JP4021574B2 - Reducing property imparting method and reducing property imparting device - Google Patents

Description

【００７０】
【発明の効果】
本発明の還元性付与方法および還元性付与装置は、このように、水、食物等の物体に対して、容易に還元性を付与することができるために、物体の酸化による劣化等を薬品等を使用することなく抑制することができる。
【図面の簡単な説明】
【図１】本発明の還元性付与装置の実施の形態の一例を示す概略構成図である。
【図２】（ａ）、（ｂ）、（ｃ）は、それぞれ、その還元性付与装置に使用される放射体の他の例を示す斜視図である。
【図３】本発明の還元性付与装置に使用される放射体のさらに他の例を示す要部の拡大図である。
【図４】本発明の還元性付与装置に使用される放射体のさらに他の例を示す斜視図である。
【図５】本発明の還元性付与装置に使用される放射体のさらに他の例を示す斜視図である。
【符号の説明】
１０ 放射体
１１ 導電線
１２ 短絡部
１３ 支持ブロック
１４ 支持板
１５ 金属板
２０ 発振回路
２１ 第１コンデンサー
２２ 第２コンデンサー
２３ 第３抵抗器
２４ 第４抵抗器
２６ スライダック
２７ 放電管[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a method and apparatus for imparting reducing properties to water, various objects containing water, inorganic objects, and the like.
[0002]
[Prior art]
It is well known that various objects such as water, food, and living things are deteriorated by oxidation. For this reason, for example, in water and food, oxidation is prevented by chemicals and additives such as SOD (active oxygen-eliminating substance), or by freezing or refrigerated storage. In recent years, alkaline water and foods that have little adverse effect due to active oxygen and have reducibility are attracting attention as being healthy and preferable.
[0003]
[Problems to be solved by the invention]
When using chemicals to suppress oxidation of various objects, secondary effects are a concern. Alkaline water and food are not necessarily good reducible, are not suitable for long-term storage, and are not capable of being produced in large quantities.
[0004]
The present invention solves such problems, and an object of the present invention is to provide a method and apparatus capable of easily imparting reducing properties to various objects such as water, food, organisms, and minerals. It is in.
[0005]
[Means for Solving the Problems]
The reducing property imparting method of the present invention is characterized by irradiating an object to be imparted with reducing properties with an electromagnetic wave having a low frequency of 7 Hz or less and having a longitudinal wave property.
[0006]
A fine waveform component is superimposed on the electromagnetic wave.
[0007]
The reducing property imparting apparatus of the present invention includes a power supply means for generating an alternating current of a low frequency of 7 Hz or less, and a low frequency of 7 Hz or less having a longitudinal wave property when the alternating current generated by the power supply means is energized. And a radiator that emits the electromagnetic wave.
[0008]
The power supply means generates an alternating current on which a fine waveform component is superimposed.
[0009]
The power supply means has an oscillation circuit configured by a bridge circuit that generates an alternating current having a low frequency of 7 Hz or less when an alternating current is applied.
[0010]
In the bridge circuit of the oscillation circuit, capacitors are provided on the first side and the second side adjacent to each other, and resistors are provided on the third side and the fourth side adjacent to each other. In addition, one radiator or a plurality of radiators connected in series to each other is connected in series to the capacitor provided on the second side.
[0011]
A discharge tube is connected in series to the radiator.
[0012]
The radiator is composed of a single or a plurality of solid bodies formed by winding a pair of conductive wires whose one ends are short-circuited in a coil shape in parallel.
[0013]
Alternatively, there are a plurality of the radiators, and each radiator is formed by winding one conductive wire in a spiral shape in a plane.
[0014]
Alternatively, the radiator is configured by electrically connecting a plurality of conductive plates arranged in parallel at appropriate intervals in series.
[0015]
The radiator is disposed in air or water.
