MINERAL FUNCTIONAL WATER, METHOD OF PRODUCING THE SAME, AND METHOD OF COMBUSTION-PROMOTING HYDROCARBONS
First Claim
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1. Mineral functional water, including mineral components of electromagnetic radioactivity and showing activating action on hydrocarbons.
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Abstract
Provided is mineral functional water including beneficial efficacy, such as improving action of combustion efficiency. Electromagnetic waves irradiated by mineral components contained in the mineral functional water according to the present invention reveals combustion-promoting action on hydrocarbons, such as hydrocarbons fuel.
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Citations
15 Claims
- 1. Mineral functional water, including mineral components of electromagnetic radioactivity and showing activating action on hydrocarbons.
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5. A method of producing mineral functional water, comprising:
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producing first mineral-containing water (A) according to the following first process (1); and producing second mineral-containing water (B) according to the following second process (2); the mineral functional water containing the first produced mineral-containing water (A) and the second produced mineral-containing water (B) according to a ratio within a range of 1;
5-1;
20 (weight ratio),wherein the first process (1) includes; immersing a conductive wire covered with insulator and mineral-imparting material (A) into water, the mineral-imparting material containing;
woody plant raw material;
vegetation raw material; and
activated carbon, the vegetation raw material including;
vegetation belonging to Asteraceae and vegetation belonging to Rosaceae, the woody plant raw material including at least one kind selected from a group consisting of Maple, Betula platyphylla, Pinus, and Cryptomeria japonica;
conducting DC electric current to the conductive wire to generate water flow around the conductive wire in the same direction as the DC electric current, applying ultrasonic vibration to the water, thereby forming raw mineral water solution (A); and irradiating far-infrared rays (wavelength of 6-14 micrometers) to the raw mineral water solution (A) to form mineral-containing water (A), and wherein the second process (2) uses six connected in series water-passing containers in which different kinds of inorganic mineral-imparting material (B) from each other is filled, the six water-passing containers including;
a first water-passing container;
a second water-passing container;
a third water-passing container;
a fourth water-passing container;
a fifth water-passing container; and
a sixth water-passing container,wherein; the mineral-imparting material (B1) filled into the first water-passing container is mixture including;
70 weight % of lime stone;
15 weight % of fossil coral; and
15 weight % of shell, respectively;the mineral-imparting material (B2) filled into the second water-passing container is mixture including;
40 weight % of lime stone;
15 weight % of fossil coral;
40 weight % of shell; and
5 weight % of activated carbon, respectively;the mineral-imparting material (B3) filled into the third water-passing container is mixture including;
80 weight % of lime stone;
15 weight % of fossil coral; and
5 weight % of shell, respectively;the mineral-imparting material (B4) filled into the fourth water-passing container is mixture including;
90 weight % of lime stone;
5 weight % of fossil coral; and
5 weight % of shell, respectively;the mineral-imparting material (B5) filled into the fifth water-passing container is mixture including;
80 weight % of lime stone;
10 weight % of fossil coral; and
10 weight % of shell, respectively; andthe mineral-imparting material (B6) filled into the sixth water-passing container is mixture including;
60 weight % of lime stone;
30 weight % of fossil coral; and
10 weight % of shell, respectively, andmaking the water pass through the six water-passing containers to form mineral-containing water (B). - View Dependent Claims (6, 7)
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9. Mineral functional water produced by a method comprising:
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producing first mineral-containing water (A) according to the following first process (1); and producing second mineral-containing water (B) according to the following second process (2); the mineral functional water containing the first produced mineral-containing water (A) and the second produced mineral-containing water (B) according to a ratio within a range of 1;
5-1;
20 (weight ratio),wherein the first process (1) includes; immersing a conductive wire covered with insulator and mineral-imparting material (A) into water, the mineral-imparting material containing;
