JP6626230B1 - Magnetic vibration water, magnetic vibration water production method, and magnetic vibration water production apparatus - Google Patents

Abstract

An object of the present invention is to produce a magnetically vibrated water in which the interaction between water molecules is weakened by subjecting water to a damped oscillating magnetic field treatment with a magnetically oscillating water producing apparatus for applying a strong damping oscillating magnetic field. An object of the present invention is to provide a method for producing magnetically vibrated water having physical properties and / or functionality. According to the present invention, a magnetic treatment water tank for magnetically treating water to be treated is accommodated in an air-core magnetic coil, a step of supplying the water to the magnetic treatment water tank, and a connection to the magnetic coil. Charging the capacitor, and discharging the power charged in the capacitor to the magnetic coil to form a damped oscillating magnetic field having a maximum peak intensity of 1.0 Tesla or more in the magnetic coil and applying the damped oscillating magnetic field to the water to be treated. Producing the magnetically vibrated water by the steps. [Selection diagram] Fig. 1

Description

The present invention relates to a magnetic vibration water method magnetic vibration water, and relates to a magnetic vibration water made ZoSo location, and more particularly, magnetic vibrations water magnetically vibration treatment by applying a damped oscillation magnetic field to the water to be treated, the magnetic vibrations The present invention relates to a water production method and a magnetic vibration water production device.

The boiling point of a liquid substantially correlates with the molecular weight if there is no interaction between the molecules of the liquid substance. However, water has a boiling point (1 atm) of 100 ° C. and a molecular weight of 18, whereas n-heptane having a boiling point similar to that of water (98 ° C.) has a molecular weight of 100. The cause of this difference is that the water molecule consists of two hydrogen atoms and one oxygen atom, and liquid water forms weak bonds between the hydrogen and oxygen atoms of adjacent water molecules, water molecules from the surface of the liquid water is because it inhibits the pop become steam (are detained).

  This weak bond between the oxygen atom and the hydrogen atom of water is an example of a well-known hydrogen bond, and the hydrogen bond between water molecules has a great effect on the properties of water. As an example, water has a property that it is difficult to diffuse into a living body, because the hydrogen bond between water molecules stops liquid water from changing to molecular water and passing through a biological membrane, It is believed to be inhibiting.

In general, a molecular bond is formed by two electrons forming a pair, but a bond including a specific atom such as a hydrogen atom forms a molecular bond when a strong magnetic field is applied. The energy level of the two electrons is polarized, and the energy corresponding to the energy difference is absorbed to activate the bond. An analysis method that utilizes this phenomenon is called a nuclear magnetic resonance absorption method (NMR), and MRI is an application of this technology to medical treatment by observing the inside of a human body.
Since the activation of molecular bonds means a decrease in the bonding strength of molecular bonds, it is presumed that if nuclear magnetic resonance absorption occurs, hydrogen bonds, which are originally weak bonds, will be further weakened.

However, nuclear magnetic resonance absorption is a phenomenon that occurs at a very high magnetic field, and NMR and MRI are performed using a magnetic field formed using a superconductor electromagnet. For example, at a magnetic field intensity of 11.74 Tesla (9365 KA / m), hydrogen ( ¹ H) absorbs 500 MHz electromagnetic waves and is activated, carbon ( ¹³ C) absorbs 125 MHz electromagnetic waves, and nitrogen ( ¹⁴ N) becomes It is activated by absorbing an electromagnetic wave of 35 MHz (Non-Patent Document 1).
Conventionally, such a strong magnetic field has not been applied to water for manufacturing purposes.

  In recent years, rare earth magnets having high magnetic properties have been developed and widely used as indispensable materials, and it is expected that the usage will increase further in the future. However, the rare earth magnet has a problem that it is extremely difficult to demagnetize the magnet once magnetized when demagnetization is required for some reason.

  In order to demagnetize the magnetized rare earth magnet, a magnetic processing coil for demagnetizing the magnet, a capacitor for supplying power to the magnetic processing coil, a charging circuit for charging the capacitor, and a power for charging the capacitor And a discharge circuit that instantaneously discharges the magnetic processing coil to form a damped oscillating magnetic field having a high peak intensity in the magnetic processing coil. For example, Patent Document 1 discloses a degaussing device that generates a strong magnetic field having a maximum peak intensity of 10 Tesla (7960 kA / m).