[0016]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0017]
FIG. 1 is a schematic configuration diagram showing an example of an embodiment of a reducing property imparting apparatus used for carrying out the reducing property imparting method of the present invention. This reducing property imparting apparatus includes an oscillation circuit 20 as a power supply unit that generates a low-frequency alternating current, and a pair of radiations that emit a low-frequency electromagnetic wave when a low-frequency alternating current generated by the oscillation circuit 20 is energized. And a body 10. In the present embodiment, the pair of radiators 10 are electrically connected in series, but one radiator 10 may be used.
[0018]
Each radiator 10 is configured by winding a pair of conductive wires 11 that are short-circuited by a short-circuit portion 12 in which one end portions are connected to each other in a coil shape in a parallel state. Each conductive wire 11 wound in a coil shape is covered with an insulator so as to be insulated from each other.
[0019]
Such radiators 10 are used singly or in combination, and when a plurality of radiators 10 are used, the radiators 10 are electrically connected in series with each other. In the present embodiment, the non-short-circuited end portion of each conductive wire 11 constituting one radiator 10 is connected to the non-short-circuited end portion of each conductive wire 11 constituting the other radiator 10. The discharge bodies 10 are electrically connected in series. An alternating current generated in the oscillation circuit 20 is energized to each radiator 10 connected in series.
[0020]
The oscillation circuit 20 is a bridge circuit composed of four sides, and an internal resistance value R is present on the first side constituting the bridge circuit. ₁ , Capacity C ₁ The capacitor 21 is provided. In addition, an AC ammeter 25 and an internal resistance value R are connected to the second side connected to the first side via the connection point 20a. ₂ And capacity C ₂ And a plurality of radiators 10 (total resistance value R) individually or in series with each other. ₆ ) And Slidac 26 (total resistance R ₅ ) Is connected in series with the discharge tube 27 through which the alternating current adjusted by (1) flows.
[0021]
The third side connected to the first side via the connection point 20b has a resistance value R ₃ The third resistor 23 is provided, and the fourth side connected to the second side via the connection point 20d has a resistance value R. ₄ The fourth resistor 24 is provided. And the resistor 23 provided in the 3rd edge | side and the 4th resistor 24 provided in the 4th edge | side are mutually connected by the connection point 20c. A blocking diode 29 is provided between the connection point 20c and the connection point 20a that faces the connection point 20c and connects the first side and the second side.
[0022]
Between the connection point 20b connecting the first side and the third side and the connection point 20d connecting the second side and the fourth side, an alternating current supplied by the AC power supply 30 is It is given in a state adjusted by the slidac 31. As this alternating current power supply 30, for example, an alternating current of 50 Hz or 60 Hz supplied to a general household is used. An earth leakage breaker 32 and an AC ammeter 33 are connected in series to the AC power source 30, respectively, and an AC voltage and an AC current supplied to the oscillation circuit 20 constituted by a bridge circuit are converted into an AC voltmeter 34 and Each is measured by the AC ammeter 35.
[0023]
The first capacitor 21 and the second capacitor 22 in the oscillation circuit 20 are, for example, their capacitance C ₁ And C ₂ Are large capacities of 2200 μF and 1250 μF, respectively. In addition, each resistance value R in the third resistor 23 and the fourth resistor 24 ₃ And R ₄ Are set so as to satisfy the following expressions (1) and (2).
[0024]
R ₃ / (R ₃ + R ₄ <1/3 (1)
R ₃ + R ₄ = 150 (Ω) (2)
[0025]
Internal resistance value R of the second capacitor 22 ₂ The total resistance value R of the slider 26 ₅ , The total resistance R of the single or multiple radiators 10 connected in series ₆ R is the total resistance value of R ₀ Then, the frequency f (Hz) of the alternating current from the oscillation circuit 20 is obtained by the following equation (3).
[0026]
f = 1 / {2π (C ₁ ・ C ₂ ・ R ₁ ・ R ₀ ) ^1/2 } (3)
[0027]
Internal resistance value R of the second capacitor 22 ₂ And the total resistance value R of the slider 26 ₅ And the total resistance value R of the connected radiator 10 ₆ All combined resistance values R including ₀ Is around 2 MΩ, the frequency f of the alternating current from the oscillation circuit 20 is 0.05 × 10 ^-3 (Hz) is expected.
