WO2022019251A1 - Magnetic field generation device, magnetic field generation system, method for producing irradiated target object, irradiated target object, liquid, water, humidifier, humidification method, program, and computer-readable storage medium - Google Patents

Abstract

[Problem] To provide a magnetic field generation device capable of generating a magnetic field which has a prescribed frequency, a magnetic field generation system, a method for producing an irradiated target object, an irradiated target object, a liquid, water, a humidifier, a humidification method, a program and a computer-readable storage medium. [Solution] A magnetic field generation device 30 according to the present invention for generating a magnetic field at a prescribed frequency, said magnetic field generation device 30 being capable of generating a magnetic field at a prescribed frequency, having a power source unit 10 which has a prescribed power source 10a, and also having a control unit 20 for controlling the power source unit 10 and a magnetic field generation unit 30 which generates a magnetic field at the prescribed frequency when an electric current is supplied from the power source unit 10.

Description

Magnetic field generator, magnetic field generation system, production method of irradiation target, irradiation target, liquid, water, humidifier, humidification method, program, computer-readable storage medium

The present invention relates to a magnetic field generator, a magnetic field generation system, a production method of an irradiation object, an irradiation object, a liquid, water, a humidifier, a humidification method, a program, and a computer-readable storage medium.

In recent years, health consciousness has been increasing more and more. For example, Patent Document 1 discloses a health appliance having an uneven surface.

Japanese Unexamined Patent Publication No. 2020-31907

By the way, in recent years, from the viewpoint of treatment and prevention of diseases, there is an increasing demand for irradiation objects such as water irradiated with a magnetic field of a predetermined frequency.

The present invention has been made in view of the above circumstances, and is a magnetic field generator capable of generating a magnetic field of a predetermined frequency, a magnetic field generation system, a production method of an irradiation object, an irradiation object, a liquid, water, and a humidifier. , Humidification methods, programs, and computer-readable storage media.

In order to achieve the above object, the magnetic field generator of the present invention is a magnetic field generator that generates a magnetic field at a predetermined frequency, and is characterized by having a generator that generates a magnetic field at the predetermined frequency.

The magnetic field of the predetermined frequency can be generated by repeatedly generating a pulse current.

The pulse current can be at least one of a positive electrode pulse current, a negative electrode pulse current, and a bipolar pulse current in which the positive electrode pulse current and the negative electrode pulse current are alternately and repeatedly generated.

By irradiating the irradiation target with a magnetic field having a predetermined frequency generated by the magnetic field generating unit, it is possible to provide the irradiation target irradiated with the predetermined magnetic field.

The irradiated object can contain a liquid, and the liquid can contain water.

In order to achieve the above object, the magnetic field generator of the present invention is a magnetic field generator that generates a magnetic field at a predetermined frequency, and includes a power supply unit having a predetermined power supply, a control unit that controls the power supply unit, and the like. It is characterized by having a magnetic field generating unit that generates a magnetic field of the predetermined frequency when a current is supplied from the power supply unit.

According to the present invention, a magnetic field having a predetermined frequency can be generated by the power supply unit, the control unit, and the magnetic field generating unit having the above configuration.

The power supply unit can form a first electric circuit through which the current of the positive electrode flows and a second electric circuit through which the current of the negative electrode flows.

The power supply unit has a resistance, and if the resistance value of the resistance is 2 to 15 kΩ, the resistance value can be set to the same level as that of the human body.

If the control unit has a polarity control unit that controls the polarity of the current and a frequency control unit that controls the frequency of the current, the control unit controls the polarity of the current and controls the frequency of the current. Can be done.

The polarity control unit includes a first polarity control, which is a control in which the polarity of the current is a positive electrode, a second polarity control, which is a control in which the polarity of the current is a negative electrode, and both poles including currents of the positive electrode and the negative electrode. At least one of the third polarity controls, which is the control to generate the sex current, can be performed.

The frequency control unit can repeatedly generate a pulse current and control the frequency of the pulse current to set the frequency of the magnetic field in the magnetic field generation unit to a predetermined frequency.

That is, the frequency control unit repeatedly generates the pulse current of the negative electrode in the first frequency control, which is the control for repeatedly generating the pulse current of the positive electrode in the first polarity control, and the second polarity control. In the second frequency control, which is the control to be performed, and in the third polarity control, the pulse current of the positive electrode and the pulse current of the negative electrode are alternately repeated to generate a pulse current of both polarities. By performing at least one of the frequency controls, the frequency of the pulse current can be controlled to set the frequency of the magnetic field in the magnetic field generation unit to a predetermined frequency.

If the voltage control unit for controlling the voltage applied to the magnetic field generation unit is provided, the frequency intensity in the magnetic field generation unit can be controlled.

The voltage control unit can control the voltage applied to the magnetic field generation unit in the low frequency region.

The magnetic field generating portion can be configured by a predetermined coil, and the coil can be a flat coil. The flat coil may be a spiral coil, and the spiral coil may have a spiral portion composed of a spirally wound electric wire.

The spiral portion has surfaces on the front surface side and the back surface side, and the magnetic flux of the magnetic field generated from the one surface is weakened on one of the front surface side and the back surface side to weaken the magnetic flux on the front surface side. And a member for strengthening the magnetic flux of the magnetic field generated from any one of the back surfaces can be provided.

The member has a plate shape and can be configured to include a magnetic material.
The magnetic material may be ceramics, and the ceramics may be ferrite. That is, by providing the member containing ferrite on either the front surface side or the back surface side of the spiral portion, the magnetic flux of the magnetic field generated from either the front surface side or the back surface side is surely weakened. It is possible to increase the magnetic flux of the magnetic field generated from either the front surface side or the back surface side.

The spiral portion is configured by winding the electric wire in a spiral shape from the outside toward the center side, and the winding direction of the electric wire from the outside toward the center side is right-handed. The winding direction of the electric wire can be the direction of drawing out bioenergy.

The swirl portion can generate a scalar wave.
That is, the spiral portion includes a first winding portion formed by spirally winding the electric wire from the outside toward the center side, and an end portion of the electric wire on the center side of the first winding portion. The first winding portion and the second winding portion have a second winding portion that is formed by spirally winding from the side to the outside, and the directions in which the current flows are opposite to each other. Can be oriented.

The first winding portion is configured by winding the electric wire from the outside toward the center side in a winding shape at predetermined intervals, and the second winding portion is the first winding portion. Continuously connected to the central end of the winding portion, the electric wire is spirally wound from the central end of the first winding portion toward the outside within the interval of the first winding portion. Can be configured.

If the predetermined information input by the input unit includes information for the polarity control unit to control the polarity of the current and information for the frequency control unit to control the frequency, the information terminal. The polarity of the current and the frequency can be controlled by the control information from the device.

By irradiating the irradiation target with a magnetic field having a predetermined frequency generated by the magnetic field generating unit, it is possible to provide the irradiation target irradiated with the predetermined magnetic field.

The irradiated object can contain a liquid, and the liquid can contain water.
If the control unit has an input unit for inputting predetermined control information for controlling the power supply unit from the predetermined information terminal device, the power supply unit is controlled by the control information from the predetermined information terminal device. It can be performed.

The information terminal device may have an output unit that outputs the predetermined control information to the control unit.

