JP3202846U - Quantum irradiator - Google Patents

Abstract

Provided is a quantum irradiator capable of easily modifying a substance by quantum energy. When an irradiation target such as a fresh flower 52, a vegetable 54, or a fish 55 is irradiated with a quantum wave 59 for modification, the quantum wave generation source 1 does not directly irradiate the target to be irradiated, but quantum. The wave radiator 2 irradiates the identification tag 3 describing the identification information that can identify the irradiated object with the quantum wave 25, and the quantum wave 59 is applied to the actual irradiated object using the quantum teleportation phenomenon 6. Irradiate. Therefore, labels 511 to 551 describing corresponding identification information are attached to the irradiated object. Further, the quantum wave 15 from the quantum wave generator 12 is propagated from the first radiator 11 to the quantum wave radiator 2 by the quantum teleportation phenomenon 7. Therefore, it is not necessary to install a large-scale irradiator in the vicinity of the irradiated object, and the work burden such as bringing in the irradiated object can be dramatically reduced. [Selection] Figure 1

Description

  The present invention relates to a quantum irradiator that modifies the irradiated object by irradiating the irradiated object with quantum waves.

  2. Description of the Related Art Conventionally, irradiated objects such as resin products, plants, foods, etc. are irradiated with quantum waves to denature their properties (for example, promotion of growth in the case of plants). In patent document 1 which this inventor proposed, it uses for the oxidation prevention of this edible oil by irradiating an edible oil with a quantum wave. Quantums include photons, electrons, quark, and neutrinos.

Japanese Patent No. 5727104

  In the above-mentioned Patent Document 1, an electrode is immersed in edible oil, a low frequency voltage from an AC power source is used as a bias, and a high frequency voltage extracted by resonance from an external electric field is applied to the electrode. The quantum wave is generated from the electrode by taking out and giving the component. Therefore, since a weak external electric field is used, mass production is difficult, and there is a problem that it is difficult to generate strong quantum waves and to strongly denature them.

  An object of the present invention is to provide a quantum irradiator capable of performing modification easily and efficiently when modifying a substance by irradiating quantum waves.

  In the quantum irradiator of the present invention, identification information individually assigned in advance to an object to be irradiated with a quantum wave is described, a first identification tag attached to the object to be irradiated, and the first A second identification tag in which identification information having the same content as that of the identification tag is described, a quantum wave generation source that generates a quantum wave, and a quantum wave generated by the quantum wave generation source is irradiated to the second identification tag A quantum wave emitter, and the quantum wave irradiated to the second identification tag is instantaneously moved to the irradiation target specified from the identification information between the first and second identification tags. The object to be irradiated is denatured by acting on the object to be irradiated by a teleportation phenomenon.

  According to the above configuration, when an object to be irradiated, such as a resin product, a plant, or a food, is irradiated with quantum waves to modify its properties (such as promoting growth in the case of plants), the quantum wave source is Rather than directly irradiating the object to be irradiated, quantum waves are irradiated to an identification tag that describes identification information that can identify the object to be irradiated. This is based on the inventor's knowledge that quantum waves behave as if they are recognizing characters, and further uses the quantum teleportation phenomenon.

  Specifically, identification information individually assigned in advance to an object to be irradiated with a quantum wave, for example, two identification tags in which arbitrary numbers having a predetermined digit length are similarly described, are prepared, and the object to be irradiated side Is attached with a first identification tag, and the quantum wave generation source side irradiates the second identification tag with quantum waves. Then, according to the experiment of the present inventor, the quantum wave specifies an object to be irradiated in a place of several hundred km, for example, and acts instantaneously regardless of the distance and time by the quantum teleportation phenomenon. It will be possible to exert a denaturing effect close to that when irradiated. In order to irradiate the second identification tag with the quantum wave, a quantum wave radiator on which the second identification tag is mounted and a quantum wave generation source that applies a quantum wave to the quantum wave radiator are provided.

  For example, when a plant or animal (meat or fish) is exposed to quantum energy, the tissue can be activated and the freshness can be maintained for a long time. In addition, in the case of food, not only can deterioration be suppressed, but a rapid aging effect can be expected. For example, it is remarkable with alcohol. Furthermore, in the case of a resin product, living organisms in the vicinity can be activated, which is extremely effective for packaging materials and the like.

  Therefore, irradiation is extremely simple, and a large energy quantum wave generated by a dedicated large-scale quantum wave generation source (oscillator) provided at a location separated from the irradiated object side is used as the second identification tag. By irradiating, many objects to be irradiated can be collected or strongly denatured.

