging the drinkable raw water 2 fixed to a portion of the body 3, a lid 5 for opening/closing the outlet port 4, and a case 6 fixed to the lid 5 at its inner side facing the body 3 for holding a radium ore 7 which maintains the radon concentration of the drinkable radon water 2 at its prescribed value. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a drinking radon water storage container and a drinking radon water feeder that maintain a radon-containing concentration of taken radon water in a predetermined range.

  In connection with the health boom, it has been proposed to drink radon water as good for the body and health. Radon water is often obtained from natural hot spring sources, and it is widely distributed by owners of natural radon water, which is springed from the source, in plastic tanks or plastic bottles. ing.

  Radon water is thought to be useful for activating the body's metabolism and improving the antioxidant function. Radon water is also considered to have an intestinal regulating action, and is considered to be one of drinking water useful for maintaining the health and promoting health of modern people. For this reason, it is thought that drinking of radon water has been proposed. For this reason, it is required to be able to drink radon water easily and at low cost at home.

Since radon water is considered to be effective in bathing, techniques for performing hot spring bathing using radon water at home have also been proposed (see, for example, Patent Documents 1 to 3). These patent documents 1-3 are disclosing the technique for obtaining hot spring water. In addition, techniques for modifying natural water and tap water with minerals have been proposed (see, for example, Patent Documents 4 to 6). In addition, the idea of the installation of the mineral for obtaining hot spring water and reformed water is also proposed (for example, refer patent documents 7 and 8).
JP 2008-18157 A JP 2006-34736 A JP 2001-322877 A JP 2007-37661 A JP 2005-329336 A JP 2006-334522 A JP 2004-130155 A JP 2008-6232 A

  However, when radon water taken from a source or obtained from a device that reforms natural water into hot spring water is packed in plastic tanks or plastic bottles and distributed and sold, the radon content of radon water will increase over time. There is a problem that the concentration decreases. Generally, the radon component contained in radon water evaporates in about 3 to 4 days to 1 week. For this reason, radon water drawn from sources packed in plastic tanks and plastic bottles, or obtained by modifying natural water, must be stored in radon during storage, transportation, and household storage. There is a problem that the concentration of content decreases. For this reason, the user who wants to use radon water for health promotion or the like has an undesirable problem that the radon-containing concentration decreases (sometimes disappears) before actually drinking.

  In addition, even if radium ore is added to natural water (including general water such as tap water), it will still take 3 to 4 weeks until it is reformed into radon water containing sufficient radon content. It takes some time. For this reason, there is a problem that even if radium ore is immersed in water or hot water at home, the radon water cannot be drunk immediately.

  Furthermore, since the radium ore and the modifier made from this are expensive, there is a problem that they are not suitable for general household use in terms of cost.

  When radon water is used as hot spring water for bathing, fine control of radon content concentration is not necessary, but when radon water is used as drinking water, it is necessary to control the prescribed radon content concentration. Become. For example, radon water having a radon-containing concentration of 5.5 Mache or higher can be displayed as hot spring water, but drinking radon water having this level of radon-containing concentration may cause diarrhea and the like.

That is, to drink radon water whose radon content concentration is adjusted easily at low cost at home,
(1) When purchasing radon water packed in a container, the radon-containing concentration decreases or disappears during transportation and storage.
(2) Even if radium ore is immersed in water or hot water, it takes a considerable amount of time to be modified to radon water containing radon-containing concentration.
(3) It is expensive to purchase radium ore to improve water at home. In particular, even if radium ore is added to tap water, there is no sanitary problem because chlorine contained in tap water has sterilizing ability, but if radium ore is added to mineral water, mineral water does not have sterilizing ability. There are hygiene problems,
(4) When the modification technology to bathing hot spring water is applied to the modification to drinking radon water, the radon content concentration is modified to be too high or too low.
It is necessary to solve such problems.

  Here, Patent Documents 1 to 3 disclose a technique for reforming natural water into hot spring water. Patent Document 1 discloses that hot spring water having hot spring components is reformed by immersing radium ore in water or hot water stretched in a bathtub. Patent Documents 2 and 3 disclose water modifiers produced by firing natural radioactive element minerals together with ceramic raw materials.

  However, since the techniques disclosed in Documents 1 to 3 are modification to hot spring water for bathing, the control of the radon-containing concentration is not considered. In addition, since water and hot water stored in a bathtub or the like are targeted for reforming, there is no consideration for transportation or transportation of radon water. For this reason, the technique which applied the technique of patent documents 1-3 to manufacture of drinking radon water cannot solve the above-mentioned problems (1)-(4).

  Patent Documents 4 to 6 disclose techniques for modifying natural water into functional water. Patent Document 4 discloses a technique for reforming hot spring water using a radium component. Patent Document 5 discloses a technique of modifying a water or a predetermined component by placing a ceramic or ore having a specific component, which is not a radium component, in the middle of a water circulation path. Patent Document 6 discloses a technique for reforming water by storing a catalyst in a water container.

  However, even if the techniques disclosed in Documents 4 to 6 are actually applied to a technique for reforming natural water or tap water into radon water at home, the above problems (2) and (3) cannot be solved.

  Patent Documents 7 and 8 disclose a technique for devising the installation position of minerals for reforming into hot spring water. Patent Document 7 discloses a technique for modifying water into hot spring water by arranging a case in which mineral is stored in accordance with an outlet of water (for example, under a faucet). Patent document 8 is disclosing the technique which arrange | positions the case which stores a mineral in the drain outlet of a bathtub, in order to obtain the hot spring water for bathing.