[0028]
As described above, the oscillation circuit 20 using the first capacitor 21 and the second capacitor 22 each having a large capacity can generate an alternating current having a very low frequency, and the low frequency generated from the oscillation circuit 20 can be generated. An alternating current is passed through each radiator 10 connected in series.
[0029]
As the slidac 26, a self-winding transformer type commonly used as a commercial product is used. In this case, the slidac 26 has a low voltage (secondary) side (OUT PUT terminal) connected in series to the electric line on the second side, and a discharge tube 27 connected to the high voltage (primary) side (INPUT terminal). The voltage applied to the discharge tube 27 is the maximum (the brightness of the discharge tube is the highest), and the current supplied to the radiator 10 is adjusted to the maximum. In this way, in the discharge tube 27 that can be interpreted as being electrically connected in series to the radiator 10, electrons emitted by glow discharge collide with the inert encapsulated gas, and thus, together with the light emission phenomenon, 10 ^-8 Electrical “fluctuation” is generated by the binding and detachment of molecules in the intermolecular region of about cm. A fine waveform component resulting from this electrical “fluctuation” is superimposed on a low-frequency alternating current that is passed through the radiator 10.
[0030]
The radiator 10 connected in series is thus energized with a low-frequency alternating current on which a fine waveform component generated by the discharge tube 27 is superimposed. Each of the radiators 10 connected in series is formed by winding a pair of conductive wires 11 whose one ends are short-circuited by the short-circuit portion 12 in a coiled state in a parallel state. The directions of the currents flowing through the pair of conductive wires 11 are opposite to each other, and the magnetic field strength of the generated electromagnetic wave is smaller than when one conductive wire is wound in a coil shape. As a result, the electromagnetic wave radiated from each radiator 10 has a transverse wave (wave oscillating in a direction orthogonal to the traveling direction) component and a longitudinal wave (wave oscillating in the same direction as the traveling direction). It appears strongly.
[0031]
Since the generated electromagnetic wave has a very low frequency and a very long wavelength, a standing wave is generated in the vicinity of the radiator 10 that is the generation source of the electromagnetic wave. In addition to the properties of waves, it is thought to have properties as standing waves.
[0032]
In the reducing property imparting device having such a configuration, objects to be imparted with reducing properties are arranged toward the radiator 10 from which standing wave-like electromagnetic waves on which fine waveforms are superimposed are respectively disposed. An electromagnetic wave radiated from the object 10 is irradiated on the object.
[0033]
In this Embodiment, when the water with which the container was filled is arrange | positioned between a pair of radiator 10, the water irradiated with the electromagnetic waves from each radiator 10 is the time of 15-30 minutes having passed. , ORP (redox potential) value decreases, and reducibility begins to be imparted. And when 2 to 12 hours have passed, the ORP value becomes substantially constant. Although the pH value of water during irradiation with electromagnetic waves slightly changes, it is in the neutral region. The water imparted with the reducing property in this manner hardly changes in the ORP value and the pH value for at least 6 months. Similar results can be obtained when the electromagnetic wave is irradiated by the single radiator 10.
[0034]
Regarding the reduction property of the object, the oxidation-reduction potential (ORP) of the object was measured, and it was determined that the reduction property was imparted by the decrease in the ORP value.
[0035]
Although it is not clear why the water is given reducibility by the electromagnetic wave radiated by the radiator 10, the electromagnetic wave radiated from the radiator 10 has a low frequency and longitudinal wave property. Therefore, although water molecules are slow, they move reliably following electromagnetic waves, and it is considered that water molecules separate and scatter during the movement. Such desorption / concentration of water molecules causes H in water. ₃ O ⁺ H which is in a relatively stable state as (hydronium ion) ⁺ It is considered that (hydrogen ions) are separated with time and water is given reducibility. In this case, since the fine waveform is superimposed on the electromagnetic wave, water molecules behave in a complicated manner. ⁺ Is also considered to be efficiently separated. Water molecules are O ^2- Against H ⁺ Is bound to the outside, so H ⁺ Is easy to separate, and is easy to be given reducibility.
