JP2002253955A - Method and device for radiating wave motion giving reducing property - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for imparting a high reducing property (a property of supplying an electron or hydrogen) to objects, such as prescribed indoor and outdoor space regions and animals and plants existing within the region and to provide a device used therefore. SOLUTION: A coaxial cable is constituted by providing a dielectric 3c between an interior conductor 3a and an external conductor 3b and a plurality of coaxial cables of a prescribed length are attached as radiators 3 by arranging in parallel to each other on a surface of a bent reflecting plate 2 so as to be respectively bent in the same direction. Each radiator 3 is connected with an AC power source in series and currents are made to flow in the interior conductor 3a and the external conductor 3b in opposite directions to each other. Thereby, wave motion generating the reducing property due to an electron donating action is radiated on a radiated body.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for imparting high reducibility (a property of supplying electrons or hydrogen) to a predetermined space area indoors and outdoors and to an object such as animals and plants existing in the area. And a device used therefor.

[0002]

2. Description of the Related Art Conventionally, methods for imparting reducibility include:
Although a chemical method using an electron donating agent or a reducing agent is known, in this method, water or a liquid is generally used as a medium, and without using such a medium,
Immediately, it was not possible to give a reducing property to the spatial region or to the object through this spatial region.

[0003] Further, even in the electrochemical method, the presence of an electrolyte is indispensable in order to utilize the reaction at the interface of the electrode, and similar to the above-described method, the object is immediately provided with a reducing property. I couldn't do that.

In order to increase the negative potential acting on the improvement of the reducing ability without using such a medium, there has been a negative ion generator. This negative ion generator uses an air spark discharge caused by a high voltage to release negative ions into the air.

[0005]

The above-mentioned conventional reduction method using a medium is intended for a specific field such as cleaning or processing of articles, and depending on an object such as animals, plants and foods. Could not be used.
In addition, it could not be used to improve the environment such as living space.

Further, a negative ion generator which discharges generated negative ions by performing air discharge between the electrodes does not use a medium, so that the environment such as a living space can be directly changed or used in the space. A negative ion effect can be given to an object located in the area, but unnecessary positive ions are generated together with the generation of negative ions due to discharge, and ozone harmful to the human body is generated if a large amount is inhaled. There was a point. In addition, there is a problem that the area where the negative ion effect is exposed is limited due to the air release method. Furthermore, this negative ion generator requires electrodes, high voltage power supply, etc., which inevitably increases the size and cost of the device, and generates noise during operation, which makes the user uncomfortable. There is also a risk of giving or giving adverse effects to surrounding transmitting and receiving equipment, precision equipment and the like.

The present invention solves the problems of the above-described conventional reduction method and reduction apparatus with a completely new method, and provides a new reduction apparatus using this method.

[0008]

In order to solve the above-mentioned problems, the invention according to claim 1 of the present invention has an inner conductor at the center and an outer conductor surrounding the inner conductor via a dielectric. An alternating current oscillated at a predetermined frequency is applied to the inner conductor and the outer conductor of the provided cylindrical member so that the directions of the currents flowing therethrough are opposite to each other. A method of radiating a wave providing reducibility, wherein a wave having a reduction function by an electron donating action is generated.

According to a second aspect of the present invention, in the method of the first aspect, the oscillation frequency of the current is limited to a range of 0.1 to 2.5 KHZ. According to a third aspect of the present invention, there is provided a coherent radiator having a wave radiating device providing reducibility, a coaxial radiator having an inner conductor at the center and an outer conductor provided around the inner conductor via a dielectric. An oscillator for supplying a current of a predetermined frequency to the body, and applying an alternating current of a predetermined frequency to the inner conductor and the outer conductor so that the currents flow in opposite directions, thereby generating an electric field versus a magnetic field. Is non-equilibrated to generate a wave having a reduction function by an electron donating action.

According to a fourth aspect of the present invention, in the configuration of the third aspect, a plurality of coaxial radiators are arranged at equal intervals, and each of the coaxial radiators is connected in series with an oscillator. A feature is added.