  The present invention applies a damped oscillating magnetic field having high peak intensity equivalent to that used in nuclear magnetic resonance analysis to water, polarizes and activates hydrogen bonds, which are intermolecular bonds of water, to weaken hydrogen bonds, Thereby, the water is activated to provide a new magnetic vibration water having a new functionality.

JP-A-2015-35558 JP 2011-249612 A

Nuclear magnetic resonance apparatus JEOL Ltd. Internet search http: // www. jeol. co. jp / science / nmr. html (Searched March 18, 2019)

It is an object of the present invention to provide a method for producing magnetically vibrated water having a new physical property and / or functionality by applying a strong damped oscillating magnetic field to water.
Another object of the present invention is to provide a magnetically vibrating water producing apparatus which forms a strong damped oscillating magnetic field and treats water with a damped oscillating magnetic field.

Another object of the present invention is to provide a magnetic vibration water producing apparatus that prevents overheating of the magnetic vibration water producing apparatus.
Still another object of the present invention is to provide a magnetically vibrated water in a state where a damped oscillating magnetic field is applied by using a magnetically oscillating water producing apparatus that forms a strong damped oscillating magnetic field.

The present invention has been made to solve such a problem, and includes a step of housing a magnetically treated water tank for magnetically treating water to be treated in an air-core magnetic coil, and the step of supplying the treated water to the magnetically treated water tank. Supplying, charging a capacitor connected to the magnetic coil, and discharging the electric power charged in the capacitor to the magnetic coil using a discharge circuit having a thyristor switch connected in anti-parallel to damped oscillation due to LCR resonance Generating a current and generating an attenuated oscillating magnetic field having a maximum peak intensity of 1.0 Tesla or more in the magnetic coil and applying the damped oscillating magnetic field to the water to be treated, thereby producing magnetically oscillating water.

Further, the water to be treated is distilled water, deionized water, purified water including reverse osmotic water, tap water, well water, natural water, drinking water including mineral water, and the like, cooking water, fruit juice, tea, coffee, tea, and cooking food water, including alcohol, etc., skin treated water, hair treated water, cleansing solution, and an aqueous cosmetic containing the perfume and the like, saline, injection, medical water, including 及 beauty ophthalmic solution or the like, electrolytic It is at least one selected from functional water including water, hydrogen water, and oxygen water, salt water, and waste water.
It is preferable that cooling means is further provided between the magnetic coil and the magnetic treatment tank.

A magnetically treated water tank for magnetically treating water to be treated, an air-core magnetic coil for housing the magnetically treated water tank, a capacitor for supplying power to the magnetic coil, a charging circuit for charging the capacitor, and a thyristor switch connected in antiparallel A magnetic field oscillating device including a discharge circuit that discharges the electric power charged in the capacitor to the magnetic coil, wherein the discharge circuit discharges the electric power of the capacitor to the magnetic coil by damping vibration due to LCR resonance to the magnetic coil. An apparatus for producing magnetically vibrated water, wherein a damped oscillating magnetic field having a maximum peak intensity of 1.0 Tesla or more is formed.

  By applying a damped oscillating magnetic field having a maximum peak intensity of 1.0 Tesla or more to the magnetic coil in a state where the magnetically treated water tank is accommodated in the magnetic coil, the water to be treated is in a state where the damped oscillating magnetic field is applied. Magnetic vibration water characterized by the above.

  According to the method for producing magnetically vibrated water of the present invention, the electric power charged in the capacitor is discharged to the magnetic coil to form an attenuated vibrating magnetic field having a maximum peak intensity of 1.0 Tesla or more in the magnetic coil, and the water is treated. By applying, magnetically vibrated water having excellent permeability and a novel function can be produced.

  The magnetic vibration water of the present invention was evaluated by sensory tests as being more delicious than the raw tap water. Further, it was shown that the magnetic vibrating water of the present invention has an increased osmotic power, and when flowers are used, the flowers do not wither and stay longer than when tap water is used, and the seed germination rate is improved.