[0036]
It is considered that the frequency of the electromagnetic wave radiated from each radiator 10 may be equal to or less than the frequency (around 7HZ) of the resonance phenomenon (Schumann resonance) that occurs between the earth and the ionosphere. The frequency of the electromagnetic wave radiated from each radiator 10 can be changed by the capacitance of the capacitors 21 and 22 in the oscillation circuit 20.
[0037]
When water is irradiated with high-frequency electromagnetic waves such as microwaves, the water molecules can not follow the high-frequency electromagnetic waves and stop, so the water molecules efficiently absorb the electromagnetic waves, Actions such as heat generation and radicalization will occur.
[0038]
Since the electromagnetic wave generated from the radiator 10 has a low frequency, this heat generation and radicalization cannot occur.
[0039]
As described above, the object to which the reducibility is imparted is not limited to water that can provide particularly remarkable effects, and the organic matter containing water is similarly imparted with the reducibility. For example, when fresh vegetables are irradiated with electromagnetic waves from the radiator 10 and observed over time, the deterioration of freshness is clearly less than that of raw vegetables under the same conditions that are not irradiated with electromagnetic waves. Yes, it had the same freshness as freshly refrigerated vegetables. In addition, when the raw eggs irradiated with electromagnetic waves were broken and observed on a petri dish, the deterioration of freshness was clearly milder than that of raw eggs not irradiated with electromagnetic waves. Furthermore, when milk was observed in the same manner, after 2 weeks, milk not irradiated with electromagnetic waves decayed, but the milk irradiated with electromagnetic waves became yogurt-like.
[0040]
In addition, it is considered that inorganic substances such as glass and ceramics, particularly crystalline inorganic substances, are also given reducibility. For example, after irradiating an empty glass container, a ceramic container or the like that is not filled with water with electromagnetic waves by the radiator 10 for about 2 to 7 days and then filling each container with water, the filled water has a pH of Although the value hardly changed, the ORP value was lowered and the reducing property was imparted to water.
[0041]
Furthermore, when the discharged dry battery was irradiated with electromagnetic waves, it returned to the charged state. In this case, it is considered that a chemical change opposite to the discharge occurred in the chemical substance in the dry battery. Further, it is considered that the metal constituting the outer case of the dry battery has transmitted the electromagnetic wave radiated from the radiator 10.
[0042]
The oscillation circuit 20 that supplies a low-frequency current to the radiator 10 uses an alternating current used in a general household as a power source. Further, the power consumption is generated by the resistors 23 and 24 and the slider 26. And 31, and the lighting of the discharge tube 27 is extremely economical. Furthermore, since the electromagnetic waves radiated from each radiator 10 have a low frequency, there is no possibility of adversely affecting the environment.
[0043]
In the case where the radiator 10 has a configuration in which a pair of conductive wires 11 that are short-circuited to each other are coiled in a parallel state, the radiator 10 may be configured to irradiate the object to be irradiated with electromagnetic waves. In addition, more than one may be used. In either case, reducing properties can be imparted to the object.
[0044]
When the radiator 10 is configured by winding a pair of conductive wires 11 in a hollow coil shape, the pair of conductive wires 11 is configured to be held in a hollow coil shape by appropriate holding means. Moreover, you may comprise in a coil form by winding a pair of conductive wire 11 around a suitable core material.
[0045]
The radiator 10 is not limited to a hollow coil shape having a constant outer diameter. For example, as shown in FIG. 2A, a pair of conductive wires 11 in which one end portions are short-circuited are parallel to each other. 2 may be formed by winding a pair of conductive wires 11 short-circuited in a spiral shape in a plane as shown in FIG. 2B. When spirally winding in a plane, it is necessary to hold the pair of conductive wires 11 in the plane by appropriate holding means. Further, as shown in FIG. 2C, the pair of conductive wires 11 that are short-circuited with each other may be embedded in the inner peripheral surface of the cylindrical support block 13 in a coiled state. Good. As described above, when the support block 13 is used, the pair of conductive wires 11 that are short-circuited with each other may be wound around the outer peripheral surface of the support block 13 in a coil shape. A pair of conductive wires 11 short-circuited with each other may be wound around the inner peripheral surface and the outer peripheral surface of the coil 13 in a coil shape.