In order to achieve the above object, the magnetic field generation system of the present invention includes the above magnetic field generator and an information terminal device having an output unit for outputting predetermined control information for controlling the power supply unit. It is characterized by that.

In order to achieve the above object, the production method of the present invention irradiates an irradiation target with a magnetic field having a predetermined frequency generated by the magnetic field generator to produce an irradiation target irradiated with the magnetic field. It is a feature.

The irradiation target can be a liquid, and the liquid can be water.

In order to achieve the above object, the irradiation object of the present invention is characterized in that it is produced by irradiating a magnetic field of a predetermined frequency generated by the above magnetic field generator.

In order to achieve the above object, the liquid of the present invention is characterized in that it is produced by irradiating a magnetic field of a predetermined frequency generated by the above magnetic field generator.

In order to achieve the above object, the water of the present invention can be produced by irradiating a magnetic field of a predetermined frequency generated by the above magnetic field generator.

In order to achieve the above object, the humidifier of the present invention is characterized by humidifying with the above water.

In order to achieve the above object, the humidification method of the present invention is characterized by humidifying with the above water.

In order to achieve the above object, the program of the present invention is characterized in that the computer of the magnetic field generator that generates a magnetic field at a predetermined frequency functions as a generator that generates a magnetic field at the predetermined frequency.

In order to achieve the above object, the program of the present invention is characterized in that a computer of a magnetic field generator that generates a magnetic field at a predetermined frequency functions as a control unit that controls a power supply unit having a predetermined power supply.

In order to achieve the above object, the program of the present invention comprises a computer of an information terminal device that outputs control information to a control unit that controls a power supply unit having a predetermined power supply in a magnetic field generator that generates a magnetic field at a predetermined frequency. It is characterized in that it functions as an output unit that outputs the predetermined control information to the control unit.

In order to achieve the above object, the computer-readable storage medium of the present invention is characterized by storing the above program.

According to the present invention, a magnetic field having a predetermined frequency can be generated.

It is a figure which shows the outline of the whole structure of the magnetic field generator which concerns on embodiment of this invention. It is a perspective view which shows the magnetic field generated in the magnetic field generator. It is a circuit diagram which shows the electric circuit of the power-source part of a magnetic field generator. It is a circuit diagram which shows the 1st electric circuit in a power-source part. It is a circuit diagram which shows the 2nd electric circuit in a power-source part. It is a block diagram which shows the structure of a control part. It is a block diagram which shows the structure of the computer of the control part of the magnetic field generator. It is a figure for demonstrating the 1st frequency control in a control part, (a) is a figure which shows the operation of a 1st switch and a 2nd switch, (b) is a figure which shows the operation of a 3rd switch and a 4th switch. , (C) is a diagram showing the frequency of the current. It is a figure for demonstrating the operation of the 2nd frequency control in a control part, (a) is a figure which shows the operation of a 1st switch and a 2nd switch, (b) is the operation of a 3rd switch and a 4th switch. , (C) is a diagram showing the frequency of the current. It is a figure for demonstrating the third frequency control in a control part, (a) is a figure which shows the operation of a 1st switch and a 2nd switch, (b) is a figure which shows the operation of a 3rd switch and a 4th switch. , (C) is a diagram showing the frequency of the current. It is a figure which shows the structure of the magnetic field generation part. FIG. It is a block diagram which shows the structure of the information terminal apparatus which outputs the control information to a magnetic field generator. It is a block diagram which shows the structure of the computer of an information terminal apparatus. It is a flowchart for demonstrating the magnetic field generation method in a magnetic field generator. It is a figure which shows the modification of this invention. It is a figure which shows the structure of the magnetic field generation part of the modification of this invention, (a) is a plan view, (b) is the AA side sectional view of (a), (c) is the BB plan sectional view of (b). .. It is a figure which shows typically the structure of the humidifier which concerns on application example of this invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a diagram showing an outline of the overall configuration of the magnetic field generator according to the embodiment of the present invention, FIG. 2 is a perspective view showing a magnetic field generated in the magnetic field generator, and FIG. 3 is a power supply unit of the magnetic field generator. A circuit diagram showing an electric circuit, FIG. 4 is a circuit diagram showing a first electric circuit in a power supply unit, FIG. 5 is a circuit diagram showing a second electric circuit in a power supply unit, and FIG. 6 is a block showing a configuration of a control unit. FIG. 7 is a block diagram showing a computer configuration of a control unit of a magnetic field generator, FIG. 8 is a diagram for explaining a first frequency control in the control unit, and FIG. 9 is a second diagram in the control unit. A diagram for explaining frequency control, FIG. 10 is a diagram for explaining a third frequency control in a control unit, FIG. 11 is a diagram showing a configuration of a magnetic field generator, and FIG. 12 is a diagram for controlling a magnetic field generator. FIG. 13 is a block diagram showing a configuration of an information terminal device that outputs information, and FIG. 13 is a block diagram showing a configuration of a computer of the information terminal device. In the following description, the direction in which the mounting portion 35 is located in the storage portion 34 is upward, and the opposite side thereof is downward, and each direction is also specified in the drawing.

Explaining the outline of the magnetic field generator 1 according to the embodiment of the present invention with reference to FIGS. 1 and 2, the magnetic field generator 1 is a device that generates a magnetic field at a predetermined frequency, and is a device that generates a magnetic field at a predetermined frequency, and has a power supply control unit 2. It has a magnetic field generating unit 30, and is configured to irradiate the irradiation target M with a magnetic field having a predetermined frequency generated by the magnetic field generating unit 30. That is, the magnetic field generator 1 functions as a magnetic field irradiation device that irradiates the irradiation target M with a magnetic field having a predetermined frequency.

Predetermined control information is transmitted from the information terminal device 50 to the magnetic field generator 1 by wireless or wired communication. As the information terminal device 50, for example, a mobile terminal device 1 such as a personal computer, a mobile phone, a smartphone, or a tablet terminal is used. The information terminal device 50 can communicate with the magnetic field generator 1 by, for example, a short-range wireless system such as Bluetooth (registered trademark). Further, the information terminal device 50 can also communicate with the magnetic field generator 1 via the base station and the control station. The magnetic field generation system 1A can be configured by the magnetic field generation device 1 and the information terminal device 50 of the present embodiment. The information terminal device 50 functions as a controller of the magnetic field generator 1. The user terminal device 3 is owned by a user who uses a commercial vehicle 6, and for example, a mobile terminal device such as a mobile phone, a smartphone, or a tablet terminal is used. The user terminal device 3 is connected to the network communication line 9 via a base station and a control station.

Here, in the present embodiment, the irradiation target object M is a target to be irradiated with a magnetic field having a predetermined frequency generated by the magnetic field generator 1, and can contain at least water, and is a solid in addition to water. , Liquid, gas, living body (human body, animal, plant, etc.) and various other irradiation objects M can be included. That is, by irradiating the irradiation target object M with a magnetic field having a predetermined frequency generated by the magnetic field generator 1, it is possible to produce an irradiation target object M containing a liquid such as water that has been irradiated with the magnetic field and exposed to the magnetic field. By implementing the same production method, it is possible to provide an irradiation target object M containing a liquid such as water produced by irradiating a magnetic field of a predetermined frequency generated by the magnetic field generator 1 and exposing it to the magnetic field. Water irradiated with a magnetic field is particularly called wave water or magnetized water, and further called information water.