According to a fifth aspect of the present invention, in the configuration of the fourth aspect of the present invention, an inner conductor and an outer conductor of each coaxial radiator are provided.
It is characterized by adding a configuration connected directly or via a capacitor.

The invention described in claim 6 is the invention according to claim 4 or 5.
The present invention is characterized in that each coaxial radiator has a configuration in which each coaxial radiator is curved in the same direction with an equal curvature.

According to a seventh aspect of the present invention, in the invention according to any one of the third to sixth aspects, a coaxial radiator is provided.
It is characterized in that it is limited to a coaxial cable cut to a predetermined length.

An eighth aspect of the present invention is characterized in that, in the configuration of the seventh aspect of the invention, the coaxial cable is limited to a cable whose outer jacket is removed.

[0015]

DESCRIPTION OF THE PREFERRED EMBODIMENTS First, the background to the present invention will be described. In order to impart reducibility to an object, it is sufficient to provide the object with a property of supplying electrons or hydrogen. We thought that it would be better to irradiate an electromagnetic wave having such a function in order to directly give an electron to the target object without using the electromagnetic wave. However, a normal electromagnetic wave is a transverse wave whose displacement is perpendicular to the traveling direction of the wave, that is, a wave that reverses in the dimension of a half wave. No charge could be left.

Therefore, unlike such an electromagnetic wave, by radiating a wave called a longitudinal wave, a standing wave, or an electron wave, a negative charge is given to the object to be irradiated, thereby providing a reducing property. It is the result of repeated thoughts, examinations, and experiments.

First, in order to obtain a required wave, the transverse wave component radiated from the radiator must be reduced to zero or reduced as much as possible. For this purpose, the magnetic field generated in the radiator by the current flowing through the radiator may be reduced to zero or reduced. Therefore, the present inventor has found that the skin effect in a coaxial cable, that is, in a coaxial cable, electricity passes more easily at the outer periphery than at the core, and high-frequency current or electromagnetic waves are localized near the surface of the conductor and do not enter the inside. If the coaxial cable is used in a manner similar to a monopole or dipole antenna, the generated electric field versus the magnetic field can be unbalanced, thereby generating the desired wave. I thought I could do it.

Thus, using a coaxial cable of a predetermined length,
When an alternating voltage was applied between the center inner conductor and the surrounding outer conductor so that the directions of the currents flowing in the respective directions were opposite to each other, the expected effect was obtained. .

In the experiment, there is no measuring instrument capable of objectively observing and measuring the nature of the radiation wave, and there is no means for objectively observing and confirming whether or not radiation is being emitted. The inventor separately prepared a sensing device 6 as shown in FIG. 5, and used it for confirmation.

The sensing device 6 is provided so as to cover a rotor 7 rotatably supported on a pin 8 and a periphery of the rotor 7 by folding up an aluminum foil into a triangular pyramid having an unequal side.
A partially notched cylindrical body 9 having an aluminum foil as a stator 9a adhered to the inner surface thereof. Therefore, the distances between the three ends of the rotor 7 and the stator 9a are all different.
An insulating rubber plate 10 is provided between the stator 9a and the rotor 7 to provide insulation. In FIG. 5,
Reference numeral 9b denotes a notch provided in the cylindrical body 9 as a wave incident portion.

Further, whether or not the reducing property has occurred is determined by using tap water as a water sample and measuring its ORP (Oxidation).
-Reduction Potentials).

Here, the ORP value will be briefly described. In general, the ability of a substance to oxidize or reduce another substance is higher as the positive potential is higher, the higher the oxidizing ability (capacity to accept electrons or hydrogen). , The greater the negative potential, the greater the reduction ability (the ability to supply electrons or hydrogen)
Can be said to be easily known by measuring the oxidation-reduction potential. OR
The P value refers to this oxidation-reduction potential, and is widely used as an index for measuring the oxidation-reduction ability of a compound or the like.

Hereinafter, considerations from various viewpoints will be described in order to support the phenomenon obtained in this experiment.

