KR20230173063A - Quantum energy generating device that irradiates quantum energy - Google Patents

Abstract

Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, Square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. The first material (paper) to which one coil shape is selected and attached. 2nd material (non-conductive materials such as PVC), 3rd material (conductive metals such as copper (Cu)), 4th material (wood such as plywood), 5th material (inorganic materials such as concrete walls), 6th material (fiber material), 7th material (glass, etc.), 8th material (transparent soft material such as polyimide) is selected as a material, and conductive ink is applied on the surface of the material through flexography, screen printing, offset printing, Select one of the printing methods among web press, inkjet printing, and dry printing to print soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag type. Print and dry any one coil shape in the selected shape among coils (up and down, left and right), extension-shaped coils, motor stator-shaped coils, square coils, RF coils, toroidal coils, and combinations of these shapes. A method of forming a quantum energy generating coil on the surface of a selected material, a method of processing a conductive metal such as copper (CU) into the shape of the selected quantum energy generating coil and attaching it to the surface of the selected material, and an adhesive on the surface of the selected material. After applying, a method of winding into a quantum energy generating coil shape using a conductive metal wire coated with a coil shape selected among the quantum energy generating coil shapes, and a method of winding the selected quantum energy generating coil shape on the surface of the selected material. A quantum energy generating coil is manufactured by attaching an electroluminescent element made of , and the manufactured quantum energy generating coil is connected to a first power supply, a second power supply, a third power supply, a fourth power supply, and a fifth power supply. , a sixth power supply, a quantum energy generator 300 consisting of a power supply selected from the battery, a sealed glass tube, a cathode, a power supply for the cathode, a first anode, and a high voltage for applying a high voltage to the first anode. A bremsstrahlung type generator (400A) consisting of a power supply, a second anode, a power supply for the second anode, and a quantum energy emission layer); and a sealed glass tube, a cathode, a cathode, a gate electrode, a first anode, and an X-ray. Second quantum energy consisting of a target plate, a second anode, a quantum energy dissipation layer, a first power supply for the cathode and the first anode, a second power supply for supplying power to the gate electrode, and a third power supply for the second anode. When the quantum energy generator of the generator (400B) is installed on the 2nd, 4th, or 6th side of a specific space and supplies the power generated by the power supply to a plurality of quantum energies, each quantum energy whose winding direction is opposite to each other is generated. A pulse-type electromagnetic field is generated from the energy generation coil, and pulse-type electromagnetic fields in opposite directions overlap and disappear at the center of space, and quantum energy is generated in a zero magnetic field state and irradiated into the space. Electrical devices/electronic devices installed in the space according to the operation mode It can remove electromagnetic waves generated in the space, sterilize harmful bacteria in the space, generate an electromagnetic field that can improve health, and irradiate quantum energy that promotes health by resonating with the new product's unique magnetic field.

Description

Quantum energy generating device that irradiates quantum energy to materials on which quantum energy generating coils are printed or attached to the surface and to a specific space defined by these materials {Quantum energy generating device that irradiates quantum energy}

The present invention is a soleroid coil attached to the surface of various materials such as paper attached to 2, 4, or 6 sides of the wall dividing a specific space, or to each side (1, 2, 3, 4, 5, 6). ,Troid coil, Cusp coil, Helmheltz coil, Gradient saddle coil, Uniform saddle coil, Maxwell coil. Trigger coil, zigzag shape (up and down, left and right), extension shape, motor stator shape coil, square coil. Select one shape among RF coil, toroidal coil shapes, and combinations of these shapes, print and dry conductive ink in the selected shape to form a quantum energy generating coil, or use model picking technology using a laser. Process metal plates such as silver or stainless steel into various quantum energy generating coil shapes and attach them by applying adhesive, or apply adhesive to the surface of a selected material and use a coated wire with a certain diameter to generate various quantum energies. A certain number of turns are wound in a coil shape, and the power generated from a power supply installed on one side of the material surface or on one side of the wall or externally is supplied directly or wirelessly and installed directly on the surface of the wall facing each other or on the surface of the material attached to the wall surface. By supplying power to the energy generation coil, forward or opposite magnetic fields generated as current flows in the quantum energy generation coil are irradiated to a specific space and the opposing magnetic fields are overlapped and extinguished to generate quantum energy in a zero magnetic phase state. Various forms of quantum energy that irradiate the generated quantum energy into space to sterilize bacteria and viruses floating in space and resonate with the natural frequency of the occupant's body to improve health or prevent spoilage of food and extend the storage period. It relates to a quantum energy generator that generates.

