KR20070044565A - Functional water, method, and apparatus for manufacturing the same - Google Patents

Abstract

The functional water (beverage water) of the present invention has an oxygen dissolved amount of 25 to 70 mg / l immediately after treatment in which oxygen is dissolved, and an oxygen dissolved amount of 24 mg or more after 24 hours in the state of being left in the air. It is. In addition, the functional water (beverage water) is a beverage after the addition treatment after adding components such as vitamins, minerals and amino acids to the beverage raw water treated with the purification treatment mechanism 11 by the addition treatment mechanism 15. It is produced by dissolving oxygen in the raw water with the oxygen dissolving treatment mechanism 20 to produce a beverage, and then filling the beverage into the container capable of being transported by the filling treatment mechanism 16 and then sealing.

Description

Functional water, its manufacturing method and manufacturing apparatus {FUNCTIONAL WATER, METHOD, AND APPARATUS FOR MANUFACTURING THE SAME}

BRIEF DESCRIPTION OF THE DRAWINGS The block diagram which shows schematic structure of the beverage manufacturing apparatus which manufactures the beverage as functional water which concerns on one Embodiment of this invention.

2 is a cross-sectional view showing a schematic configuration of an oxygen dissolution treatment mechanism according to the present embodiment.

3 is a cross-sectional view of the arrow A-A direction in FIG. 2.

4 is a cross-sectional view of the arrow B-B direction in FIG. 2.

FIG. 5 is a cross-sectional view of the arrow C-C direction in FIG. 2. FIG.

6 is an explanatory diagram for explaining the flow of water in this embodiment.

7 is a cross-sectional view showing a schematic configuration of an oxygen dissolution processing mechanism according to another embodiment of the present invention.

FIG. 8 is a cross-sectional view of the arrow D-D direction in FIG. 7. FIG.

9 is an explanatory diagram for explaining the flow of water in another embodiment of the present invention.

10 is a plan view showing a schematic configuration of a second defrosting plate according to another embodiment of the present invention.

11 is a cross-sectional view showing a schematic configuration of a second defrosting plate according to another embodiment of the present invention.

12 is a cross-sectional view showing a schematic configuration of a defrosting member and the like according to another embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

DESCRIPTION OF SYMBOLS 1: Drinking water manufacturing apparatus 11: Purification processing apparatus

12: first filter processor 13: second filter processor

14 reverse osmosis treatment unit 15 addition treatment mechanism

20: oxygen dissolution treatment mechanism 21: container body

22: oxygen supply unit 23: water supply unit

29 exhaust pipe 30 attachment member

The present invention relates to a functional water in which oxygen is dissolved at a high concentration, a method for producing the same, and an apparatus for producing the same.

In recent years, various types of functional water in which oxygen is dissolved at high concentration have been proposed, and one of them has a beverage. Oxygen can be ingested from the lungs by inhaling it, and it is also possible to drink such beverages from the stomach or intestine.If oxygen is ingested, oxygen promotes the decomposition of alcohol contained in alcohol to prevent hangovers and is included in cigarette smoke. It has been found that the carbon monoxide prevents the oxygen supply ability to each part of the body from being lowered, increases metabolism, promotes the discharge of waste products, and promotes the decomposition of lactic acid produced during exercise, thereby preventing fatigue. .

As the beverage, for example, it is known to be disclosed in Japanese Patent Application Laid-Open No. 2001-292748. The beverage is dissolved in oxygen in the water after adjusting to a predetermined salt concentration with deep sea water in the deep sea. The oxygen dissolved amount is increased from 6 to 8 mg / l to 25 to 30 mg / l, and water obtained after the above oxygen dissolution treatment is filled into a bottle and sealed. As described above, since the oxygen dissolved amount is high and the deep ocean water contains various natural mineral components, the value of the product as a beverage for the purpose of improving health is high.

In addition, as a method of dissolving oxygen in water (beverage water), for example, as disclosed in a beverage according to Japanese Patent Application Laid-Open No. 10-314561, air or oxygen gas generated by an oxygen generating device By passing the into water, oxygen can be dissolved in the water.

However, in the conventional beverage, when the bottle is opened, the beverage in the bottle touches the air, and dissolved oxygen is released into the air, so that the amount of oxygen dissolved decreases with the passage of time, and in a short time, the same as before the oxygen dissolution treatment. The level is lowered.

For this reason, when the bottle is opened, all of the beverages in the bottle must be drunk at once or left after drinking, and even after drinking a certain amount of time, the dissolved oxygen content is lowered. Difficult to get, when you want to drink it was impossible to drink as much as you want to drink.

Thus, even if the functional water represented by the said drinking water etc. is large in the amount of oxygen dissolved immediately after oxygen dissolution treatment, when it is left in air | atmosphere, there exists a problem that oxygen dissolved amount will fall to the level equivalent to before oxygen dissolution treatment with time.

SUMMARY OF THE INVENTION The present invention has been made in view of the above circumstances, and an object thereof is to provide a functional water having a large amount of oxygen dissolved immediately after oxygen dissolution treatment and which does not decrease even when left in the air, and a method and a production apparatus thereof. .

The present invention for achieving the above object,

A functional water obtained by dissolving oxygen of more than the natural dissolution concentration in raw water, the oxygen dissolved amount immediately after the oxygen dissolved treatment is 25 to 70 mg / l, the oxygen dissolved after 24 hours in the state left in the air after that The amount of water is maintained at 15 mg / l or more.

In addition, this functional water may contain at least 1 sort (s) of a vitamin, a mineral, an amino acid, or a drug, and may be filled and sealed in the container which can be carried.

According to such a functional water, the oxygen dissolved amount immediately after the treatment which dissolved oxygen is 25-70 mg / l, and it is 15 mg of oxygen dissolved amount, when the elapsed time is within 24 hours even if it is left in the air and contacts with air. Since it is maintained in many states of / l or more, for example, when used as a beverage, the oxygen dissolved amount is maintained in a high state even after opening the transportable container filled and sealed, and you want to drink the beverage (functional water). You can drink as much as you want to drink at any time, and at any time, you can take in enough oxygen to achieve the same effect. This facilitates handling of the beverage. Moreover, the oxygen dissolved amount after more preferable 24 hours passes is 35 mg / l or more.

In addition, this functional water can be used for raw materials of medicines and cosmetics, in addition to beverages, and when used in eye drops, face-washes, and lotions, for example, oxygen is absorbed from the surface of the eyes and skin, and metabolism of this part is carried out. The effect of promoting is also obtained. In addition, the application use of the said functional water showed an example, It is not limited to these.

Thus, according to the functional water which concerns on this invention, since the dissolved oxygen amount does not fall even if it is left to stand in air | atmosphere, the commodity value of the said functional water can be made higher. In addition, by including at least one of vitamins, minerals, amino acids or drugs, the product value of the functional water can be further increased.