[0046]
The core material and the support block 13 that hold the pair of conductive wires 11 wound in a coil shape may be any non-magnetic insulator, but glass and ceramics are more electrically insulating than plastics and wood. It is preferable because it is an excellent non-magnetic material, and crystalline ores, especially quartz is more preferable.
[0047]
In either case, the pair of conductive wires 11 wound in a coil shape may be twisted once or multiple times. Further, instead of the pair of conductive wires 11 short-circuited to each other, one conductive wire may be folded in two and wound in a coil shape.
[0048]
Further, as shown in FIG. 3, a state in which one end of each conductive wire 11 covered with an insulator is short-circuited and the other conductive wire 11 is wound around one conductive wire 11. Thus, the radiator 10 may be configured by being wound in a coil shape. In this case, it is preferable to wind as shown in FIG. 3 so that the other conductive wire 11 wound around one conductive wire 11 does not loosen.
[0049]
Further, the present invention is not limited to a configuration in which the pair of conductive wires 11 are wound in a hollow coil shape, and as shown in FIG. 4, one conductive wire 11 is spirally wound in a plane to form a flat support plate. The radiator 10 may be configured to be fixed to 14. When a metal is used as the flat support plate 14 for fixing the conductive wire 11, an aluminum plate is particularly preferable, and a copper plate can also be suitably used.
[0050]
When such a planar radiator 10 is used, it is preferable to use two or more radiators. When two radiators 10 are used, an object irradiated with electromagnetic waves is interposed between them. It is preferable to be in a state of being opposed to each other. When three radiators 10 are used, an object is placed between a pair of radiators 10 so as to face each other, and another radiator 10 is placed above the object. It is preferable to use it so as to cover it. In this case, the influence of magnetism existing in the surrounding environment is reduced for the electromagnetic waves generated from each radiator 10.
[0051]
In the planar radiator 10, as in the solenoid coil, the current flows in the same direction in the adjacent conductive wire 11, so the ratio between the electric field strength and the magnetic field strength of the radiated electromagnetic wave is small. On the other hand, by surrounding two or three planar radiators 10 for use, the ratio between the electric field strength and the magnetic field strength of the electromagnetic wave between the respective radiators 10 can be increased, and longitudinal waves are applied to the object. An electromagnetic wave having the following properties can be irradiated.
[0052]
The radiator 10 is not limited to the configuration using the conductive wire 11, and may be configured by combining a plurality of conductive metal plates 15 as shown in FIG. 5. In this case, the plurality of metal plates 15 are arranged in parallel to each other with an appropriate interval. Then, for example, a pair of bolts 16 made of an insulator such as vinyl chloride is inserted through all the metal plates 15, so that each pair of adjacent metal plates 15 keeps a certain distance. In the state where the spacer 18 is fitted between a pair of adjacent metal plates 15, nuts 17 made of an insulator such as vinyl chloride are screwed to the end portions of the respective bolts 16. Each metal plate 15 is electrically connected in series so that one metal plate 15 and a metal plate 15 adjacent to one side of the metal plate 15 are respectively connected by conductive wires 11. Electrically connected.
[0053]
In such a radiator 15, the direction of the current flowing through the adjacent metal plate 15 is reversed, the ratio between the electric field intensity and the magnetic field intensity of the radiated electromagnetic wave is increased, and the electromagnetic wave having the property of longitudinal wave is radiated. Is done.
[0054]
Each radiator 10 may directly radiate an electromagnetic wave to the radiated body. However, the radiant body 10 is sealed in water, and the electromagnetic wave radiated from the radiant body 10 is passed through the water. May be irradiated. In this case, as the container for storing water for sealing the radiator 10, glass, ceramic, ceramics, etc., which are inorganic other than metal and have a small relative dielectric constant, are preferable.