  However, in Patent Document 7, the contact time between water and mineral is very short, and the modification is not sufficiently performed. That is, Patent Document 7 cannot solve the problem (2). Moreover, patent document 8 is a technique which produces | generates the hot spring water for bathing, Comprising: Although it cannot apply to the production | generation of radon water to drink, even if it can apply temporarily, said problem (4) cannot be solved. In addition, neither of Patent Documents 7 and 8 can solve the problem (3).

  As described above, techniques for generating hot spring water for bathing using radium ore (Patent Documents 1 to 3), techniques for modifying natural water or tap water into functional water (Patent Documents 4 to 6), and hot spring water All of the above problems (1) to (4) cannot be solved at the same time by any of the technologies (Patent Documents 7 to 8) related to the installation position of the mineral for reforming to the above. The same applies even if these techniques are appropriately combined.

  In particular, considering the above problem (2), when radon water taken in a container is packed in a container for use at home, the radon content in the container is drastically reduced or eliminated. Without the need to provide radon water at low cost.

  In order to solve the above problems, the present invention is a drinking radon water storage container that can sell drinking radon water to a home at low cost while maintaining the radon-containing concentration of the radon water taken at a suitable concentration for drinking. The purpose is to provide.

  In view of the above problems, the device for preserving drinking radon water of the present invention is provided with a main body part for containing taken radon water containing a radon component, and a part of the main body part for discharging radon water for drinking. A radium ore body that can be installed inside the main body, and the radium ore body maintains drinking radon water at a predetermined radon-containing concentration.

  The drinking radon water storage container of the present invention can maintain the radon-containing concentration of radon water taken up almost semi-permanently at a concentration suitable for drinking (considered to be effective for health promotion). For this reason, it is possible to provide the user with radon water that is considered to be useful for health promotion and health maintenance and in which the radon-containing concentration is stably maintained.

  In addition, since the radon water storage container is filled with radon water containing the radon component from the beginning and then delivered to the home, there is no fear of being drunk without containing the radon component. In addition, since the radon-containing storage container can maintain the radon-containing concentration, the user can obtain the effect of the radon component whenever the user drinks the obtained radon water.

  Furthermore, since the radium ore body can be reused even if it is washed together with the case or removed from the case and washed, the cost of drinking radon water that can be provided to the home can be reduced.

  A drinking radon water storage container according to the first invention of the present invention is provided in a main body part for containing drinking radon water containing a radon component and a part of the main body part, and discharges radon water for drinking. The radium ore body is provided with a water outlet and a case that houses a radium ore body that can be installed inside the main body. The radium ore body maintains drinking radon water at a predetermined radon-containing concentration.

  With this configuration, the radon component contained at the time of water intake can be maintained at a predetermined radon-containing concentration semi-permanently (at least until the stored radon water is used up). As a result, when using the drinking radon water accommodated by the user, it is possible to provide a radon-containing concentration that can be surely expected to have potable effects.

  In the drinking radon water storage container according to the second aspect of the present invention, in addition to the first aspect, the water outlet is located at the upper part of the main body.

  With this configuration, the drinking radon water storage container can be used in various aspects.

  In the drinking radon water storage container according to the third invention of the present invention, in addition to any of the first and second inventions, the drinking radon water storage container further includes a lid for opening and closing the water outlet, and the case is attached to the inside of the main body of the lid It is done.

  With this configuration, the radium ore body can be charged into the main body simply by closing the lid. Furthermore, since only the case can be replaced, the radium ore body can be easily reused.

  In the drinking radon water storage container according to the fourth invention of the present invention, in addition to any of the first to third inventions, the case can contact the radium ore body and the drinking radon water contained in the main body. It has a through hole.

  With this configuration, the radium ore body can efficiently radiate radium radiation to drinking radon water.

  In the drinking radon water storage container according to the fifth invention of the present invention, in addition to any of the first to fourth inventions, at least a part of the case can be attached to and removed from the lid. .

  With this configuration, the case is handled integrally with the lid, and the radium ore body is accommodated inside the main body portion only by sealing the lid to the main body portion, and drinking radon water contained in the main body portion. Can emit radium radiation.

  In the drinking radon water storage container according to the sixth aspect of the present invention, in addition to any one of the first to fifth aspects, the main body has a deformable flexibility.

  With this configuration, when the drinking radon water storage container is used in a water server or a water dispenser, the stored radon water does not come into contact with air, so that hygiene is improved.

  In the drinking radon water storage container according to the seventh invention of the present invention, in addition to any of the first to sixth inventions, the radium ore body is at least in a state of being housed in a case and a state of being taken out of the case. Washable in one state.

  With this configuration, only expensive radium ore bodies can be reused. As a result, the cost for providing drinking radon water using a drinking radon water storage container can be reduced.

  In the drinking radon water storage container according to the eighth aspect of the present invention, in addition to any one of the first to seventh aspects, the radium ore body includes one or more ceramics containing less than 50% by weight of radium ore. It is a ball.

  This configuration facilitates handling of the radium ore body.

  In the drinking radon water storage container according to the ninth invention of the present invention, in addition to the eighth invention, the case has a diameter of about 3 mm with a total amount of about 55 g (grams) with respect to 20 liters of radon water. Contains a ceramic ball.

  In the drinking radon water storage container according to the tenth invention of the present invention, in addition to any one of the first to ninth inventions, the radium ore body contains the stored drinking radon water from 0.3 mache to 2. Maintain a radon-containing concentration of 7 Mache.

  With these configurations, it is possible to provide drinking radon water that does not have any drinking problems.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  In addition, the radon water in this specification means the water or hot water containing the radon component which is a radiation component by a radium ore body. The drinking radon water means a radon water that can be drunk, and may be used not only for drinking but also for cooking and cooking.

(Embodiment 1)
First, the overall outline of a drinking radon water storage container will be described with reference to FIG. 1 (overall outline)
FIG. 1 is a perspective view of a drinking radon water storage container according to Embodiment 1 of the present invention.