And this functional water can be manufactured suitably using the following manufacturing methods. That is, this manufacturing method supplies oxygen gas pressurized to the sealed container body, makes the inside of the sealed container body into the oxygen gas atmosphere of atmospheric pressure or more, discharges raw water into the sealed container body, and seals the discharged raw water into the sealed container body. By flowing down in a film form in a container body, oxygen gas and gas-liquid contact are made | generated, and the functional water which melt | dissolved 25-70 mg / l oxygen was produced, and the produced | generated functional water is then filled in the said airtight container body. It was pulled out of the

According to this manufacturing method, the oxygen dissolved amount of the raw water is caused by flowing the raw water into a membrane shape and contacting it with oxygen gas on both sides of the water film, inside the sealed container body in which the oxygen gas pressure is increased above atmospheric pressure. The oxygen dissolved amount is 15 mg / l or more, more preferably 35 even when 24 hours have elapsed from the previous 6 to 8 mg / l to 25 to 70 mg / l, resulting in a high oxygen concentration and being left in the air. Functional water maintained at or above mg / l is generated. This is because when a water molecule and an oxygen molecule come into contact with each other under a high-pressure oxygen gas atmosphere, some of them are ionized to form a state in which the water molecule and the oxygen molecule are bound by an ionic bond, and oxygen is dissolved in raw water. It is thought that functional water is produced which has a high oxygen concentration and does not lower the oxygen dissolved amount. The generated functional water is withdrawn from the sealed container body.

In the above production method, the raw water is purified by reverse osmosis treatment, and the purified raw water is supplied into the sealed container, and at least one of vitamins, minerals, amino acids or drugs is supplied to the raw water. After the addition, the raw water after the addition treatment is supplied into the sealed container, or at least one of vitamins, minerals, amino acids or drugs is added to the purified water, and then the raw water after the addition treatment is used for the sealing. Preferably, at least one of vitamins, minerals, amino acids, or drugs is added to the functional water extracted from the sealed container body or supplied into the gas. Groups that are sealed after being filled in transportable containers or which have at least one of vitamins, minerals, amino acids or drugs added The hard water may be sealed after being filled into the transportable container.

And this manufacturing method can implement this suitably with the following manufacturing apparatuses.

That is, this manufacturing apparatus is an oxygen dissolution treatment mechanism part which melt | dissolves oxygen more than natural dissolution concentration in raw water, and produces | generates a functional water, and the filling process which fills and seals the functional water produced | generated by the said oxygen dissolution treatment mechanism part after filling in a container which can be carried The oxygen dissolution treatment mechanism part includes a sealed container body and a supply pipe connected to the sealed container body, supplies oxygen gas into the closed container body through the supply pipe, and provides the sealed container body. An oxygen supply means having an inside of an oxygen gas atmosphere at atmospheric pressure or higher, and a first water supply pipe having one end connected to the sealed container body in an up-down direction in the sealed container body and having a discharge port formed at an upper end thereof; Water supply water for discharging the raw water from the discharge port of the first water supply pipe toward the ceiling of the sealed container body And a second water supply pipe connected to the sealed container body to supply the functional water stored in the bottom of the sealed container body to the outside, and a first defrosting projecting inwardly from an inner surface of the sealed container body. ) And / or a plate-shaped second defrosting member protruding outward from an outer peripheral surface of one end of the first water supply pipe, discharging the raw water from the discharge port toward the ceiling of the sealed container body, Raw water discharged from the discharge port and flowing through the inner surface of the sealed container body and / or the outer circumferential surface of the first water supply pipe is formed from the protruding end of the first and / or second regulating member. The gas is brought into contact with the raw water and the oxygen gas in the hermetically sealed container body so as to generate the functional water. The lid mechanism part is configured to seal the functional water supplied from the second water supply pipe of the oxygen dissolution treatment mechanism part after being filled into the transferable container.

According to this manufacturing apparatus, first, functional water is produced | generated from raw water in an oxygen dissolution processing mechanism part. Specifically, after oxygen gas is supplied into the hermetically sealed container body by the oxygen supply means through the supply pipe, and the inside of the hermetically sealed container body is an oxygen gas atmosphere at or above atmospheric pressure, the raw water ( Water before oxygen dissolution) is supplied, and the supplied raw water is discharged through the first water supply pipe and then discharged from the discharge port into the sealed container body.

The discharged raw water is spouted in a fountain shape (radially around the discharge port) toward the ceiling direction and impinges on the inner surface of the hermetically sealed container such as the ceiling surface or the inner circumferential surface, and flows along the inner surface or springs up to the sealed container body. The raw water falling in the inner space of the gas or flowing along the outer circumferential surface of the first water supply pipe, and then flowing along the inner surface of the sealed container body or the outer circumferential surface of the first water supply pipe, the flow is respectively controlled by each defrosting member. Each of the defrosting members flows from the protruding end into a thin film and falls in the inner space of the closed container body.

The raw water flowing in the sealed container body is stored at the bottom of the sealed container body, and oxygen in contact with the raw water is dissolved in the flow process in the oxygen gas atmosphere. Thereby, the oxygen dissolved amount of the said raw water increases from 6-8 mg / l before the said process to 25-70 mg / l, becomes high oxygen concentration, and even if 24 hours pass in the state left to stand in air | atmosphere, oxygen dissolved Functional water in which the amount is maintained at 15 mg / l or more, more preferably 35 mg / l or more is produced.

The functional water stored in the sealed container body (water after oxygen dissolution) is supplied from the second water supply pipe to the outside of the sealed container body by the oxygen gas pressure inside the sealed container body, and the supplied functional water is supplied by the filling processing mechanism part. Sealed after filling in the transportable container. In this way, the functional water which is filled and sealed in the portable container is manufactured.

The manufacturing apparatus further includes a reverse osmosis treatment mechanism portion for purifying the raw water, and the water supply means of the oxygen dissolution treatment mechanism portion supplies raw water purified by the reverse osmosis treatment mechanism portion from a discharge port of the first water supply pipe. It is preferable that it is comprised so that it may discharge. Moreover, the said manufacturing apparatus further includes the addition processing mechanism part which adds at least 1 sort (s) of a vitamin, a mineral, an amino acid, or a drug to the said raw water, and supplies the water of the said oxygen dissolution processing mechanism part. The means is configured to discharge raw water processed by the addition processing mechanism unit from a discharge port of the first water supply pipe, or the manufacturing apparatus includes at least one of vitamins, minerals, amino acids, and drugs in the reverse osmosis treatment mechanism unit. It further comprises an addition processing mechanism portion for adding to the purified water by the water supply means, wherein the water supply means The raw water processed by the processing mechanism unit is configured to discharge from the discharge port of the first water supply pipe, or the manufacturing apparatus includes at least one of vitamins, minerals, amino acids, and drugs in the second water supply pipe of the oxygen dissolution processing mechanism unit. It is preferable to further comprise an addition treatment mechanism portion to be added to the functional water supplied from the above, wherein the filling treatment mechanism portion is configured to seal the functional water treated by the addition treatment mechanism portion in the transportable container after filling.

EMBODIMENT OF THE INVENTION Hereinafter, preferred embodiment of this invention is described according to drawing. BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which shows schematic structure of the beverage manufacturing apparatus which manufactures the beverage as functional water which concerns on one Embodiment of this invention, and FIG. 2 is a schematic structure of the oxygen dissolution processing mechanism which concerns on this embodiment. It is sectional drawing, FIG. 3 is sectional drawing of the arrow AA direction in FIG. 2, FIG. 4 is sectional drawing of the arrow BB direction in FIG. 2, FIG. 5 is sectional drawing of the arrow CC direction in FIG. 6 is an explanatory diagram for explaining the flow of water in this embodiment.