As described above, between the inner conductor and the outer conductor of the coaxial cable used as the radiator, a current (reciprocating current / current in the opposite direction) corresponding to the capacitance of the dielectric existing between the two. ) Will flow. Since the voltage and current are distributed on the open end pattern, the mode is the standing wave mode.

Further, the space in the immediate vicinity of the radiator is defined as an effective region (it is known that a wave that does not carry energy exists only in the immediate vicinity of the wave source (≒ standing wave)). If such an operation method is adopted, it can be treated as a standing wave.

In addition, the composition of the electromagnetic field component generated by the radiator results in a longitudinal wave having an extremely strong electric field component in the direction of the coaxial center line because the magnetic field component is small. It is known that a longitudinal wave becomes an extremely strong field within a radius of one wavelength near a wave source. In addition, it is known that longitudinal waves cause electrostatic induction on an object, and an electric field penetrates according to the dielectric constant of the object.

Although the particle nature of electrons is widely known, the theory of “probability wave of existence of electrons” that discusses the wave nature implies that when electrons become clear wavy due to the conditions (presence of existence) of electrons, He says that there are cases where it appears to spread in space, and cases where it becomes a wave packet and acts like a particle.

The reason is that “、 _R ²
+ [Psi _I ² "of [psi _R and [psi _I phase is unlike 90 °.

In the aforementioned coaxial radiator, if the terminals of the inner conductor and the outer conductor are connected and a voltage is applied in the same manner as described above,
Of course, a round-trip current flows, but the radiation from the central inner conductor and the radiation from the surrounding outer conductor are one in the opposite direction.
Due to the presence of the dielectric between them, the radiation from the inner conductor is shifted by about 90 ° between the electric field (generated in proportion to the voltage) and the magnetic field (generated in proportion to the current). Guessing from the common sense of generating a 90 ° phase difference
This is considered to be a synthetic spatial radiation wave having a phase shift of 90 ° obtained by adding (or subtracting) this 90 ° from the aforementioned 180 °. A general electromagnetic wave radiated from a monopole or dipole is a transverse wave, and this radiated wave, which has a nuance different from the fact that the electric field and the magnetic field are not out of phase, is called "electron existence probability wave" (≒ electron wave) It may have a property that leads to

Also, if the wavelength (frequency) of the radiation wave is different,
It is known that phenomena (properties) differ,
It was found that even if the wavelengths were the same, the phenomena would be different if the waveforms were different. In other words, whether the coaxial radiator is arranged linearly or curved, and used alone, used in plurals, or used in plurals, how to arrange at that time, Depending on various conditions, such as opening or connecting the terminals of each coaxial radiator, connecting them in series, or connecting them in parallel for energization, the radiated waves are generated in space. And produce complicated interference.
In the experiment, these conditions were verified in various combinations, and useful radiator arrangements and combinations were selected from the various phenomena that appeared as a result.

In view of the characteristics of the radiation wave (presenting phenomenon) and the adjustment of the radiation dose, the linear or slightly curved radiator is arranged at a certain interval on a plurality of lines, a plane, or a slight curved surface. The set form was considered a good solution, and this point was also verified in experiments.

Although the radiator wound in a coil shape generates an extremely strong longitudinal wave in the direction of the central axis of the coil, it is extremely difficult to adjust and manufacture the radiator. .

When radiators are assembled, it is common sense that the length of each radiator correlates with the frequency. That is, when the body length is "1 / an even multiple of the wavelength", resonance tuning is performed, and radiation is completely generated. It also correlates with the capacitance of the dielectric existing between the inner and outer conductors of the radiator.

[0034] The number of rows of radiators arranged is correlated with the radiation dose, but the spacing between the arrays greatly affects the interference. The connection and opening of the terminal will determine the fundamental properties of the radiated wave, and it is likely that mixing this connection and open alone in multiple strips will result in a more complex radiated wave.