  The drinking radon water storage container 1 includes a main body 3 that contains drinking radon water 2, a water outlet 4 that is provided in a part of the main body 3 and discharges the radon water 2, and a lid 5 that opens and closes the water outlet 4. And a case 6 that is provided inside the main body 3 of the lid 5 and that stores the radium ore body 7.

  The drinking radon water 2 is drinkable drinking water containing radium, for example, taken from a hot spring source or obtained by applying radium radiation to natural water or tap water. This drinking radon water 2 has a predetermined radon-containing concentration at the time of water intake.

  The main body 3 accommodates the taken radon water taken in. The main body 3 has a predetermined shape and size, and the shape and size are determined depending on the application. For example, when the drinking radon water storage container 1 is used for a water server or a water dispenser, it has a size of several tens of liters. Alternatively, when the drinking radon water storage container 1 is used as it is for drinking in a home or office, it has a size of several liters. For example, the main body 3 may be a plastic bottle of several liters.

  The main body 3 has a spout 4 for discharging the drinking radon water 2 accommodated therein. The water discharge port 4 may be used for a user to pour it into a cup or the like when drinking, or when the drinking radon water storage container 1 is used for a water server or a water dispenser, as a connection port to a water supply pipe. May be used. The water outlet 4 is covered with a lid 5, and the water outlet 4 is also opened and closed by opening and closing the lid 5.

  The main body 3 side of the lid 5 includes a case 6. When the lid 5 is attached to the water outlet 4, the lid 5 has an outer side and an inner side of the main body 3. The case 6 is attached to this inner side. By attaching the case 6 to the inside of the main body 3, the radium radiation from the radium ore body 7 accommodated in the case 6 is emitted to the drinking radon water accommodated in the main body 3. Become. The case 6 may be fixed to the lid 5 or may be removable.

  Case 6 stores radium ore body 7. The radium ore body 7 emits radium radiation based on its characteristics. Since the case 6 is provided on the inner side of the main body 3 of the lid 5 as described above, the radium ore body 7 radiates radium radiation to the drinking radon water 2 inside the main body 3. Radium radiation contains radon in water. The taken radon water 2 that has been taken up has the characteristic that the radon-containing concentration decreases over time. If the radon-containing concentration is reduced as it is, the taken radon water 2 that has been taken in becomes ordinary mineral water that has lost the radon-containing concentration.

  The drinking radon water storage container 1 can emit radiation radon water 2 containing radium radiation from the radium ore body 7 housed in the case 6. As a result, the drinking radon water 2 accommodated in the drinking radon water storage container 1 can maintain the radon-containing concentration semipermanently. In particular, by storing the radium ore body 7 having a predetermined amount, the radon-containing concentration of the stored radon water 2 can be maintained at a predetermined concentration.

  As described above, the drinking radon water storage container 1 can maintain the drinking radon water 2 taken and stored at a predetermined radon-containing concentration semi-permanently (excluding cases based on other external or internal factors). . As a result, the consumer who purchased the drinking radon water storage container 1 containing the drinking radon water 2 can drink the drinking radon water 2 suitable for health promotion and drinking over a long period of time.

  Next, details of each part will be described.

(Main body)
The main body 3 is a main part of a container for storing the drinking radon water 2.

  The main body 3 is formed of resin, vinyl, metal, PET, PEN, plastic, or the like, and has a predetermined shape or a predetermined size. The main body 3 may be used by a user to pour drinking radon water 2 contained in a cup or the like as it is, or may be used by being attached to a water server or a water dispenser.

  The main body 3 may have a plastic bottle shape as shown in FIG. 2 when used by a user as it is poured into a cup or the like. FIG. 2 is a perspective view of a drinking radon water storage container having a plastic bottle shape according to Embodiment 1 of the present invention.

  Since the main body 3 has a plastic bottle shape, for example, the main body 2 shown in FIG. 2 has a size of about 1.5 liters or 2 liters to about 10 liters. Further, as is clear from FIG. 2, the water outlet 4 of the main body 3 is provided with a lid 5. The lid 5 is used to open and close the water outlet 4 of the plastic bottle-shaped main body 3 and may be opened and closed in a rotary manner. Or you may open and close by one opening.

  The lid 5 includes a case 6 for housing the radium ore body 7. The radium ore body 7 radiates radium radiation to the drinking radon water 2 accommodated in the main body 3 having a plastic bottle shape. As a result, the radon-containing concentration of the drinking radon water 2 is maintained.

  Moreover, when the main-body part 3 is a plastic bottle shape, in the state which accommodated drinking radon water 2, it may be sold or distributed as drinking water containing a plastic bottle, and may be delivered to each household. In this case, since the plastic bottle is small, when the user has finished drinking the radon water 2, it may be discarded as it is. Of course, for the reuse of the radium ore body 7 described later, a drinking radon water storage container in the form of a plastic bottle may be collected.

  Moreover, the main-body part 3 has a magnitude | size of several tens of liters, as FIG. 1 shows, and may be used by attaching to a water server or a water supply machine. In this case, the main body portion 3 may have a solid shape, or may have a flexible flexibility as shown in FIG. When formed of resin or PET, the main body 3 can have flexibility. In this case, the main body 3 is attached to a water server or a water dispenser, and the drinking radon water 2 accommodated in the main body 3 is supplied through the water supply means. FIG. 3 is a schematic diagram of the main body according to the first embodiment of the present invention.

  Here, when the main-body part 3 has a solid shape which does not deform | transform, the drinking radon water storage container 1 is used suitably for the water server and water supply machine which supply water by the natural flow from a water container. Particularly in this case, the drinking radon water container 1 is attached to the upper side of the water server or the water supply device. This is to make natural flow easier to use.