In addition, the method for producing magnetically vibrated water according to another embodiment of the present invention further includes a cooling means between the magnetically treated water tank and the magnetically treated water tank, and prevents the temperature of the magnetically treated water tank from rising during application of the damping vibration magnetic field. be able to.
Further, the present invention can provide a novel magnetic vibrating water in a state where a damped oscillating magnetic field having a maximum peak intensity of 1.0 Tesla or more is applied to the water to be treated.

It is a perspective view showing composition of a magnetic vibration water production device concerning one example of the present invention. It is sectional drawing which shows the magnetic treatment water tank and magnetic coil which concern on one Example of this invention. It is a circuit diagram of the magnetic field vibration device of the present invention. It is a process block diagram of the manufacturing method of magnetic vibration water of the present invention. 5 is a graph showing the magnetic field strength of the damped oscillating magnetic field of the present invention. It is sectional drawing which shows the magnetic treatment water tank and magnetic coil which concern on another Example of this invention. It is the figure which used wild chrysanthemum for magnetic vibration water and tap water of the present invention, and observed until wild chrysanthemum withered.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
FIG. 1 is a perspective view showing a configuration of a magnetic vibration water producing apparatus according to one embodiment of the present invention, and FIG. 2 is a cross-sectional view showing a magnetic treatment water tank and a magnetic coil according to one embodiment of the present invention. .
As shown in FIGS. 1 and 2, a magnetic vibration water producing apparatus 1 according to one embodiment of the present invention includes a magnetically treated water tank 10 and a magnetic field vibration device 20.

The magnetically treated water tank 10 is formed inside a magnetic field vibrator 20 and is made of a material through which lines of magnetic force can pass, and includes a treated water introduction valve 13 and a treated water introduction pipe 11 provided with a pump 15 for supplying treated water 16. And a treated water discharge pipe 12 provided with a treated water discharge valve 14.

  The magnetic field vibration device 20 includes an air-core magnetic coil 30 that accommodates the magnetic treatment water tank 10 and applies a magnetic field, a capacitor 40 that supplies power to the magnetic coil 30, a charging circuit 50 that charges the capacitor 40, It is preferable to include a discharge circuit 60 that instantaneously discharges the power charged in the capacitor 40 to the magnetic coil 30 to generate a damped oscillating current due to LCR resonance, and causes the magnetic coil 30 to form a damped oscillating magnetic field. The charging circuit 50 can be connected to a commercial power supply 52.

  In the magnetic coil 30 of the present invention, it is preferable to apply a magnetic field having a maximum peak intensity of a damped oscillating magnetic field of 1.0 Tesla or more to the magnetic treatment water tank 10 to magnetically treat water, and to have a maximum peak intensity of 5.0. It is more preferable to apply a magnetic field of Tesla or more. If the maximum peak intensity of the damping oscillating magnetic field is less than 1.0 Tesla, a sufficiently strong damping oscillating magnetic field may not be applied to the water 16 to be treated. Since the maximum peak intensity of the damped oscillating magnetic field is limited to the maximum peak intensity of the usable magnetic field vibration device 20, no upper limit is set.

FIG. 3 is a circuit diagram of the magnetic field vibration device of the present invention.
As shown in FIG. 3, the magnetic field vibration device 20 of the present invention preferably includes a charging circuit 50 and a discharging circuit 60.

  The charging circuit 50 includes a step-up transformer 54 having a primary coil 54 a connected to the commercial power source 52, an AC phase control circuit 56 including a thyristor element connected in anti-parallel to one terminal of the commercial power source 52, A dual-wave rectifier circuit 58 connected to the secondary coil 54b for full-wave rectification of the boosted AC is provided, and a voltage detection circuit 59 is connected between the DC output terminals of the dual-wave rectifier circuit 58. The capacitor 40 is connected between both terminals of the voltage detection circuit 59, and the voltage detection circuit 59 detects the charging voltage of the capacitor 40.

On the other hand, the discharge circuit 60 includes the capacitor 40 and the magnetic coil 30 connected between both electrodes of the capacitor 40. The discharge circuit 60 includes a plurality of thyristors tasks acme switch 6 2.

