TW201615561A - Mineral functional water, production method therefor, body-function-activating composition, and functional fiber product - Google Patents

Abstract

Provided are mineral functional water having the effect of activating a human body function, and applied products thereof. This mineral functional water has the effect of activating a human body function, such as the effect of improving blood circulation as a result of electromagnetic waves emitted by mineral components contained therein.

Description

Mineral functional water and its manufacturing method, and body function activating composition and functional fiber product (Priority Information)

This international application is based on the Japanese Patent Application No. 2014-189333, filed on September 17, 2014, by the Japanese Patent Office, and the priority of the Japanese Patent Application No. 2014-189333 The content is used in this international application.

The present invention relates to mineral functional water having a body functional activity and its use.

In the case of moderate aerobic exercise such as running or walking, it is considered to be effective in preventing the prevention of lifestyle-related diseases, and it has been popular in recent years for the improvement of lifestyle-related diseases such as lack of exercise, health maintenance, or improvement of physical strength. In addition, sports with higher loads are also popular among young people.

Fatigue after exercise resumes eating a balanced diet, improves blood circulation by bathing or massage, and can effectively rest well. On the other hand, various types of fatigue recovery agents are being developed for the purpose of preventing or recovering fatigue and improving physical strength more easily.

When such a fatigue-recovering agent is ingested orally, it is difficult to digest and absorb, and even if it is practically used, it is sufficient that the amount of effectiveness is small. In particular, among the sports players who usually perform excessive training, they are seeking early fatigue recovery. From this point of view, the existing supplemental ingredients have a limit on the application of food.

On the other hand, in order to promote the fatigue reduction of the foot in sports or the fatigue recovery effect after sports, sports materials are being developed.

For example, Patent Document 1 or Patent Document 2 reports a sports clothing that uses a stepwise pressure. Such sports materials are reduced in unsatisfactory oppression by tailoring the sporting movements. They are self-contained, but difficult to obtain, and the price is high. Usually, ordinary people cannot easily use it. shape. Furthermore, even the medical clothes have the same problem.

On the other hand, in the case of water containing mineral components, it is considered that the possibility of soil reforming, plant growth, decomposition of harmful chemicals, deodorization, air purification, etc. is developing better than ever. A wide range of manufacturing equipment containing mineral water or mineral water.

The inventors of the present invention are developing a device (A) for producing mineral-containing water, which comprises immersing a conductive wire covered with an insulator and a mineral-imparting material (A) in water to conduct a direct current to the conductive wire. The water around the conductive wire generates a water flow in the same direction as the direct current current, and imparts ultrasonic vibration to the water to form a raw material mineral aqueous solution (A). The segment and the far-infrared rays which are irradiated with the raw material mineral aqueous solution (A) formed to form the mineral-containing water (A) (see Patent Document 3).

Moreover, the inventors of the present invention are developing a mineral functional water producing apparatus which is a mineral functional water producing apparatus including a mineral water manufacturing apparatus (A) and a mineral water manufacturing apparatus (B). The mineral water producing apparatus (B) includes a plurality of water-passing containers filled with different types of mineral-imparting materials (B), and a water-feeding path of the plurality of water-passing containers connected in series, and the plurality of The water container is connected in parallel to the water return passage of the water supply path and the water flow switching valve provided in each of the water supply path and the branch portion of the bypass water passage (see Patent Document 4). Further, when it is reported that the mineral-functional water-making equipment is used, it is possible to produce mineral functional water (far-infrared-generated water) having a far-infrared function which produces a characteristic wavelength.

[Previous Technical Literature] [Patent Document]

[Patent Document 1] Japanese Patent Laid-Open No. 10-130915

[Patent Document 2] International Publication No. 2010/082677

[Patent Document 3] Japanese Patent No. 4817817

[Patent Document 4] Japanese Patent Laid-Open Publication No. 2011-56366

As mentioned above, although various mineral waters have been reported in the past, the effects of mineral water have not been scientifically proven. The true effect of mineral water is not yet fully defined. many. Therefore, in the past mineral-containing waters, there are many people who are not effective in performance, or who are effective but not practical enough or lacking in performance.

Even if the mineral functional water produced by the apparatus reported in Patent Document 4 is used, it cannot be said that the mineral functional water exhibiting the beneficial performance as the target can be surely produced. In particular, the type or blending ratio of the raw material (mineral imparting material) used in the mineral-containing water manufacturing equipment (A) and (B) is complicated, and if the mineral-based material is used, it is finally obtained. The mineral function water that can show how effective it is is not fully known.

In this case, an object of the present invention is to provide a mineral functional water having an effect of activating human body functions and an application thereof.

The inventors of the present invention used the mineral functional water producing equipment disclosed in Patent Document 2, and found the mineral functional water system manufactured under a specific condition as a result of an effort to study the type or blending ratio of the mineral imparting material. The present invention has been accomplished by having an effect of activating human body functions.

That is, the present invention relates to the following inventors.

<1> A mineral functional water characterized by electromagnetic wave radioactivity The mineral component has the function of activating the body's functions.

<2> Mineral water, such as <1>, which has a blood circulation improving effect.

<3> The mineral functional water according to <1> or <2>, wherein the mineral component emits a mineral component containing electromagnetic waves of a megahertz wave.

<4> The mineral functional water according to any one of <1> to <3>, wherein the spectral emissivity spectrum in the range of 4 μm to 24 μm measured at 25 ° C is a shape as shown in FIG. 12 .

<5> A composition for the activation of a body function, which comprises the mineral functional water of any one of <1> to <4>.

<6> A composition for activating a body function according to <5>, which is an external composition.

<7> A composition for activating a body function according to <5>, which is a cosmetic composition.

<8> A composition for activating a body function according to <5>, which is indirectly contacted with a person in a clothing, a bedding, or a medical fiber product.

<9> A functional fiber product comprising a fiber which immobilizes the mineral functional water of any one of <1> to <4>.

<10> A functional fibrous product such as <9>, which is a clothing material or a bedding type.

<11> A functional fibrous product such as <10>, which is a medical or sports clothing.

<12> A functional fibrous product according to <9>, which is a medical fiber product.

<13> A medical or sports appliance, wherein the mineral functional water of any one of <1> to <4> is immobilized.

<14> A method for producing a mineral functional water according to any one of <1> to <4>, which is characterized in that it is formed in the following step (1) The mineral water (A) and the mineral-containing water (B) formed in the step (2) described below are mixed in a ratio of 1:5 to 1:20 (weight ratio);

step 1):

The conductive wire coated with the insulator and the mineral-importing material (A) are immersed in water, and the mineral-imparting material (A) contains herbal materials composed of herbs of the compositae and plants of the genus Rosaceae, and a woody plant material composed of one or more woody plants of free maple, white birch, pine, and cedar, so that a direct current is conducted to the conductive wire, so that water around the conductive wire generates the same direction as the direct current. The water flow imparts ultrasonic vibration to the water to form a raw material mineral aqueous solution (A), and secondly, irradiates far infrared rays (wavelength 6 to 14 μm) to the raw mineral aqueous solution (A) to form mineral-containing water (A). Step

Step (2):

The inorganic mineral-imparting material (B) having different types of inorganic materials is filled in the first water-passing container in the first water-passing container to the sixth water-passing container connected in series. The material-imparting material (B1) contains a mixture of limestone, coral fossil, and shells of 70% by weight, 15% by weight, and 15% by weight, respectively. The mineral-imparting material (B2) in the second water-passing container includes a mixture of 40% by weight, 15% by weight, 40% by weight, and 5% by weight of each of limestone, coral fossil, shell, and activated carbon, and a third water-passing container. The mineral-imparting material (B3) in the present invention contains a mixture of 80% by weight, 15% by weight, and 5% by weight of each of limestone, coral fossil, and shell, and a mineral-imparting material (B4) in the fourth water-passing container. The mixture containing 90% by weight, 5% by weight, and 5% by weight of limestone, coral fossil, and shell, and the mineral-imparting material (B5) in the fifth water-passing container respectively contain limestone, coral fossil, and shell each having 80 weights. The mixture of %, 10% by weight, and 10% by weight, and the mineral-imparting material (B6) in the sixth water-passing container are a mixture of 60% by weight, 30% by weight, and 10% by weight of each of limestone, coral fossil, and shell. The six water-passing containers are passed through water to form a step of producing mineral-containing water (B) containing mineral water (B).

<15> The method for producing a mineral functional water according to <14>, wherein the amount of the mineral-imparting material (A) added to the water is 10 to 15% by weight, and the current value of the direct current which is electrically connected to the conductive wire And the voltage values are in the range of 0.05 to 0.1 A and 8000 to 8600 V, respectively.

<16> The method for producing mineral water, wherein the mineral material (A) is a herb material (A1) and a wood material (A2) as a herb material ( A1) with woody plants The mineral-providing material (A') obtained by mixing the weight ratio of the raw material (A2) to 1:5, and the herbaceous plant material (A1) as the raw material of the herb, the wild scorpion (leaf, stem, and flower part) ), wormwood (leaf and stem), oyster (leaf and stem) are mixed in a ratio of 10% by weight, 60% by weight, and 30% by weight, respectively, and dried to crush the compositae Dry pulverized material, and Japanese rose (leaf, flower), bayberry (leaf and stem), raspberry (leaf, stem, and flower) are 20% by weight, 10% by weight, 70, respectively The ratio of % by weight is mixed, and after drying, the dried pulverized material of the pulverized Rosaceae plant is mixed at a ratio of 1:1 (weight ratio); the woody plant material (A2) is used as the raw material of the aforementioned woody plant, and the maple tree is used. (deciduous), birch (deciduous, stem, and bark), fir (deciduous, stem, and bark) are mixed at a ratio of 20% by weight, 60% by weight, and 20% by weight, respectively, and dried. It is composed of pulverized dry pulverized material.