  Moreover, when the main-body part 3 has a deformable softness | flexibility as FIG. 3 shows, it uses suitably for the water server and water supply machine which supply water by suction | inhalation, such as a pump. Since the main body 3 has a deformable flexibility, the main body 3 swells when the drinking radon water 2 is filled, and the main body 3 as the drinking radon water 2 is sucked from the main body 3. Contracts. When all of the drinking radon water 2 contained in the main body 3 is sucked, the main body 3 is completely contracted and folded. In this way, when the main body 3 is flexible enough to be deformed, it is not necessary to feed air into the main body 3 in the supply of the drinking radon water 2 accommodated in the main body 3, so the drinking radon water 2 is sanitary. There is merit to be kept. This is because the drinking radon water 2 accommodated in the main body 3 does not touch the air in the main body 3.

  Anyway, the main-body part 3 accommodates the drinking radon water 2, and forms the form which can be provided to a home or an office.

  In addition, even when the main-body part 3 has a shape used for a water server or a water feeder instead of a plastic bottle shape, it may be discarded after use or may be collected.

  The main body 3 accommodates the drinking radon water 2 generated by the source or industrial production as described above, and forms the main part of the drinking radon water storage container 1.

(Water outlet and lid)
The main body 3 includes a water outlet 4 for discharging the drinking radon water 2 accommodated therein, and the water outlet 4 is opened and closed by a lid 5. The water discharge port 4 may be provided at any position of the main body 3, but is preferably provided at the top of the main body 3. By being provided in the upper part of the main-body part 3, the lid | cover 5 does not become obstructive at the time of storage, and it is easy to pour directly from the drinking radon water storage container 1 to a cup. Moreover, when the drinking radon water storage container 1 is installed in the upper part of a water server or a water supply machine and natural flow is used, the spout 4 can be formed by simply installing the drinking radon water storage container 1 upside down. There is an advantage of facing the machine side of the water server and water supply machine. Alternatively, when the drinking radon water storage container 1 is installed in the lower part of a water server or water dispenser and sucked with a pump or the like, the spout 4 faces upward, so the drinking radon water storage container 1 is simply installed as it is. There are good merits.

  The lid 5 opens and closes the water outlet 4. The lid 5 may be screwed into the water outlet 4 by rotation or removed from the water outlet 4, and a part of the lid 5 is attached to the main body 3 and can be opened and closed with this part as a fulcrum. May be.

  The lid 5 may be discarded after use together with the main body 3 or may be collected. Further, the lid 5 may be collected together with a case 6 described later separately from the main body 3.

(Case)
The case 6 is provided inside the main body 3 in the lid 5. The case 6 houses a radium ore body 7 that radiates radium radiation. The case 6 may be attached to the main body 3 together with the lid 5 by being attached to the lid 5.

  In order to efficiently radiate the radium radiation from the radium ore body 7 accommodated in the case 6 to the drinking radon water 2, it is also preferable that the case 6 has a through hole 10 in a part of the case. When the through-hole 10 is provided, the radon water 2 accommodated in the main body 3 and the radium ore body 7 can be brought into direct contact with each other, so that radium radiation tends to affect the drinking radon water 2. Has merit. Or there is also a merit that the radium ore body 7 can be washed together with the case 6 after the case 6 is recovered by having the through hole 10.

  Actually, the radium ore body 7 radiates radium radiation to the drinking radon water 2 through the air to promote the radon content of the drinking radon water 2, so that the drinking radon water 2 and the radium ore body 7 Does not have to be in direct contact.

  The case 6 is preferably attached to the lid 5. The case 6 only needs to contain the radium ore body 7 and the radium radiation from the radium ore body 7 may be radiated to the inside of the main body 3. Therefore, the case 6 is suitably attached to the lid 5. is there. In particular, the case 6 can be attached to the main body 3 together with the lid 5 by being handled integrally with the lid 5, and the case 6 can be detached from the main body 3 together with the lid 5. If the case 6 has an independent form separate from the lid 5, it is necessary to put the case 6 into the main body portion 3, and the removal of the case 6 from the main body portion 3 becomes troublesome.

  For example, the case 6 may be attached to the lid 5 as shown in FIG.

  FIG. 4 is an explanatory diagram for explaining attachment of the case according to the first embodiment of the present invention. FIG. 4 shows a state where the case 6 is attached to the bottom surface of the lid 5 by a protruding bar.

  The lid 5 has two projecting bars 15, and the projecting bars 15 penetrate the upper surface 12 of the case 7. The tip of the projection bar 15 is crushed after passing through the upper surface 12, and the projection bar 15 attaches the case 7 to the lid 5. At this time, the tip of the projection bar 15 may be crushed by heat welding using an electric iron or laser irradiation. When the tip is crushed, the top surface 12 may be caught and the projection bar 15 may be attached to the top surface 12. When the tip is crushed, the tip is fixed to the back surface of the top surface 12 so that the projection bar 15 is The upper surface 12 may be fixed.

  The case 6 is configured by attaching a top surface 12 and a bottom surface 14 to a cylindrical main body 13. With this structure, a case 6 that is cylindrical as a whole and can store the radium ore body 7 is formed.

  The upper surface 12 is fixed to the main body 13, and the upper surface 12 and the main body 13 constitute a basic structure of the case 6. The upper surface 12 is fixed to the bottom surface of the lid 5 by the protruding bar 15. After the protruding bar 15 penetrates the upper surface 12, the tip of the protruding bar 15 is crushed, and the protruding bar 15 fixes or hooks the upper surface 12. Since the upper surface 12 is fixed to the main body 13, up to the main body 13 is fixed and attached to the lid 5 by the protruding bar 15.