In this example, the beverage as an example of the functional water contains vitamins, minerals, amino acids, etc. in addition to dissolving oxygen at a high concentration, and is filled and sealed in a bottle (carryable container) having a predetermined inner volume. . In addition, the dissolved water has an oxygen dissolved amount of 25 to 70 mg / l immediately after treatment in which oxygen is dissolved, and an oxygen dissolved amount of 15 mg / l or more, more preferably 35 mg, after 24 hours in a state of being left in the air. oxygen dissolved amount in a sealed state of 25 to 70 mg / l, and even if 24 hours have elapsed after opening the bottle, the oxygen dissolved amount is kept to 15 (35) mg / l or more Will be.

And such a beverage can be manufactured suitably using the beverage production apparatus 1 shown in FIG. 1, The beverage production apparatus 1 is a purification processing mechanism 11, as shown in FIG. It is comprised with the addition processing mechanism 15, the oxygen dissolution processing mechanism 20, and the filling processing mechanism 16, and the water (drink raw water) used as raw water in each said processing mechanism 11, 15, 20, 16 is carried out. The sequential treatment produces bottled beverages.

The said purification processing mechanism 11 consists of the 1st filter processing part 12, the 2nd filter processing part 13, and the reverse osmosis processing part 14, The 1st filter processing part 12 suitably drinks with a filter, It is configured to remove dirt, dust, and the like from the raw water, and the second filter processing unit 13 adsorbs and removes chlorine-based compounds such as trihalomethane from the raw water processed by the first filter processing unit 12 by a carbon filter. The reverse osmosis treatment unit 14 is configured to include impurities (for example, dioxins) that are not removed by the treatment units 12 and 13 from raw water treated by the filter treatment units 12 and 13 by the reverse osmosis membrane. Or environmental hormones).

The addition processing mechanism 15 is configured to add vitamins, minerals, amino acids, and the like to the raw water of the beverage processed by the reverse osmosis treatment unit 14 of the purification treatment mechanism 11.

The oxygen dissolution treatment mechanism 20 is configured to dissolve oxygen in the beverage raw water treated by the addition treatment mechanism 15 to produce a beverage, and as shown in Figs. , The container body 21 which has a sealed space, the oxygen supply part 22 which supplies oxygen gas in the container body 21, and the pressure detector which detects the oxygen gas pressure inside the container body 21 (not shown). And a water supply unit 23 for supplying the raw water to the container body 21, a water supply pipe (third water supply pipe) 24 for supplying the beverage water inside the container body 21 to the outside, and the container body 21. 1st, 2nd, and 3rd dripping plates 25, 26, 27 arrange | positioned at the upper position in the inside, and the water level detection part 28 which detects the water level in the container body 21 are provided.

The ceiling of the container body 21 is formed with a spherical curved surface protruding outward, and the exhaust pipe 29 is connected to the ceiling to communicate the inside and the outside of the container body 21, and the exhaust pipe ( 29, an exhaust valve 29a that is normally controlled in a closed state is provided. In addition, the lower surface of the container body 21 is mounted and supported on the attachment member 30 suitably.

The said oxygen supply part 22 is an oxygen supply source 22a which supplies oxygen gas, and one end side is connected to the oxygen supply source 22a, and the other end side is supply pipe 22b connected to the 1st water supply pipe 23a mentioned later. And a supply valve 22c for adjusting the flow rate of the oxygen gas supplied from the oxygen supply source 22a to the container body 21 through the supply pipe 22b, and through the supply pipe 22b and the first water supply pipe 23a. Oxygen gas is supplied into the container body 21, and the inside of the container body 21 is made into the oxygen gas atmosphere of atmospheric pressure or more. In addition, the opening degree of the supply valve 22c is adjusted so that the pressure value detected by the said pressure detector (not shown) and the water level detected by the said water level detection part 28 become substantially constant.

The water supply part 23 has an axis line set along the up and down direction, is disposed at a coaxial position with the container body 21, and has an upper end surface at a predetermined distance from the ceiling surface of the container body 21. 1st water supply pipe 23a arrange | positioned at the upper side of (), and one end side penetrate into the container body 21 from the outer peripheral surface of the container body 21, and between the upper end part and the lower end part of the said 1st water supply pipe 23a. It was connected to the other end side of the 2nd water supply pipe 23b and 2nd water supply pipe 23b connected to the inside, and was processed by the said addition processing mechanism 15 in the container body 21 through each water supply pipe 23b, 23a. And a pump device 23e for supplying the raw water of beverage.

The first water supply pipe 23a has a discharge port 23c which is opened in the upper end surface thereof and discharges the raw water of the drink toward the ceiling direction. The inner diameter of the discharge port 23c is the first water supply pipe 23a. It is formed with a diameter smaller than the other part of (diameter D1). Moreover, the other end side of the said supply pipe 22b is connected to the lower end part of the 1st water supply pipe 23a, and the lower end surface of the said 1st water supply pipe 23a is suitably sealed by 23d of sealing members.

The check valve which is not shown in figure is provided in the said 2nd water supply pipe 23b, The drink raw water supplied to the container body 21 flows back by this check valve (not shown), or is supplied from the supply pipe 22b. Oxygen gas to be leaked to the outside is prevented.

One end of the third water supply pipe 24 penetrates into the inside from the outer circumferential surface of the bottom of the container body 21 and is stored in the bottom of the container body 21 (oxygen dissolved water). Is supplied to the outside of the container body 21 by the oxygen gas pressure inside the container body 21. Further, the third water supply pipe 24 has a diameter smaller than or equal to that of the internal diameter D1 of the first and second water supply pipes 23a and 23b, the diameter of which is smaller than or equal to that of the first and second water supply pipes 23a and 23b. And a suction port 24a for supplying a drink to the outside.

The said 1st, 2nd and 3rd dripping plates 25, 26, 27 are comprised by the plate-shaped annular member arrange | positioned at predetermined intervals in the up-down direction, and the 1st dripping plate 25 has The outer circumferential surface is inserted into and fixed to the upper inner circumferential surface of the container body 21, and the inner circumferential surface is fitted to the upper end of the first water supply pipe 23a, and the inner circumferential surface of the second discharge plate 26 is the first water supply pipe 23a. The outer peripheral surface is fitted into the upper inner peripheral surface of the container body 21 to be inserted into and fixed to the upper end portion of the container body 21. It is arrange | positioned below the 2 dripping plate 26.

The first deicing plate 25 includes four fan-shaped through-holes 25a opened at its front and back and flows along the inner circumferential surface of the container body 21 and the outer circumferential surface of the first water supply pipe 23a. The raw water and the beverage raw water which has collided with the ceiling surface of the container body 21 are restrained (by controlling the flow of the beverage raw water), and the container body (from the through holes 25a of the first dripping plate 25 is discharged). The thin film shape in the inner space of 21) also flows down into the waterfall shape.

As for the said 2nd dripping plate 26, the outer peripheral surface (short edge) is formed in the zigzag shape, and the raw water of drink which drifted and flowed down by the 1st dripping plate 25, and each of the 1st dripping plates 25 The raw water having passed through the through hole 25a is restrained so that a thin film and a waterfall flow into the inner space of the container body 21 from the outer circumferential portion (protrusion end) of the second dripping plate 26.