<17> A method for activating a body function, which comprises the step of bringing a mineral functional water such as <1> or a body function activating composition such as <5> directly or indirectly into contact with a human.

<18> Use of mineral functional water according to any one of <1> to <4> for the production of a composition for the activation of body functions.

<19> The mineral functional water according to any one of <1> to <4>, which is used as a composition for activation of body functions.

The mineral functional water of the present invention is suitable for the inventions <X1> and <X2> specified in the production method as described below. Still, invention The mineral functional water system of <X2> corresponds to the mineral functional water of Example 1 to be described later.

<X1> A mineral functional water which is a mineral-containing water (A) formed in the following step (1) and a mineral-containing water (B) formed in the following step (2) to become The ratio of 1:5 to 1:20 (weight ratio) is contained.

step 1):

The conductive wire coated with the insulator and the mineral-importing material (A) are immersed in water, and the mineral-imparting material (A) contains herbal materials composed of herbs of the compositae and plants of the genus Rosaceae, and a woody plant material composed of one or more woody plants of free maple, white birch, pine, and cedar, so that a direct current is conducted to the conductive wire, so that water around the conductive wire generates the same direction as the direct current. The water flow imparts ultrasonic vibration to the water to form a raw material mineral aqueous solution (A), and secondly, irradiates far infrared rays (wavelength 6 to 14 μm) to the raw mineral aqueous solution (A) to form mineral-containing water (A). The steps.

The amount of the mineral-imparting material (A) added to water is 10 to 15% by weight, and the current value and voltage value of the direct current which is electrically connected to the conductive wire are in the range of 0.05 to 0.1 A and 8000 to 8600 V, respectively. The mineral-importing material (A') is obtained by mixing the herbaceous plant material (A1) and the woody plant material (A2) in a weight ratio of the herbaceous plant material (A1) to the woody plant material (A2) of 1:5. The step of the mineral-imparting material (A'), the herbaceous plant material (A1) is used as the raw material of the herbaceous plant, and the wild cockroach (leaf, stem and flower), wormwood (leaf and stem) and anthocyanin (leaf and stem) are mixed in a ratio of 10% by weight, 60% by weight, and 30% by weight, respectively, and dried to pulverize the dried pulverized material of the comminuted plant And the ratio of Japanese rose (leaf, flower), bayberry (leaf and stem), raspberry (leaf, stem, and flower) to 20% by weight, 10% by weight, and 70% by weight, respectively. After mixing, the dried pulverized material of the pulverized Rosaceae plant is mixed at a ratio of 1:1 (weight ratio); the woody plant material (A2) is used as the raw material of the woody plant, and the maple tree (leaf part) ), birch (leaf, stem, and bark), cedar (leaf, stem, and bark) are mixed at a ratio of 20% by weight, 60% by weight, and 20% by weight, respectively, and dried. It is composed of pulverized dry pulverized material.

Step (2):

The inorganic mineral-imparting material (B) filled with different types of minerals is used in the first water-passing container from the first water-passing container connected to the sixth water-passing container connected in series, which is the mine in the first water-passing container. Each of the substance-imparting materials (B1) contains a mixture of limestone, coral fossil, and shells of 70% by weight, 15% by weight, and 15% by weight, and the mineral-importing material (B2) in the second water-passing container contains limestone, respectively. The mixture of 40% by weight, 15% by weight, 40% by weight, and 5% by weight of the coral fossil, shell, and activated carbon, and the mineral-giving material (B3) in the third water-passing container respectively contain limestone, coral fossil, and shell. a mixture of 80% by weight, 15% by weight, and 5% by weight, The mineral-imparting material (B4) in the fourth water-passing container includes a mixture of 90% by weight, 5% by weight, and 5% by weight of limestone, coral fossil, and shell, and a mineral-imparting material in the fifth water-passing container. (B5) includes a mixture of 80% by weight, 10% by weight, and 10% by weight of each of limestone, coral fossil, and shell, and a mineral imparting material (B6) in the sixth water-passing container contains limestone, coral fossil, and shell. Each of the mixture of 60% by weight, 30% by weight, and 10% by weight, and the six water-passing containers are passed through water to form a mineral-containing water (B) for producing mineral-containing water (B).

<X2> The mineral functional water according to the above <X1>, wherein a mixing ratio of the mineral-containing water (A) to the mineral-containing water (B) is 1:10 (weight ratio).

According to the present invention, there is provided an action-mineral functional water having an activity for activating a human body and an application thereof.

1‧‧‧Mineral functional water manufacturing equipment

2‧‧‧Mineral water (A) manufacturing equipment

3‧‧‧Mineral water (B) manufacturing equipment

10‧‧‧Methods for the production of raw materials and mineral aqueous solutions

11, W‧‧‧ water

12‧‧‧ Mineral Substance (A)

13‧‧‧Reaction container

13a‧‧‧ wall

14‧‧‧Insulator

15‧‧‧Flexible wire

16‧‧‧Ultrasonic generation means

17‧‧‧DC power supply unit

18a, 18b, 18c‧‧ ‧ cycle path

19‧‧‧Drainage

20, 23‧‧‧ opening adjustment valve

21, 25‧‧‧Drain valve

22‧‧‧ housing trough

24‧‧‧Drainage pipe

26‧‧‧Water temperature meter

29, 29a~29g, 29s, 29t‧‧‧ conductive cable

30‧‧‧ Terminal

31‧‧‧ storage container

31f‧‧‧ hook

40‧‧‧Processing container

41‧‧‧ Raw material mineral aqueous solution (A)

42‧‧‧Agitating blades

43‧‧‧ far infrared ray generation means

44‧‧‧ Mineral water (A)

45‧‧‧ Mineral water (B)

46‧‧‧ mixing tank

47‧‧‧Mineral functional water

51‧‧‧1st water container

52‧‧‧2nd water container

53‧‧‧3rd water container

54‧‧‧4th water container

55‧‧‧5th water container

56‧‧‧6th water container

51a~56a‧‧‧ Body Department

51b~56b‧‧‧ switch button

51c~56c‧‧‧Axis

51d~56d‧‧‧ cover

51f~56f‧‧‧Rim

51m~56m‧‧‧ Mineral Substance (B)

51p~56p‧‧‧迂回水道

51v~56v‧‧‧Water flow switching valve

57, 57x, 57y‧‧‧ water supply path

57a‧‧‧ Inlet

57b‧‧‧Water outlet

57c‧‧‧Filter

57d‧‧‧Automatic air valve

58‧‧‧Operation panel

59‧‧‧Signal cable

60‧‧‧ bracket

61‧‧‧ casters

62‧‧‧Level adjuster

63‧‧‧ original sink

DC‧‧‧ DC current

DW‧‧‧ tap water

R‧‧‧Water flow

Fig. 1 is a block diagram showing a schematic configuration of a mineral functional water producing facility.

[Fig. 2] is a mineral water functional manufacturing facility shown in Fig. 1. A schematic view of a method for producing a mineral-containing aqueous solution of a part of a mineral-containing water (A) manufacturing apparatus.

Fig. 3 is a partially omitted cross-sectional view taken along line A-A of Fig. 2 .

Fig. 4 is a side view showing a storage container using the mineral-imparting material (A) of the raw material mineral aqueous solution production means shown in Fig. 2 .

Fig. 5 is a schematic view showing a state of reaction in the vicinity of a conductive wire of the raw material mineral aqueous solution production means shown in Fig. 2.

Fig. 6 is a schematic cross-sectional view showing a far-infrared ray irradiation apparatus which is a part of a mineral-containing water (A) manufacturing apparatus which constitutes the mineral-functional water-making apparatus shown in Fig. 1 .

Fig. 7 is a block diagram showing a device for producing mineral-containing water (B) constituting the mineral functional water producing apparatus shown in Fig. 1.

Fig. 8 is a front elevational view showing the apparatus for producing mineral-containing water (B) constituting the mineral-functional water producing apparatus shown in Fig. 1.

Fig. 9 is a side view showing the apparatus for producing mineral-containing water (B) shown in Fig. 8.

FIG. 10 is a side view showing a part of the configuration of the apparatus (B) for containing mineral water shown in FIG.

Fig. 11 is a side view showing a water-passing container constituting the apparatus (B) for containing mineral water shown in Fig. 8.

[Fig. 12] The spectroscopic emissivity spectrum of the sample in which 20 parts by weight of the mineral functional water of Example 1 was immobilized, and the spectroradiance spectrum of the black body (theoretical value) (measured temperature: 25) with respect to 100 parts by weight of the ceramic carrier. °C, wavelength range: 4~24μm, carrier: ceramic powder).

In the following, the present invention is described in detail with reference to the accompanying drawings, and the present invention is not limited to the following examples, and the invention may be arbitrarily modified without departing from the scope of the invention. In addition, in this specification, the "~" is used as a performance including the numerical value or physical quantity before and after.

<1. Mineral functional water of the present invention>

The mineral functional water of the present invention is a mineral functional water characterized by a mineral component containing electromagnetic wave radioactivity, which has an effect of activating human body functions. In addition, the raw material and manufacturing conditions of the mineral functional water of the present invention are described later in <3. The method for producing mineral functional water of the present invention>. In addition, as a suitable example of the mineral functional water of the present invention, a mineral functional water A20ACA-717 which is equivalent to the first embodiment described later, and is made by Riken Techno System Co., Ltd. is listed.