  The bottom surface 14 can be detachably attached to the main body 13 like a cap. The user or provider throws the radium ore body 7 into the main body 13 with the bottom surface 14 removed. After the radium ore body 7 is charged, the case 6 in which the radium ore body 7 is stored is configured by attaching and fixing the bottom surface 14 to the main body 13. At this time, the case 6 is fixedly attached to the bottom surface of the lid 5.

  As shown in FIG. 4, by attaching the case 6 to the bottom surface of the lid 5, the radium radiation is emitted from the radium ore body 7 inside the main body 3 simply by attaching the lid 5 to the water outlet 4 of the main body 3. It becomes radiated. That is, the radon-containing concentration of the drinking radon water 2 contained in the main body 3 is maintained. In addition, it is also preferable that the through hole 10 is provided in the main body 13 and the bottom surface 14 of the case 6 so that the radium radiation from the radium ore body 7 is efficiently radiated into the main body 3. In some cases, the through-hole 10 also serves to help the radium ore body 7 directly contact with the drinking radon water 2 accommodated in the main body 3. In addition, it is suitable for the through-hole 10 that it is a magnitude | size which is a grade which the radium ore body 7 does not escape.

  When the main body 13 and the upper surface 12 in FIG. 4 are removable, as shown in FIG. 5, the upper surface 12 and the lid 5 are first attached by the protruding rod 15, and then the case 6 is covered with the lid 5. It is also suitable to be attached to. FIG. 5 is a perspective view showing a state in which the upper surface is attached to the lid according to Embodiment 1 of the present invention.

  Further, the case 6 may be attached to the lid 5 as shown in FIG. FIG. 6 is an explanatory diagram for explaining attachment of the case according to the first embodiment of the present invention. Unlike the case of FIG. 4, a state in which the lid 5 also serves as the upper surface of the case 6 is shown.

  The case 6 has a main body 13 and a bottom surface 14 fixed in advance or integrally molded, and the upper surface is open. A radium ore body 7 is accommodated in the case 6. Further, the through hole 10 may be provided in the main body 13 and the bottom surface 12 of the case 6. This is because the radium radiation from the radium ore body 7 is efficiently emitted into the main body 3. Moreover, the through-hole 10 also has a function which helps the radium ore body 7 contact directly with the drinking radon water 2 accommodated in the main-body part 3 depending on the case. In addition, it is suitable for the through-hole 10 that it is a magnitude | size which is a grade which the radium ore body 7 does not escape.

  After the radium ore body 7 is stored in the main body 13, the case 6 is attached to the lid 5. You may attach with the screw used for a cap, and you may attach with an adhesive agent. A known means for attaching the members to each other may be used. However, the case 6 is preferably removable from the lid 5. This is because there is a merit that the radium ore body 7 inside the case 6 can be taken out and washed.

  Since the case 6 shown in FIG. 6 is also attached to the bottom surface of the lid 5, the radium ore body 7 radiates radium radiation inside the main body 3 just by attaching the lid 5 to the water outlet 4 of the main body 3. it can. Moreover, the case 6 in which the radium ore body 7 is accommodated can be removed simply by removing the lid 5, and the case 6 can be handled independently together with the lid 5.

  In either case 6 shown in FIG. 4 or case 6 shown in FIG. 6, the case 6 containing the radium ore body 7 can be handled independently by simply separating the lid 5 from the main body 3. .

  For example, after collecting the drinking radon water storage container 1 after use by the user, a provider who stores and provides the drinking radon water 2 in the drinking radon water storage container 1 provides only the case 6 while discarding the main body 3. Can be reused. The case 6 is attached to the lid 5, but can be detached from the lid 5. Since the case 6 has the through hole 10, the radium ore body 7 accommodated therein can be washed together with the case 6. Alternatively, in the case 6 shown in FIG. 4, the radium ore body 7 can be taken out by removing the bottom surface 14. Alternatively, in the case 6 shown in FIG. 6, the radium ore body 7 can be taken out by removing the lid 5. FIG. 7 shows a state in which the radium ore body 7 is put into the case 6 in the case of FIG. FIG. 7 is a perspective view of the case according to Embodiment 1 of the present invention.

  The radium ore body 7 thus taken out is washed and can be reused.

  The main body 3 is poorly balanced between hygiene problems and cost advantages for reuse, but the radium ore body 7 is very expensive and can be consumed by the drinking radon water storage container 1 when used up. The cost of providing radon water increases. This is inconvenient for both business and users. On the other hand, since the radium ore body 7 can radiate radium radiation semipermanently, it is not preferable to use it up. Since the radium ore body 7 does not have a complicated structure such as the inner surface and the outer surface like the main body portion 3, it can be easily and reliably washed.

  In this way, the case 6 can be handled independently in the drinking radon water storage container 1 so that only the radium ore body 7 or the radium ore body 7 stored in the case 6 is washed after use of the drinking radon water. Can be reused. As a result, the most expensive radium ore body 7 in the potable radon water storage container 1 can be reused, and the selling price of potable radon water stored in the potable radon water storage container 1 can be reduced.

(Radium ore body)
Next, the radium ore body 7 will be described.

  The radium ore body 7 is an ore or an ore processed product capable of emitting radium radiation. The radium ore itself, which is the raw material of the radium ore body 7, is collected from nature, but the material collected from nature may be used as a radium ore body or may be used after being processed. The radium ore body 7 may have any shape and form as long as it can emit radium radiation.

  The radium ore body 7 is also preferably a ceramic ball containing radium ore of less than 50% by weight because of easy handling. Ceramic balls are formed by mixing powdered radium ore with ceramics and clays and firing them. Ceramics and clays are also powders, and are molded into a predetermined shape when the powdered radium ore and the powdered ceramics and clays are mixed and fired.