The power supply control unit 2 has a power supply unit 10 and a control unit 20. The power supply control unit 2 forms the main body of the magnetic field generator 1, and has a lightweight and / or miniaturized configuration and is suitable for carrying. The power supply control unit 2 functions as a pulse generator.

That is, as shown in FIG. 3, the power supply unit 10 has a power supply 10a, a first electric wire 11, a second electric wire 12, a third electric wire 13, a fourth electric wire 14, a first switch 11a, and a second. It has a switch 12a, a third switch 13a, a fourth switch 14a, a resistance 16, and a voltage control circuit 17.

The power supply 10a is for supplying a current to the magnetic field generation unit 30. The power supply 10a can supply a direct current with a maximum voltage of 16V. The power source 10a can be, for example, a rechargeable lithium ion battery or an alkaline battery. The power supply 10a can be configured by mounting four lithium ion AA batteries as an example, and can output up to 16V to the magnetic field generating unit 30.

The first electric wire 11 is an electric wire that electrically connects the positive side 10a1 of the power supply 10a, that is, the current output side 10a1 and the first connection 32 of the magnetic field generating unit 30.

The second electric wire 12 is an electric wire that electrically connects the negative side 10a2 of the power supply 10a, that is, the current input side 10a2 and the second connection 33 of the magnetic field generating unit 30.

The third electric wire 13 is an electric wire that electrically connects the intermediate portion of the first electric wire 11 and the intermediate portion of the second electric wire 12. The third electric wire 13 is located between the output side 10a1 of the power supply 10a in the first electric wire 11 and the first switch 11a, the second switch 12a in the second electric wire 12, and the second magnetic field generator 30. It is an electric wire connecting between the connection 33 and the connection 33.

The fourth electric wire 14 is an electric wire that electrically connects the intermediate portion of the first electric wire 11 and the intermediate portion of the second electric wire 12. The fourth electric wire 14 is formed between the first switch 11a of the first electric wire 11 and the first connection 32 of the magnetic field generating unit 30, and the input side 10a2 and the second of the power supply 10a of the second electric wire 12. It is an electric wire connecting to and between the switch 12a.

In this embodiment, the connection point where the first electric wire 11 and the third electric wire 13 are connected is connected to the first connection point A, and the first electric wire 11 and the fourth electric wire 14 are connected to each other. The connection point is connected to the second connection point B, the connection point where the second electric wire 12 and the third electric wire 13 are connected is connected to the third connection point C, and the second electric wire 12 and the fourth electric wire 14 are connected to each other. The connection point is a fourth connection point D.

The first switch 11a is provided between the first connection point A and the second connection point B in the first electric wire 11, and can turn on / off the first electric wire 11.

The second switch 12a is provided between the third connection point C and the fourth connection point D in the second electric wire 12, and can turn on and off the second electric wire 12.

The third switch 13a is provided on the third electric wire 13. The third switch 13a can turn on / off the third electric wire 13.

The fourth switch 14a is provided on the fourth electric wire 14a. The fourth switch 14a can turn on / off the fourth electric wire 14. The first switch 11a to the fourth switch 14a can be, for example, a switching element such as a contact switch or a switching transistor, and in addition, various switches capable of turning on and off an electrical connection can be adopted. can.

The resistance 16 is a resistance of the current flowing through the magnetic field generating unit 30. The resistance value of the resistor 16 is preferably set to 5 to 10 kΩ rather than set to 2 to 15 kΩ. The resistance value of the resistance 16 is set to be about the same as the resistance value of the human body.

The voltage control circuit 17 has a function of controlling the voltage applied to the magnetic field generation unit 30. The voltage applied to the magnetic field generation unit 30 by the voltage control circuit 17 can be arbitrarily changed between 0 and 16V.

Here, as shown in FIG. 4, the power supply unit 10 turns on the first switch 11a and the second switch 12a, and turns off the third switch 13a and the fourth switch 14a, when the power supply 10a is turned on. Output side 10a1, first electric wire 11, first connection 32 of the magnetic field generating unit 30, second connection 33 of the magnetic field generating unit 30, second electric wire 12, and current of the positive electrode reaching the input side 10a2 of the power supply 10a. The first electric circuit 10A1 through which the current flows can be formed.

Further, as shown in FIG. 5, the power supply unit 10 of the power supply unit 10 turns on the third switch 13a and the fourth switch 14a, and turns off the first switch 11a and the second switch 12a. Output side 10a1, first connection point A, third electric wire 13, third connection point C, second connection 33 of magnetic field generation unit 30, first connection 32 of magnetic field generation unit 30, second connection It is possible to form a second electric circuit 10A2 through which the current of the negative electrode flows to the point B, the fourth electric wire 14, the fourth connection point D, and the input side 10a2 of the power supply 10a.

The control unit 20 can generate and output a control signal for controlling the power supply unit 10. As shown in FIG. 6, the control unit 20 includes an input unit 21, a polarity control unit 23, a frequency control unit 24, and a voltage control unit 25.

The control unit 20 has a general configuration as a computer. As shown in FIG. 7, the control unit 20 includes a central processing unit (CPU, GPU, DSP) 20B, a storage device (ROM, RAM, hard disk, cache memory) 20C, and an input device connected to each other via a bus 20A. It has a (keyboard, touch panel, input interface, input port) 20D, display device (liquid crystal display) 20E, and the like. The storage device 20C functions as a storage medium that can be read by a computer. The program 100 is stored in the storage device 20C. By executing the program 100, each unit 21 to 24 of the control unit 20 can be made to function. That is, the program 100 can make the computer of the control unit 20 function as an input unit 21, a polarity control unit 23, a frequency control unit 24, and a voltage control unit 25.

The input unit 21 can input predetermined control information for the control unit 20 to control the power supply unit 10 from the information terminal device 50. The input unit 21 includes a receiving circuit capable of communicating with the output unit 55 of the information terminal device 50 by the Bluetooth (registered trademark) method, and wirelessly receives and inputs control information from the output unit 55 of the information terminal device 50. can do. The input unit 21 functions as a communication unit capable of communicating with the output unit 55 of the information terminal device 50.

The polarity control unit 23 generates and outputs a control signal based on the control information input by the input unit 21, and can perform the first polarity control, the second polarity control, and the third polarity control.

The first polarity control selects the first electric circuit 10A1 by turning on the first switch 11a and the second switch 12a and turning off the third switch 13a and the fourth switch 14a to select the current. This is a control in which the polarity of is the positive electrode.

The second polarity control selects the second electric circuit 10A2 by turning on the third switch 13a and the fourth switch 14a and turning off the first switch 11a and the second switch 12a to select the current. This is a control in which the polarity of is the negative electrode.

The third polarity control is the first electric circuit 10A1 and the third switch 13a and the third switch 13a which turn on the first switch 11a and the second switch 12a and turn off the third switch 13a and the fourth switch 14a. It is a control to select both the second electric circuit 10A2 in which the switch 14a of 4 is turned on and the first switch 11a and the second switch 12a are turned off to generate currents of both polarities including the currents of the positive and negative electrodes. ..