In the present specification, the term "mineral functional water" means a substance containing a mineral component and exhibiting at least one or more effective potency. In addition, in the present specification, the term "mineral-containing water" means that the raw material water in the preceding stage and the mineral-containing water also contain a mineral component in the production of mineral functional water. In detail, the method for producing mineral functional water of the present invention will be described later. Still, mineral water may or may not have effective efficacy for itself.

In addition, in this specification, "mineral composition" does not mean that the narrow definition of minerals excludes "inorganic components (including trace elements) of "four elements (carbon, hydrogen, nitrogen, oxygen)", but coexist In the aspect, it may include the aforementioned four elements (carbon, hydrogen, nitrogen, oxygen) excluded in a narrow definition. Therefore, for example, "plant-derived mineral component" also includes a concept of a plant-derived inorganic component together with an inorganic component derived from a plant such as calcium.

In addition, examples of the inorganic component (constituting the mineral component) include sodium, potassium, calcium, magnesium, and phosphorus, and examples of the trace elements include iron, zinc, copper, manganese, iodine, selenium, chromium, and molybdenum. It is not limited to this.

Hereinafter, the mineral functional water of the present invention will be described in further detail.

The mineral functional water system of the present invention has an effect of activating human body functions. In addition, in this specification, "the effect of activating a person's body function" is synonymous with "body function activity".

Specific examples of the functional activity of the body include blood circulation improvement, relaxation of the nervous system, promotion of metabolism, reduction of muscle fatigue or muscle pain, neck stiffness, edema, and chilling relaxation. The mineral functional water of the present invention has one of the advantages of blood circulation improving effect. Therefore, it is expected that the improvement in blood circulation or the synergy with blood circulation improvement can be expected to be manifested in the improvement of various body functions described above.

Further, the warming action of the mineral component contained in the mineral functional water derived from the present invention is also an effective advantage. For example, the fiber product from which the mineral component derived from the mineral functional water of the present invention is immobilized exhibits more excellent warming characteristics than when the heater is heated without being fixed. The details are illustrated in the examples.

The reason why the mineral functional water of the present invention has an effect on the function of the body function or the warming effect is not known, but it is presumed to be related to the mineral component of the electromagnetic wave radioactivity.

The mineral component contained in the mineral functional water of the present invention is regarded as a mineral component that emits electromagnetic waves including megahertz waves. The term "megahertz wave" refers to an electromagnetic wave having a wavelength of 6 to 14 μm. The megahertz wave system is also required for the cultivation of plants in the sun's rays or for the health maintenance of animals. It can also be said to be electromagnetic waves of active light. In other words, it can be said that a living body (including cells) maintains life activities by absorbing and radiating megahertz waves suitable for various wavelengths.

The mineral functional water of the present invention is presumed to emit a megahertz wave, and is absorbed by the living tissue by the megahertz wave, and the possibility of activation of the body function is high.

The details of the megahertz effect of mineral functional water have not been fully understood so far, but it is speculated that by absorbing the mutual movement of the amino acids constituting the protein, the steric structure is restored and the expansion of the peripheral blood vessels is The blood flow is smoothed, and the blood circulation is improved to relax the distal and central nerves. This is related to the recovery of aging substances such as lactic acid accumulated in the muscles, and the regeneration of liver and sugar by the liver, which is related to the improvement of fatigue and the improvement of stamina, and the relaxation of nerves by blood circulation, and the mental concentration and correctness can be expected. Improvement in motor function.

Further, the mineral-functional water-activated cells of the present invention activate the SOD enzyme and the like, and enhance the action of the oxidative action (antioxidation) of the active oxygen which suppresses the source of fatigue, and thereby, it is expected to be formed without oxidation. The healthy body of strength.

Further, since the spectral emissivity of the liquid sample is difficult to directly measure, it is usually measured by being fixed to a reference carrier. The spectral emissivity spectrum of the mineral functional water of the present invention is measured by being immobilized on a ceramic powder for carrying mineral water.

Specifically, a suitable aspect of the mineral functional water of the present invention shown in the examples is a sample in which 20 parts by weight of the mineral functional water is immobilized with respect to 100 parts by weight of the ceramic carrier, at a wavelength of 4 μm to 24 μm. The range photoluminescence spectrum (measurement temperature: 25 ° C) shows a specific shape (shape shown in Fig. 12). The details are described later in the embodiment.

In the present specification, the term "radiation rate" refers to the ratio of the radiation divergence of the radiator to the radiation divergence of the black body at the same temperature as the radiator (JIS Z 8117). The "radiation emissivity" is displayed. The ratio of the radiation of the sample at the radioactivity of the black body at this temperature is set to 100%. The evaluated samples have a unique spectral emissivity spectrum. In addition, the so-called "black body" refers to an object that absorbs 100% of incident light and is the most capable of radiating energy. In theory, there is no such thing as a radioactivity that shows greater power than a black body.

The measurement method of the spectroradiance spectrum is defined by JIS R 180, and may be configured by a device according to JIS R 180, and measured by an emissivity measuring system using Fourier transform infrared spectrophotometry (FTIR). As an emissivity measuring system, a far infrared radiance measuring apparatus (JIR-E500) manufactured by Nippon Denshi Co., Ltd. is exemplified as an example.

The above-mentioned mineral functional water of the present invention is directed to expressing the body The reason for the functional activity or the warming effect is only presumed at the present time point, and even if it is found to be a mechanism different from the above, the useful performance of the mineral functional water in the present invention should not be construed restrictively. . Further, in the mineral functional water of the present invention, there is a possibility of having a plurality of different useful effects, and there is a possibility that different performance mechanisms are also applied to individual effects.

The above-mentioned presumption mechanism is only presumed at the current time point, and even if it is found to be a mechanism different from the above, the useful performance of the mineral functional water in the present invention should not be construed restrictively. Further, in the mineral functional water of the present invention, there is a possibility of having a plurality of different useful effects, and there is a possibility that different performance mechanisms are also applied to individual effects.

(other ingredients)

The mineral functional water of the present invention can be diluted with a suitable solvent for dilution (water or alcohol, etc.) insofar as it does not impair the object of the present invention.

The mineral functional water of the present invention may contain any component insofar as it does not impair its performance. The additive which does not impair the object of the present invention is not particularly limited as long as it is an optional component, and examples thereof include a known suspending agent, an emulsion, and the like. Further, the mixing ratio may be any range that does not impair the purpose of the invention of the present invention.

<2. Application of mineral functional water>

The body activation action of the mineral functional water resulting from the present invention is as described above by specific electromagnetic wave radiation. Therefore, not only the mineral functional water of the present invention is directly in contact with human skin, but also if not The physical activation of the mineral functional water caused by the present invention can be obtained by direct contact with the electromagnetic wave effective communication range to the person (i.e., indirect contact).

Hereinafter, a suitable method and an application product using the mineral functional water of the present invention will be described, but the use of the mineral functional water of the present invention is not limited thereto. Further, although the object of the present invention is mainly human, it is also applicable to animals other than humans as long as the effects can be exerted.

(2-1. Body function activation method)

One of the application uses of the mineral functional water of the present invention is a body function activation method comprising the mineral functional water of the present invention or the body function activating composition (described later) of the present invention, either directly or The step of indirect contact with people. In the body function activation method of the present invention, the "body function activation" is the same as the above, and the description is omitted. Further, the body function activation method of the present invention includes both medical purposes and non-medical purposes. In addition, the amount of use of the mineral functional water of the present invention may be appropriately selected in addition to the purpose of use, the form of use, individual differences (age, sex, etc.) of the subject, and other appropriate effects of the body function activity.

(2-2. Composition for activation of body function)

The body function activating composition of the present invention contains the above-described mineral functional water of the present invention, and may contain any component other than the mineral functional water if necessary. Further, the body function activating composition of the present invention It also contains the concept of a mineral-only functional water that does not contain any constituents.

As a suitable use of the composition for activation of a body function of the present invention, an external composition or a composition for cosmetics can be mentioned.

(external composition)

The external preparation composition of the present invention contains one aspect of the body functional activation composition of the mineral functional water of the present invention. Further, the composition for external use of the present invention includes not only pharmaceuticals but also the concept of Quasi medicine.

The form of the composition for external use of the present invention is not particularly limited, but is generally liquid, cream or gel when used as a form applied to the skin. Moreover, it can also be used as a form of a patch. Moreover, when it is used as a composition for external use, it is also suitable for a spray type. In particular, sports such as sports can be applied directly to the skin or coated on the clothes before and after exercise to improve the body function and promote exercise endurance and fatigue recovery.

The external preparation composition of the present invention can be directly used as the mineral functional water constituting the mineral functional water of the present invention, or can be used by diluting with a solvent such as water or alcohol. Further, if necessary, it may contain any components such as an oil component, a solubilizer, a moisturizer, a coloring matter, an emulsifier, and a fragrance which are formulated in pharmaceuticals and quasi-drugs.

In addition, since it is usually sweating after exercise, it is possible to apply a topical composition for application to the skin in such a manner that the mineral-functional water of the spray type is improved in adhesion to the skin. Well-known adhesion Lifting agent, film forming agent.

The blending amount of the mineral functional water of the present invention of the external preparation composition of the present invention is appropriately selected within the range in which the body activation effect is exhibited. In addition, the composition of the external preparation of the present invention may contain any component such as an oily component, a solubilizing agent, a moisturizing agent or the like which is usually formulated in a pharmaceutical or quasi-drug, as long as it does not impair the effects of the present invention. .