In order to arrange a plurality of radiators in a row and make the whole a flat or curved surface, it is also possible to attach and assemble the respective radiators to a metal plate of a reflector type. In this case, if a metal plate is used as the reflection plate, absorption of radiant energy (electrostatic induction to electric field penetration to secondary radiation (reflection) and scattering) may occur, and electromagnetic induction is provided. It is preferable to use a non-magnetic material such as aluminum, copper, or an alloy thereof.

The coaxial radiator does not necessarily need to use the above-described coaxial cable, but has an inner conductor in the center and a dielectric (air layer) around the inner conductor.
Any cylindrical member provided with an external conductor via the first and second conductors may be used. Further, it is preferable that there is no equivalent to the jacket of the coaxial cable, because a higher radiation effect can be obtained.

Next, the radiation device according to the present invention obtained as a result of the above experiment will be described in detail based on the illustrated embodiment.

FIG. 1 is a perspective view of a wave radiating device 1 according to the present invention which imparts reducibility. As shown in the figure, this radiating device 1 has a long and narrow shape on the surface of an aluminum reflecting plate 2 which is curved so that the surface protrudes outward (left front side of the drawing in FIG. 1), and whose both ends are folded back. Coaxial radiator 3
Are mounted at predetermined intervals and arranged in a row in the vertical direction. This coaxial radiator 3 has an inner conductor 3a at the center, and its periphery is covered with an outer conductor 3b with a dielectric 3c as an insulating material interposed therebetween. Coaxial cable for antenna line (3
C2V) is used for convenience.

Each of the radiators 3 made of a coaxial cable has a length of about 200 to 220 mm, and one end (lower end in FIG. 1) of the radiator 3 is connected to the inner conductor 3a of the coaxial radiator 3 adjacent to the radiator 3. The outer conductors 3b are connected alternately.
Then, the conductive wire 4 drawn out from both ends is connected to an oscillator (not shown) for converting a power supply to a predetermined frequency.
It is designed to be connected to a power supply.

Here, in the present invention, an oscillator having an input of DC 12 V, 10 mA and outputting an alternating current having a frequency of 2.5 KHz is used as the oscillator. Then, the wave radiating device 1 of the present invention having the above configuration is placed in a predetermined position indoors in an energized state, and by measuring the change over time of the ORP value of the water sample placed at various locations around the device, The effect was confirmed.

The test was conducted in one section (approximately 35 square meters) of the third-floor part of a general high-rise apartment house (five-story steel concrete building) in Osaka city. The radiators were installed at the upper part of the wall and on the furniture. The position of the “water sample” was on a piece of furniture elsewhere in the room or at a plurality of locations inside the same.

The linear distance from the radiator 1 to the water sample is 0.
At a distance of 45 to 5.5 m, furniture and furniture were present on the straight line, and they were obstacles.

As the water of the water sample, general tap water is used, and two kinds of containers are used: a general 180 ml glass cup and a PET bottle (hereinafter abbreviated as PET) processed into a container. Using. The filling capacity was 150 ml.

This water sample was placed 0.45 m from the radiator 1,
1.2 m, 3.0 m, 4.2 m, and 5.5 m were placed in various places of the room, and the change with time of the ORP value was measured.

For measurement of the ORP value, a portable RM-20P type (PST-2739C as a sensor unit) manufactured by Toa Denpa Kogyo KK was used. In this case, strictly speaking, it is necessary to add the potential of the silver chloride electrode with respect to the hydrogen electrode as the measured numerical value. However, in order to avoid complication, the numerical value displayed on the instrument is used as it is.

Table 1 below shows the change over time of the ORP value of each water sample thus measured.

[0047]

[Table 1]

As is clear from this table, the ORP value of each of the water samples A to E placed in the room together with the radiator 1 is initially 7
What was 21 mV dropped rapidly over time. Further, the closer the change is to the radiator 1, the larger the change is, and a clear correlation is recognized.

At this time, the pH value of the water sample was measured at the same time, but hardly changed from the initial value of 7.3. In addition, for the purpose of comparison, the change in the ORP value of tap water at a place not affected by the radiator (another room separated by 20 m or more) was also measured. Was not recognized, and even when left for about 10 days, it was only reduced to about 300 mV.