FIG. 4 is a process block diagram of the method for producing magnetic vibration water of the present invention.
As shown in FIG. 4, the first stage of the method for producing magnetically vibrated water of the present invention includes a to-be-treated water storage stage (S-1) in which the to-be-treated water 16 is contained in the magnetically treated water tank 10.

Here, the water 16 to be treated is distilled water, deionized water, purified water including reverse osmotic water, tap water, well water, natural water, drinking water including mineral water, and the like, cooking water, fruit juice, tea. , coffee, tea, and cooking food water, skin processing water containing alcohol, such as, hair treated water, cleansing solution, and an aqueous cosmetic containing the perfume and the like, saline, injection, medical water, including 及 beauty ophthalmic solution or the like, It may be at least one selected from functional water including electrolyzed water, hydrogen water, and oxygen water, saline, and wastewater.

  In addition, the present embodiment includes a capacitor charging step (S-2) in which the voltage controlled from the commercial power supply 52 via the step-up transformer 54, the AC phase control circuit 56, and the double-wave rectification circuit 58 charges the capacitor 40. Can be. At this time, all the switching elements 62 of the discharge circuit 60 are off. In addition, the order of the to-be-processed water accommodating stage and the capacitor charging stage can be interchanged.

  Next, when the voltage detection circuit 59 detects that the voltage of the capacitor 40 reaches the set voltage and the charging is completed, the AC phase control circuit 56 electrically disconnects the commercial power supply 52 and the capacitor 40 from each other. (S-3) is performed.

Next, the discharge circuit is controlled to perform the damping oscillating magnetic field applying step (S-4).
When the electric power charged in the capacitor 40 is instantaneously discharged to the magnetic coil 30, a damped oscillating current is generated in the capacitor 40 and the magnetic coil 30 due to LCR resonance.
FIG. 5 is a graph showing the magnetic field strength of the damped oscillating magnetic field according to the present invention.

  The method of generating and applying a waveform of a damped oscillating magnetic field and a magnetic field strength peak value as shown in FIG. 5 by a predetermined magnetic field oscillating device 20 includes the electromagnetic properties and voltages of the magnetic coil 30 and the capacitor 40, and the thyristor of the discharge circuit. Although control can be performed by the configuration and operation method of the switch, these are design items of those skilled in the art, and are also described in Patent Documents 1 and 2, and thus detailed description is omitted.

According to the present invention, the magnetic treatment of the water contained in the magnetic treatment water tank 10 can be performed a plurality of times.
Magnetic Kisho sense of a predetermined number of times to fetch magnetic water treatment when finished with magnetic vibration water discharge step (S-5).

The magnetic field vibrating device 20 of the present invention generates heat based on electric resistance because a high-voltage damped oscillating current is applied to the magnetic coil 30. However, since the processing time is short, a cooling device is particularly necessary when the number of times of processing is small. And not. However, if the number of processing times the greater the magnetic field vibration device 20 is heated, the magnetic coil 30 and / or magnetic treatment water tank 10 may become hot.

FIG. 6 is a sectional view of a magnetic treatment water tank and a magnetic coil according to another embodiment of the present invention.
As shown in FIG. 6, a magnetic field vibration device 120 according to another embodiment of the present invention includes a cooling unit 131 between a magnetic coil 130 and a magnetically treated water tank 10. The cooling means is not particularly limited as long as it can transmit magnetism and shut off generated heat, but a cooling water circulating device formed of a magnetically permeable material, or a cooling device such as a liquid nitrogen spraying device may be used. Can be.

Hereinafter, the present invention will be described with reference to examples.
[Example 1]
Using an air-core magnetic coil 30 having an inner diameter of 110 mm and a length of 220 mm and a capacitor 40 of the type shown in FIG. 1, 500 mL of tap water contained in a magnetic treatment water tank 10 having an inner diameter of 80 mm and a length of 100 mm was subjected to magnetic vibration treatment.
After the capacitor 40 is charged from the commercial power supply 52 to a voltage of 3500 V using the step-up transformer 54 and the charging circuit 50 and the capacitor 40 are electrically disconnected, the electric power charged in the capacitor 40 is discharged using the discharging circuit 60. An instantaneous discharge is generated in the magnetic coil 30 to generate a vibration damping current, and a vibration damping magnetic field having a maximum peak intensity of 4.46 MA / m (5.6 Tesla) is applied to the magnetic coil 30. The water 16 to be treated was discharged from the treated water tank 10 to obtain 500 mL of the magnetic vibration water of Example 1.