As for the said 3rd dripping plate 27, the internal peripheral surface (end edge) is formed in the zigzag shape, and the raw water and the drink which drifted and flowed down by the 1st dripping board 25 and the 2nd dripping board 26, The raw water passed through each through hole 25a of the first defrosting plate 25 is restrained, and a thin film shape is formed into the inner space of the container body 21 from the inner circumferential portion (protrusion end) of the third defrosting plate 27. Let it flow down into the waterfall shape.

The water level detection unit 28 is made of a light-transmitting material such as glass or resin, and has a longitudinal direction in the vicinity of the introduction tube 28a and the introduction tube 28a that are attached to the outer circumferential surface of the container body 21 along the vertical direction. It consists of two water level sensors 28b and 28c which are arranged up and down on the outer peripheral surface of the container body 21. As shown in FIG.

The upper end and the lower end of the introduction pipe 28a communicate with the inside of the container body 21, and the position of the liquid level in the introduction pipe 28a is raised and lowered according to the water level in the container body 21, and the water level sensor ( 28b and 28c detect the liquid surface position.

According to this water level detection part 28, when the water level in the container body 21 rises and the liquid level position in the inlet pipe 28a rises, and this will be detected by the upper water level sensor 28b, it will be in the container body 21. It is judged that the water level has exceeded the upper limit, the opening degree of the supply valve 22c is adjusted, and the oxygen gas supply amount is increased. Thereby, the oxygen gas pressure in the container body 21 becomes high, the supply amount to the outside increases, and the water level in the container body 21 falls.

On the other hand, when the water level in the container body 21 falls and the liquid surface position in the inlet pipe 28a falls, and this is detected by the lower level sensor 28c, it is determined that the water level in the container body 21 exceeds the lower limit. Then, the opening degree of the supply valve 22c is adjusted and the oxygen gas supply amount is reduced. Thereby, the oxygen gas pressure in the container body 21 becomes low, the supply amount to the outside becomes small, and the water level in the container body 21 raises.

In this way, according to this oxygen dissolution processing mechanism 20, oxygen gas is first supplied from the oxygen supply source 22a into the container body 21 through the supply pipe 22b and the first water supply pipe 23a, and the container body ( 21) The inside becomes an oxygen gas atmosphere at or above atmospheric pressure.

Subsequently, when the raw water to drink (water before oxygen dissolution) processed by the addition processing mechanism 15 is supplied to the 2nd water supply pipe 23b by the pump apparatus 23e, the supplied raw water to drink is the 2nd water supply pipe 23b. After the inside is circulated, the inside of the first water supply pipe 23a is circulated while being mixed with the oxygen gas supplied from the supply pipe 22b in contact with each other in the first water supply pipe 23a, and the oxygen gas is discharged from the discharge port 23c. And discharged at the same time.

The discharged beverage raw water is spouted up in a fountain shape (radial shape around the discharge port 23c) toward the ceiling direction (see FIG. 6 arrow C1), and the raw beverage discharged is the inner diameter of the discharge port 23c. Since it is formed with a diameter smaller than the other part of this 1st water supply pipe 23a, the pressure at the time of discharge becomes high, the flow velocity becomes high, and it is spun up harder and broader radially.

Then, the raw water of the beverage spouted from the discharge port 23c collides with the ceiling surface or the inner circumferential surface of the container body 21 and flows downward along the ceiling surface or the inner circumferential surface (see arrow C2) or pops up (shown in FIG. Not shown), and flows downward along the outer circumferential surface of the first water supply pipe 23a (not shown), and thereafter, is drifted by the first dripping plate 25 to penetrate the through hole of the first dripping plate 25. From 25a, the thin film form also falls in the inner space of the container body 21 in a waterfall form (refer to arrow C3 and C4).

Subsequently, the beverage raw water that has been drifted down by the first defrosting plate 25 and the beverage raw water that has sprung up and passed through the through holes 25a of the first defrosting plate 25 are transferred to the second defrosting plate 26. And the film flows down into the cascade from the outer circumferential portion of the second dripping plate 26 into the inner space of the container body 21 (see arrow C5).

Thereafter, the raw water drinked by the first and second flow plates 25 and 26 flows down, and the raw water that has passed through the through holes 25a of the first flow plates 25 is And is degreased by the third defrosting plate 27 and flows from the inner circumferential portion of the third defrosting plate 27 into the inner space of the container 21 in a cascade shape (see arrow C6). 21 is stored at the bottom of the.

Then, in contact with the beverage raw water, oxygen is dissolved in the flow process in the first water supply pipe 23a and the container body 21 of the beverage raw water.

Thereby, the oxygen dissolved amount of the said beverage raw water rises from 6-8 mg / l before the said process to 25-70 mg / l, and is high oxygen concentration, and even if 24 hours pass after opening a bottle, the oxygen dissolved amount Drinking water is produced which is maintained at 15 mg / l or more, more preferably at least 35 mg / l. This is because when the water molecules and the oxygen molecules come into contact with each other under a high-pressure oxygen atmosphere, some of them are ionized to form a state in which the water molecules and the oxygen molecules are bonded by ionic bonds, thereby dissolving oxygen in water. It is considered that water at which the high oxygen concentration and the oxygen dissolved amount do not decrease is obtained.

After that, the beverage (water after oxygen dissolution) stored in the container body 21 is external from the third water supply pipe 24 by the oxygen gas pressure inside the container body 21 (the filling processing mechanism 16). Supplied to.

When the water level of the beverage water stored in the container body 21 exceeds the upper limit or the lower limit, it is detected by the water level detection unit 28. When the water level exceeds the upper limit, the liquid level position in the inlet pipe 28a is upward. When the water level exceeds the lower limit, this is detected by the water level sensor 28c below.

In this way, when the water level sensor 28b, 28c detects that the water level exceeded a certain limit, the opening degree of the supply valve 22c is adjusted, and the oxygen gas supply amount is adjusted, thereby adjusting the oxygen in the container body 21. The gas pressure is adjusted to adjust the supply amount to the outside, and the ratio of the oxygen gas and the beverage in the container body 21 is maintained within a certain range.

In addition, in the 1st and 2nd water supply pipes 23a and 23b and the 3rd water supply pipe 24, the internal diameter D2 of the 3rd water supply pipe 24 is the same as the internal diameter D1 of the 1st and 2nd water supply pipes 23a and 23b. Since it is formed with a diameter of less than or equal to the diameter, the drinking water in the container body 21 is difficult to be supplied to the outside (the drinking water is easily stored in the container body 21), and the oxygen inside the container body 21 is reduced. The gas pressure is increased to higher pressure.

In addition, when oxygen is dissolved in the source of the beverage, the gas, such as nitrogen, originally contained (dissolved) is released from the source of the beverage according to Henry's law, so that the concentration of oxygen gas in the container body 21 gradually decreases. , The amount of dissolved oxygen in the raw water of the drink decreases. For this reason, in order to maintain the oxygen gas density | concentration in the container body 21 more than a fixed value, gas, such as nitrogen, in the container body 21 is discharged regularly.