  In the quantum irradiator according to the present invention, the first identification tag is a seal attached to the irradiated object.

  According to said structure, the to-be-irradiated target object which stuck the seal | sticker can be irradiated to a quantum wave collectively.

  Furthermore, in the quantum irradiator of the present invention, the quantum wave source and the quantum wave radiator include metal conductors made of the same material, and the quantum wave generator is in relation to the quantum wave radiator, By causing the assimilation phenomenon to share consciousness to each other by being initially placed in contact or in the vicinity, the quantum wave is generated from the quantum wave radiator by the quantum teleportation phenomenon by being separated, It is characterized in that irradiation of quantum waves to the second identification tag is realized.

  According to the above configuration, as described above, by irradiating the second identification tag with quantum waves, the object to be irradiated at a remote location can be denatured by the quantum teleportation phenomenon (resonance phenomenon). However, since a quantum wave source that gives a quantum wave to a quantum wave radiator that actually irradiates the second identification tag with a quantum wave is required, they are made of materials equal to each other, particularly preferably a metal conductor made of aluminum. Configure. Then, according to the experiments of the present inventors, once the quantum wave source and the quantum wave radiator are placed in contact or in the vicinity, an assimilation phenomenon that shares consciousness occurs. The quantum wave can be supplied by the teleportation phenomenon (resonance phenomenon). With respect to the primary quantum wave supplied from the quantum wave generation source to the quantum wave radiator, the object to be irradiated is given as a secondary quantum wave.

  Therefore, the quantum wave emitter that actually irradiates the second identification tag with a quantum wave is small, and even if it is realized with a simple configuration, the quantum wave generation source can be configured to an arbitrary size, Waves can be generated, and quantum waves can be supplied to a plurality of quantum wave radiators from a single quantum wave source, which is also efficient.

  In the quantum irradiator of the present invention, the quantum wave radiator is made of a metal conductor, and the quantum wave generator is a negative high voltage of 50 to 60 Hz and 3000 to 9000 V with respect to the quantum wave radiator. It is characterized by generating quantum waves by giving.

  According to the above configuration, according to the experiment of the present inventor, the power source for generating the high voltage is applied to a metal conductor, for example, SUS, iron, zinc, tin, preferably aluminum, with a conductive wire (copper or aluminum wire). By connecting and applying the high voltage, quantum waves can be generated efficiently.

  Furthermore, in the quantum irradiator of the present invention, the quantum wave radiator is made of a metal conductor, and the quantum wave generation source is a negative low voltage of 2 to 2000 Hz and 24 to 48 V with respect to the quantum wave radiator. Quantum waves are generated by applying a frequency potential oscillation.

  According to the above configuration, according to the experiment of the present inventor, a power source that generates a low frequency is connected to a metal conductor with a conductive wire (copper or aluminum wire), and the quantum wave is efficiently generated by applying the low frequency. Can be generated automatically. By changing the frequency, it is possible to select an object to be irradiated to be denatured.

  The quantum irradiator of the present invention further includes a vibration device that promotes assimilation of the second identification tag by applying low-frequency vibration to the quantum wave radiator.

  According to said structure, a 2nd identification tag accumulate | stores quantum energy by giving a low frequency, Preferably about 5-6Hz vibration to the quantum wave radiator with which the 2nd identification tag is mounted. It is assimilated with the quantum wave radiator.

  Therefore, a larger quantum wave can be delivered to the irradiated object in a short time.

  As described above, the quantum irradiator of the present invention irradiates an object to be irradiated, for example, a resin product, a plant, a food, etc. with a quantum wave to modify its properties (in the case of a plant, promote growth, etc.). The quantum wave generating source does not directly irradiate the object to be irradiated, but the quantum wave radiator is quantum for the second identification tag that describes the identification information that can identify the object to be irradiated. A wave is irradiated, and an actual irradiated object is irradiated with a quantum wave using a quantum teleportation phenomenon.

  Therefore, the irradiation is very simple, and the quantum wave radiator that actually irradiates the second identification tag with the quantum wave is small, and even if the quantum wave generator is realized with a simple configuration, the quantum wave generation source is arbitrarily large. Further, it is possible to generate a strong quantum wave, and a quantum wave can be supplied from a single quantum wave generation source to a plurality of quantum wave radiators, which is also efficient.

It is a schematic diagram for demonstrating the usage method of the quantum irradiator which concerns on one Embodiment of this invention. It is an electric circuit diagram of a quantum wave generator.