Further, in the treatment of various patients, the external preparation composition of the present invention may contain, as an active ingredient of other medicines, in addition to the above-mentioned active ingredients, if necessary.

(cosmetic composition)

The cosmetic composition of the present invention contains one aspect of the body functional activation composition of the mineral functional water of the present invention. Further, the cosmetic composition of the present invention may be used in the form of a body care product for protecting and washing the skin, such as a body wash or a shampoo or a soap, in addition to a cosmetic such as a general cosmetic use.

The blending amount of the mineral functional water of the present invention for the cosmetic composition of the present invention is appropriately selected within the range in which the body activation effect is exhibited. In the cosmetic composition, a conventional cosmetic substrate can be appropriately formulated to be a desired dosage form. This form is not particularly limited, and examples thereof include a gel, an emulsion, and a cream. Moreover, the cosmetic composition of the present invention can be usually added to any component used in cosmetics without departing from the effects of the present invention.

Further, as described above, the body of the mineral water of the present invention The body activation action is effective not only by direct contact with a person but also by indirect contact with clothes or the like due to electromagnetic waves caused by mineral components contained in the radiation.

Therefore, as one aspect of the body function activating composition of the present invention, it is also included to provide clothing, bedding, or medical fiber products in indirect contact with humans.

(2-3) Functional fiber products

The functional fiber product of the present invention is characterized by containing a fiber which fixes the mineral functional water of the present invention described above. By immobilizing the mineral functional water of the present invention, it is possible to obtain a functional fiber product which is caused by the functional water of the present invention and which has electromagnetic wave irradiation properties.

Therefore, the functional fiber product containing the fiber of the mineral functional water of the present invention can be obtained by wearing it, and the body activation action of the mineral functional water caused by the present invention can be obtained.

The type of the fiber to be used is not particularly limited as long as the mineral functional water of the present invention can be immobilized, and both natural fibers and synthetic fibers can be used.

It is not limited to a functional fiber product including a fiber in which the mineral functional water of the present invention is immobilized, for example, a clothing such as a shirt or a trousers, a bedding such as a bedding, a pillow, a blanket, a curtain, a towel, or the like, which is used daily. Fiber products and the like are targeted.

The functional fiber product of the present invention is preferably a clothing or bedding type in view of daily contact with the body.

Moreover, the functional fiber product of the present invention is suitable for medical or sports clothing from the viewpoint of effectively utilizing the body activation action.

In the present invention, the term "medical clothes" means a type I of a medical device prescribed by the Pharmaceutical Affairs Law as a general medical device. In addition, "sports materials" means clothes that are used in sports (including the concept of all body movements). In addition, the type of "sports" is not particularly limited, and examples thereof include baseball, soccer, and the like, athletics, cycling, running, walking, and the like.

The aspect of the medical or sports clothing is not particularly limited, and examples thereof include a foot protector, a swimsuit, a sports tights, a tights, and a body suit.

Further, the functional fiber product of the present invention is also suitable as a medical fiber product from the viewpoint of effectively utilizing the body activation action. Examples of the medical fiber product include a bandage, a gemstone, a gauze, a medical tape, and the like, but are not limited thereto.

In addition, the method of immobilizing the mineral functional water of the functional fiber product of the present invention is not particularly limited, and examples thereof include a method of impregnating or coating a mineral functional water in a fiber product or the like, and drying the method. Further, in the case of a medical fiber product such as a bag or a gauze, the mineral functional water of the present invention to which the fiber product is applied is not completely dried and used as a wet state.

(2-4) Other uses

The mineral functional water of the present invention can also be immobilized for use as a medical or sports appliance.

The type of medical or sports equipment is not limited. For example, a sports equipment includes a baseball bat, a racket, a snowboard, a gym weight training device, and the like.

There is no limitation on the method of fixing the mineral functional water of the device, and a method of applying it to a surface or the like, drying it, or blending it with a constituent member may be mentioned. Further, the functional fiber product of the present invention described above may be used as a member.

Further, the mineral functional water system of the present invention is fixed to this, and may be applied to an ornament which is in contact with the body other than the above. For example, it is also suitable for use in a frame or a nose pad arm of a pair of glasses, a frame or belt of a watch and a buckle, a wrist band, a pierce, an earring, a necklace, and the like. There is no limitation on the method of fixing the mineral functional water, and the method of applying it to a surface or the like, drying it, or blending it with a constituent member, etc.

<3. Method for producing mineral functional water>

The mineral functional water (hereinafter sometimes referred to as "mineral functional water of the present invention") containing a mineral component having electromagnetic radiation is not particularly limited, but the above-mentioned Patent Document 2 (Japanese Patent Laid-Open No. 2011) is suitable. The apparatus disclosed in Japanese Laid-Open Patent Publication No. Hei-56366 can be manufactured by the method of the method disclosed in the literature.

In addition to the production method of the manufacturing apparatus, if the mineral functional water containing the mineral component having electromagnetic radiation is obtained, the production method is not limited.

In the following, an embodiment suitable for the method for producing mineral functional water of the present invention will be described with reference to the drawings, using an apparatus disclosed in Patent Document 2 (JP-A-2011-56366).

As shown in Fig. 1, the mineral functional water producing apparatus 1 includes a mineral water (A) manufacturing apparatus 2, a mineral water (B) manufacturing apparatus 3, and a mixing tank 46, which is mixed. The mineral-containing water (B) 45 produced by the mineral-containing water (B) manufacturing apparatus 3 is contained in the mineral-containing water (A) 44 produced by the mineral-containing water (A) manufacturing apparatus 2 to form mineral-functional water. 47 means of mixing.

The mineral water (A) manufacturing apparatus 2 includes a raw material mineral aqueous solution manufacturing means 10 and a far infrared ray generating means 43, which is a water supply material 11 supplied from a water channel and a mineral imparting material which will be described later. (A) 12 (refer to FIG. 4) means for forming a raw material mineral aqueous solution (A) 41 as a raw material, and the far infrared ray generating means 43 is irradiated with the raw material mineral aqueous solution (A) 41 obtained by the raw material mineral aqueous solution manufacturing means 10. Far infrared rays, which means that they change in mineral water (A) 44.

The mineral water-containing (B) manufacturing apparatus 3 has a mineral-containing water (B) containing a mineral component eluted from the mineral-imparting material by passing the water W supplied from the outside through the water-passing containers 51 to 56. ) 45 function.

Hereinafter, the mineral-containing water (A) manufacturing apparatus 2 and the mineral-containing water (B) manufacturing apparatus 3 will be described in detail.

(3-1: Mineral-containing water (A) manufacturing device)

Next, the mineral-containing water (A) manufacturing apparatus 2 constituting the mineral functional water producing apparatus 1 shown in Fig. 1 will be described with reference to Figs. 2 to 6 . As shown in Fig. 1, the mineral-containing water (A) manufacturing apparatus 2 includes a raw material mineral aqueous solution producing means 10 (see Fig. 2) and a far-infrared generating means 43 (see Fig. 6), and the raw mineral aqueous solution manufacturing means 10 The raw material mineral aqueous solution (A) 41 is formed by using the water 11 supplied from the water channel and the mineral-importing material (A) 12 (see FIG. 4) to be described later as a raw material, and the far-infrared generating means 43 is used for the raw material ore. The mineral-containing aqueous solution (A) 41 obtained by the aqueous solution production method 10 irradiates far infrared rays to change the mineral-containing water (A) 44.

As shown in FIGS. 2 and 3, the raw material mineral aqueous solution manufacturing apparatus 10 includes a reaction container 13, a conductive wire 15, an ultrasonic wave generating means 16, a DC power supply device 17, and circulation paths 18a and 18b, and a circulation pump P. 13 is a reaction container for accommodating the water 11 and the mineral-importing material (A) 12, and the conductive wire 15 is immersed in the conductive line of the water 11 in the reaction container 13 in a state where the insulator 14 is covered, and the ultrasonic generating means 16 is used. An ultrasonic generating means for imparting ultrasonic vibration to the water 11 in the reaction vessel 13, the DC power supply unit 17 is configured to conduct a direct current power source DC to the DC power supply unit of the conductive line 15, and the circulation paths 18a and 18b and the circulation pump P are connected to each other. The water 11 around the conductive line 15 is made to be the same as the direct current DC The means of water flow R in the direction. The DC power supply unit 17, the ultrasonic generating means 16 and the circulation pump P are all operated by power supply from a general commercial power source.

The reaction container 13 has an inverted conical tubular shape with an upper opening, and a drain port 19 is provided in the bottom portion of the apex. The drain port 19 is connected to a circulation path 18a that communicates with the suction port P1 of the circulation pump P. An opening degree adjusting valve 20 for adjusting the amount of displacement to the circulation path 18a and a drain valve 21 for discharging water or the like in the reaction vessel 13 are provided directly below.

The discharge port P2 of the circulation pump P is connected to the base end portion of the circulation path 18b, and the tip end portion of the circulation path 18b is connected to the accommodation groove 22. A proximal end portion of the circulation path 18c for feeding the water 11 in the storage tub 22 into the reaction container 13 is connected in the vicinity of the bottom of the outer periphery of the housing groove 22, and the tip end portion of the circulation path 18c is connected to the reaction container. The position of the opening of the 13th. In the circulation path 18c, an opening degree adjustment valve 23 for adjusting the amount of water fed from the storage tank 22 to the reaction container 13 is provided.