The dictionary meaning of space (or room) is defined as an empty place with nothing, a wide range physically and psychologically, and a place, area, or world where any material or object can exist. Usually, the inside of space. It is usually referred to as indoor.

Depending on the classification method, space is classified into commercial space, residential space, office space, sports facility space, leisure space, medical facility space, educational facility space, etc. Depending on the size (volume), it can be divided into sports facilities, business center, etc. It is classified into various types depending on the size of the volume, such as medium space such as space, storage, refrigerator, food container, medicine storage container, or strain storage container. It can be classified into various forms, such as a rectangular parallelepiped complex space or sphere, and has various uses.

Economic development resulting from industrialization has brought about many changes in human lifestyles and living environments. In particular, the time spent indoors in residential spaces increases, and in particular, the acute illness caused by the virus that broke out on December 1, 2019 Coronavirus disease 2019 (COVID-19), a respiratory disease, is spreading around the world, and in Korea, coronavirus disease 2019 (COVID-19) has spread again from December 8, 2020, and social distancing level 2.5 has been implemented nationwide. Authorities recommend staying at home as much as possible, refraining from going out to gatherings and using public facilities as much as possible, and preventing infection from coughing, sneezing, breathing, respiratory droplets (saliva), or touching your eyes, nose, and mouth after touching contaminated objects. As people are being asked to stay indoors, the amount of time spent indoors in certain spaces (e.g. homes) has increased.

As indoor spaces become increasingly sealed, a new environmental problem called indoor air pollution has emerged.

Indoor air pollution refers to various indoor spaces (houses, schools, offices, public buildings, hospitals, livestock farms, industrial processes, refrigerators, food storage containers (e.g. Lock&Lock), injection containers, fruit storage containers, packaging containers, capsule interior, etc.) Air pollution refers to air pollution, which is caused by very complex causes. It can have adverse health effects on indoor residents, and it can cause contamination by bacteria or microorganisms during the storage process of food or medicine, deterioration, denaturation of proteins, etc., leading to product disposal, etc. It causes other environmental problems, and in the case of livestock breeding facilities, it causes large losses to livestock farms due to the mass death of livestock raised due to foot-and-mouth disease, avian influenza, and land fever, and is emerging as a social problem.

In general, indoor air pollutants include formaldehyde, volatile organic compounds (VOCs), carbon monoxide (CO), carbon dioxide (CO2), fine dust (PM2.5), and microorganisms in offices and residential spaces. , radon, etc., and are exposed to electromagnetic waves generated from indoor electrical devices and electronic products.

Odorous substances emitted from livestock breeding facilities (spaces) include ammonia, hydrogen sulfide, methyl mercaptan, methyl sulfide, trimethylamine, acetaldehyde, propionaldehyde, toluene, and xylene, resulting in complaints of odor.

Food storage space causes a lot of loss due to deterioration of storage objects or denaturation of proteins due to changes in moisture or growth of microorganisms, causing spoilage or loss of product value.

Various electrical and electronic devices can be installed inside various spaces. When these electrical and electronic devices are used, electromagnetic waves of various frequencies are generated, and occupants, livestock, stored goods, etc. inside the space are affected by the electromagnetic waves.