Further, after the ORP value of the water sample was sufficiently reduced, the radiation was stopped, and the projected water (projected water sample) was left in the room as it was. Gradually progresses, and after about 24 hours, 3
It exhibited around 0 mV. On the other hand, a small number of these subjects were placed in the normal space (the above-mentioned building and the equipment storage on the roof), but their deterioration progressed slowly, and the
mV to 200 mV.

Furthermore, fresh tap water (around 700 mV) as a similar water sample placed in the room where radiation is stopped is 130 mV to 200 m after 24 hours.
V, and after about 80 hours, this value hardly changed.

From the above, it can be seen that almost the entire area of the room is reduced, and the residue reduces a new object (one having poor reducibility).

When the radiation device 1 is energized, the notch 9b of the sensing device 6 shown in FIG. 5 is directed toward the radiation device.
Started to rotate, and it was confirmed that radiation having an electron donating action was being emitted from the radiation device 1.

Furthermore, during this experiment, the portable telephone was received over the entire frequency range of AM and FM by the portable radio, but no noise derived from radiation waves was observed. Also,
No problems were observed with televisions, mobile phones, and personal computers used indoors.

When the radiating device 1 is used in a space region, the radiating device 1 may have a shape housed in a plastic case, or may have a bare form as described above. What is stored in a plastic case may be a watertight structure, submerged in water or floated on the water surface, or buried in the ground for use. Further, even in the case of a naked shape without a case, if each coaxial radiator 3 has an insulating jacket 3d as described above, it can be used by immersing it in water or burying it in the ground.

Table 2 shows that the radiating device 1 of the embodiment shown in FIG. 1 was energized while immersed in water, and the water specimens A to E placed at predetermined locations were respectively placed in the same manner as described above. O
It is an experimental result which measured RP value.

[0057]

[Table 2]

As is clear from this table, also in this case,
The ORP value of each of the water samples A to E is rapidly decreasing with time, unlikely under a natural environment. Also, the ORP value of the water sample A placed closest to the radiator 1 is
ORP of water samples B, C and D placed farther away
Although the change was smaller than the value, the water samples B, C, D,
In E, the closer to the radiating device 1, the greater the change, during which a clear correlation was observed.

The findings obtained during the above-mentioned experiments show that the freshness of vegetables is prolonged, the dying period of cut flowers is prolonged, the growth of potted plants is promoted, the evaporation and diffusion of liquid is promoted, bottles, cans, Examples include improvement of taste of beverages and foods in pack packaging, change of oxidizing agent aqueous solution, and the like.

FIG. 2 shows a second embodiment of the present invention. This radiating device 11 separates the outer conductor 3d of the coaxial cable constituting each radiator 3 to expose the braided wire of the outer conductor 3b, and connects the inner conductor 3a and the outer conductor 3b to every other capacitor. Are connected with each other.

By doing so, more powerful radiation is produced without attenuation by the jacket 3d, and the same effect is obtained as when the length of the radiator 3 itself is extended. That is, when the capacitance of the dielectric 3c of the 3C2V coaxial cable is calculated assuming that the capacitance is 100 pF / m, the capacitance becomes 0.
Those connected with capacitors of 22 μF, 0.46 μF and 1.0 μF have a single unit length of 2200 m,
It corresponds to 600m and 10,000m.

FIG. 3 is a perspective view showing a third embodiment of the present invention. The radiating device 21 is provided with each coaxial radiator 3
Is fixed to the curved surface of the support plate 5 in a state where the is stretched linearly. That is, each coaxial radiator 3 is curvedly arranged so as to form a part of an arc. When an experiment was performed on the radiation device 21 in the same manner as described above,
Although the tendency of the improvement of the ORP value of the water sample which appeared with the passage of time was almost the same, the rate of the improvement was slow, and the value considered to be the best (saturated) ORP was not preferable.