Specifically, first, the supply valve 22c is closed, and the supply of oxygen gas into the container body 21 is stopped, and then the exhaust valve 29a of the exhaust pipe 29 is opened to open and close the container body 21. To communicate. Thereby, the gas pressure inside the container body 21 falls to the pressure equivalent to atmospheric pressure, and the drink water stored in the container body 21 is not supplied from the 3rd water supply pipe 24 to the outside.

Subsequently, the raw water is further supplied from the water supply pipes 23a and 23b into the container body 21, the water level in the container body 21 is raised, and the gas in the container body 21 is discharged from the exhaust pipe 29. (21) Discharge to the outside.

As described above, when oxygen is dissolved in the raw water of the beverage by the oxygen dissolution treatment mechanism 20 and the beverage is produced, the filling treatment mechanism 16 is then connected to the third water supply pipe of the oxygen dissolution treatment mechanism 20. The beverage supplied from 24) is sealed after filling in bottles by predetermined volumes.

According to the beverage production apparatus 1 configured in this manner, first, the raw water is sequentially purified by the purification treatment mechanism 11 in the first filter processing unit 12, the second filter processing unit 13, and the reverse osmosis processing unit 14. Processed and purified, and then, the addition treatment mechanism 15 adds vitamins, minerals, amino acids and the like to the raw water purified by the purification treatment mechanism 11, and then to the oxygen dissolution treatment mechanism 20. As a result, the beverage containing dissolved oxygen at a high concentration is produced from the beverage raw water to which the vitamins, minerals, amino acids and the like are added in the addition processing mechanism 15, and thereafter, the oxygen treatment treatment is performed by the filling treatment mechanism 16. The beverage produced by the apparatus 20 is filled into a bottle and then sealed, thereby producing a beverage filled in the bottle.

Thus, according to the beverage of this example manufactured by this beverage production apparatus 1, even if the oxygen dissolved amount is high concentration in a sealed state, and even if the bottle is opened and comes into contact with air, before the predetermined time elapses after opening. In this case, since it is maintained in the state of high oxygen concentration, when it is desired to drink the said drink, it is possible to drink as much as you want, and at any time, you can ingest sufficient amount of oxygen in order to acquire the above effects. Thereby, handling of the said drink becomes easy, and can raise a commodity value more.

In addition, since it is produced from the beverage raw water purified by the purification processing mechanism 11 with little incorporation of impurities, and added with vitamins, minerals, amino acids and the like in the additive processing mechanism 15, the product value is further increased. Can be.

Moreover, according to the said beverage production apparatus 1, in addition to being able to manufacture such a beverage suitably, it also has the following advantages.

That is, the raw water is sprayed radially from the discharge port 23c, and the contact area with the oxygen gas of the raw water is increased, and the raw water is restrained by the respective dripping plates 25, 26, 27, respectively. Since the thin film shape also flows down into the casing shape from the distillation plates 25, 26, 27 into the inner space of the container body 21, and comes into contact with oxygen gas on both sides of the water film, the inside of the container body 21 is also provided. Since the oxygen gas pressure of was made high, much oxygen can be dissolved efficiently by the said drinking raw water, and it can produce | generate the drinking water which is high oxygen concentration and the oxygen dissolved amount does not fall as mentioned above efficiently.

In addition, each of the dehumidifying plates 25, 26, 27 is provided in the container body 21. As a result, the falling flow rate of the drinking water is not limited, so that a large amount of the drinking water can be efficiently treated and nitrogen When the gas is discharged, the water level in the container body 21 is rapidly raised to quickly discharge the gas.

In addition, since the raw water purified by the purification processing mechanism 11 is supplied to the container body 21, foreign substances such as dust are introduced into the through-holes 25a of each of the first defrosting plates 25 and the delimiting plates 25 and 26. And 27), there is no clogging between them, so that there is no need to remove foreign matters, the maintenance cost can be lowered, and the container body 21 is not decomposable for removing foreign matters. The structure of the container body 21 can be simplified, manufacturing cost can be made low, and the airtightness of the container body 21 can be improved.

In addition, by providing a plurality of deicing plates 25, 26, 27, and by increasing the number of drift of the raw water of the beverage, the flow state of the raw beverage is changed to increase the number of times of contact between the beverage and the oxygen gas, thereby Also, oxygen can be dissolved more efficiently.

In addition, since the outer circumferential surface of the second deliming plate 26 and the inner circumferential surface of the third deliming plate 27 were formed in a zigzag shape, the circumferential lengths of the outer circumferential surface and the inner circumferential surface were lengthened so that the second deliming plate 26 and the third The surface area of the source water of the beverage flowing down from the dripping plate 27 to the waterfall shape can be increased to increase the contact area with the oxygen gas, so that more oxygen can be efficiently dissolved in the source of beverage.

Moreover, since the upper part of the container body 21 was formed in the spherical curved surface which protruded outward, the drinking water which discharged from the discharge port 23c and collided with the ceiling surface of the container body 21 is the said ceiling surface. Along the side of the first defrosting plate 25, and can be defrosted by the first defrosting plate 25 to flow down into the inner space of the container body 21, thereby increasing the amount of oxygen dissolved in the beverage source water. Can be.

In addition, since the upper end surface of the 1st water supply pipe 23a was arrange | positioned at the upper side in the container body 21, and the raw water of drink was discharged from the discharge port 23c at the upper side in the container body 21, from the discharge port 23c, After being discharged, the flow distance of the raw beverage until it is stored in the bottom part of the container body 21 can be lengthened, and the oxygen dissolution amount of the raw beverage can be further increased.

Moreover, since the internal diameter D2 of the 3rd water supply pipe 24 was comprised with the diameter equal to or less than the internal diameter D1 of the 1st and 2nd water supply pipes 23a and 23b, it is stored in the container body 21. It is difficult to supply the drinking water to the outside, so that the pressure of the oxygen gas in the container body 21 can be made higher, and much oxygen can be efficiently dissolved by the raw water flowing in the oxygen gas atmosphere.

Moreover, even if the oxygen gas pressure in the container body 21 rises for any reason, the water level in the container body 21 does not fall, so that the water level falls below the inlet port 24a of the third water supply pipe 24. The problem that oxygen gas in the gas 21 leaks out from the third water supply pipe 24 can be effectively prevented.

In addition, since the source of the drink and the oxygen gas are mixed and brought into contact with each other, and the oxygen is dissolved in the source of the drink, the inside of the first water supply pipe 23a is flowed toward the discharge port 23c, so that the oxygen is more efficiently and in a large amount. Can be dissolved in raw water.

In addition, since the inner diameter of the discharge port 23c is configured to have a diameter smaller than that of the other parts of the first water supply pipe 23a, the pressure at the time of discharge can be increased to increase the flow rate thereof, and the raw water discharged from the discharge port 23c can be obtained. To a wider radial shape to more efficiently and in large quantities dissolve oxygen in the beverage raw water, or oxygen mixed with the beverage raw water in the first water supply line 23a to the beverage raw water more efficiently and in large quantities. Can be.

Moreover, since the 1st water supply pipe 23a was arrange | positioned coaxially with the container body 21, the raw water discharged from the discharge port 23c can be disperse | distributed evenly, and the inside of the container body 21 can flow down, and the said The process can be performed efficiently.

As mentioned above, although one Embodiment of this invention was described, the specific aspect which this invention can employ | adopt is not limited to this.