[Example 2]
Using an air-core magnetic coil 30 having an inner diameter of 50 mm and a length of 200 mm and a condenser 40 of the type shown in FIG. 1, 80 mL of tap water stored in a magnetic treatment water tank 10 having an inner diameter of 32 mm and a length of 100 mm was subjected to magnetic vibration treatment.
After the capacitor 40 is charged from the commercial power supply 52 using the step-up transformer 54 and the charging circuit 50 and the capacitor 40 are electrically disconnected, the electric power charged in the capacitor 40 is supplied to the magnetic coil using the discharging circuit 60. Discharge instantaneously to generate a vibration damping current, apply a vibration damping magnetic field having a maximum peak intensity of 0.80 MA / m (1.0 Tesla) to the magnetic coil 30, and after the vibration damping magnetic field disappears, The water 16 to be treated was discharged to obtain 80 mL of magnetic vibration water of Example 2.

[Example 3]
Used form of internal diameter 70mm shown in FIG. 6, the magnetic coil 1 30 for air core length 200 mm, a capacitor 40, and a cooling means 131 of the glass cylinder and housed in the magnetic treatment water tank 10 having an inner diameter of 32mm length 100 mm 80 mL Tap water (water temperature at the start: 18 ° C.) was subjected to magnetic vibration treatment.
After the capacitor 40 is charged from the commercial power source 52 using the step-up transformer 54 and the charging circuit 50 and the capacitor 40 are electrically disconnected, the electric power charged in the capacitor 40 is transferred to the magnetic coil 130 using the discharging circuit 60. after instant discharged by generating vibration damping current, by applying a vibration damping magnetic field of the highest peak intensity 0.80MA / m (1.0 Tesla) in the magnetic coil 1 30, the vibration damping magnetic field disappears, the capacitor 40 After the operation of recharging and re-discharging the magnetic coil was repeated 10 times at 10-minute intervals, the water 16 to be treated was discharged from the magnetically treated water tank 10 to obtain 80 mL of magnetically vibrated water of Example 3. The temperature of the magnetic vibration water of Example 3 immediately after the completion of the treatment was 28 ° C.
The sensory test showed that the magnetic vibration water obtained in Example 3 had the same taste as the magnetic vibration water obtained in Example 1.

[Comparative Example 1]
As in Example 2, 80 mL of tap water stored in a magnetic treatment water tank 10 having an inner diameter of 32 mm and a length of 100 mm using an air-core magnetic coil 30 and a condenser 40 having an inner diameter of 50 mm and a length of 200 mm of the type shown in FIG. Was subjected to a magnetic vibration treatment, except that the maximum peak intensity of the vibration damping magnetism applied to the vibration damping magnetic coil 30 was 0.40 MA / m (0.5 Tesla) to obtain a magnetic vibration water of Comparative Example 1.

[Comparative Example 2]
In the same manner as in Example 2, 80 mL of tap water contained in a magnetic treatment water tank 10 having an inner diameter of 32 mm and a length of 100 mm using an air-core magnetic coil 30 and a condenser 40 having an inner diameter of 50 mm and a length of 200 mm of the type shown in FIG. Magnetic vibration processing is performed using a vibration damping magnetic field having a maximum peak intensity of 0.80 MA / m (1.0 Tesla), and then, after the vibration damping magnetic field has disappeared, an operation of recharging the capacitor 40 and discharging the magnetic coil again is performed. When the process was repeated seven times at minute intervals, the temperature of the water 16 to be treated in the magnetically treated water tank 10 reached 85 ° C., and the operation was stopped. 80 mL of vibration water was obtained.
The magnetically oscillated water of Comparative Example 2 was cooled to 15 ° C. and subjected to a sensory test. The taste of the magnetically oscillated water of Comparative Example 2 was inferior to the taste of the magnetically oscillated water of Example 2.