FIG. 4 shows a fourth embodiment of the present invention, in which the arrangement of the coaxial radiators 3 in the third embodiment is linear. The effect obtained from the radiating device 31 is further reduced.

From the above, the following points were found.

That is, radiation that is a standing wave in a non-equilibrium state can be obtained by opening the end of each coaxial radiator.

By connecting the inner conductor and the outer conductor of the coaxial radiator, radiation having a phase shift can be obtained.

In a radiating device of a collective type in which a plurality of coaxial radiators are arranged, interference of radiated waves becomes complicated depending on the number of rows, but the width of radiation (intensity / radiation range) increases.

Preferably, the power supply conductor is connected in series.

It is preferable that the coaxial radiator is curved rather than linearly extended.

The presence of a reflector is preferred.

It is preferable that the inner conductor and the outer conductor of each coaxial radiator are connected via a capacitor.

It is preferable to use an AC power supply of 0.1 to 0.25 KHZ. Also, judging from various points of changes and effects (effects) caused to the object / substance that has received the radiation (by the radiation), the following points can be listed as characteristics of the radiation wave.

(1) Normal (transverse wave used for communication, ie, an electromagnetic wave in which the electric field component and the magnetic field component match)
Is not considered to be identical to the nature of the radio waves.

The reason is that no noise is recognized in AM and FM reception, and since the power supply frequency is 2.5 KHz, the magnetic field component of the radiated wave is only an extremely small electric field component. This is probably because there is no carrier (transverse electromagnetic wave) that carries noise that is not a complete transverse wave, so it can be treated as a “standing wave”.

(2) Compared to the energy of infrared rays (a kind of electromagnetic wave) that gives a physical action, if infrared rays are incident (absorbed) on an object or substance, almost no scientific reaction occurs, Much of the energy is converted to heat energy. In an electric stove utilizing this principle, the ORP value of a water sample that has received the radiation (heating) gradually improves to a certain extent, but does not reach the present invention far. In addition, the power supply of the device of the present invention is
Since the output is 0 mA and the output is an IC circuit of 2.5 KHz, the average radiation output is considered to be several mW or less.
It turns out that both energies are completely different.

(3) When the impedance of the radiator of the apparatus was adjusted to tune to 600Ω, since the diffusion and evaporation of water and liquid were recognized, the radiation was the same as that of the ultrasonic wave. It is presumed to be a "wave."

(4) The radiated wave is characterized in that it has good transparency and low attenuation at a low frequency.

(5) If the improvement of the ORP value of the “water sample” is interpreted as an increase in hydrated electrons, the electrons are absorbed by the sample container (glass, PET, etc.) and charge is generated. It is considered that this is due to the generation of electric charge in the filling water by the principle of "induction charging". Or by radiation, not only the water of the water sample, but also empty containers, furniture, walls, tatami, and even clothes are given a deeply immersed electrostatic charge (excessive electron and reducibility), which persists for a considerable period of time. Therefore, it seems to have the nature of electrostatic waves.

From the above, this radiated wave is considered to be a “standing wave”, which is “an electrostatic wave having (superimposed) a longitudinal wave component and a transverse wave component having a phase shift”. Alternatively, the wave may have a characteristic of "compression wave" as a longitudinal wave and a characteristic of "electron wave" as an electrostatic wave.

As described above, in the method and apparatus of the present invention using waves, excess electrons can be directly applied to an object without using any medium, thereby reducing the object.

[0081]

As described above, according to the first aspect of the present invention, an alternating current of a predetermined frequency is applied to a cylindrical member provided with a dielectric between an inner conductor and an outer conductor. By doing so, a wave having an electron donating action is generated, so that there is an effect that a reductivity can be easily given to objects around the medium without requiring a medium or the like.

According to the second aspect of the present invention, by setting the frequency of the current to 0.1 to 2.5 KHZ, the effect of imparting reducibility can be further enhanced without affecting the surrounding electronic devices and the like. There is an effect that can be.