[0055]
【Example】
<Example 1>
As the radiator 10, an inner peripheral surface and an outer periphery of a core material constituted by a jade ball (a trigonal system of silicate mineral) having a bottomed cylindrical shape having an inner diameter of 50 mm, an outer diameter of 70 mm, a thickness of 10 mm, a depth of 70 mm, and a height of 100 mm. 0.5mm on the surface ² A pair of vinyl cords with a total length of 20m are short-circuited at one end of each, closely wound around each, and the vinyl cords wound around the inner peripheral surface and outer peripheral surface are respectively covered with a waterproof adhesive tape Thus, this single radiator 10 was connected to the oscillation circuit 20 as shown in FIG. Capacitance C of each of the first capacitor 21 and the second capacitor 22 of the oscillation circuit 20 ₁ And C ₂ Are 2200 μF and 1250 μF. Then, the AC voltage adjusting slidac 31 is adjusted so that the voltage from the AC power source 30 is about 5V, and the neon lamp used as the discharge tube 27 is lit brightest so that the slidac 26 for adjusting the discharge tube 27 is adjusted. did. Thereafter, the energizing current to the radiator 10 was set to 2.5 A with the voltage 10 V by the slidac 31 for adjusting the alternating current.
[0056]
In such a state, the radiator 10 is placed on a desk on which plate glass is laid, and a glass container (NO.1) filled with 300 ml of tap water on a desk about 15 cm away, and tap water 300 A container made of polypropylene (NO. 2) filled with milliliters was placed. A glass container (NO. 3) filled with 300 ml of tap water was placed on a desk 130 cm away from the radiator 10. A space is formed around each container.
[0057]
Elevated tank storage tap water in high-rise houses in Osaka city generally shows an ORP value of +600 to +700 mV when sampled from a tap, and after boiling it, it can be cooled or put into an open container It is known that by filling and allowing to stand for about 1 day and night, an ORP value of +400 to +300 mV is obtained, and dissolved chlorine decreases with the progress.
[0058]
In order to accurately represent the effect obtained for these tap waters that are irradiated from the radiator, the container is filled and opened for about 20 to 24 hours for the purpose of minimizing the effect of this dissolved chlorine. It was decided to use one that was left indoors, and a 0.1% aqueous solution of orthotolidine was added dropwise immediately before irradiation to confirm that there was no residual chlorine.
[0059]
When the ORP value of water in each container was measured by an oxidation-reduction potentiometer (trade name “RM-12P, No5ACZ636W”, sensor part “PTS-2019C, No801F0151” manufactured by Toa Denpa Inc.), before emission of electromagnetic waves , NO. The ORP value of water in one glass container is +288 mV, NO. The ORP value of water in the two containers is +289 mV, NO. The ORP value of water in the three containers was +287 mV, but when about 1 hour and 30 minutes passed after the start of energization, NO. The ORP value of water in one glass container is +251 mV, NO. The ORP value of water in the two containers is +250 mV, NO. The ORP value of the water in the three containers was +256 mV, respectively. When about 3 hours have passed, NO. The ORP value of water in one glass container is +231 mV, NO. The ORP value of water in the two containers is +230 mV, NO. The ORP value of water in the three containers was +234 mV, respectively. Thereafter, until about 5 hours have passed, NO. The ORP value of water in one glass container is around +229 mV, NO. The ORP value of water in the two containers is around +230 mV, NO. The ORP value of water in the three containers was around +232 mV.
[0060]
The results are shown in Table 1.
[0061]
<Example 2>
The radiator 10 in Example 1 was placed in a cylindrical polypropylene container having a diameter of 130 mm and a depth of 140 mm, and the container was filled with 1.2 liters of tap water and sealed. As in Example 1, except that the radiator 10 was sealed with tap water, NO. 1 glass container, NO. 2 containers, NO. When the ORP value of each water in the three containers was measured, the NO. 1 ORP value of water in glass container is +293 mV, NO. The ORP value of water in the two containers is +325 mV, NO. The ORP value of the water in the three containers was +313 mV, and the ORP value of the water in which the radiator 10 was sealed was +296 mV. The ORP value of water in one glass container is +280 mV, NO. The ORP value of water in the two containers is +277 mV, NO. The ORP value of the water in the three containers is +287 mV, and the ORP value of the water sealing the radiator 10 is +245 mV. When about 3 hours have passed, NO. The ORP value of water in one glass container is +256 mV, NO. The ORP value of water in the two containers is +253 mV, NO. The ORP value of water in the three containers was +263 mV, and the ORP value of water sealing the radiator 10 was +167 mV.