In Korea, thanks to the development of the electrical and electronic industries and information and communication technology, the use of various wireless communications and broadcasting services using radio waves has become possible. And technologies using radio waves are commonly used in fields ranging from mobile communications to the medical industry. The scope of development is gradually expanding to include fields such as aviation and space industries. In terms of its effectiveness, the use of radio waves has relieved various visual and spatial constraints that exist in our lives.

On the other hand, the rapid increase in the use of electromagnetic waves has resulted in a decrease in the performance of electrical / electronic equipment due to communication difficulties or malfunctions due to interference between devices. This has caused the problem of worsening electromagnetic environment due to various electromagnetic waves. .In particular, most of the various contents provided in the U-City environment using ubiquitous technology use wireless communication infrastructure, so the environment for electromagnetic waves becomes worse and the space where radio waves are concentrated increases. Therefore, from various factors, It must be possible to diagnose electromagnetic interference by measuring and analyzing the electromagnetic waves generated.

In general, electromagnetic waves are known to be harmful to the human body when exposed to low-frequency electromagnetic waves for a long period of time, even if the level is small. When the human body is exposed to low-frequency electromagnetic waves for a long time, an induced current is generated within the human body, causing Na ⁺ , K ⁺ , Cl existing inside and outside the cell membrane. ^- It is known to cause various ion imbalances, such as affecting hormone secretion and immune cells.

In addition, due to the development of science and technology, the influence of electromagnetic waves in living spaces has increased in the number of electric appliances such as refrigerators, TVs, air conditioners, and large rotating machines (motors) in factories. As a result, occupants and animals in the space are always affected by electromagnetic waves, and humans and animals are always affected by electromagnetic waves. The electromagnetic waves that affect livestock are millimeter waves with a frequency of 30-300 GHz and a wavelength of 1-10 mm, which are generated from natural electromagnetic fields and various electrical and electronic devices, and the reality is that humans live in an environment exposed to millimeter waves. Green onions have a huge impact on the human body.

It is known that if the human body is exposed to electromagnetic waves for a long period of time, there is a high possibility of it developing into a disease due to changes in body temperature and disruption of biorhythms. Also, very strong electromagnetic waves can cause stress, heart disease, and chemical changes in the blood. In men, sperm count is low. Research results have also been published showing that, in the case of women, it can cause menstrual irregularities and birth defects.

Recently, as these devices become larger and more powerful, interest in the problem of harmony between the electromagnetic field and human society is increasing. Among these, the effect of electromagnetic fields on the living body has been a topic of interest for a long time, the mechanism of its action is being elucidated, and the electrical properties and absorption power distribution of the living body in response to electromagnetic waves are also being well investigated. When millimeter waves are irradiated to the human body, the depth at which they can penetrate into skin cells is limited depending on the frequency and output, so they are harmless to the human body and open the possibility of diagnosis and treatment for the human body. Recently, millimeter waves have been used in the medical and biological fields. Active research is underway in this field.

The extent of such electromagnetic waves varies depending on the various electrical devices used inside a building. Therefore, electromagnetic wave blocking devices and electromagnetic wave blocking and absorbing compositions are developed and used to protect the human body from electromagnetic waves.

Since the degree of absorption and blocking of electromagnetic waves cannot be known for such electromagnetic wave blocking devices or electromagnetic wave blocking and absorbing compositions, there is a problem in that the electric field strength and magnetic field must be measured by placing electric devices and home appliances inside the building identical to the actual situation. There are inconvenient problems, such as having to rearrange electronic products and electrical devices to suit the electromagnetic wave situation one by one.