  Note that the name of the ball is not limited to a sphere, and may include a corner, or a shape having a shape close to a cube or a rectangular parallelepiped. The ceramic ball contains less than 50% by weight of the radium ore body, so that it can radiate radium radiation and has a merit that handling is facilitated by mixing ceramic and clay powders.

  In the case 6, this ceramic ball is stored as a radium ore body 7.

  Here, the ceramic balls may be large and single, but are preferably small and plural in order to increase the radiation efficiency of the radium radiation. This is because even if the total weight is the same, the total surface area of the small ceramic balls is larger than that of the large and simple ceramic balls. Since the total surface area is large, the area for emitting radium radiation is increased, and the radiation efficiency of radium radiation is increased.

  The ceramic ball preferably has a diameter larger than that of the through hole 10 provided in the case 6. This is to prevent the case 6 from spilling. It is also effective in increasing the surface area that the ceramic balls have fine holes on the surface.

  Further, the radium ore body 7 can be reused by being taken out of the case 6 or being washed out of the case 6 and washed. However, since the radium ore body 7 is a ceramic ball, the washing becomes easy.

  The ceramic ball is housed inside the case 6 and attached to the main body 3 together with the lid 5 to radiate radium radiation toward the inside of the main body 3. By the radium radiation of the radium ore body 7 including this ceramic ball, the radon-containing concentration of drinking radon water originally having a radon-containing concentration is maintained at a predetermined concentration. At this time, since the radium ore body 7 can radiate radium radiation semipermanently, the radon-containing concentration of the drinking radon water 2 accommodated in the main body 3 is maintained semipermanently (of course usually several days) In the next few months, the stored radon water 2 is used and used, so that the radon-containing concentration is sufficiently maintained during this period of use).

  As described above, the drinking radon water storage container according to the first embodiment has a radon-containing concentration of drinking radon water containing the radon component taken in semi-permanently (at least until the contained radon water is used up). During the period) can be maintained at a predetermined radon-containing concentration. Furthermore, the radium ore body 7 is housed in the case 6 that can be integrated with the lid 5, so that the radon-containing concentration of the drinking radon water accommodated by simply attaching the lid 5 to the main body 3 can be maintained. In addition, the radium ore body 7 can be reused by being washed, and can greatly reduce the cost when selling and drinking potable radon water storage containers. As a result, potable radon water, which is considered to be effective for health promotion, can be provided at low cost.

  The drinking radon water storage container 1 may be a large container attached to a water server or a water dispenser, may be a plastic bottle type container of several liters size, a refrigerator at home or office, etc. It may be a medium-sized container that can be stored in, and variations suitable for various applications can be prepared.

  Next, examples performed by the inventors will be described.

  The inventor constructed a drinking radon water storage container by storing a plurality of ceramic balls having a diameter of approximately 3 mm in a total amount of 55 g with respect to 20 liters of drinking radon water contained therein.

  This potable radon water storage container was left on the transport vehicle for about two weeks while containing potable radon water. This is because when drinking radon water is packed in a drinking radon water storage container and sold, there is a possibility that transportation or leaving for about two weeks may occur.

  When the radon-containing concentration of the drinking radon water after being allowed to stand was examined, the radon-containing concentration was 0.44 mache. Here, “Mache” is a unit generally used as a reference for radon-containing concentration.

  Radon water of 5.5 mache or higher can be displayed as radon hot spring water. However, it is known that when radon water of 5.5 mache or more is drunk, the radon-containing concentration is too high and diarrhea is likely to occur. Considering this, 0.44 Mache's radon water has a radon-containing concentration of 1/10 or less of the radon hot spring water standard, so it is considered that there is almost no adverse effect on drinking. In addition, a radon-containing concentration of 0.44 Mache is expected to be effective for drinking.

  Of course, the radon-containing concentration that can be maintained can be adjusted by adjusting the balance between the amount of radon water for drinking and the amount of radium ore body. However, it is preferred that the radium ore body can maintain the contained drinking radon water at about 0.3 to 2.7 Mache.

  Thus, from the examples actually prepared, the radon-containing concentration of drinking radon water left over a period of 2 weeks is a concentration suitable for drinking (concentration with which there is no adverse effect and the effect on drinking can be felt). It can be seen that In conventional technology, when radon water containing radon is stored, the radon content is reduced and disappears, or even if radium ore bodies are added to natural water, it takes a considerable time to obtain the radon content. In both cases, it is impossible to obtain an appropriate concentration of radon at the time of drinking. On the other hand, as is clear from the examples, the drinking radon water storage container in the first embodiment can reliably provide a radon-containing concentration suitable for drinking when the user drinks.

(Embodiment 2)
Next, a second embodiment will be described. In the second embodiment, a case where the drinking radon water storage container described in the first embodiment is applied to a water server or a water dispenser will be described.

  First, the water feeder which supplies drinking radon water by the natural flow from a drinking radon water storage container is demonstrated using FIG. FIG. 8 is a schematic diagram of a water feeder according to Embodiment 2 of the present invention.

  The water supply device 21 is provided with a tank storage case 30 at the uppermost part of the water supply device 21, and the tank storage case 30 has a drinking radon water storage container 1 detachably installed therein. The bottom portion of the drinking radon water storage container 1 is detachably connected to a water conduit 30 extending from the top of the storage tank 23, and a heating tank 24 and a cooling tank 25 are connected to the water storage tank 23. The drinking radon water storage container 1 contains drinking radon water, and the radon content of the drinking radon water is kept at a predetermined concentration by the radium ore body stored in the case attached to the drinking radon water storage container 1. .