For example, in the above-described example, the oxygen dissolution treatment mechanism 20 was used to dissolve oxygen in the raw water of the beverage to produce the beverage, but the present invention is not limited thereto, and the oxygen dissolution shown in FIGS. 7 to 9 is used. It is also possible to use the processing mechanism 40. 7 is sectional drawing which shows schematic structure of the oxygen dissolution processing mechanism which concerns on other embodiment of this invention, FIG. 8 is sectional drawing of the arrow DD direction in FIG. 7, and FIG. 9 is another embodiment of this invention. It is explanatory drawing for demonstrating the flow of water in a form.

As illustrated in FIG. 7, the oxygen dissolution treatment mechanism 40 includes an oxygen supply portion 22, a water supply portion 23, a third water supply pipe 24, and each agent in the oxygen dissolution treatment mechanism 20. The flow plates 25, 26, and 27 are different, and the same components as in the oxygen dissolution treatment mechanism 20 are denoted by the same reference numerals, and detailed description thereof is omitted.

As shown in FIG.7 and FIG.8, the said oxygen dissolution processing mechanism 40 is the said container body 21, the oxygen supply part 41 which supplies oxygen gas in the container body 21, and the said pressure detector (Not shown), a water supply part 42 for supplying the raw water to the container body 21, a water supply pipe (second water supply pipe) 43 for supplying the beverage water in the container body to the outside, and a container body First and second dripping plates 44 and 45 disposed at an upper position in 21 are provided, and the water level detector 28 is provided.

The said oxygen supply part 41 is the said oxygen supply source 22a, the supply pipe 41a which connected one end side to the oxygen supply source 22a, and the other end side connected to the upper part of the container body 21, and the said supply valve 22c and the exhaust valve 41b which communicates the inside and the exterior of the container body 21, the supply valve 22c is open in a predetermined opening degree, the exhaust valve 41b is closed, and is normally controlled. do.

One end of the water supply part 42 is inserted through the bottom circumferential surface of the container body 21 therein, and is bent in an L shape at the center of the container body 21 to form an upper portion of the container body 21. The 1st water supply pipe 42a extended toward the side, the said pump apparatus 23e etc. connected to the other end side of the 1st water supply pipe 42a are provided.

The first water supply pipe 42a is provided with a discharge port 42b whose one end (upper end) is disposed at a predetermined distance from the ceiling surface in the container body 21 and is opened on the upper end surface, and the discharge port 42b is provided. Opens toward the ceiling direction in the container body 21, and discharges the drink raw water toward the ceiling direction. Moreover, the check valve which is not shown in figure is provided in the 1st water supply pipe 42a, and this drinking valve (not shown) prevents the back of the drink raw water supplied to the container body 21.

One end of the second water supply pipe 43 is inserted through the bottom circumferential surface of the container body 21 therein, and is bent into an L shape in the container body 21 to form a bottom of the container body 21. The drinking water (oxygen dissolved water) stored in the bottom part in the container body 21 is extended and installed toward the surface side, and is moved out of the container body 21 by the oxygen gas pressure in the inside of the container body 21. Supply.

In addition, the second water supply pipe 43 has one end (lower end) of which is disposed at a predetermined distance from the bottom surface of the container body 21, and is opened on the lower end surface to supply a drinking water to the outside ( 43a). Moreover, the 2nd water supply pipe 43 is comprised by the small diameter whose inner diameter D2 is the same diameter or less than the inner diameter D1 of the 1st water supply pipe 42a.

The first discharge plate 44 is constituted by a flat plate and an annular member, the outer circumferential surface of which is inserted into the upper inner circumferential surface of the container body 21 to be fixed, and is substantially the same as the upper end of the first water supply pipe 42a. The raw water is disposed at a height position and flows along the inner circumferential surface of the container body 21, or the beverage raw water colliding with the ceiling surface of the container body 21 is restrained to discharge the raw water. The thin film shape also flows down into the waterfall shape from the inner circumference to the inner space of the container body 21.

Similarly, the said 2nd dripping plate 45 is comprised from a flat plate and an annular member, The inner peripheral surface is fitted in the upper peripheral side outer peripheral surface of the 1st water supply pipe 42a, it is fixed, and is arrange | positioned below the 1st dripping plate 44 The raw water and the beverage raw water which has flowed along the outer circumferential surface of the first water supply pipe 42a and impinge on the ceiling surface of the container body 21 are restrained and are discharged from the outer circumferential portion of the second dripping plate 45. In the inner space of the container body 21, the thin film shape also flows down into the waterfall shape.

In this way, according to this oxygen dissolution processing mechanism 40, oxygen gas is supplied into the container body 21 by the oxygen supply part 41, and the inside of the container body 21 becomes an oxygen gas atmosphere of atmospheric pressure or more. Subsequently, when the raw water for drinking water (water before oxygen dissolution) is supplied to the first water supply pipe 42a by the pump device 23e, the supplied raw water flows through the first water supply pipe 42a, and then the discharge port 42b. ) Is discharged into the container body 21.

The discharged beverage raw water is sprayed up in a fountain shape (radially around the discharge port 42b) toward the ceiling direction (see FIG. 9 arrow C11), and collides with the ceiling surface or the inner circumferential surface of the container body 21, and the cloth It flows downward along the scene or inner circumferential surface (see arrow C12), springs up (not shown), or flows downward along the outer circumferential surface of the first water supply pipe 42a (see arrow C13).

Drinking water flowing along the inner circumferential surface of the container body 21 is then restrained by the first dripping plate 44, and the internal space of the container body 21 from the inner circumferential portion of the first dripping plate 44. The raw water flowing down into the thin film shape or the waterfall shape (see arrow C14), and the raw water flowing along the outer circumferential surface of the first water supply pipe 42a is discharged by the second distillation plate 45, and the second distillation plate 45 The thin film shape also falls into the waterfall shape from the outer peripheral portion of the container body 21 (see arrow C15).

In addition, most of the said spring water of the drinking water flows in the internal space of the container body 21, without being restrained by each defrosting plate 44 and 45. FIG.

And the raw drinking water which flowed down in the oxygen gas atmosphere is stored in the bottom part of the container body 21, and the stored raw drinking water (water after oxygen dissolution, ie, drinking water), is the oxygen gas in the inside of the container body 21. The pressure is supplied from the second water supply pipe 43 to the filling treatment mechanism 16.

In this manner, the oxygen dissolution treatment mechanism 40 can also spray the raw water of the beverage radially from the discharge port 42b and along the inner circumferential surface of the container body 21 and the outer circumferential surface of the first water supply pipe 42a. It is possible to flow the raw beverage to flow from each of the dripping plates 44 and 45 into a thin film shape or a waterfall shape, so that it is possible to produce a beverage in which oxygen is dissolved at a high concentration. The effect can be obtained.

In addition, in the oxygen dissolution treatment mechanism 40, the second defrosting plate 45 may be configured as a second delimiting plate 46 as shown in FIGS. 10 and 11.

As shown in Figs. 10 and 11, the second delimiting plate 46 is formed of a flat plate and a rectangular shape, and a plurality of through holes 46a whose outer peripheral surface is formed in a zigzag shape and penetrates the front and back. ) And a fitting insertion hole 46b formed in the center portion, allowing the raw water to flow from the outer circumferential portion into a thin film and a waterfall, and dropping the raw water from the through hole 46a in a plurality of droplets. .