In addition, the air we breathe is closely related to human health. Recently, as air pollution has become more serious, the indoor air of food processing facilities and living spaces contains various viruses, E. coli, mold, Pseudomonas aeruginosa, Staphylococcus aureus, pneumoniae, and Legionella. Harmful bacteria such as bacteria and mutated viruses (MRSA), MERS-COV, Ebola virus, SARS-COV, COVID-19, MERS, new flu, SARS, etc. And infectious bacteria are floating around, and the content of various organic substances that cause odor is increasing. If you inhale polluted air without sterilization, it can cause fatal harm to your health. According to a report by the World Health Organization (WHO), It is known that indoor pollutants have a 1,000 times higher impact on the lungs than outdoors. You can guess the damage. In addition, according to a report by the Ministry of Environment in 2006, the number of patients with asthma, atopic dermatitis, and allergic rhinitis is increasing to 6.65 million, and recently, the world is experiencing a global pandemic due to COVID-19, with travel, social gatherings, education, business, and religious life. Group behavior is strictly controlled. Quarantine activities such as limited entry bans, social distancing, and infection prevention in public facilities such as schools, performance halls, residential spaces, religious facilities, factories, restaurants, and culture and arts centers are being strongly implemented around the world. Accordingly, to protect public health, Research should be conducted at a national level to prepare preventive measures. In addition, bacteria such as fungi, Pseudomonas aeruginosa, Staphylococcus aureus, pneumoniae, and Legionella, as well as MRSA, MERS-COV, and Ebola viruses. , floating viruses such as SARS-COV and bacteria may spread.

In addition, livestock breeding facilities create a favorable environment for bacteria, floating viruses, and harmful microorganisms to live in the remaining feed, unsterilized drinking water, and excrement, thereby preventing avian influenza (AI), foot-and-mouth disease (FMD), and swine fever bacteria ( ASF), Edwardsiellus Tarda, Streptococcus iniae or vibrio ichtyoenteri in fish farms, MRSA (methicillin-resistant S. aureus) ], mutant viruses such as MRSE [methicillin-resistant S. epidermidis], Mycobacterium tuberculosis, Mycobacterium avium, drug-resistance P. aeruginosa, enterotoxigenic E. coli, enterohemorrhagic E. coli, Klebsiella pneumoniae, Clostridium difficile , Heliobacter pylori, Legionella pneumophila, Enterococcus faecalis, Enterobacter cloacae, Salmonella typhimurium, Proteus vulgaris ( Proteus vulgaris, Yersinia enterocolitica, Vibrio cholerae, and Shigella Flexneri, MRSA, MERS-COV, and Ebola virus. , SARS-COV, bacteria, etc. are suspended in the air. Harmful bacteria and floating viruses suspended in the air can cause infection through the air, and waterborne bacteria such as Bacillus and Bacillus anthracis can be transmitted through the air. ), food poisoning bacteria (Bacillus Cereus), Bacillus Coagulans, etc. These viruses build biofilms and become resistant to disinfectants and disinfectants, so the reliability of sterilization cannot be secured.

The quantum energy generator, designed by Tesla, is a device that wraps two cylinders without iron cores, one with a right-hand winding and the other with a left-hand winding, and then supplies power to each coil so that the current flows in the opposite direction, causing the current to flow around the coils. A magnetic field is created, the two magnetic fields overlap and cancel each other out, and the intensity of the magnetic field becomes 0 (zero). As the magnetic field is created in this way, strange energy is discovered, and scientists call this energy a Non-Hertzian Wave. Alternatively, it was referred to as quantum energy or scalar energy.

Mobius called the Tesla Coil coil winding method of winding two coils in a ∞ manner around a cylinder without a core, and while the quantum energy field generated in the existing Tesla Coil has the same frequency as the incoming current, it has been improved. The Mobius Coil allows the generated quantum energy field to be created as a set of harmonic functions combined by amplification, cancellation, interference, etc. at a specific frequency.

Since Tesla, much research has been conducted on the Tesla Coil. The characteristic of the Tesla Coil is that one coil is wound on the right and the other is wound on the left, and then the direction of the current flows in the opposite direction, creating a magnetic field in the opposite direction. The two magnetic fields cancel each other out and the magnetic field becomes zero. It is known. In this way, it was discovered that strange new energy appears as the magnetic field is canceled out. Scientists called this energy *?**?*N-Hertzian Wave*?**?*.