The frequency control unit 24 generates and outputs a control signal based on the control information input by the input unit 21, and can arbitrarily control the frequency by controlling the on time and the off time of the pulse current.

That is, the frequency control unit 24 generates and outputs a control signal, and as shown in FIGS. 8 to 10, the polarity control unit 23 turns on / off the first switch 11a and the second switch 12a at predetermined time intervals. And / or the pulse current is repeatedly generated by controlling the third switch 13a and the fourth switch 14a to be turned on and off repeatedly, and the time interval is set to a predetermined value according to the generated control signal to determine the frequency of the pulse current. Can be controlled to have a predetermined frequency. As a result, the frequency of the magnetic field in the magnetic field generating unit 30 can be controlled to be a predetermined frequency.

That is, the frequency control unit 24 can generate and output a control signal to perform a first frequency control, a second frequency control, and a third frequency control.

That is, as shown in FIG. 8, in the first frequency control, in the first polarity control, the polarity control unit 23 is performed at predetermined time intervals with the third switch 13a and the fourth switch 14a turned off. Controls the on / off of the first switch 11a and the second switch 12a to be repeated in synchronization with each other to repeatedly generate the pulse current of the positive electrode, and sets the time interval to a predetermined value according to the generated control signal. The frequency of the pulse current can be controlled to be a predetermined frequency on the positive electrode side.

In the second frequency control, as shown in FIG. 9, in the second polarity control, the polarity control unit 23 is second at predetermined time intervals with the first switch 11a and the second switch 12a turned off. The pulse current of the negative electrode is repeatedly generated by controlling the switch 13a of the third switch 13a and the fourth switch 14a to be turned on and off repeatedly, and the time interval is set to a predetermined value according to the generated control signal, and the pulse current is generated on the negative electrode side. The frequency can be controlled to be a predetermined frequency.

In the third frequency control, as shown in FIG. 10, in the third polarity control, the first switch 11a and the second switch 12a are turned on, and the third switch 13a and the fourth switch 14a are turned off. The first electric circuit 10A1 and the third switch 13a and the fourth switch 14a are turned on, and the first switch 11a and the second switch 12a are turned off. A pulse current of both polarities is generated by repeatedly selecting and inverting the pulse current of the positive electrode and the pulse current of the negative electrode, and the time interval is set to a predetermined value according to the generated control signal to obtain the pulse current of both polarities. The frequency can be controlled to be a predetermined frequency. In the third frequency control, when the first electric circuit 10A1 is off, the second electric circuit 10A2 is turned on, and when the second electric circuit 10A2 is off, the first electric circuit 10A1 is turned on. Will be done. That is, in the third frequency control, it is possible to control the pulse current to be always on (it is turned off only at the moment when the positive electrode and the negative electrode are switched).

In the present embodiment, the frequency region includes a low frequency region, a medium frequency region, and a high frequency region, and the frequency control unit 24 is used in each frequency control of the first frequency control to the third frequency control. In each frequency region of low frequency region (typically 10 Hz to 1 kHz), medium frequency region (typically 1 kHz to 10 kHz), and high frequency region (typically 10 kHz to 1000 kHz), the generated control signal Therefore, the time interval can be set to a predetermined value and the frequency of the pulse current can be controlled to be a predetermined frequency.

The voltage control unit 25 generates and outputs a control signal based on the control information input by the input unit 21, and the voltage (frequency intensity) applied to the magnetic field generation unit 30 is a predetermined voltage value (frequency intensity). ) Can be controlled. In the voltage control unit 25, the voltage (frequency intensity) applied to the magnetic field generation unit 30 is a predetermined voltage only in a predetermined frequency region according to the control signal and more specifically only in a low frequency region (typically 10 Hz to 1 kHz). It can be controlled to be a value (intensity of a predetermined frequency). on the other hand. In the medium frequency region and the high frequency region, the voltage applied to the magnetic field generating unit 30 is a fixed voltage value (16V), and control for changing the applied voltage is not performed.

The power supply control unit 2 has an LED lamp, and the control unit 20 causes the LED lamp to emit light when the frequency control unit 24 controls the frequency and / or the voltage. Control signals can be generated and output.

The magnetic field generation unit 30 is electrically connected to the power supply control unit 2 via a cable 2'. As shown in FIG. 11, the magnetic field generation unit 30 can be configured by a predetermined coil 31, and the coil 31 can be a flat coil 31.

The flat coil 31 is a spiral coil, and the spiral coil is a spiral portion 31a composed of a spirally wound electric wire 31', and a first connection 32 and a second connection which are ends of the spiral portion 31a. 33 and. The first connection 32 is connected to the first electric wire 11 of the power supply unit 10, and the second connection 33 is connected to the second electric wire 12. The first connection 32 is introduced from the lower side of the swirl portion 31a, and the second connection 33 is derived from the upper side of the swirl portion 31a.

The spiral portion 31a is configured by winding the electric wire 31'from the outside toward the center side in a spiral shape, and the spiral portion 31'is spirally wound with the winding direction of the electric wire 31'from the outside toward the center side when viewed from above. It can be a structure (in other words, it can be a spiral structure in which the winding direction of the electric wire 31'from the center side to the outside when viewed from above is left-handed). The electric wire 31'constituting the spiral portion 31a can be a copper wire. When a current flows through the spiral portion 31a, a magnetic field is generated according to the right-handed screw rule. The range of the generated magnetic field is about 3 to 4 cm around the circumference including the upper side when the voltage of the power supply 10a is 16V. The number of turns of the electric wire 31'in the spiral portion 31a is preferably 9 to 13 turns, more preferably 10 to 12 turns, and 11 turns, for example, when the diameter of the spiral portion 31a is about 4 cm. Is even more preferable. The spiral portion 31a has a donut shape, and the central portion of the donut shape is a circular region 31b without the wound electric wire 31'. The ratio X of the area α of the circular region shown in Equation 1 to the area β of the region (doughlet-shaped portion) around which the electric wire 31 is wound is preferably 0.1 to 0.4. It is more preferably 0.15 to 0.35, and even more preferably 0.2 to 0.3. Further, the ratio Y to the area β of the region (doughnut-shaped portion) around which the electric wire 31 of the spiral portion 31a having the number of turns λ shown in Equation 2 is wound shall be 1000 to 100,000 (number of turns / m ² ). are preferred, more preferably to 3,000 to 60,000 (the wrapping number / ^{m 2),} it is even more preferred to 5,000 to 20,000 (the wrapping number / ^{m 2).}
[Number 1]
X = α / β
[Number 2]
Y = λ / β
In the third frequency control, the direction of the magnetic field generated by the spiral portion 31a is mutually inverted between the pulse current of the positive electrode and the pulse current of the negative electrode.

On the back surface side (lower surface side) of the spiral portion 31a configured in this way, a member 31c for weakening the magnetic flux of the magnetic field generated from the back surface side and increasing the magnetic flux of the magnetic field generated from the front surface side (upper surface side) is provided. It is provided.

The member 31c has a plate shape and is configured to include a magnetic material. The magnetic material can be ceramics containing iron oxide, and the ceramics containing iron oxide can be ferrite. That is, by providing the member 31c containing ferrite on the back surface side of the spiral portion 31a, it is possible to surely weaken the magnetic flux of the magnetic field generated from the back surface side and increase the magnetic flux of the magnetic field generated from the front surface side.