According to the third aspect of the present invention, the coaxial radiator provided with a dielectric between the inner conductor and the outer conductor and an oscillator for supplying an alternating current of a predetermined frequency to the coaxial radiator are reduced. Since the wave radiating device giving the property is constructed, there is an effect that the reduction function by the electron donating action can be obtained though it can be manufactured simply and at low cost.

According to the fourth aspect of the present invention, by arranging a plurality of coaxial radiators in a row and connecting them in series to an oscillator, it is possible to radiate a wave which gives a stronger reducing property. There is.

According to the fifth aspect of the present invention, the inner conductor and the outer conductor of each of the coaxial radiators arranged in a line are connected directly or via a capacitor, so that the coaxial radiators can be connected regardless of their length. There is an effect that a desired wave can be generated.

According to the sixth aspect of the present invention, the coaxial radiators arranged in a line are curved in the same direction with the same curvature, whereby the generated waves can be radiated strongly in a predetermined direction. is there.

According to the seventh aspect of the present invention, by forming the coaxial radiator with a coaxial cable, there is an effect that this kind of wave radiating device providing reducibility can be manufactured easily and at low cost.

According to the eighth aspect of the present invention, by removing the outer jacket of the coaxial cable, in addition to the effect of the seventh aspect, the generated wave is not attenuated by the outer jacket.
There is an effect that radiation can be emitted more strongly.

[Brief description of the drawings]

FIG. 1 is a perspective view of an embodiment of a wave radiating device for providing reducibility according to the present invention.

FIG. 2 is a perspective view of a main part of a second embodiment of the device of the present invention.

FIG. 3 is a perspective view of a main part of a third embodiment of the device of the present invention.

FIG. 4 is a perspective view of a main part of a fourth embodiment of the device of the present invention.

FIG. 5 is a perspective view of a sensing device used in the present invention.

[Explanation of symbols]

 1, 11, 21, 31 Radiating device 3 Coaxial radiator 3a Inner conductor 3b External conductor 3c Dielectric 3d Jacket 4 Conductor 6 Detector 7 Rotor 8 Pin 9 Cylindrical body 9a Stator 10 Insulating rubber plate

Continued on the front page F-term (reference) 2B022 DA19 4G075 AA03 AA42 BA06 CA13 CA23 CA24 DA02 DA18 EB21 EB31 EE01 EE02 EE21 FB02 FC11 FC15

Claims (8)

[Claims] 1. The direction of current flowing in each of an inner conductor and an outer conductor of a cylindrical member having an inner conductor at the center and an outer conductor provided around the inner conductor via a dielectric is opposite to each other. An alternating current oscillated at a predetermined frequency is applied so that the cylindrical member is used as a radiator to generate a wave having a reducing function by an electron donating action. How to give the wave. 2. The method according to claim 1, wherein the frequency is set in a range of 0.1 to 2.5 KHZ. 3. A coaxial radiator having an inner conductor at the center and an outer conductor provided around the inner conductor via a dielectric, and an oscillator for supplying a current of a predetermined frequency to the coaxial radiator. By applying an alternating current of a predetermined frequency to the inner conductor and the outer conductor so that the current directions are opposite to each other, the generated electric field versus the magnetic field is non-equilibrium, and a reduction function by an electron donating action is provided. A wave radiating device for providing reducibility, characterized in that a wave is generated. 4. The reducibility as set forth in claim 3, wherein a plurality of said coaxial radiators are arranged at equal intervals, and each coaxial radiator is connected in series with an oscillator. Giving wave radiation device. 5. The wave radiating device according to claim 4, wherein the inner conductor and the outer conductor of each of the coaxial radiators are connected directly or via a capacitor. 6. The radiating device for providing reducibility waves according to claim 4, wherein each of the coaxial radiators is curved in the same direction with an equal curvature. 7. The radiation of a wave providing reducibility according to claim 3, wherein the coaxial radiator is constituted by a coaxial cable cut to a predetermined length. apparatus. 8. The radiating device for reducing waves according to claim 7, wherein a jacket of the coaxial cable is removed.