In the bottom of the storage tub 22, the drain pipe 24 having the drain valve 25 and the water temperature gauge 26 is connected in a hanging shape. When it is necessary to open the drain valve 25, the water in the storage tub 22 can be discharged from the lower end portion of the drain pipe 24. At this time, the temperature of the water 11 passing through the drain pipe 24 can be measured by the water temperature meter 26.

As shown in FIG. 5, the conductive wires 15 and the plurality of conductive cables 29 (29a to 29g) including the insulator 14 are wired in a ring shape so as to be in a plurality of positions in the reaction container 13 having different depths. The annular conductive cables 29a-29g are all matched with the reaction container 13. Placed on a slightly coaxial. The inner diameters of the individual conductive cables 29a to 29g are matched with the inner diameter of the inverted cone-shaped reaction container 13, and the inner diameter of the reaction container 13 is gradually reduced to correspond to the inner diameter of the individual arrangement place. Since each of the conductive cables 29a to 29g is detachably connected to the insulating terminal 30 provided in the wall body 13a of the reaction container 13, the annular portion can be taken out or attached from the terminal 30 if necessary.

A bottomed cylindrical storage container 31 formed of an insulating mesh body is disposed in a portion corresponding to the axial center of the reaction container 13, and the mineral storage material (A) 12 is filled in the storage container 31. The storage container 31 is detachably attached to the upper edge portion of the wall body 13a of the reaction container 13 by a hook 31f provided at an upper portion thereof.

As shown in Fig. 2, the conductive cables 29s and 29t are spirally wound around the outer circumferences of the circulation paths 18a and 18b, and DC current DC is supplied from the DC power supply unit 17 to the conductive cables 29s and 29t. The direction of the direct current DC flowing through the conductive cables 29s and 29t is set so as to slightly coincide with the direction of the water flow in the flow circulation paths 18a and 18b.

In the raw material mineral aqueous solution manufacturing apparatus 10, a specific amount of water 11 is placed in the reaction container 13 and the storage tank 22, and the storage container 31 filled with the mineral-imparting material (A) 12 is set in the center of the reaction container 13, The circulation pump P is started, and the opening degree regulating valve 20 at the bottom of the reaction vessel 13 and the opening degree regulating valve 23 of the circulation path 18c are adjusted to pass from the reaction vessel 13 through the drain port 19, the circulation path 18a, the circulation pump P, and the circulation path 18b. , the storage tank 22 and the circulation path 18c, return to the reaction volume again The upper portion of the device 13 circulates the water 11. When the DC power source device 17 and the ultrasonic wave generating means 16 are activated, the elution reaction of the mineral component from the mineral material (A) 12 in the storage container 31 to the mineral component of the water 11 is started.

The raw material mineral aqueous solution manufacturing method 10 is used, and the working conditions in the production of the raw material mineral aqueous solution (A) are not particularly limited. However, in the present embodiment, the raw material mineral aqueous solution (A) is produced under the following working conditions.

(1) In the conductive cables 29, 29s, and 29t, a direct current DC of a voltage of 8000 to 8600 V and a current of 0.05 to 0.1 A is turned on. Further, the insulator 14 constituting the conductive cable 29 or the like is formed of a polytetrafluoroethylene resin.

(2) The mineral-imparting material (A) 12 filled in the reaction container 13 is filled with a mass ratio of 10 to 15% with respect to the water 11 system. The specific description of the mineral-imparting material (A) 12 will be described later.

(3) The water 11 may be an electrolyte containing a DC current DC. For example, it is possible to use sodium carbonate which dissolves about 10 g of electrolyte with respect to 100 liters of water, but it can be used as it is groundwater.

(4) The ultrasonic generating means 16 is a supersonic wave having a frequency of 30 to 100 kHz, and the ultrasonic vibration portion (not shown) is arranged to vibrate in direct contact with the water 11 in the reaction container 13 to arrange ultrasonic generation. Means 16.

When the raw material mineral aqueous solution manufacturing means 10 is operated under such conditions, it is generated in the reaction vessel 13 while rotating in the left-hand direction. The water flow R sucked into the water discharge port 19 and the water 11 discharged from the water discharge port 19 continue to return to the inside of the reaction container 13 via the above-described circulation paths 18a and 18b.

According to this, by the stirring action of the water flow R, the action of the direct current flowing through the conductive cable 29 and the ultrasonic generating means 16 by the ultrasonic vibration imparted to the water 11, the mineral component from the mineral imparting material (A) 12 is rapidly formed. Dissolved in the water 11, it is possible to efficiently produce a raw material mineral aqueous solution (A) which is appropriately dissolved in a necessary mineral component.

In the raw material mineral aqueous solution manufacturing means 10, the plurality of conductive cables 29a to 29g which are in the form of a ring are slightly coaxially wired in the reaction container 13, and a water flow R which rotates in the left-hand direction is generated in the reaction container 13. According to this, a field of electrical energy in a relatively compact state can be formed in the reaction container 13 having a constant volume, and the raw material mineral aqueous solution (A) can be efficiently produced in the reaction container 13 having a relatively small volume.

Further, since the reaction container 13 has an inverted conical tubular shape and along the plurality of conductive cables 29a to 29g which are annular, the flow R can be relatively easily and stably generated, and the elution of the mineral component can be promoted. Further, the flow R of the inside of the reaction vessel 13 which flows in the inverted conical shape increases the flow rate with the drain port 19 facing the bottom of the reaction vessel 13, and also increases the contact frequency with the mineral-imparting material (A) 12, and captures The free electrons e present in the water 11 can increase the quality of the ionized mineral.

Further, since the stored water 11 is between the circulation paths 18b and 18c and the discharge storage tank 22 is provided, the water 11 exceeding the volume of the reaction container 13 can be circulated and subjected to a mineral elution reaction. Therefore, the raw material mineral aqueous solution (A) can be efficiently produced in large quantities.

The circulation pump P is continuously operated, and when these reactions are continued, the raw material mineral aqueous solution (A) in which the mineral component is dissolved is finally produced. The size of the drain port 19 at the bottom of the reaction vessel 13, the amount of circulating water, the shape of the reaction vessel 13 (especially the angle γ between the axis C and the wall 13a shown in Fig. 2), etc., can be controlled in the water 11 In the presence of the free electrons e, the mineral-donating material (A) 12 acts on the water solubility of the mineral components by giving the action of the free electrons e.

Once the raw material mineral aqueous solution (A) is formed, the raw material mineral aqueous solution (A) 41 is moved into the processing container 40 shown in Fig. 6. In this case, in the reaction container 13, the residue of the mineral-imparting material (A) 12 leaking from the storage container 31 can be discharged from the drain valve 21 provided at the bottom of the reaction container 13. The raw material mineral aqueous solution (A) 41 accommodated in the processing container 40 is slowly stirred by the stirring blade 42, and the far infrared ray is irradiated by the far infrared ray generating means 43 disposed inside the processing container 40.

In addition, the far-infrared ray generating means 43 may be a far-infrared ray having a wavelength of about 6 to 14 μm, and may be a heating method regardless of the material or the means for generating the material. However, at 25 ° C, it is desirable to have a radiation ratio of 85% or more with respect to black body radiation in a wavelength region of 6 to 14 μm.

In the raw material mineral aqueous solution manufacturing apparatus 10 shown in Fig. 2, the stirring action by the water flow R, the action of the direct current DC flowing through the conductive wire 15, and the ultrasonic vibration, the mineral-containing material (A) 12 is included. The mineral component dissolves quickly in the water 11, which is efficient A mineral aqueous solution 41 which is moderately dissolved into a necessary mineral component is produced.

Further, in the far-infrared ray generating means 43 shown in Fig. 6, by irradiating the mineral aqueous solution 41 with far-infrared rays, the dissolved mineral component and the water molecules are fused to form the mineral-containing water (A) 44 having a high degree of negative electrical conductivity.

In the mineral-containing water (A) manufacturing apparatus 2, the mineral-containing water (A) 44 formed by the above-described steps is fed to the mixing tank 46 via the water supply path 57y as shown in Fig. 1, and is mixed in the mixing tank 46. It is mixed with the mineral-containing water (B) 45 fed from the mineral-containing water (B) manufacturing apparatus 3.

Hereinafter, the mineral-imparting material (A) will be described.

The mineral-improving material (A) contains a herbaceous plant material composed of a herbaceous plant of the family Asteraceae and a herbaceous plant of the family Rosaceae, and a woody plant selected from the group consisting of maple, white birch, pine, and cedar. Woody plant material.

In addition to herbaceous plants other than Compositae and Rosaceae, other herbs may be included, but herbaceous plants of only Compositae and Rosaceae are preferred.

As a suitable herbaceous plant of the genus Compositae, there may be mentioned Phyllostachys pubescens, wormwood, and wild pheasant. Further, examples of suitable Rosaceae herbs include Japanese rose, bayberry, snakeberry, shellac, and raspberry. In the herbaceous plant, the site where the mineral component is easily eluted, such as a leaf portion, a stem portion, or a flower portion, can be used as it is, but it can also be used as a dried product.

Further, the types of woody plants include maple, birch, pine or cedar. In woody plants, the parts used are appropriate leaves and stems. The part which is easy to dissolve mineral components, such as a part and a bark part, can be used as it is, but it can also be used as a dry substance.