The magnetic field generation unit 30 has a storage unit 34 for accommodating the flat coil 31. The storage unit 34 is configured to store the flat coil 31 in the storage space inside the circular casing. The magnetic field generation unit 30 can irradiate the irradiation target M with a predetermined frequency through the surface of the storage unit 34.

More specifically than the surface of the storage portion 34, the upper surface 34a is a mounting portion 35 on which the irradiation target object M is placed. The irradiation target object M can be placed on the mounting portion 35, and the irradiation target object M can be irradiated with a magnetic field having a predetermined frequency to expose the irradiation target object M to a magnetic field having a predetermined frequency. That is, the mounting portion 35 functions as an irradiation unit that irradiates the irradiation target object M with a magnetic field of a predetermined frequency, and the upper surface 34a of the storage portion 34 is an irradiation surface that irradiates the irradiation target object M with a magnetic field of a predetermined frequency. Functions as.

The mounting portion 35 has a flat surface, and the irradiation target M can be mounted on the flat surface. When the irradiation target object M is, for example, a liquid, it is placed on the placing portion 35 via the container 60. The storage unit 34 can be made of, for example, plastic. As is clear from FIG. 11, the spiral portion 31a is wound to the right in the winding direction of the electric wire 31'from the outside to the center side when viewed from the mounting portion 35 provided on the upper surface 34a of the storage portion 34. It has a spiral structure.

That is, the spiral portion 31a is housed so that the back surface side where the member 31c is provided and the magnetic flux is weakened faces the lower surface 34b side of the storage portion 34, and the front surface side (on the back surface side) where the member 31c is not provided. The surface side on which the magnetic flux is strengthened by the provided member 31c) is stored so as to face the upper surface 34a side of the storage portion 34.

The information terminal device 50 has a storage unit 51, an input unit 52, a display unit 53, a generation unit 54, and an output unit 55.

The information terminal device 50 has a general configuration as a computer. As shown in FIG. 13, the information terminal device 50 includes a central processing unit (CPU, GPU, DSP) 50B, a storage device (ROM, RAM, hard disk, cache memory) 50C, and inputs connected to each other via a bus 50A. It has a device (keyboard, patch panel, input interface, input port) 50D, display device (liquid crystal display) 50E, output device 50F (output interface, output port) and the like. The storage device 50C functions as a storage medium that can be read by a computer. The program 200 is stored in the storage device 50C. By executing the program 200, each part 51 to 55 of the information terminal device 50 can be made to function. That is, the program 200 can make the computer of the information terminal device 50 function as a storage unit 51, an input unit 52, a display unit 53, a generation unit 54, and an output unit 55.

The storage unit 51 can store a predetermined recording table 51a. The recording table 51a includes a disease table in which a predetermined disease and specific polarity information, frequency information, and voltage information (applied voltage information) corresponding to the predetermined disease are recorded. Further, the storage unit 51 can store the current polarity information, frequency information, and applied voltage information in the recording table 51a when the user presses the memory button on the display unit 52. In addition, in the power supply control unit 2 forming the main body of the magnetic field generator 1, more specifically, the predetermined disease, the information of the specific polarity corresponding to the predetermined disease, the information of the frequency, and the voltage are stored in the power supply control unit 2. The disease table in which the information (information on the applied voltage) is recorded is not stored. Therefore, the power supply control unit 2 can be configured to be lightweight and / or miniaturized, and can perform more information processing.

The input unit 52 can input predetermined information. The predetermined information input by the input unit 52 is the polarity information for controlling the polarity of the current so that the polarity of the current becomes a predetermined polarity, and the frequency control unit 24 controls so that the frequency becomes a predetermined frequency. The frequency information for this purpose, the area information indicating whether the frequency is in the low frequency region, the medium frequency region, or the high frequency region, and the voltage applied by the voltage control unit 25 to the magnetic field generation unit 30 are set to predetermined voltage values. Can include applied voltage information for control.

The polarity information can include information on whether the polarity of the current is the positive electrode, the negative electrode, or both polarities. The frequency information and the applied voltage information can include, for example, information for controlling a plurality of frequencies corresponding to the disease and information for controlling the applied voltage.

The input unit 52 reads out the polarity information, the frequency information, and the applied voltage information corresponding to the predetermined disease from the recording table 51a of the storage unit 51 and inputs them through a predetermined operation (input of the disease name) by the user. Can be done.

When the user presses the "memory" of the menu screen on the display unit 53, the input unit 52 reads out the polarity information, the frequency information, and the applied voltage information stored by pressing the memory button from the recording table 51a. You can enter it.

The input unit 52 has a low frequency when the user presses any of the icons indicating the "low frequency region", "medium frequency region", and "high frequency region" information on the menu screen on the display unit 53. Area information indicating whether it is a frequency domain, a medium frequency domain, or a high frequency domain can be input. Further, the input unit 52 can simply input the polarity information, the frequency information, and the applied voltage information by the required operation of the user's display unit 53, regardless of whether or not the disease is associated with the disease.

The display unit 53 can display predetermined information for input by the input unit 52. The display unit 53 displays a menu screen including an icon indicating each information for input by the input unit 52, and the input unit 52 stores each information corresponding to the icon when the user presses the icon. It can be input by reading from. By pressing the specified icon, you can select "Low frequency domain", "Medium frequency domain", "High frequency domain", "Disease name", and "Memory" in addition to "How to use guide" via the menu screen. I have to. Further, the display unit 53 displays an input screen for inputting each information (for example, an arbitrary polarity, frequency, applied voltage) input by the input unit 52, and the input unit 52 inputs the user to the input screen. Each information (for example, arbitrary polarity, frequency, applied voltage) can also be input.

The generation unit 54 can generate control information based on the information input by the input unit 52. The control information generated by the generation unit 54 is, for example, "power supply 10a on", "bipolar current", "low frequency region", "frequency 10Hz", "voltage 10V".

The output unit 55 can output the control information generated by the generation unit 54 to the input unit 21 of the magnetic field generator 1 via wireless or wired communication. The output unit 55 can communicate with the magnetic field generator 1 by, for example, a short-range wireless system such as Bluetooth (registered trademark). The output unit 55 functions as a communication unit capable of communicating with the input unit 21 of the magnetic field generator 1.

Next, the magnetic field generation method by the magnetic field generator 1 configured as described above will be described in detail with reference to the flowchart of FIG.

First, in step S1, the irradiation target object M is placed on the mounting portion 35 in the storage portion 34.

Next, in step S2, the input unit 52 of the information terminal device 50 controls the polarity control unit 23 so that the polarity of the current becomes a predetermined polarity via a required operation (for example, input of a disease name) by the user. Polar information for, frequency information for controlling the frequency to be a predetermined frequency by the frequency control unit 24, and control so that the voltage applied to the magnetic field generation unit 30 by the voltage control unit 25 becomes a predetermined voltage value. The applied voltage information for this is read out from the storage unit 51 (recording table 51a) and input. Further, the input unit 52 of the information terminal device 50 inputs region information indicating whether the frequency is in the low frequency region, the medium frequency region, or the high frequency region through a required operation by the user. The user's operation can be performed via the display unit 53.