  FIG. 1 is a schematic diagram for explaining a method of using a quantum irradiator according to an embodiment of the present invention. The quantum irradiator of this embodiment includes a quantum wave generation source 1 and a quantum wave radiator 2. The quantum irradiator of the present invention does not directly irradiate the irradiation target object 5 with the quantum wave generation source 1 when the irradiation target object 5 is irradiated with the quantum wave (59) for modification. A quantum wave (25) is irradiated to the identification tag 3 that describes at least the identification information 32 that can identify the object 5 to be irradiated. This is based on the inventor's knowledge that the quantum wave (25) behaves as if it recognizes a character. Further, the propagation of the quantum wave (25, 59) has a quantum teleportation phenomenon 6,7. It is characterized by using.

  Specifically, the quantum wave source 1 includes a first radiator 11 that emits quantum waves, a quantum wave generator 12 that generates quantum waves in the first radiator 11 as described later, and the quantum wave generator 12. A conductive wire 13 that generates a quantum wave (15) by applying a voltage generated by the wave generator 12 to the first radiator 11 is provided. The first radiator 11 is, for example, a flat plate made of a metal conductor, for example SUS, iron, zinc, tin, preferably aluminum. The conducting wire 13 is made of an insulating coated copper or aluminum wire.

  The quantum wave generator 12 applies a negative voltage having a predetermined period to the first radiator 11 made of a metal conductor, and applies a negative potential or electric field, so that a quantum wave ( 15) is generated. The quantum wave generator 12 includes, for example, an application circuit 121 shown in FIG. 2A and an application circuit 122 shown in FIG. The first radiator 11 made of a metal conductor may be placed in the aerial space, but may be grounded via a high resistance of, for example, MΩ or more in order to control the energy of the generated quantum wave (15). Good.

  An application circuit 121 shown in FIG. 2A includes a series circuit of a diode 1212 and a resistor 1213 connected to one terminal of an AC power supply 1211 and a series circuit of a diode 1214 and a resistor 1215 connected to the other terminal. It is prepared for. The cathodes of the diodes 1212 and 1214 are connected to the AC power supply 1211, and the anode is connected to one end of the resistors 1213 and 1215. As a result, a negative half-wave voltage extracted from the other end of the resistors 1213 and 1215 is applied to the first radiator 11 of the metal conductor via the conductive wire 13. When the AC power supply 1211 is a single-phase two-wire, one wire is grounded in a pole transformer or the like, and this application circuit 121 is surely negative when either of the two wires is hot. The voltage can be taken out.

  The application circuit 122 is configured by a diode bridge composed of diodes 1222 to 1225. The cathode of the diode 1222 and the anode of the diode 1224 are connected to one terminal of the AC power supply 1221, the cathode of the diode 1223 and the anode of the diode 1225 are connected to the other terminal, and the cathodes of the diodes 1224 and 1225 are grounded. . As a result, the negative and full-wave voltage extracted from the anodes of the diodes 1222 and 1223 is applied to the first radiator 11 of the metal conductor via the conductive wire 13.

  Here, the application circuits 121 and 122 select the AC power sources 1211 and 1221 and the breakdown voltage of the element, and according to the experiment of the present inventor, the first radiator 11 is subjected to any of the following conditions: By applying a voltage, a quantum wave can be generated. The first is a negative high voltage of 50-60 Hz, 3000-9000V. Second, the application circuits 121 and 122 are negative low-frequency voltages of 2 to 2000 Hz and 24 to 48 V. Thereby, a quantum wave can be generated efficiently. Note that the voltage generated by the AC power supplies 1211 and 1221 is not limited to a sine wave that requires a simple circuit, but may be a triangular wave, a rectangular wave, a pulse wave, or the like.

  In this way, by applying a periodic negative voltage to the first radiator 11 of the metal conductor, as shown by reference numeral 15 in FIG. 1, 17 kinds of quantum such as photons, electrons, quack, neutrinos, etc. Any of the above occurs (among others, quark is likely to occur (occurs frequently), and neutrinos may be generated). Then, the quantum wave (15) is also generated in the quantum wave radiator 2 installed at a separated place by the quantum teleportation phenomenon (resonance phenomenon) 7 (reference numeral 25).