(sensory test)
Example 1 and Example 2, Example 2 and Comparative Example 1, and Comparative Example 1 and tap water were compared by a sensory test.
<Test method>
The temperature of the test water in the 15 ℃, 20 panelists (12 females, 8 males) presented without informing the type of water in, compared to drink either water or delicious, or whether the same I got it.
<Judgment criteria>
When the number of panelists who answered that they are the same (I do not know) is 10 or less, and the number of panelists who selected one magnetically oscillating water is more than twice the number of panelists who selected the other magnetically oscillating water One magnetic vibrating water was judged to be more delicious, and when this condition was not satisfied, it was judged that there was no difference between the sensory evaluations of both magnetic vibrating waters.

<Result>
Comparison of Magnetic Vibration Water of Example 1 and Magnetic Vibration Water of Example 2 Nine panelists answered that the magnetic vibration water of Example 1 was more delicious, and three panelists preferred the magnetic vibration water of Example 2 He answered that he did not know the remaining eight people. Therefore, it was determined that the magnetic vibration water of Example 1 was more delicious.
Comparison of Magnetic Vibration Water of Example 2 with Magnetic Vibration Water of Comparative Example 1 Twelve panelists answered that the magnetic vibration water of Example 2 was more delicious, and two panelists answered that the magnetic vibration water of Comparative Example 1 was good. He said that it was better. Therefore, it was determined that the magnetic vibration water of Example 2 was more delicious than the magnetic vibration water of Comparative Example 1 .
Comparison of Magnetic Vibration Water of Example 2 and Tap Water Five panelists answered that the magnetic vibration water of Example 2 was more delicious, and three panelists answered that tap water was more delicious. Therefore, it was determined that there was no significant difference between the taste of the magnetic vibration water of Example 2 and the taste of tap water.

  Magnetic vibration water in which a vibration damping magnetic field having a maximum peak intensity of 4.46 MA / m (5.6 Tesla) is applied to the magnetic coil 30 of the first embodiment, and a magnetic peak water of 0.80 MA / m (1.0 The magnetic vibration water to which the vibration damping magnetic field of (Tesla) was applied was judged by the sensory test that the magnetic vibration water of Example 1 was more delicious (although there is no great difference), and the magnetic vibration water of Example 2 and Comparative Example 1 In the case of the magnetically vibrated water to which a vibration damping magnetic field having a maximum peak intensity of 0.40 MA / m (0.5 Tesla) was applied, the magnetically vibrated water of Example 2 was determined to be more delicious, and the magnetically vibrated water of Comparative Example 1 was determined. The taste and the taste of tap water were determined to have no significant difference in the sensory test. Therefore, the present invention limits the maximum peak intensity of the vibration damping magnetic field applied to the magnetic coil 30 to be 1.0 Tesla (0.80 MA / m) or more.

(Permeability test)
[Example 4 ]
FIG. 7 is a diagram in which wild chrysanthemums are utilized in the magnetic vibration water and tap water of the present invention, and the wild chrysanthemums are observed until they die.
As shown in FIG. 7a, 3 g of sodium chloride was dissolved in 200 mL of magnetic vibration water obtained in Example 1 to obtain Example 4, and 3 g of sodium chloride was dissolved in 200 mL of tap water used for production of magnetic vibration water. In Example 3, wild chrysanthemum flowers were used as cut flowers, and the saline of Example 1 and the saline of tap water were exchanged daily and observed.
As shown in FIG. 7b, on the 16th day after the start of the test, the wild chrysanthemum flowers used in the salt water of Comparative Example 3 withered, but the wild chrysanthemum flowers used in the salt water of the magnetically oscillating water of Example 1 of Example 4 died. The flowers were fine.
As shown in FIG. 7c, the wild chrysanthemum flower used in the vibration water of the test example of Example 4 died on the 36th day.

  When cutting flowers are used, it is said that it is important to suck water from the cut to make the cut flowers last longer. The magnetically vibrating water of Example 1 was obtained by applying a strong vibration damping magnetic field to weaken the hydrogen bonds between water molecules, so that water easily penetrated from the cut ends of cut flowers to extend the cut flowers of wild chrysanthemum. it is conceivable that.