Next, in step S3, the generation unit 54 generates control information based on the information input in step S2.

Subsequently, in step S4, the output unit 55 outputs the control information generated in step S3 to the input unit 21 of the magnetic field generator 1.

Next, in step S5, the input unit 21 of the magnetic field generator 1 inputs the control information output in step S4.

Next, in step S6, the polarity control unit 23, the frequency control unit 24, and the voltage control unit 25 are controlled to control the current polarity to a predetermined polarity based on the control information input in step S5. To control the signal, the control signal for controlling the frequency to be a predetermined frequency, and the voltage (frequency intensity) applied to the magnetic field generating unit 30 to be a predetermined voltage value (predetermined frequency intensity). Control signals are generated and output, and current polarity control, frequency control, and voltage control are performed. The voltage control unit 25 can control the applied voltage only in the low frequency region.

As described above, the magnetic field generator 1 of the present embodiment has a magnetic field generator 30 that generates a magnetic field having a predetermined frequency. Therefore, more specifically, the power supply unit 10 having the power supply 10a and the power supply unit 30 Since it is determined to have a control unit 20 that controls 10 and a magnetic field generation unit 30 that generates a magnetic field of a predetermined frequency when a current is supplied from the power supply unit 10, a magnetic field of a predetermined frequency is generated. Can be done.

That is, for example, when water is irradiated with a magnetic field having a frequency generated by the magnetic field generator 1 and a person ingests the water (wave water or magnetized water, information water), the water is exposed to a magnetic field having a predetermined frequency. Therefore, it is expected to lead to the treatment and prevention of various diseases (even if the irradiation target M is a solid or liquid, when the individual or liquid is ingested by a person, the solid or liquid is predetermined. Since it is exposed to a magnetic field of the same frequency, it is expected to lead to the treatment and prevention of various diseases as well).

Further, since the power supply unit 10 has the resistance 16 and the resistance value of the resistance 16 is preferably 5 to 10 kΩ rather than 2 to 15 kΩ, the resistance value can be set to the same level as that of the human body.

Further, since the control unit 20 has a polarity control unit 23 for controlling the polarity of the current and a frequency control unit 24 for controlling the frequency of the current, the control of the polarity of the current and the control of the frequency of the current are performed. It can be performed.

Further, since the voltage control unit 25 for controlling the voltage applied to the magnetic field generation unit 30 is provided, the frequency intensity in the magnetic field generation unit 30 can be controlled.

Furthermore, since the spiral portion 31 of the magnetic field generating portion 30 is set to wind the electric wire 31'from the outside toward the center to the right, the winding direction of the electric wire 11'is set to the direction of drawing out bioenergy. can do.

Further, the surface of the storage portion 34 of the magnetic field generating portion 30 has a mounting portion 35 on which the irradiation target object M is placed, and the irradiation target object M is placed on the mounting portion 35 and placed on the irradiation target object M. Since it was decided to irradiate a magnetic field of a predetermined frequency, it is possible to irradiate a magnetic field of a predetermined frequency while placing the irradiation target M.

Since the mounting portion 35 has a flat surface and the irradiation target object M is placed on the flat surface, the irradiation target object M can be stably placed.

Further, since the control unit 20 from the information terminal device 50 has an input unit 21 for inputting predetermined control information for controlling the power supply unit 10, the power supply unit 10 is based on the control information from the information terminal device 50. You can control it.

Further, the predetermined information input by the input unit 52 of the information terminal device 50 is information for the polarity control unit 23 to control the polarity of the current, information for the frequency control unit 24 to control the frequency, and the voltage control unit 25. Since the information for controlling the voltage applied to the magnetic field generation unit 30 is included, the current polarity can be controlled, the frequency can be controlled, and the voltage can be controlled by the control information from the information terminal device 50.

Furthermore, polarity control, frequency control, based on a disease table that records a predetermined disease and specific polarity information, frequency information, and voltage information (applied voltage information) corresponding to the predetermined disease. And since it is decided to perform voltage control, for example, if a person drinks water irradiated with a magnetic field by the magnetic field generator 1, it will lead to further treatment and prevention of various diseases.

Needless to say, the present invention is not limited to the above-described embodiment, and various modifications and applications can be carried out within the scope of the claims.

That is, for example, in the above-described embodiment, the frequency control unit 24 is the first frequency control, which is a control for repeatedly generating the pulse current of the positive electrode, and the control, which is the control for repeatedly generating the pulse current of the negative electrode. The frequency control of No. 2 and the third frequency control, which is the control of alternately repeating the pulse current of the positive electrode and the pulse current of the negative electrode to generate a pulse current of both polarities, are performed, but only one of them is performed. Even so, it produces the required effect.

That is, the frequency control unit 24 has a first frequency control that repeatedly generates a positive pulse current, a second frequency control that repeatedly generates a negative pulse current, a positive pulse current, and a negative negative. It is also possible to obtain a required effect by performing at least one of the third frequency control, which is a control for generating a pulse current having both polarities by alternately repeating the pulse currents of the above.

However, in the case of the third frequency control, which is a control for generating a pulse current having both polarities while alternately repeating and inverting the pulse current of the positive electrode and the pulse current of the negative electrode, the magnetic field generated in the magnetic field generation unit 30 is used. Since the direction changes so that the direction is reversed, for example, when the irradiation target M is water, water is provided that has the properties of magnetically treated water because it is exposed to magnetism while resonating and resonating with the oscillation frequency. It is possible to do so, which is more preferable.

Further, in the frequency control unit 24, in the first polarity control, the polarity control unit 23 sets the first switch 11a and the first switch 11a at predetermined time intervals with the third switch 13a and the fourth switch 14a turned off. All of the switches 12a of No. 2 are controlled to be repeatedly turned on and off to repeatedly generate the pulse current of the positive electrode, but the third switch 13a and the fourth switch 14a are turned off. And, with either one of the first switch 11a and the second switch 12a turned on, the polarity control unit 23 sets the polarity control unit 23 to the other of the first switch 11a and the second switch 12a at predetermined time intervals. It also has the required effect by controlling it to be turned on and off repeatedly.

That is, in the first polarity control, the frequency control unit 24 has the polarity control unit 23 the first switch 11a and the first switch 11a at predetermined time intervals with the third switch 13a and the fourth switch 14a turned off. A required effect can be obtained even if control is performed so that at least one of the switches 12a of 2 is repeatedly turned on and off to repeatedly generate the pulse current of the positive electrode.

Further, in the second polarity control, the frequency control unit 24 has the polarity control unit 23 turning off the first switch 11a and the second switch 12a, and the polarity control unit 23 sets the third switch 13a and the second switch 12a at predetermined time intervals. All of the switches 14a of No. 4 are controlled to be repeatedly turned on and off to repeatedly generate the pulse current of the negative electrode, but the first switch 11a and the second switch 12a are turned off. And, with either one of the third switch 13a and the fourth switch 14a turned on, the polarity control unit 23 sets the polarity control unit 23 to the other of the third switch 13a and the fourth switch 14a at predetermined time intervals. It is also possible to obtain a required effect by controlling so as to repeatedly turn on and off and to repeatedly generate a pulse current of the negative electrode.