As a suitable mineral-imparting material (A), the weight ratio of the herbaceous plant material (A1) and the woody plant material (A2) to the herbaceous plant material (A1) and the woody plant material (A2) is 1: The mineral-providing material (A') obtained by mixing the method of 5, the herbaceous plant material (A1) is used as the raw material of the herbaceous plant, and the wild cockroach (leaf, stem, and flower), wormwood (leaf and stem)蕗), 蕗 蕗 (leaf and stem) are mixed in a ratio of 10% by weight, 60% by weight, and 30% by weight, respectively, and dried to pulverize the dried pulverized material of the compositae, and the Japanese rose (leaf, flower), bayberry (leaf and stem), raspberry (leaf, stem, and flower), mixed at a ratio of 20% by weight, 10% by weight, and 70% by weight, respectively. After drying, the dried pulverized material of the pulverized Rosaceae plant is mixed at a ratio of 1:1 (weight ratio); the woody plant material (A2) is used as the raw material of the woody plant, which is a maple tree (leaf part) and white birch ( Leaves, stems, and bark parts, and cedar (leaf, stem, and bark) are mixed at a ratio of 20% by weight, 60% by weight, and 20% by weight, respectively, and dried. Pulverizing the dried product was pulverized constituted.

As a raw material for the herb (A1), it is suitable for use as "P-101 (product number)" manufactured by Riken Techno System Co., Ltd., and as a woody plant material (A2), it is suitable for use by Riken Techno System Co., Ltd. P-201 (item number).

(3-2: Mineral water (B) manufacturing equipment)

Next, the structure, function, and the like of the mineral-containing water (B) manufacturing apparatus 3 will be described with reference to Figs. 1 and 7 .

As shown in Fig. 1 and Fig. 7, the mineral water-containing (B) manufacturing apparatus 3 includes a first water-passing container 51 to a sixth water-passing container 56 that are filled with mineral-specific materials (B) of different types and The water supply path 57 that connects the first water-passing container 51 to the sixth water-passing container 56 in series is connected to the water return path 51p of the water supply path 57 in a state of being juxtaposed with the first water-passing container 51 to the sixth water-passing container 56, respectively. 56p and water flow switching valves 51v to 56v which are respectively provided in the branch portions of the respective water return passages 51p to 56p and the water supply path 57.

The switching operation of the water flow switching valves 51v to 56v can be performed by operating the six switch buttons 51b to 56b provided on the operation panel 58 connected to the water flow rate switching valves 51v to 56v via the signal cable 59. Since the six switch buttons 51b to 56b are numbered corresponding to the six water flow switching valves 51v to 56v, if any one of the switch buttons 51b to 56b is operated, the water flow switching valves 51v to 56v corresponding to the corresponding numbers can be switched. Flow direction.

Here, the mineral-imparting material (B) 51 m to 56 m can be suitably produced by mixing limestone, coral fossils, and shells as raw materials for the base.

First, analyze the components contained in limestone, coral fossils, and shells, and evaluate the amounts of cerium oxide, iron oxide, activated carbon, titanium nitride, calcium carbonate, magnesium carbonate, and calcium phosphate, respectively. And based on the content of each component, mixing Limestone, coral fossils, shells, minerals-giving material (B) 51m~56m.

In addition, the mineral-based material (B) 51m to 56m is expected to contain the components contained in the mixture ratio of limestone, coral fossil, and shell, but the limestone, coral fossil, and shell which are raw materials are caused by the place of origin. If the content of the component is insufficient, additional cerium oxide, iron oxide, activated carbon, titanium nitride, calcium carbonate, magnesium carbonate or calcium phosphate may be added if necessary. In particular, since activated carbon is hardly contained in limestone, coral fossils, and shells, it is usually added in other ways.

The mineral-importing material (B) is 51 m to 56 m, and the mineral-imparting material (B1) in the first water-passing container 51 contains 70% by weight, 15% by weight, and 15% by weight of limestone, coral fossil, and shell, respectively. The mixture of % and the mineral-imparting material (B2) in the second water-passing container 52 respectively contain a mixture of 40% by weight, 15% by weight, 40% by weight, and 5% by weight of each of limestone, coral fossil, shell, and activated carbon. The mineral-imparting material (B3) in the third water-passing container 53 contains a mixture of 80% by weight, 15% by weight, and 5% by weight of each of the limestone, the coral fossil, and the shell, and the mineral in the fourth water-passing container 54. Each of the imparting materials (B4) contains a mixture of limestone, coral fossil, and shells of 90% by weight, 5% by weight, and 5% by weight, and the mineral-importing material (B5) in the fifth water-passing container 55 contains limestone, respectively. Coral fossils and shells are 80% by weight and 10% by weight, respectively. 10% by weight of the mixture, and the mineral-imparting material (B6) in the sixth water-passing container 56 contains a mixture of 60% by weight, 30% by weight, and 10% by weight of each of limestone, coral fossil, and shell, and minerals. When water (A) is mixed, it exhibits excellent control action to obtain mineral-containing water (B).

In particular, the limestone, coral fossil, and shell used in the mineral-imparting materials (B1) to (B6) are preferably the following (1-1) to (1-3).

(1-1) Limestone:

Grinding a small stone of about 3 cm of limestone mixed in a volcanic deposit containing the following components

Calcium carbonate: 50% by weight or more

Iron oxide: 3~9% by weight of iron

Total of titanium oxide, titanium carbide, and titanium nitride: 0.8% by weight or more

Magnesium carbonate: 7~10% by weight

As such a limestone, it is suitable to use the Riken Techno System. Co., Ltd. "CC-200 (item number)".

(1-2) Coral fossils:

The following two types of coral fossils are mixed in a weight ratio of 1:9 and pulverized into granules of 3 to 5 mm.

A coral fossil produced from approximately 100 meters underground and composed of heavy pressure modified crystals.

Coral fossils (including calcium or calcium phosphate other trace elements) produced from the land near Okinawa Oshima

As such a coral fossil, "CC-300 (item number)" manufactured by Riken Techno System Co., Ltd. can be used.

(1-3) Shell:

Abalone, Japanese abalone, and barnacle are mixed and pulverized into 3~5mm granules by the same weight.

As such a shell, "CC-400 (item number)" manufactured by Riken Techno System Co., Ltd. can be used.

(1-4) Activated carbon

The activated carbon can be produced from any raw material, but an activated carbon produced by using coconut shell as a raw material is preferable. For example, "CC-500 (product number)" manufactured by Riken Techno System Co., Ltd., which uses coconut shells made in Thailand, is used.

When the switch buttons 51b to 56b of the operation panel 58 are operated, when the water flow rate switching valves 51v to 56v are switched to the water-passing container side, the water flowing to the water supply path 57 is operated by the operated water flow switching valve to the downstream side. When the first water-passing container 51 to the sixth water-passing container 56 are inflow, if the water flow rate switching valves 51v to 56v are switched to the bypass waterway side, the water flowing to the water supply path 57 is flown downward by the operated water flow switching valve. The side of the backwater channel 51p~56p flows in. Accordingly, by operating any of the switch buttons 51b to 56b, the water flow switching valves 51v to 56v can be selectively switched to form a selectivity. The mineral-containing water (B) 45 of the mineral component eluted from the respective mineral-imparting materials (B) 51m to 56m from the first water-passing container 51 to the sixth water-passing container 56 is dissolved.

Next, the structure, function, and the like of the actual mineral-containing water (B) manufacturing apparatus 3 will be described with reference to Figs. 8 to 11 . Further, in Figs. 8 to 10, the above-described bypass water passages 51p to 56p, the water flow switching valves 51v to 56v, the operation panel 58 and the signal cable 59 are omitted.

As shown in FIG. 8 and FIG. 9, the mineral water-containing (B) manufacturing apparatus 3 includes the first water-passing container 51 to the sixth water-passing container 56 which are mounted on the substantially cylindrical shape of the holder 60, and is connected in series. The water supply path 57 of the first water-passing container 51 to the sixth water-passing container 56 is disposed in the uppermost portion of the holder 60 for storing the raw water tank 63 from the water W supplied from the water channel. In the raw water tank 63, an inorganic porous body 64 having a function of adsorbing impurities in the water W is accommodated. A plurality of casters 61 and a level adjuster 62 are disposed at the bottom of the bracket 60. The first water-passing container 51 to the sixth water-passing container 56 having a substantially cylindrical shape are mounted on the holder 60 of the rectangular parallelepiped lattice structure in a state in which the individual axial centers 51c to 56c (see FIG. 9) are held in the horizontal direction. The first water-passing container 51 to the sixth water-passing container 56 are detachable from the bracket 60.

As shown in Fig. 10, the first water-passing container 51 to the sixth water-passing container 56 have the same structure, and are provided with a disk shape by providing the rims 51f to 56f at both end portions of the cylindrical body portions 51a to 56a. The lids 51d to 56d form an airtight structure. When the shaft centers 51c to 56c are in the horizontal state, the water inlet 57a communicating with the water supply path 57 is provided at the lowermost portion of the main body portions 51a to 56a, and the uppermost portion of the lid bodies 51d to 56d farthest from the water inlet 57a is provided. A water outlet 57b that communicates with the water supply path 57 is provided, and a sieve 57c is attached to the water outlet 57b. An automatic air valve 57d for separating the air in the first water-passing container 51 to the sixth water-passing container 56 is attached to a portion directly above the water outlet 57b around the main body portions 51a to 56a.

The water supplied from the water supply path 57 on the upstream side passes through the water inlet 57a, and flows into the first water-passing container 51 to the sixth water-passing container 56, and is filled with the mineral-imparting material (B) filled in the individual interior. When it is in contact with the water, the mineral component is dissolved in the water, and the water is supplied to the downstream water supply path 57 from the water outlet 57b in the water containing the mineral component of the individual mineral material (B) 51m to 56m.