(Germination test)
<Measurement method>
[Example 5 ]
Two sheets of filter paper are placed on a glass Petri dish, and the whole surface is moistened by dripping the magnetic vibration water produced in Example 1, and 100 seeds are placed on the Petri dish so that they do not overlap. And put it in a chiller at the specified temperature. During the test, observation was made daily while replenishing magnetic vibrating water so as not to dry the filter paper, germinated seeds were removed, and the germination rate was calculated from the number of remaining seeds.
Germination rate (%) = Number of germinated seeds / Number of sown seeds × 100
[Comparative Example 4 ]
A germination test was performed in the same manner as in Example 5 , except that tap water was used instead of the magnetically oscillating water produced in Example 1.

(2) Results Table 1 shows the results of the germination test.

As shown in Table 1, the germination rate of all the seeds was improved by using the magnetic vibration water manufactured in Example 1 in Example 5 as compared with the case of using the tap water in Comparative Example 4 .
Seeds germinate when given moisture at an appropriate temperature, but the magnetic vibration water produced in Example 1 is subjected to a strong vibration damping magnetic field to weaken hydrogen bonds between water molecules. It is considered that the magnetically oscillating water quickly penetrated the seeds and improved the germination rate.

  As described above, the preferred embodiments of the present invention have been described. However, the present invention is not limited to the above-described embodiments, and includes all modifications without departing from the technical scope to which the present invention belongs.

DESCRIPTION OF SYMBOLS 1 Magnetic vibration water manufacturing apparatus 5 Magnetic vibration water 10 Magnetic treatment water tank 11 Treatment water introduction pipe 12 Treatment water discharge pipe 13 Treatment water introduction valve 14 Treatment water discharge valve 15 Pump 16 Treatment water 20, 120 Magnetic field vibration device 30, 130 Magnetic coil 40 Capacitor 50 Charging circuit 52 Commercial power supply 54 Boost transformer 54a Primary coil 54b Secondary coil 56 AC phase control circuit 58 Double-wave rectifier circuit 59 Voltage detection circuit 60 Discharge circuit 62 Thyristor switch 131 Cooling means

Claims (4)

Housing a magnetically treated water tank for magnetically treating the water to be treated in an air-core magnetic coil;
Supplying the water to be treated to the magnetically treated water tank;
Charging a capacitor connected to the magnetic coil;
The power charged in the capacitor is discharged to the magnetic coil using a discharge circuit having a thyristor switch connected in anti-parallel to generate an attenuated oscillating current due to LCR resonance . Forming a damped oscillating magnetic field of 0 Tesla or more and applying the same to the water to be treated;
A method for producing magnetic vibration water, comprising producing magnetic vibration water by the method. The treated water is distilled water, deionized water, purified water including reverse osmotic water, tap water, well water, natural water, drinking water including mineral water, etc., cooking water, fruit juice, tea, coffee, tea and cooking food water containing liquor or the like, the skin treated water, hair treated water, facial solution, and an aqueous cosmetic containing perfumes, etc., physiological saline, injectable solutions, medical water containing 及 beauty eye drops or the like, the electrolytic water, hydrogen The method for producing magnetically vibrated water according to claim 1, wherein the water is at least one selected from functional water containing water and oxygen water, salt water, and waste water.   The method according to claim 1, further comprising a cooling unit between the magnetic coil and the magnetic treatment water tank. A magnetically treated water tank for magnetically treating the water to be treated,
An air-core magnetic coil accommodating the magnetic treatment water tank therein, a capacitor for supplying power to the magnetic coil, a charging circuit for charging the capacitor, and a thyristor switch connected in anti-parallel to charge the capacitor A discharge circuit that discharges the generated power to the magnetic coil, and a magnetic field vibration device including:
With
The discharging circuit forms a damped oscillating magnetic field having a maximum peak intensity of 1.0 Tesla or more in the magnetic coil by an oscillating current caused by LCR resonance when discharging the power of the capacitor to the magnetic coil. Magnetic vibration water production equipment.