woody plant raw material; and
vegetation raw material;
the vegetation raw material including;
vegetation belonging to Asteraceae and vegetation belonging to Rosaceae, the woody plant raw material including at least one kind selected from a group consisting of Maple, Betula platyphylla, Pinus, and Cryptomeria japonica;
conducting DC electric current to the conductive wire to generate water flow around the conductive wire in the same direction as the DC electric current, applying ultrasonic vibration to the water, thereby forming raw mineral water solution (A); and irradiating far-infrared rays (wavelength of 6-14 micrometers) to the raw mineral water solution (A) to form mineral-containing water (A), and wherein 10 to 15 weight % of the mineral-imparting material (A) based on the water is added; and
the DC electric current conducted to the conductive wire has 0.05-0.1 A of a current value and 8000-8600 V of a voltage value, respectively,wherein; dried pulverized product of Asteraceae plants and dried pulverized product of Rosaceae plants are used as the mineral-imparting material (A); the dried pulverized product of the Asteraceae plants is produced by; mixing 10 weight % of Cirsium japonicum (leaf parts, stem parts and flower parts thereof), 60 weight % of Artemisia indica (leaf parts and stem parts thereof) and 30 weight % of Farfugium japonicum (leaf parts and stem parts thereof), respectively to produce first mixture thereof;
making the first mixture dry; and
then pulverizing the dried first mixture;the dried pulverized product of the Rosaceae plants is produced by; mixing 20 weight % of Rosa multiflora (leaf parts and flower parts thereof), 10 weight % of Geum japonicum (leaf parts and stem parts thereof), and 70 weight % of Rubus L. (leaf parts, stem parts, and flower parts thereof), respectively to produce second mixture thereof;
making the second mixture dry; and
then pulverizing the dried second mixture;the dried pulverized product of the Asteraceae plants and the dried pulverized product of the Rosaceae plants are mixed according to 1;
1 (weight ratio) to obtain vegetation raw material (A1);the woody plant raw material (A2) is produced by; mixing 25 weight % of Maple (leaf parts and stem parts thereof), 25 weight % of Betula platyphylla (leaf parts, stem parts, and bark parts thereof), and 50 weight % of Cryptomeria japonica (leaf parts, stem parts, and bark parts thereof) to produce third mixture;
making the third mixture dry; and
then pulverizing the dried third mixture; andactivated carbon is composed of activated carbon powder (A3) produced by carbonizing coconut shell at activation temperature of 1000 Centigrade; and the mineral-imparting material (A′
) is obtained by;mixing the vegetation raw material (A1) and the woody plant raw material (A2) according to 1;
3 (weight ratio) to produce plant mixture; andbased on 100 pts. wt. of the plant mixture, mixing 2-8 weight % of the activated carbon powder (A3) thereto, wherein the second process (2) uses six connected in series water-passing containers in which different kinds of inorganic mineral-imparting material (B) from each other is filled, the six water-passing containers including;
a first water-passing container;
a second water-passing container;
a third water-passing container;
a fourth water-passing container, a fifth water-passing container; and
a sixth water-passing container,wherein; the mineral-imparting material (B1) filled into the first water-passing container is mixture including;
70 weight % of lime stone;
15 weight % of fossil coral; and
15 weight % of shell, respectively;the mineral-imparting material (B2) filled into the second water-passing container is mixture including;
40 weight % of lime stone;
15 weight % of fossil coral;
40 weight % of shell; and
5 weight % of activated carbon, respectively;the mineral-imparting material (B3) filled into the third water-passing container is mixture including;
80 weight % of lime stone;
15 weight % of fossil coral; and
5 weight % of shell, respectively;the mineral-imparting material (B4) filled into the fourth water-passing container is mixture including;
90 weight % of lime stone;
5 weight % of fossil coral; and
5 weight % of shell, respectively;the mineral-imparting material (B5) filled into the fifth water-passing container is mixture including;
80 weight % of lime stone;
10 weight % of fossil coral; and
10 weight % of shell, respectively; andthe mineral-imparting material (B6) filled into the sixth water-passing container is mixture including;
60 weight % of lime stone;
30 weight % of fossil coral; and
10 weight % of shell, respectively, andmaking the water pass through the six water-passing containers to form mineral-containing water (B). - View Dependent Claims (10, 11, 12, 13, 14, 15)
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Specification