[0062]
Furthermore, when about 8 hours have passed, NO. The ORP value of water in one glass container is +246 mV, NO. The ORP value of water in the two containers is +245 mV, NO. The ORP value of water in the three containers is +247 mV, the ORP value of water sealing the radiator 10 is +159 mV, and when about 10 hours have passed, NO. The ORP value of water in one glass container is +212 mV, NO. The ORP value of water in the two containers is +210 mV, NO. The ORP value of the water in the three containers is +213 mV, the ORP value of the water sealing the radiator 10 is +138 mV, and when about 12 hours have elapsed, NO. The ORP value of water in one glass container is +209 mV, NO. The ORP value of water in the two containers is +207 mV, NO. The ORP value of the water in the three containers is +210 mV, the ORP value of the water that seals the radiator 10 is +121 mV, and NO. The ORP value of water in one glass container is +208 mV, NO. The ORP value of water in the two containers is +206 mV, NO. The ORP value of the water in the three containers was +209 mV, the ORP value of the water sealing the radiator 10 was +93 mV, and then the respective ORP values were maintained for about 12 hours.
[0063]
When about 12 hours passed, the energization of the radiator 10 was terminated, and the water in each container was stored in a sealed state. The ORP value of water in one glass container is +220 mV, NO. The ORP value of water in the two containers is +225 mV, NO. The ORP value of water in the three containers is +225 mV, the ORP value of water sealing the radiator 10 is +145 mV, and NO. The ORP value of water in one glass container is +233 mV, NO. The ORP value of water in the two containers is +235 mV, NO. The ORP value of water in the three containers was +233 mV, and the ORP value of water sealing the radiator 10 was +197 mV. The results are also shown in Table 1.
[0064]
The water in each container has been drunk. It was mellow and had a refreshing sensation equal to or greater than that of natural water filled in PET bottles and marketed. Moreover, when black tea was extracted with the water in each container, a ring color that could not be obtained with tap water was obtained. Furthermore, when green tea is extracted with water in each container, a bright green color is obtained, and the time until yellowing is about 2 to 3 times that when extracted using normal tap water. It took time. Moreover, when the water in each container was poured into cut flowers at any time, the period until it withered more than doubled compared with the case where normal tap water was poured at any time.
[0065]
<Example 3>
In order to construct the radiator 10 shown in FIG. 4, a 1 mm thick aluminum punching metal (300 × 200 mm) is used as a support plate 14, and a TV coaxial cable (3C2V) having a total length of 7 m is formed in the punch hole at the center. Was inserted from the back and spirally wound around the front of the punching metal toward the outer periphery. The cable was fixed to the support plate 14 with a copper wire having an outer diameter of 6 mm using appropriate punch holes in the support plate 14 made of punching metal.
[0066]
Three such radiators 10 were prepared. As for the cable of each radiator 10, the winding direction of the spiral is the same. Each radiator 10 is arranged in a vertical state in which the cables are opposed to each other with a spacing of 40 cm so that a 40 cm square cubic space is formed on the desk, and the other one. Was arranged horizontally so that the cable was on the lower side so as to cover the upper part between the pair of radiators 10 arranged vertically. The radiator 10 arranged horizontally was suspended by a string. Each radiator 10 was connected in series in place of the radiator 10 in the oscillation circuit 20 shown in FIG. 1 with the respective cables connected in series.
[0067]
In the same manner as in Example 1, each radiator 10 includes a glass container (NO.1) filled with 300 ml of tap water and a polypropylene container (NO.2) filled with 300 ml of tap water. Placed in the center of the space surrounded by. A glass container (NO. 3) filled with 300 ml of tap water was placed on a desk 130 cm away from the space surrounded by each radiator 10. Thereafter, the oscillation circuit 20 was energized under the same conditions as in Example 1.