  The drinking radon water storage container 1 may be formed in a shape that can be reduced and deformed along with the decrease in water accompanying the natural flow of the stored drinking radon water, or while taking air from the outside into the drinking radon water storage container 1 It may be formed in a solid shape that naturally flows down. The shape that can be reduced and deformed with the reduction of the water accompanying the naturally flowing water is realized, for example, by the drinking radon water storage container 1 being a bellows.

  The storage tank 23 temporarily stores drinking radon water taken out from the drinking radon water storage container 1 by natural flow or suction as described later. Further, a pair of magnets 51 are attached to the outer periphery of the storage tank 23 so as to face each other, and water molecules (clusters) are activated by passing water through the magnetic field generated by the magnets 51 to prevent water from decaying. It is designed to prevent the propagation of germs. Further, inside the storage tank 23, a filter 52 for water purification antibacterial is provided at the inlet of the heating tank 24 and the cooling tank 25.

  The heating tank 24 is inserted with a pipe 60 extending downward from the bottom of the storage tank 23. This pipe 60 sends drinking radon water from the storage tank 23 to the heating tank 24. Further, a hot water supply unit 62 for supplying heated hot water from the heating tank 24 is provided. Here, a heating band 63 is wound around the outer periphery of the heating tank 24, and the drinking radon water stored in the heating tank 24 is heated by the heating band 63 to become hot water. It is preferable that a sensor or a heater control device for adjusting the temperature adjustment of hot water is provided.

  Similar to the heating tank 24, the cooling tank 25 is inserted with a pipe 70 extending downward from the bottom of the storage tank 23. This pipe 70 sends drinking radon water from the storage tank 23 to the cooling tank 25. Further, a supply unit 72 for supplying cooled cold water from the cooling tank 25 is provided. A compressor 74 and a condenser 75 are connected to the cooling tank 25 to cool drinking radon water inside. Further, a sensor, a refrigeration cycle control device, or the like for adjusting the temperature adjustment of the cold water may be provided.

  As described above, the drinking radon water storage container 1 is attached to the water supply device 21, so that the heated radon water and the cooled drinking radon water are converted into home and office by natural flow from the drinking radon water storage container 1. Can be easily provided.

  In addition, as described in Embodiment 1, the drinking radon water storage container 1 can maintain the radon-containing concentration of the drinking radon water accommodated for a long period of time, so that the hot water obtained from the water supply machine shown in FIG. Or cold water is potable radon water that is potable. In particular, since the radon component is contained in the steam when hot water is supplied, various effects can be expected.

  Next, the water feeder supplied with a suction means is demonstrated using FIG.

  FIG. 9 is a schematic diagram of a water feeder according to Embodiment 2 of the present invention. The water supply machine in FIG. 9 is different from the water supply machine shown in FIG. 8 in that a drinking radon water storage container 1 is installed at the bottom of the water supply machine, and drinking radon water is supplied from the drinking radon water storage container 1 by suction means such as a pump. Supplied.

  The water supply device 100 is provided with a tank storage case 107 at the bottom of the water supply device 100, and the tank storage case 107 is detachably installed with the drinking radon water storage container 1 therein. The drinking radon water storage container 1 has a deformable flexibility that contracts in accordance with a decrease in the drinking radon water contained therein. For this reason, as a material for the drinking radon water storage container 1, a flexible film (polypropylene film, polyethylene laminate film, etc.) is used, and a material that does not harm the human body (for example, elution of environmental hormones). Is used.

  The drinking radon water storage container 1 is connected to suction means 160 for sucking up the stored water. The suction means 160 may be any type of pump. A storage tank 102 for temporarily storing the sucked drinking radon water is installed on the upper portion of the water feeder 100. The storage tank 102 includes a sensor 120 (float sensor). When the water level of the storage tank 102 falls below a certain level, the sensor 120 sends the information to the suction means 160, and the suction means 160 is activated to suck up the drinking radon water from the drinking radon water storage container 1 to a predetermined water level. Since the drinking radon water storage container 1 has the flexibility to contract as the water decreases, it is not necessary to take air into the drinking radon water storage container 1 from the outside when sucking from the suction means 160. For this reason, in the drinking radon water storage container 1, the drinking radon water is not exposed to air, and the drinking radon water is kept hygienic.

  In addition, a pair of magnets 121 are attached to the outer periphery of the storage tank 102 so as to face each other. The magnets 121 activate water molecules (clusters) by passing a magnetic field through drinking radon water, Prevent corrosion and suppress the growth of germs. An air hole 122 fitted with an antibacterial filter 123 may be formed at the upper end of the storage tank 102. Or you may provide the air pipe which supplies not the air hole 122 but the heat | fever sterilized or filter-sterilized air to the storage tank 102. FIG.

  The storage tank 102 cools the drinking radon water stored by the compressor 144 and the condenser 145. The cooled drinking radon water is supplied from the cold water supply unit 142. That is, in the water feeder of FIG. 9, the storage tank 102 also has a cooling tank. Here, an ultraviolet lamp 124 for sterilization may be provided inside the storage tank 102 to sterilize drinking radon water inside. The sterilizing ultraviolet lamp 124 may always be a point or the like, or may be lit only for a predetermined period.

  A heating tank 131 to which potable radon water is supplied via a conduit 130 is provided at the lower part of the storage tank 102. A heating band 133 is attached to the outer periphery of the heating tank 131, and drinking radon water stored therein is heated to warm water. A sensor for adjusting the temperature of hot water and a heater control device may be provided. A hot water supply unit 132 that supplies hot water is connected to the heating tank 131, and hot water is supplied from the hot water supply unit 132 by water pressure.