  Similarly to the first radiator 11, the quantum wave radiator 2 as the second radiator is also a flat plate made of a metal conductor such as SUS, iron, zinc, tin, preferably aluminum, for example. According to the experiment of the present inventor, the quantum wave radiator 2 is made of the same kind of metal material as that of the first radiator 11, particularly preferably aluminum, and is in the state of being placed in contact with or in the vicinity in the initial state. The quantum wave radiator 2 is caused to generate a quantum wave (15) by the high voltage or low frequency from the quantum wave generator 12, thereby allowing the quantum wave radiator 2 to share assimilation with the first radiator 11. A phenomenon can be caused. As a result, as described above, quantum can be generated in the quantum wave radiator 2 by the quantum teleportation phenomenon (resonance phenomenon) 7 as indicated by the reference numeral 25 even if it is separated later.

  When this quantum 25 is irradiated to the identification tag 3 placed on the quantum wave radiator 2, and the identification tag 3 is assimilated to the quantum wave radiator 2, according to the experiment result of the present inventor, the quantum 25 is It behaves as if it is recognizing characters, and the irradiated object 5 to which the identification information corresponding to the identification information described in the identification information column 32 is given is separated by, for example, several hundred km regardless of the distance and time. Even if it is located, it can be specified and the quantum teleportation phenomenon (resonance phenomenon) 6 can act instantaneously and exhibit a modification effect close to that when directly irradiated.

  Specifically, in the example of FIG. 1, as the irradiated object 5, a film 51 and a planter 53 are shown as a resin product, a fresh flower 52 and a vegetable 54 are shown as plants, and a fish 55 is shown as an animal. Yes. Then, labels 511 to 551 as first identification tags on which identification information assigned individually in advance is pasted are attached to these irradiated objects 5, and the identification tags 3 as second identification tags are attached. In the identification information column 32, corresponding identification information is described. In the present embodiment, in order to avoid complication of the drawing, the identification information is a three-digit number or an alphabetic character. The labels 511 to 551 can be managed by POS at the time of sale, and a barcode corresponding to the identification information is also described. The identification tag 3 includes a barcode corresponding to the barcode column 33. In the product name column 31, product names such as the fresh flowers 52 and vegetables 54 are described for identification of the worker.

  FIG. 1 conceptually shows that when a quantum wave (25) is irradiated to the identification tag 3, the quantum 59 acts on the irradiated object by the quantum teleportation phenomenon (resonance phenomenon) 7. . As a mechanism of denaturation by the quantum 59, when a quantum wave (59) is exposed to, for example, a plant or a living organism (52, 54, 55), the tissue is activated, and specifically, the electronic arrangement of atoms is affected ( For example, the freshness is maintained (less likely to be damaged) in the vegetable 54 and the fish 55, and in the case of the fresh flower 52 Of course, the flower lasts longer, and the fresh flowers 52 that have been wilting come back. Moreover, in the example of the resin product (51, 53), deterioration due to ultraviolet exposure is delayed. In particular, when the resin product (51, 53) is activated, living organisms adjacent thereto are also activated. When the film 51 is used for packaging fresh flowers 52, vegetables 54, and fish 55, the quantum 59 does not act on them. But you can extend the shelf life. In addition, when the planter 53 is activated, the growth of the fresh flowers 52 is accelerated. Furthermore, the target effect can be varied according to the AC cycle.

  By comprising in this way, in irradiating the to-be-irradiated target object 5 with a quantum wave (59) and performing modification | denaturation, the quantum wave generation source 1 does not directly irradiate the to-be-irradiated object 5, Since the quantum wave (25) is irradiated to the identification tag 3 that describes the identification information that can identify the irradiation target object 5, it is necessary to install a large irradiator near the irradiation target object 5. Without the need to bring the object to be irradiated 5 or the trouble of bringing in the object to be irradiated 5, and it is possible to perform irradiation very easily, and a dedicated large-scale quantum wave generator (oscillator) provided at a location separated from the object to be irradiated 5 ) By irradiating the identification tag 3 with the quantum wave (15, 25) having a large energy generated in 1, a large modification effect of the irradiation object 5 can be obtained.

  In the present embodiment, as described above, the identification target 3 is irradiated with the quantum wave (25), and the irradiated object 5 at a distant place is denatured by the quantum teleportation phenomenon (resonance phenomenon) 6. The quantum wave generator 1 can be installed in a remote place as a quantum wave source that gives the quantum wave (25) to the quantum wave radiator 2 that actually irradiates the identification wave 3 with the quantum wave (25). Is used to supply the primary quantum wave (25) by the quantum teleportation phenomenon (resonance phenomenon) 7, and the object to be irradiated 5 is further subjected to the secondary quantum wave obtained by the quantum teleportation phenomenon (resonance phenomenon) 6. (55) is given. With this configuration, the quantum wave emitter 2 that actually irradiates the identification wave 3 with the quantum wave (25) is small, and the quantum wave source 1 can be of any size even if it is realized with a simple configuration. In addition, it is possible to generate strong quantum waves (15, 7), and to supply quantum waves from a single quantum wave generation source 1 to a plurality of quantum wave radiators 2. It is possible and efficient.