In the mineral-containing water (B) manufacturing apparatus 3 shown in Figs. 8 to 10, any one of the switch buttons 51b to 56b of the operation panel 58 shown in Fig. 7 is operated, and the water W of the raw water tank 63 is passed through One or more of the water-passing container 51 to the sixth water-passing container 56 are filled in the mineral-imparting material (B) 51m to 56m from the first water-passing container 51 to the sixth water-passing container 56, respectively, and can be selected. The mineral-containing water (B) 45 containing the characteristic mineral component is separately dissolved.

Further, in the mineral water-containing (B) manufacturing apparatus 3, the first water-passing container 51 to the sixth water-passing container 56 are connected in series by the water supply path 57, and the water is continuously flowed by the water supply path 57, and mass production is possible. The mineral-containing water (B) 45 of the mineral component of 51 m to 56 m of the mineral-imparting material (B) in the first water-passing container 51 to the sixth water-passing container 56 is dissolved.

Further, the mineral-containing water (B) 45 formed in the mineral-containing water (B) manufacturing apparatus 3 is fed into the mixing tank 46 through the sixth water-passing vessel 56 via the downstream-side water supply path 57x. The inside is mixed with the mineral-containing water (A) 44 produced by the mineral-containing water (A) manufacturing apparatus 2 shown in Fig. 1 to form mineral-functional water 47.

The ratio of the mineral-containing water (A) to the mineral-containing water (B) is determined by considering the type of the raw material contained in the mineral-containing water (A) and the mineral-containing water (B) and the concentration of the dissolved components. , but the weight ratio of mineral water (A) to mineral water (B) ([mineral water (A)]: [mineral water (B))) is 1:5~1:20 The range is suitably in the range of 1:7 to 1:12, and more suitably in the range of 1:10.

When the mineral-containing water (A) is too small (excessive mineral water (B)) and the mineral-containing water (A) is excessive (mineral water (B) is too small), there is an active ingredient that dilutes the functional water of minerals. The role as a goal has not been sufficient.

In the above, although a suitable embodiment of the method for producing mineral functional water of the present invention is described, the mineral functional water of the present invention having the above-described configuration can be produced, and various formulas can be used in addition to the above-described preferred embodiments. The composition should be considered as not being restricted. In particular, in the embodiments disclosed herein, matters not disclosed, such as operating conditions or operating conditions, various parameters, size, weight, volume, etc. of the constituents, are well within the scope of the present invention. Usually, values which can be easily imagined by those having ordinary knowledge in the field of the invention are employed.

[Examples]

The present invention will be more specifically described by the following examples, but the invention is not limited thereto.

[Example 1] <1>Manufacture of mineral functional water

The mineral functional water is used in the mineral functional water producing apparatus described in the above embodiment of the present invention. In the above-described manufacturing method, the mineral functional water of Example 1 produced by the following raw materials and methods is used.

The mineral functional water of Example 1 produced by the following raw materials and methods was produced.

1. Manufacture of mineral-containing water (A)

As a raw material of the mineral-based material (A), "P-101 (product number)" manufactured by Riken Techno System Co., Ltd. was used as the herbal material (A1), and "P-201 (manufactured by Riken Techno System Co., Ltd.) was used. Item No.)" as a woody plant material (A2).

"P-101" is a herbaceous plant material (A1) in which the dried pulverized material of the genus Compositae and the dried pulverized material of the Rosaceae plant are mixed at a ratio of 1:1 (weight ratio), and "P-201" is described below. Woody plant material (A2).

(A1) Herbaceous material (dried of herbaceous plants) (A1-1) Dry pulverized material of Compositae

The ratio of the wild carp (leaf, stem, and flower), wormwood (leaf and stem), and oyster (leaf and stem) to 10% by weight, 60% by weight, and 30% by weight, respectively. Mix and dry until crushed.

(A1-2) Dry pulverized material of Rosaceae plants

Japanese rose (leaf, flower), bayberry (leaf and stem), raspberry (leaf, stem and flower), 20%, 10%, 70% by weight Mix and dry until crushed.

(A2) Woody plant material (dried woody plant)

The ratio of maple (leaf), birch (leaf, stem, and bark), fir (leaf, stem, and bark) to 20% by weight, 60% by weight, and 20% by weight, respectively Mix and dry until crushed.

The mineral-containing material (A) in which the herbaceous plant material (A1) and the woody plant material (A2) are mixed at a ratio of 1:5 (weight ratio), and the mineral-containing water (A) manufacturing apparatus 2 shown in Fig. 1 In the raw material mineral aqueous solution manufacturing means 10 (refer to FIG. 2), the water is added in an amount of 10 to 15% by weight, and the conductive wire of the raw material mineral aqueous solution manufacturing means 10 conducts a direct current (DC8300V, 100 mA) and is electrically conductive. The water around the line generates a water flow in the same direction as the direct current, and ultrasonic vibration (vibration frequency: 50 kHz, amplitude: 1.5/1000 mm) is applied to the water to form a raw material mineral aqueous solution (A). Next, the mineral-containing water (A) of Example 1 was obtained by irradiating far-infrared rays (wavelength: 6 to 14 μm) to the raw material mineral aqueous solution (A) supplied to the far-infrared ray generating means 43 in the subsequent stage.

2. Manufacture of mineral-containing water (B)

As a raw material of the mineral-imparting material (B), a mixture of pulverized ‧ mixed limestone, coral fossil, shell, and activated carbon is used. The mixture of the raw material of the mineral-imparting material (B) and the first to sixth water-passing containers (mineral-imparting materials (B1) to (B6)) is as follows.

(1) Raw materials (1-1) Limestone: "CC-200 (item number)" manufactured by Riken Techno System Co., Ltd.

Grinding a small stone of about 3 cm of limestone mixed in a volcanic deposit containing the following components

Calcium carbonate: 50% by weight or more

Iron oxide: 3~9% by weight of iron

Total of titanium oxide, titanium carbide, and titanium nitride: 0.8% by weight or more

Magnesium carbonate: 7~10% by weight

(1-2) Coral fossil: "CC-300 (item number)" manufactured by Riken Techno System Co., Ltd.

The following two types of coral fossils are mixed in a weight ratio of 1:9 and pulverized into granules of 3 to 5 mm.

A coral fossil produced from approximately 100 meters underground and composed of heavy pressure modified crystals.

Coral fossils (including calcium or calcium phosphate other trace elements) produced from the land near Okinawa Oshima

(1-3) Shell: "CC-400 (item number)" manufactured by Riken Techno System Co., Ltd.

‧ Mix abalone, Japanese abalone, and barnacle in the same weight and pulverize into 3~5mm granules

(1-4) Activated carbon (used only in the second water container): "CC-500 (item number)" manufactured by Techno System Co., Ltd. (2) Proportion of use in the first to sixth water containers

‧1st water container:

Minerals-giving material (B1): Mixing limestone, coral fossils, and shells with 70% by weight, 15% by weight, and 15% by weight, respectively.

‧2nd water container:

Minerals-giving material (B2): Mixing limestone, coral fossil, shell, and activated carbon at 40% by weight, 15% by weight, 40% by weight, and 5% by weight, respectively (corresponding to cerium oxide and activated carbon)

‧3rd water container:

Mineral-giving material (B3): Mixing limestone, coral fossil, and shell with 80% by weight, 15% by weight, and 5% by weight, respectively

‧4th water container:

Minerals-giving material (B4): Mixing limestone, coral fossils, and shells with 90% by weight, 5% by weight, and 5% by weight, respectively

‧5th water container:

Minerals-giving material (B5): Mixing limestone, coral fossils, and shells with 80% by weight, 10% by weight, and 10% by weight, respectively

‧6th water container:

Minerals-giving material (B6): Mixing limestone, coral fossils, and shells with 60% by weight, 30% by weight, and 10% by weight, respectively

The mineral-containing water (B) manufacturing apparatus 3 constructed as shown in Fig. 1 is obtained by using the first to sixth water-passing containers of the mineral-imparting materials (B1) to (B6) to circulate water to obtain mineral-containing water ( B). (B1) to (B6) are respectively 50 kg (total 300 kg), and the amount of water passing through is 1000 kg, and the flow rate is set to 500 mL/40 s.

The mineral-containing water (A) of Example 1 formed by the above method and the mineral-containing water (B) were mixed so as to be 1:10 (weight ratio) to obtain the mineral functional water of Example 1.

When the mineral functional water of Example 1 was measured by a pH meter (glass electrode type hydrogen ion concentration indicator TPX-90 manufactured by Dongxing Chemical Research Institute), the pH was 11.5.

Further, the mineral functional water of the first embodiment corresponds to the mineral functional water A20ACA-717 (Tera Support (trade name), A20ACA-717 (item number)) of the Riken Techno System Co., Ltd.

(evaluation of spectroradiance)

In the ceramic carrier, the spectral emissivity of the mineral functional water sample of Example 1 was measured by a far-infrared radiance measuring apparatus (JIR-E500 manufactured by JEOL Ltd.). The apparatus is composed of a Fourier transform infrared spectrophotometer (FTIR) body, a black body furnace, a sample heating furnace, a temperature controller, and an attached optical system.

The evaluation sample of the spectroscopic rate was produced in the following order.

100 parts by weight with respect to the ceramic powder for carrying (the rock powder produced by Amakusa Oyao Island). The clay state of 20 parts by weight of the mineral functional water of Example 1 was made into water. This was processed into a circular shape having a circular thickness of about 5 mm and a diameter of 2 cm, and was fired at 1000 ° C to obtain an evaluation sample of the mineral component contained in the immobilized sample (mineral functional water).