That is, in the second polarity control, the frequency control unit 24 has the polarity control unit 23 turning off the first switch 11a and the second switch 12a, and the polarity control unit 23 sets the third switch 13a and the second switch 12a at predetermined time intervals. A required effect can be obtained even if control is performed so that at least one of the switches 14a of No. 4 is repeatedly turned on and off to repeatedly generate the pulse current of the negative electrode.

Further, in the above-described embodiment, the upper surface 34a of the storage unit 34 is used as the mounting unit 35 on which the irradiation target object M is placed, but the lower surface 34b of the storage unit 34 also mounts the irradiation target object M. As the mounting portion 35b to be placed, both the upper surface 34a and the lower surface 34b may be the mounting portions 35 and 35b. In this case, the spiral portion 31a has a spiral structure in which the winding direction of the electric wire 31'from the outside to the center side when viewed from the mounting portion 35b provided on the lower surface 34b of the storage portion 34 is left-handed. In this modification, as shown in FIG. 15, identification information (character information, symbol information, color, etc.) for identifying the upper surface 34a side and the lower surface 34b side of the storage portion 34 is provided on the upper surface 34a side and the lower surface 34b. It can be identified by attaching it to the side.

Furthermore, in the above-described embodiment, the magnetic flux of the magnetic field generated from the back surface side is weakened and the magnetic flux of the magnetic field generated from the front surface side (upper surface side) is strengthened on the back surface side (lower surface side) of the spiral portion 31a. A member 31c for this purpose is provided, but in order to weaken the magnetic flux of the magnetic field generated from the surface side and increase the magnetic flux of the magnetic field generated from the front surface side (lower surface side) on the surface side (upper surface side) of the spiral portion 31a. The required effect can be obtained even if the member 31c of the above is provided.

That is, the spiral portion 31a has surfaces on the front surface side and the back surface side, and the magnetic flux of the magnetic field generated from any one surface on either the front surface side or the back surface side is weakened to weaken the magnetic flux on the front surface side and the back surface side. A member 31c for increasing the magnetic flux of the magnetic field generated from any one of the sides can be provided.

Further, instead of the spiral portion 31a of the above-described embodiment, the spiral portion 131a of the modified example shown in FIG. 16 may be used.

That is, the spiral portion 131a of the modified example shown in FIG. 16 can generate a scalar wave.

The spiral portion 131a has a first winding portion 131a1 and a second winding portion 131a2. The first winding portion 131a1 is configured by winding the electric wire 31'in a spiral shape from the outside toward the center side, and the second winding portion 131a2 is formed by winding the electric wire 31'in the first winding portion 131a1. It is configured by winding in a spiral shape from the end on the center side toward the outside. The direction in which the current flows in the first winding portion 131a1 and the second winding portion 131a2 are opposite to each other.

More specifically, the first winding portion 131a1 is configured by winding the electric wire 31'from the outside toward the center side in a winding shape at a predetermined interval d. The second winding portion 131a2 is continuous with the end portion 131a1'on the center side of the first winding portion 131a1, and the electric wire 31'is outward from the end portion 131a1' on the center side of the first winding portion 131a1. It is configured to be spirally wound within the interval d of the first winding portion 131a.

By using such a winding portion 131a, the directions of the currents flowing between the first winding portion 131a1 and the second winding portion 131a2 are opposite to each other, so that the first winding portion The direction of the magnetic field generated in one current flow between the 131a1 and the second winding portion 131a2 can be opposite to each other. As a result, a "zero magnetic field" environment can be realized and a scalar wave can be generated. The first connection 132 in the first winding portion 131a1 is electrically connected to the first electric wire 11, and the second connection 133 is electrically connected to the second electric wire 12.

Further, as an additional implementation means, a sweep function in a predetermined frequency region, a timer function capable of setting a desired end time, and the like may be provided. These functions can be added by displaying an input box, a button, / or a bar or the like on the screen of the information terminal device 50 by a known program configuration.

Further, using water produced by exposing to a magnetic field by the magnetic field generator 1 of the above-described embodiment (the magnetic field generator 30 of the magnetic field generator 1 includes the winding portion 31a or the winding portion 131a of the modified example). It may be possible to provide a humidifier or a humidifying method capable of humidifying. By providing such a humidifier and a humidifying method, water exposed to the magnetic field of the present invention can be diffused into the surrounding environment.

As shown schematically in FIG. 17, the humidifier 140 has a discharge section having an atomizing section 141 for atomizing water and a discharge port for discharging water atomized by the atomizing section 141 to the outside. 142, and there are steam type, vaporization type, ultrasonic type and the like. In the steam type, the atomization unit 141 is equipped with a heater to evaporate the water to atomize the water (wave water or magnetized water, information water) and release humid air to the surrounding environment via the discharge unit 142. It is a method of releasing. In the vaporization type, the atomization unit 141 is provided with a filter and a fan, and air is sent to the filter containing water through the fan to atomize the water (wave water) and discharge high-humidity air through the discharge unit 142. It is a method. The ultrasonic type is a method in which an ultrasonic generator is provided in the atomization unit 141, and water (wave water) atomized by ultrasonic waves is discharged through the discharge unit 142. The ultrasonic method is a particularly preferred embodiment in combination with the effect of a magnetic field exposed to water.

M: Irradiation target A: First connection point B: Second connection point C: Third connection point D: Fourth connection point d: Spacing 1: Magnetic field generator 1A: Magnetic field generation system 2: Power supply control Part 2': Cable 10: Power supply unit 10A1: First electric circuit 10A2: Second electric circuit 10a: Power supply 10a1: Output side 10a2: Input side 10b: Power supply switch 11: First electric wire 11a: First switch 12: Second electric wire 12a: Second switch 13: Third electric wire 13a: Third switch 14: Fourth electric wire 14a: Fourth switch 16: Resistance 20: Control unit 20A: Bus 20B: Central processing device 20C : Storage device 20D: Input device 20E: Display device 21: Storage unit 22: Input unit 24: Polarity control unit 25: Frequency control unit 30: Magnetic field generation unit 31: Coil (flat coil)
31': Electric wire 31a: Swirling portion 31b: Region 31c: Member 32: First connection 33: Second connection 34: Storage portion 34a: Upper surface 34b: Lower surface 35: Mounting portion 35b: Mounting portion 50: Information terminal Device 50A: Bus 50B: Central processing unit 50C: Storage device 50D: Input device 50E: Display device 51: Input unit 52: Display unit 53: Generation unit 54: Output unit 60: Container 100: Program 131a: Swirling unit 131a 1: First 1 swirl part 131a2: 2nd swirl part 140: humidifier 141: atomizer 142: discharge part 200: program

Claims (46)