  Moreover, it is preferable to give a low frequency vibration to the quantum wave radiator 2. In the example of FIG. 1, a seismic device 4 is provided below the quantum wave radiator 2, and the swinging arm 41 moves the quantum wave radiator 2 in the direction of the arrow 42 at a low frequency, preferably 5 Vibrate at about 6 Hz. As a result, the identification tag 3 is promoted to be assimilated with the quantum wave radiator 2 storing the quantum energy (25), and in a short time, a larger quantum wave (6, 59) is applied to the irradiated object 5. Can be delivered to.

  Here, in the above-described embodiment, the quantum 15 is propagated from the first radiator 11 to the quantum wave radiator 2 by the quantum teleportation phenomenon (resonance phenomenon) 7, and the same kind of metal plate is used for such propagation. The quantum wave radiator 2 is dedicated to the irradiation of the quantum wave (25) to the identification tag 3, and the propagation of the quantum 15 is performed by the antenna 16 instead of using the first radiator 11 and the quantum wave radiator 2 which are , 26 may be used.

  Specifically, the quantum wave generator 12 is connected to the antenna 16 by a conducting wire 17, and the quantum wave (15) generated by the antenna 16 is received by the antenna 26 by the quantum teleportation phenomenon (resonance phenomenon) 9. The quantum 25 is given to the quantum wave radiator 2 through the conducting wire 27. The antennas 16 and 26 are made of the same kind of metal material, preferably aluminum, and are formed in a similar shape of a hexagonal cylinder (the transmitting-side antenna 16 is relatively large and the receiving-side antenna 26 is often small). May be the same size). Thus, using the antennas 16 and 26 for the quantum teleportation 9 is preferable because the propagating quantum energy (15) can be increased.

DESCRIPTION OF SYMBOLS 1 Quantum wave generation source 11 1st radiator 12 Quantum wave generator 121,122 Application circuit 13 Conductor 15 Quantum 16 Antenna 17 Conductor 2 Quantum wave radiator 25 Quantum 26 Antenna 27 Conductor 3 Identification tag 31 Product name column 32 Identification information column 33 Barcode field 4 Seismic device 41 Oscillating arm 5 Irradiated object 51 Film 52 Fresh flower 53 Planter 54 Vegetable 55 Fish 511 to 551 Label 59 Quantum 6, 7, 9 Quantum teleportation phenomenon

Claims (6)

Identification information assigned individually in advance to the irradiation object of the quantum wave is described, and a first identification tag attached to the irradiation object,
A second identification tag in which identification information of the same content as the first identification tag is described;
A quantum wave source for generating quantum waves;
A quantum wave radiator that irradiates the second identification tag with a quantum wave generated by the quantum wave source;
Due to the quantum teleportation phenomenon in which the quantum wave irradiated to the second identification tag instantaneously moves to the irradiation target specified from the identification information between the first and second identification tags, the irradiation target A quantum irradiator characterized in that the object to be irradiated is denatured by acting on the object.   The quantum irradiator according to claim 1, wherein the first identification tag is a seal attached to the object to be irradiated.   The quantum wave generation source and the quantum wave radiator include metal conductors made of the same material, and the quantum wave generation source is initially placed in contact with or in the vicinity of the quantum wave radiator. , Generating an assimilation phenomenon that shares consciousness with each other and then separating them to generate a quantum wave from the quantum wave emitter by a quantum teleportation phenomenon to irradiate the second identification tag with the quantum wave The quantum irradiator according to claim 1, wherein the quantum irradiator is realized.   The quantum wave radiator is made of a metal conductor, and the quantum wave generator generates a quantum wave by applying a negative high voltage of 50 to 60 Hz and 3000 to 9000 V to the quantum wave radiator. The quantum irradiator according to any one of claims 1 to 3.   The quantum wave radiator is made of a metal conductor, and the quantum wave generator generates a quantum wave by applying a negative low-frequency potential oscillation of 2 to 2000 Hz and 24 to 48 V to the quantum wave radiator. The quantum irradiator according to claim 1, wherein the quantum irradiator is generated.   The quantum device according to claim 1, further comprising a vibration device that promotes assimilation of the second identification tag by applying low-frequency vibration to the quantum wave radiator. Irradiator.

Images