The through holes 46a are formed concentrically around the insertion hole 46b, and the through holes 46a formed on the inside and the through holes 46a formed on the outside are staggered in the circumferential direction, respectively. It is open.

In addition, the inner peripheral surface of the insertion hole 46b is fitted to the upper peripheral side outer peripheral surface of the first water supply pipe 42a, and the second corner plate 46 is supported by the inner peripheral surface of the container body 21. It is arrange | positioned in the upper position with the predetermined space | interval from the 1st dripping plate 44, and the clearance gap 46c is formed between the outer peripheral surface and the inner peripheral surface of the container body 21. As shown in FIG.

In the oxygen dissolution processing mechanism including the second and second distillation plates 46 and 44 configured as described above, the raw water of the beverage flows through the container body 21 as follows.

That is, the raw water spouted radially (see arrow C21) then collides with the ceiling surface or the inner circumferential surface of the container body 21 and flows downward along the ceiling surface or the inner circumferential surface (see arrow C22). Or bounces (not shown) or flows downward along the outer circumferential surface of the first water supply pipe 42a (see arrow C23).

And the beverage raw water which flows along the outer peripheral surface of the 1st water supply pipe 42a, and the beverage raw water which protruded are then restrained by the 2nd distillation board 46, and are discharged from the outer peripheral part of the said 2nd dripping board 46. The thin film shape also flows down into a waterfall shape or falls into a plurality of droplets from the through hole 46a of the second dripping plate 46 (see arrow C24).

On the other hand, the beverage raw water which flows along the inner peripheral surface of the container body 21, the beverage raw water which jumped up and passed through the clearance 46c, and the beverage raw water which drifted and flowed down by the 2nd distillation board 46 are 1st distillation boards. It is deregulated by 44, and the thin film form also falls in a waterfall form from the inner peripheral part of the said 1st dripping plate 44 (refer arrow C25).

Even in the case of forming and arranging each of the deicing plates 44 and 46 in this way, the raw water discharged from the discharge port 42b can be caused to flow down from the inner circumferential portion or the outer circumferential portion of the deicing plates 44 and 46 in a waterfall shape or a waterfall shape. At the same time, since the water can be dropped from the through hole 46a in a number of droplets, the same effect as described above can be obtained, for example, to produce a beverage in which oxygen is dissolved at a high concentration.

In addition, as shown in FIG. 12, in the oxygen dissolution processing mechanism 20, the container body 21 is arranged such that the cylindrical deicing member 31 having both end surfaces thereof is opened along its vertical direction. Even if it is installed on the ceiling surface of the container, the raw water discharged from the discharge port 23c and flowing along the ceiling surface is restrained by the defrosting member 31, and the container body 21 is formed from the lower end of the defrosting member 31. The thin film shape into the inner space of the can also flow down to the waterfall shape. In addition, although not shown in figure, this also applies to the said oxygen dissolution processing mechanism 40 similarly.

In this case, when the inner circumferential surface of the deicing member 31 is formed in a zigzag shape in plan view, as described above, the circumferential length of the inner circumferential surface is lengthened, and the surface area of the raw water of the beverage flowing down from the deliming member 31 is increased. It is possible to increase the contact area with the oxygen gas so that more oxygen can be efficiently dissolved in the beverage raw water.

In addition, in the said example, although the arrangement position of each dripping plate 25, 26, 27, 44, 45, 46 is not specifically limited, It is preferable to arrange | position in the upper position in the container body 21. As shown in FIG. For example, the sump plates 25, 45, 46 are provided at the upper ends of the water supply pipes 23a, 42a, or within the range smaller than the value obtained by about three times the inner diameter of the discharge ports 23c, 42b. What is necessary is just to provide it in the position lowered | hanged, and also to install the distillation plates 27 and 44 in the position higher than the discharge ports 23c and 42b.

In this case, since the falling distance from each of the dripping plates 25, 26, 27, 44, 45, 46 to reach the water surface of the beverage stored in the container body 21 can be increased, Many oxygen gases can be dissolved in the beverage by contacting it.

In addition, with respect to the positional relationship of each deicing board 25, 26, 27, 44, 45, 46, you may install either in an upper side or a lower side, and can also install in substantially the same height position.

In addition, the shape of each of the deicing plates 25, 26, 27, 44, 45, 46, for example, the shape of the outer circumferential surface or the inner circumferential surface, the shape, the forming position of the through holes 25a, 46a, and the like are also particularly limited. no. The shape of the outer circumferential surface or the inner circumferential surface formed in a zigzag shape (toothed shape) may be a smooth curved shape, a rectangular wave shape, or a combination of these saw tooth shapes, curved shapes, and rectangular wave shapes, instead of the zigzag shape.

In addition, the arrangement | positioning number of the drift plates 25, 26, 27, 44, 45, 46 is not limited at all, A part or all of the drift plates 25, 26, 27, 44, 45, 46 is not provided. It may be configured without, or may be provided in multiple stages than the above-described example.

In addition, it is preferable that the upper end surfaces of the water supply pipes 23a and 42a are provided on the upper side in the container body 21. In this case, since the raw water of the drink can be discharged from the upper side in the container body 21, the discharge port After discharging from 23c and 42b, the flow distance of the raw water to be stored to the bottom part of the container body 21 can be lengthened, and the amount of oxygen dissolved in the beverage can be further increased.

In addition, in the above-mentioned example, although one water supply pipe 23a, 23b, 42a was provided in the container 21, it is also possible to provide some water supply pipe 23a, 23b, 42a. In addition, the inner diameter D1 of the water supply pipes 23a, 23b, 42a is constantly formed except for the portion of the discharge port 23c, and the inner diameter D2 of the water supply pipes 24, 43 is constantly formed. It may be formed so as to change.

In addition, in the above-mentioned example, although the upper part of the container body 21 was formed in the spherical curved surface which protruded outward, it is not limited to this, Although it is not shown in figure, it forms in the spherical curved surface which protruded inward. You may also Even in this case, the raw water of the beverage collided with the ceiling surface of the container body 21 is caused to flow along the ceiling surface to the inner circumferential surface side of the container body 21, that is, the first distillation plates 25 and 44 side. Since it can make it flow and make it flow down by the 1st defrosting members 25 and 44, the oxygen dissolution amount of a drinking water can be raised.

In the above-described example, the addition processing mechanism 15 is configured to add vitamins, minerals, amino acids and the like to the raw water of the beverage, but is not limited to this, so that components other than these vitamins, minerals and amino acids may be added. You may comprise.

In addition, the addition processing mechanism 15 was configured to add vitamins, minerals, amino acids and the like to the purified raw water after purification by the purification treatment mechanism 11, but the present invention is not limited thereto, and the purification treatment is performed by an oxygen dissolution treatment mechanism. After dissolving oxygen in the raw water purified by the apparatus to produce a beverage, the beverage, vitamins, minerals and amino acids, are added to the beverage by the addition treatment mechanism, and then, by the filling treatment mechanism, the beverage after the addition treatment. It is also possible to configure to seal after filling into the bottle.