1. A magnetic field generator that generates a magnetic field at a predetermined frequency.
   A magnetic field generator comprising a magnetic field generating unit that generates a magnetic field having a predetermined frequency.
2. The magnetic field generator according to claim 1, wherein the magnetic field having a predetermined frequency is generated by repeatedly generating a pulse current.
3. The pulse current is at least one of a positive electrode pulse current, a negative electrode pulse current, and a bipolar pulse current in which the positive electrode pulse current and the negative electrode pulse current are alternately and repeatedly generated. Item 2. The magnetic field generator according to Item 2.
4. The magnetic field generator according to claim 1, wherein a magnetic field having a predetermined frequency generated by the magnetic field generating unit is applied to an object to be irradiated.
5. The magnetic field generator according to claim 1, wherein the irradiation target contains a liquid.
6. The magnetic field generator according to claim 5, wherein the liquid contains water.
7. A magnetic field generator that generates a magnetic field at a predetermined frequency.
   A magnetic field having a power supply unit having a power source, a control unit for controlling the power supply unit, and a magnetic field generating unit for generating a magnetic field having a predetermined frequency when a current is supplied from the power supply unit. Generator.
8. The power supply unit
   While forming a first electric circuit through which the current of the positive electrode flows,
   The magnetic field generator according to claim 7, wherein a second electric circuit through which a current of a negative electrode flows is formed.
9. The magnetic field generator according to claim 7, wherein the power supply unit has a resistance, and the resistance value of the resistance is 2 to 15 kΩ.
10. The magnetic field generator according to claim 7, wherein the control unit includes a polarity control unit that controls the polarity of the current and a frequency control unit that controls the frequency of the current.
11. The polarity control unit is a first polarity control, which is a control in which the polarity of the current is a positive electrode.
    The second polarity control, which is a control in which the polarity of the current is the negative electrode,
    The magnetic field generator according to claim 10, further comprising performing at least one of a third polarity control, which is a control for generating currents of both polarities including currents of the positive electrode and the negative electrode.
12. The frequency control unit
    The magnetic field generator according to claim 10, wherein the pulse current is repeatedly generated, and the frequency of the pulse current is controlled so that the frequency of the magnetic field in the magnetic field generating unit is set to a predetermined frequency.
13. The frequency control unit
    In the first polarity control, the first frequency control, which is a control for repeatedly generating a pulse current of a positive electrode,
    In the second polarity control, the second frequency control, which is the control for repeatedly generating the pulse current of the negative electrode,
    In the third polarity control, at least one of the third frequency control, which is a control for generating a pulse current having both polarities by alternately repeating the pulse current of the positive electrode and the pulse current of the negative electrode, is performed.
    The magnetic field generator according to claim 11, wherein the frequency of the pulse current is controlled so that the frequency of the magnetic field in the magnetic field generating unit is set to a predetermined frequency.
14. The magnetic field generator according to claim 7, further comprising a voltage control unit that controls a voltage applied to the magnetic field generation unit.
15. The magnetic field generator according to claim 14, wherein the voltage control unit controls a voltage applied to the magnetic field generation unit in a low frequency region.
16. The magnetic field generator according to claim 7, wherein the magnetic field generator is composed of a predetermined coil.
17. The magnetic field generator according to claim 16, wherein the coil is a flat coil.
18. The magnetic field generator according to claim 17, wherein the planar coil is a spiral coil, and the spiral coil has a spiral portion composed of a spirally wound electric wire.
19. The spiral portion has surfaces on the front surface side and the back surface side, and the magnetic flux of the magnetic field generated from the one surface is weakened on one of the front surface side and the back surface side to weaken the magnetic flux on the front surface side. The magnetic field generator according to claim 18, further comprising a member for increasing the magnetic flux of the magnetic field generated from any one of the back surface sides.
20. The magnetic field generator according to claim 19, wherein the member has a plate shape and is configured to include a magnetic material.
21. The magnetic field generator according to claim 20, wherein the magnetic material is ceramics.
22. The magnetic field generator according to claim 21, wherein the ceramic is ferrite.
23. The spiral portion is characterized in that the electric wire is spirally wound from the outside toward the center side, and the winding direction of the electric wire from the outside toward the center side is right-handed. The magnetic field generator according to claim 18.
24. 23. The magnetic field generator according to claim 23, wherein the spiral portion generates a scalar wave.
25. The spiral portion includes a first winding portion formed by winding the electric wire in a spiral shape from the outside toward the center side, and the electric wire outside from the end portion on the center side of the first winding portion. The first winding portion and the second winding portion have a second winding portion formed by spirally winding toward the head, and the directions in which the current flows are opposite to each other. The magnetic field generator according to claim 23 or 24.
26. The first winding portion is configured by winding the electric wire from the outside toward the center side in a winding shape at predetermined intervals, and the second winding portion is the first winding portion. Continuously connected to the central end of the winding portion, the electric wire is spirally wound from the central end of the first winding portion toward the outside within the interval of the first winding portion. 25. The magnetic field generator according to claim 25.
27. A claim that the predetermined information input by the input unit includes information for the polarity control unit to control the polarity of the current and information for the frequency control unit to control the frequency. 7. The magnetic field generator according to 7.
28. The magnetic field generator according to claim 7, wherein a magnetic field having a predetermined frequency generated by the magnetic field generating unit is applied to an irradiation target.
29. 28. The magnetic field generator according to claim 28, wherein the irradiation target contains a liquid.
30. 29. The magnetic field generator according to claim 29, wherein the liquid contains water.
31. The magnetic field generator according to claim 7, wherein the control unit has an input unit for inputting predetermined control information for controlling the power supply unit from a predetermined information terminal device.
32. The magnetic field generator according to claim 31, wherein the information terminal device has an output unit that outputs the predetermined control information to the control unit.
33. It is characterized by having the magnetic field generator according to any one of claims 1 to 32, and an information terminal device having an output unit for outputting predetermined control information for controlling the power supply unit. Magnetic field generation system.
34. It is characterized in that an irradiation target is produced by irradiating the irradiation target with a magnetic field having a predetermined frequency generated by the magnetic field generator according to any one of claims 1 to 32. Production method of the irradiated object.
35. The production method according to claim 34, wherein the irradiation target contains a liquid.
36. The production method according to claim 35, wherein the liquid contains water.
37. An irradiation object, which is produced by irradiating a magnetic field having a predetermined frequency generated by the magnetic field generator according to any one of claims 1 to 32.
38. A liquid characterized by being produced by irradiating a magnetic field having a predetermined frequency generated by the magnetic field generator according to any one of claims 1 to 32.
39. A water produced by irradiating a magnetic field having a predetermined frequency generated by the magnetic field generator according to any one of claims 1 to 32.
40. A humidifier according to claim 39, wherein the humidifier is humidified with the water.
41. A humidification method comprising humidifying with the water according to claim 39.
42. A computer with a magnetic field generator that generates a magnetic field at a predetermined frequency,
    A program characterized by functioning as a magnetic field generator that generates a magnetic field having a predetermined frequency.
43. A computer with a magnetic field generator that generates a magnetic field at a predetermined frequency,
    A program characterized by functioning as a control unit that controls a power supply unit having a predetermined power supply.
44. A computer of an information terminal device that outputs predetermined control information to a control unit that controls a power supply unit having a predetermined power supply in a magnetic field generator that generates a magnetic field at a predetermined frequency.
    A program characterized in that it functions as an output unit that outputs the predetermined control information to the control unit.
45. A computer of a magnetic field generation system comprising the magnetic field generator according to any one of claims 1 to 32 and an information terminal device for outputting predetermined control information for controlling the power supply unit.
    A program characterized in that it functions as an output unit that outputs the predetermined control information to the control unit.
46. A computer-readable storage medium for storing the program according to any one of claims 42 to 45.
    

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