Fig. 12 shows a spectroradiometer spectrum (measurement temperature: 25 ° C, wavelength range: 4 to 24 μm) of the mineral functional water of the measurement sample, which is the measurement sample. Further, the spectral emissivity spectrum (theoretical value) of the black body is also shown in Fig. 12. Further, in Fig. 12, the vertical axis scale indicates the radiation energy intensity, which indicates the number of W per square centimeter. Moreover, the curve of the "sample" means that the closer to the black body, the higher the radiation ability.

<2. Physical activation test> (2-1. Improvement of blood circulation)

In order to confirm the effect of the mineral functional water of Example 1 on the blood flow change of the living body, purified water was used as a control group, and a body activation test was performed.

The body activation test is performed by measuring changes in blood flow velocity and blood flow. Blood flow velocity and blood flow rate were measured using a Laser Doppler blood flow meter (FLO-N1-TWIN Omega Wave Co., Ltd.). Still, the data measured by the Laser Doppler blood flow meter is represented by computer processing as an individual numerical representation of blood flow velocity and blood flow.

Healthy adult male (38 years old) as the subject After sleeping in the state of the bench for 10 minutes, as a control, 50 cc of purified water was uniformly applied to the upper body, and the blood flow velocity and blood flow rate after 20 minutes were measured over time in a laser Doppler blood flow meter. The test was carried out at room temperature (25.5 ° C) and humidity of 46%.

Next, after 15 minutes of rest, the blood flow rate and blood flow rate of the mineral function water of Example 1 of 50 cc were measured in the same manner as time after 20 minutes. The measured values of blood flow velocity and blood flow rate are shown in Table 1. Still, blood flow velocity and blood flow are arbitrary units (a.u.).

As shown in Table 1, the blood flow rate of the purified water with respect to the control was 1.95 (average value), and the blood flow rate of the functional water of Example 1 was 1.87 (average value). That is, when the functional water of Example 1 was used, it was observed that the blood flow velocity was reduced by about 4% as compared with the purified water. This is presumed to be caused by the absorption of the megaheave living tissue of the functional water of Example 1 to cause vasodilatation. Also, the blood flow rate relative to the purified water is 25.64 (average Value) The blood flow rate of the functional water of Example 1 was 28.28 (average value). That is, when the functional water of Example 1 was used, it was observed that the blood flow rate was greatly improved by about 10% as compared with the purified water.

From the above results, it was confirmed that the mineral functional water of Example 1 has an excellent blood circulation improving effect and causes physical activation.

(2-2. Warming effect)

The warming action was evaluated for the sample of the mineral functional water of Example 1 (processed product) and the uncoated sample (non-processed product) with respect to the commercially available suit fabric.

The evaluation was carried out by a 90 degree parallel re-radiation method using a heater to heat the sample for thermal imaging photography.

However, the 90-degree parallel re-radiation method is evaluated at a higher temperature than the previous 45-degree parallel re-radiation method at 90 ° C. The deviation is less than the previous 45-degree re-radiation parallel method, and the influence from the surrounding environment of the test sample. Fewer, can be measured under stable conditions.

Specifically, the measurement procedure is performed by arranging the sample on the measurement table, adjusting the measurement chamber to a specific temperature and humidity, and then sliding the heater heated to 90° C. to obtain an image of the measurement sample in continuity. Immediately before the heating by the heater, the image is taken out for a certain period of time, and the average surface temperature is measured. Next, the arrangement of the processed sample and the unprocessed sample is replaced with the left and right, and the measurement is performed to confirm the processed product and the non-processed product. There are differences in the characteristic values. In addition, the position of the left and right of the processed product and the non-processed product was measured eight times.

Comparing the temperature distribution image to the heater after heating for 60 seconds When the temperature was raised, it was confirmed that the processed product was 7.9 ° C, and the unprocessed product was at 6.6 ° C and 1.3 ° C. From this result, it can be said that the warming property is improved by coating the mineral functional water.

[Industrial Applicability]

The mineral functional water of the present invention can be used for various purposes such as sports use and medical use because it can activate the body function of the human body, fatigue recovery or sustained strength.

Claims (19)

A mineral functional water characterized by a mineral component containing electromagnetic wave radioactivity, which has an effect of activating human body functions. The mineral functional water of claim 1 has a blood circulation improving effect. The mineral functional water according to claim 1, wherein the mineral component emits a mineral component containing electromagnetic waves of a megahertz wave. The mineral functional water of claim 1, wherein the spectroscopic spectroscopy spectrum is in the range of 4 μm to 24 μm in the sample in which the mineral functional water is immobilized in an amount of 20 parts by weight relative to 100 parts by weight of the ceramic carrier. Temperature: 25 ° C) is the shape shown in FIG. A body function activating composition comprising the mineral functional water according to any one of claims 1 to 4. The body function activating composition according to claim 5, which is an external composition. A composition for activating a body function according to claim 5, which is a cosmetic composition. The body function activating composition according to claim 5, which is imparted to clothing, bedding, or medical fiber products, and is in indirect contact with a person. A functional fibrous product comprising a fiber which immobilizes the mineral functional water of any one of claims 1 to 4. A functional fibrous product according to claim 9 which is a clothing or bedding type. A functional fibrous product according to claim 10, which is a medical or sports clothing. A functional fibrous product according to claim 9 which is a medical fibrous product. A medical or sports appliance for immobilizing mineral functional water according to any one of claims 1 to 4. A method for producing a mineral functional water, which is a method for producing mineral functional water according to any one of claims 1 to 4, which is characterized by a mineral-containing water formed in the following step (1) (A) And the mineral-containing water (B) formed in the following step (2) is contained in a ratio of 1:5 to 1:20 (weight ratio), and the step (1): the conductive wire covered with the insulator and The mineral-imparting material (A) is immersed in water, and the mineral-imparting material (A) contains a herbaceous plant material composed of a herbaceous plant of the family Asteraceae and a herbaceous plant of the family Rosaceae, and is selected from the group consisting of maple, white birch, and pine. a woody plant material composed of one or more kinds of woody plants in the cedar, wherein a direct current is conducted to the conductive wire, and water in the same direction as the direct current is generated in the water around the conductive wire, and the water is superimposed on the water. The sound wave is vibrated to form the raw material mineral aqueous solution (A), and secondly, the far infrared ray (wavelength 6 to 14 μm) is irradiated to the raw mineral aqueous solution (A) to form the mineral-containing water (A). Step (2): filling Inorganic mineral-giving material (B) of different types from each other, first connected in series 6 water passing through the water container to the 6th water container In the container, the mineral-imparting material (B1) in the first water-passing container contains a mixture of 70% by weight, 15% by weight, and 15% by weight of each of limestone, coral fossil, and shell, and a second water-passing container. The mineral-imparting material (B2) includes a mixture of 40% by weight, 15% by weight, 40% by weight, and 5% by weight of each of limestone, coral fossil, shell, and activated carbon, and a mineral-imparting material in the third water-passing container. (B3) includes a mixture of 80% by weight, 15% by weight, and 5% by weight of each of limestone, coral fossil, and shell, and a mineral imparting material (B4) in the fourth water-passing container respectively contains limestone, coral fossil, Each of the shells is a mixture of 90% by weight, 5% by weight, and 5% by weight, and the mineral-importing material (B5) in the fifth water-passing container contains 80% by weight and 10% by weight, respectively, of limestone, coral fossil, and shell. 10% by weight of the mixture and the mineral-imparting material (B6) in the sixth water-passing container include a mixture of 60% by weight, 30% by weight, and 10% by weight of limestone, coral fossil, and shell, and water is passed through the 6 Passing a water container to form a mineral-containing water (B) for producing mineral-containing water (B) Sudden. The method for producing a mineral functional water according to claim 14, wherein the amount of the mineral-imparting material (A) added to the water is 10 to 15% by weight, and the current value and the voltage value of the direct current conducted to the conductive wire are respectively It is in the range of 0.05~0.1A and 8000~8600V. The method for producing mineral functional water according to claim 14 or 15, wherein the mineral imparting material (A) is a herbal plant material (A1) and a woody plant material (A2) as a herb material (A1) and wood. The mineral material (A') obtained by mixing the plant material (A2) in a weight ratio of 1:5, and the herb material (A1) as a raw material of the herb, which is a wild stalk (leaf, stem, and Flower part), wormwood (leaf part and stem part), and oyster (leaf part and stem part) are mixed in a ratio of 10% by weight, 60% by weight, and 30% by weight, respectively, and dried to be pulverized Dried pulverized material of the family plant, and Japanese rose (leaf, flower), bayberry (leaf and stem), raspberry (leaf, stem, and flower) are 20% by weight, 10% by weight, respectively And 70% by weight of the mixture is mixed, and after drying, the dried pulverized material of the pulverized Rosaceae plant is mixed at a ratio of 1:1 (weight ratio); the woody plant material (A2) is used as the raw material of the aforementioned woody plant, Maple (deciduous), birch (deciduous, stem, and bark), fir (deciduous, stem, and bark) are 20%, 60%, and 20, respectively. % Of the mixing ratio, to be dried is composed of the pulverized product of dried pulverized. A method for activating a body function (except for excluding a medical action for a human), which comprises directly or indirectly constituting a mineral functional water as claimed in claim 1 or a body function activating composition according to claim 5 The steps to get in touch with people. A use of mineral functional water as claimed in claim 1 To produce a composition for the activation of body functions. The mineral functional water of claim 1 is for use as a composition for activation of body functions.