In addition, the structure of the oxygen dissolution processing mechanisms 20 and 40 has shown an example, It is not limited to the said structure, Furthermore, the flow of the source water of a drink described with reference to FIG. 6, 9, and 11 (C1-C6, C11 to C15, C21 to C25) are one example, and this flow naturally changes depending on the discharge amount, discharge pressure, etc. of the raw water of the beverage.

In addition, in the above-mentioned example, although drinking water was mentioned as an example of functional water, it is not limited to this, This functional water can also be used as a raw material, such as a medicine and cosmetics, For example, when used for eye drops, face-washing water, and lotion, Oxygen is absorbed from the surface of the eyes and skin, which promotes metabolism.

And when using this functional water as a raw material, such as a medicine and cosmetics, for example, in the raw water purified by the said purification processing mechanism 11, oxygen is made into high concentration with the said oxygen dissolution processing mechanisms 20 and 40. It is good to melt | dissolve, produce | generate functional water, and supply the produced | generated functional water as it is to a manufacturing line of a medicine or cosmetics, or to fill it in an appropriately transportable container, and supply.

In addition, chemicals may be added to the functional water by the addition treatment mechanism 15 to produce eye drops, face-wash water, lotion, and the like.

Thus, according to these functional water production methods and production apparatuses, raw water is radiated from the discharge port radially to increase the contact area with the oxygen gas of the raw water, and along the inner surface of the sealed container body or the outer peripheral surface of the first water supply pipe. The flow of raw water that flows is controlled by the first or second defrosting member to cause the thin film or waterfall to flow into the inner space of the sealed container body from the protruding end of the defrosting member, so that both sides of the water film And oxygen gas pressure inside the hermetically sealed container was increased, so that much oxygen can be efficiently dissolved by the raw water, and the oxygen concentration is high as described above. The functional water which does not fall in dissolved amount can be produced efficiently.

As mentioned above, according to the functional water which concerns on this invention, even if it is left to stand in air | atmosphere, since the said predetermined time passes before it maintains in the state of high oxygen concentration, the added value of the said functional water can be improved. . In addition, by including vitamins, minerals, amino acids or drugs, the added value of the functional water can be further increased.

Moreover, according to the functional water manufacturing method and manufacturing apparatus which concern on this invention, the functional water as mentioned above can be manufactured suitably.

Claims (15)

A functional water obtained by dissolving more than the natural dissolved concentration of oxygen in raw water, the oxygen dissolved amount immediately after the oxygen dissolved treatment is 25 to 70 mg / l, and thereafter, the dissolved oxygen amount after 24 hours in a state of standing in the air is 15 mg. The number of functions characterized by being kept above / l. The method of claim 1, A functional water comprising at least one of vitamins, minerals, amino acids or drugs. The method according to claim 1 or 2, Functional water characterized by being filled and sealed in a transportable container. The pressurized oxygen gas is supplied into the sealed container body to make the inside of the sealed container body an oxygen gas atmosphere at atmospheric pressure or higher, Discharging the raw water into the sealed container body and causing the discharged raw water to flow down into the membrane in the sealed container to make gas-liquid contact with oxygen gas to produce functional water in which 25 to 70 mg / l of oxygen is dissolved, Subsequently, the produced functional water is taken out from the said airtight container body, The manufacturing method of the functional water characterized by the above-mentioned. The method of claim 4, wherein And purifying the raw water by reverse osmosis treatment, and supplying the purified raw water into the sealed container body. The method of claim 4, wherein And adding at least one of vitamins, minerals, amino acids or drugs to the raw water, and then supplying the raw water after the addition treatment into the sealed container body. The method of claim 5, And adding at least one of a vitamin, a mineral, an amino acid or a drug to the purified water, and then supplying the raw water after the addition treatment into the sealed container body. The method according to claim 4 or 5, And at least one of vitamins, minerals, amino acids or drugs is added to the functional water extracted from the sealed container body. The method according to any one of claims 4 to 7, A functional water production method, wherein the functional water extracted from the sealed container body is sealed after being filled in a transportable container. The method of claim 8, A functional water production method, wherein a functional water containing at least one of a vitamin, a mineral, an amino acid, or a drug is added and sealed in a transportable container. An oxygen dissolution treatment mechanism portion for dissolving oxygen at a natural dissolution concentration or higher in raw water to generate functional water, and a filling treatment mechanism portion for sealing and sealing the functional water generated by the oxygen dissolution treatment mechanism portion in a transportable container, The said oxygen dissolution processing mechanism part is equipped with the airtight container body and the supply pipe connected in the said airtight container body, supplies oxygen gas to the said airtight container body through the said supply pipe, and the inside of the said airtight container body is the oxygen gas atmosphere of atmospheric pressure or more. And a first water supply pipe connected to the one end side in the sealed container body in an up-down direction in the sealed container body, and having a discharge port formed at an upper end surface thereof, and from the discharge port of the first water supply pipe. Water supply means for discharging the raw water toward the ceiling of the sealed container body, a second water supply pipe connected to the sealed container body and supplying the functional water stored at the bottom of the sealed container body to the outside; The first defrosting member protruding inwardly from the inner surface of the hermetic container body and / or the outer side of one end side peripheral surface of the first water supply pipe. Having a second plate-like member omphalocele protrudes, and The raw water is discharged from the discharge port toward the ceiling of the sealed container body and discharged from the discharge port and flows through the inner surface of the sealed container body and / or the outer circumferential surface of the first water supply pipe. Configured to allow the raw water and oxygen gas to gas-liquid contact within the sealed container body to generate the functional water by flowing down from the protruding end of the first and / or second defrosting member in the inner space of the sealed container body. Become, The said filling processing mechanism part is comprised so that the functional water supplied from the 2nd water supply pipe of the said oxygen dissolution processing mechanism part may be filled and sealed in the said portable container, The functional water manufacturing apparatus characterized by the above-mentioned. The method of claim 11, wherein It further comprises a reverse osmosis treatment mechanism for purifying the raw water, The water supply means of the said oxygen dissolution processing mechanism part is comprised so that the raw water purified by the said reverse osmosis processing mechanism part may be discharged from the discharge port of the said 1st water supply pipe. The method of claim 11, wherein It further comprises an addition processing mechanism for adding at least one of vitamins, minerals, amino acids or drugs to the raw water, The water supply means of the said oxygen dissolution processing mechanism part is comprised so that the raw water processed by the said addition processing mechanism part may be discharged from the discharge port of the said 1st water supply pipe, The functional water manufacturing apparatus characterized by the above-mentioned. The method of claim 12, It further comprises an addition processing mechanism portion for adding at least one of vitamins, minerals, amino acids or drugs to the raw water purified by the reverse osmosis treatment mechanism portion, The water supply means of the said oxygen dissolution processing mechanism part is comprised so that the raw water processed by the said addition processing mechanism part may be discharged from the discharge port of the said 1st water supply pipe, The functional water manufacturing apparatus characterized by the above-mentioned. The method according to claim 11 or 12, And an addition treatment mechanism portion for adding at least one of vitamins, minerals, amino acids or drugs to the functional water supplied from the second water supply pipe of the oxygen dissolution treatment mechanism portion. The said filling processing mechanism part is comprised so that the functional water processed by the said addition processing mechanism part may be sealed after filling in the said portable container. The functional water manufacturing apparatus characterized by the above-mentioned.

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