  As described above, the water supply device 100 shown in FIG. 9 sucks drinking radon water from a drinking radon water storage container having a deformable flexibility that can be contracted by suction means such as a pump, and then drinks it as cold water and hot water. Radon water can be supplied. The drinking radon water storage container 1 stores drinking radon water, and the radon content of the drinking radon water is kept at a predetermined concentration by the radium ore body stored in the case attached to the drinking radon water storage container 1. Be drunk. Therefore, drinking radon water supplied as cold water and hot water maintains a radon-containing concentration considered to be effective for drinking until the radon water stored in the drinking radon water storage container 1 is used up. it can.

  In addition, the water supply apparatus 100 shown in FIG. 9 may be provided with a heating tank and a cooling tank separately from the storage tank, similarly to the water supply apparatus 21. Since the drinking water radon water storage container 1 has the deformation | transformation flexibility which shrinks, the water supply machine 100 shown by FIG. 9 does not enter air inside the drinking radon water storage container 1, and is hygienic rather than the case of FIG. There are merit in terms.

  As described in the second embodiment, the drinking radon water storage container 1 is suitably used for a water supply device using natural flow or a water supply device using suction. As a result, it is possible to easily provide drinking radon water maintained at an appropriate radon-containing concentration at home or office. Further, by being used in a water supply machine, the provider can provide drinking radon water to many users simply by delivering and collecting the drinking radon water storage container 1 filled with drinking radon water. In this delivery and storage, the radon-containing concentration of the drinking radon water can be maintained even if time passes, so that the provider and the user can drink the drinking radon water with peace of mind. Moreover, since the provider can collect the drinking radon water storage container 1 and reuse the radium ore body, the provision price of the drinking radon water storage container filled with drinking radon water can be reduced.

  In addition, in Embodiment 2, although the water supply apparatus provided with both the cooling tank (and its supply system) which supplies cold water and the heating tank (and its supply system) which supplies warm water was demonstrated, a cooling tank and a heating tank Even if it is a water supply machine provided only with either of these, it is contained in this invention.

  In addition, in the water feeder in Embodiment 2, a sterilization filter, heat sterilization, a sterilization ultraviolet lamp, a filter for water purification, a disinfectant, a purification agent, an antibacterial agent, an ozone generator, etc. are stored in a storage tank, a heating tank, a cooling tank. It is also possible to ensure the sanitary aspect of drinking radon water by installing it in the water supply system.

  The drinking radon water storage container and the drinking radon water dispenser described in the first and second embodiments are examples for explaining the gist of the present invention, and modifications and modifications within the scope of the present invention are not permitted. Including.

It is a perspective view of the drinking radon water storage container in Embodiment 1 of the present invention. It is a perspective view of the drinking radon water storage container which has a plastic bottle shape in Embodiment 1 of this invention. It is a schematic diagram of the main-body part in Embodiment 1 of this invention. It is explanatory drawing explaining the attachment of the case in Embodiment 1 of this invention. It is a perspective view which shows a mode that an upper surface is attached to the lid | cover in Embodiment 1 of this invention. It is explanatory drawing explaining the attachment of the case in Embodiment 1 of this invention. It is a perspective view of the case in Embodiment 1 of this invention. It is a schematic diagram of the water supply machine in Embodiment 2 of this invention. It is a schematic diagram of the water supply machine in Embodiment 2 of this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Drinking radon water storage container 2 Drinking radon water 3 Main body part 4 Water outlet 5 Lid 6 Case 7 Radium ore body 10 Through-hole 12 Upper surface 13 Main body 14 Bottom surface 15 Protrusion stick

Claims (12)

A body portion for containing ingested drinking radon water containing a radon component;
A spout provided in a part of the main body, for discharging the drinking radon water;
A case for storing a radium ore body that can be installed inside the main body, and
The radium ore body is a drinking radon water storage container that maintains the drinking radon water at a predetermined radon-containing concentration.   The drinking radon water storage container according to claim 1, wherein the water outlet is located at an upper part of the main body. A lid that opens and closes the spout;
The drinking radon water container according to claim 1, wherein the case is attached to the inside of the main body of the lid.   The drinking radon water storage container according to any one of claims 1 to 3, wherein the case has a through-hole through which the radium ore body and the drinking radon water contained in the main body can come into contact.   The drinking radon water storage container according to any one of claims 1 to 4, wherein at least a part of the case is attachable to and detachable from the lid.   The said main-body part is a drinking radon water storage container in any one of Claim 1 to 5 which has a flexible flexibility.   The drinking radon water storage container according to any one of claims 1 to 6, wherein the radium ore body can be washed in at least one of a state housed in the case and a state taken out from the case.   The drinking radon water storage container according to any one of claims 1 to 7, wherein the radium ore body is one or more ceramic balls containing less than 50% by weight of radium ore.   The drinking radon water storage container according to claim 8, wherein the case contains the ceramic balls having a diameter of about 3 mm and a total amount of about 55 g (grams) with respect to 20 liters of the drinking radon water.   The radon water storage container according to any one of claims 1 to 9, wherein the radium ore body maintains the contained radon water contained therein at a radon-containing concentration of 0.3 to 2.7 mache. A drinking radon water storage container according to any one of claims 1 to 10,
A storage tank for temporarily storing drinking radon water removed from the drinking radon water storage container;
Transport means for transporting the drinking radon water contained in the drinking radon water storage container to the storage tank by at least one of natural flow and suction;
A drinking radon water feeder comprising: supply means for supplying drinking radon water from the storage tank. The storage tank is
A cooling tank for cooling potable radon water sucked by the suction means;
A heating tank for heating drinking radon water sucked by the suction means,
The supply means includes
A cold water supply unit for supplying cold water from the cooling tank;
A drinking radon water dispenser according to claim 11, further comprising a hot water supply unit that supplies hot water from the heating tank.

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