[0068]
NO. The ORP value of water in one glass container is +261 mV, NO. The ORP value of water in the two containers is +259 mV, NO. The ORP value of the water in the three containers was +260 mV, but when about 1 hour and 30 minutes passed after the start of energization, NO. The ORP value of water in one glass container is +233 mV, NO. The ORP value of water in the two containers is +231 mV, NO. The ORP value of the water in the three containers is +234 mV, and when about 4 hours have passed, NO. The ORP value of water in one glass container is +215 mV, NO. The ORP value of water in the two containers is +215 mV, NO. The ORP value of water in the three containers was +216 mV, respectively. Thereafter, since the respective ORP values were substantially maintained for about 12 hours, the energization to the oscillation circuit 20 was terminated when about 12 hours passed. The result of using water in each container was the same as in Example 2. The results are also shown in Table 1.
[0069]
[Table 1]

[0070]
【The invention's effect】
Since the reducing property imparting method and the reducing property imparting device of the present invention can easily impart reducing properties to an object such as water and food in this way, deterioration of the object due to oxidation, etc. Can be suppressed without using.
[Brief description of the drawings]
FIG. 1 is a schematic configuration diagram showing an example of an embodiment of a reducing property imparting apparatus of the present invention.
FIGS. 2A, 2B, and 2C are perspective views showing another example of a radiator used in the reducing property imparting apparatus. FIG.
FIG. 3 is an enlarged view of a main part showing still another example of a radiator used in the reducing property imparting apparatus of the present invention.
FIG. 4 is a perspective view showing still another example of a radiator used in the reducing property imparting apparatus of the present invention.
FIG. 5 is a perspective view showing still another example of a radiator used in the reducing property imparting apparatus of the present invention.
[Explanation of symbols]
10 Radiator
11 Conductive wire
12 Short-circuit part
13 Support block
14 Support plate
15 Metal plate
20 Oscillator circuit
21 1st condenser
22 Second condenser
23 3rd resistor
24 4th resistor
26 Slidac
27 Discharge tube

Claims (11)

A reducing property imparting method characterized by irradiating an object to be imparted with a reducing property, an electromagnetic wave having a low frequency of 7 Hz or less and having a longitudinal wave property. The reducing property imparting method according to claim 1, wherein a fine waveform component is superimposed on the electromagnetic wave. Power supply means for generating an alternating current with a low frequency of 7 Hz or less;
One or a plurality of radiators that are energized with an alternating current generated by the power supply means and emit electromagnetic waves of a low frequency of 7 Hz or less having a longitudinal wave property;
A reducibility imparting device comprising: The reduction | restoration provision apparatus of Claim 3 with which the said power supply means generate | occur | produces the alternating current on which the fine waveform component was superimposed. The reduction | restoration imparting apparatus of Claim 3 with which the said power supply means has an oscillation circuit comprised by the bridge circuit in which the alternating current of a low frequency of 7 Hz or less is emitted when an alternating current is supplied. In the bridge circuit of the oscillation circuit, capacitors are provided on the first side and the second side adjacent to each other, and resistors are provided on the third side and the fourth side adjacent to each other. The reducing property imparting apparatus according to claim 5, wherein one radiator or a plurality of radiators connected in series to each other is provided in series with a capacitor provided on the second side. The reducing property imparting apparatus according to claim 6, wherein a discharge tube is connected in series to the radiator. The reducing device according to claim 3, wherein the radiator is configured by winding a pair of conductive wires in which one end portions are short-circuited in a coil shape in a parallel state. 4. The reducing property imparting apparatus according to claim 3, wherein there are a plurality of the radiators, and each radiator is configured by winding one conductive wire in a spiral shape in a plane. The reducing device according to claim 3, wherein the radiator is configured by electrically connecting a plurality of conductive plates arranged in parallel at appropriate intervals in series. The reducing device according to claim 3, wherein the radiator is disposed in air or water.

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