Aharonov (1959) mathematically proved that a magnetic field exists inside the Tesla Coil, but on the outside the magnetic field disappears and disappears, and only quantum energy exists. In addition, Jennison said that the Tesla Coil has a topological singularity and produces high-dimensional energy. It is said to have a capturing quality.

Jennison said that when calculated using a mathematical formula, two orthogonal standing waves are observed. In addition, the interaction of two standing waves varies depending on the winding shape of the coil, and the field trapped in the cavity ) It is said that it varies depending on the distribution of the Tesla Coi. And it is said that the Tesla Coi can operate like an antenna. Also, Chambers (1960) generated quantum energy by sending direct current to the Tesla Coil, but said that quantum energy can also be generated by sending alternating current.

Georges Lakhovsky developed a device for beauty treatment in France in the 1920s. He created it by connecting an antenna to a Tesla Coil and called it a multi-wave oscillator.

According to Seiki (1990), in a Mobius coil, half of the vectors point upward and half point downward, so when considered as an overall system, the sum of the vectors becomes zero (0) (the electromagnetic field is zero).

Seiki said that an imaginary electric field was discovered when the resistance loss of the Möbius coil was calculated mathematically. It is said that this imaginary energy corresponds to the imaginary part of the electrostatic scalar energy and the imaginary part of the magnetic field in Maxwell's electromagnetic equation. The imaginary electromagnetic field is said to be a quantum energy field. Bearden also called imaginary electric fields scalar energy.

According to Johnson (1992), the Mobius coil is an electromagnetic field that causes curvature of local space-time, that is, destroys symmetry, allowing high-dimensional energy to enter the three-dimensional world. As such, the field of studying the topology of electromagnetism is called topological electromagnetic field. It is called electronics.

Various quantum energy generators were created using the principles described above.

The types of quantum energy generators are as follows.

1.Tesla Coil

2. Mobius Coil or Caduceus Coil, a modified Tesla Coil

3. A device that combines the Mobius Coildp frequency generator

4. Device using Plasma Wave: Priore machine

5. A device that combines a frequency generator with a plasma wave

In other words, since quantum energy, superquantum energy, scalar energy, and non-Hertzian wave energy are used similarly, they are used with the same meaning in quantum medicine.

1. In Korean Patent Publication No. 10-2081951 (Synthetic Sterilizing Surface with Nanospike Array), information on the frequency group at which at least one microorganism responds to electromagnetic wave energy effective for microbial targets is stored, and exists in various microbial targets. Or, information about microorganisms, germs, viruses or bacteria that cannot exist is stored, and the information includes biological information about each organ or cell of the target and microorganism, as well as electromagnetic wave information about the frequencies and frequency bands that affect them. A signal oscillator (G) that generates electromagnetic waves in at least one band based on information transmitted from the microbial database 20 and a microbial database 20 stored therein; and transmitted from the microbial database 20 Based on the information provided, the entire operation is controlled, and the microcomputer (C), which controls the operation of the signal oscillator (G) to generate a signal in a specific frequency band as a target, and the signal generated from the signal oscillator (G) An output control device (OC) that adjusts the output intensity of electromagnetic waves, a filter (F) that passes or blocks signals in a specific frequency band, and a power amplifier that amplifies the intensity of the fundamental frequency generated by the signal oscillator (G) ( AMP) and electromagnetic waves It consists of a protection circuit (PC) that detects excessive or abnormal current and automatically blocks the connection, and an antenna unit (ANT) that receives the frequency and emits electromagnetic waves to the target, and shielding that determines the radiation range of electromagnetic waves. This technology, which is a growth control system based on the characteristics of the electromagnetic wave band including the structure, can connect the microbial database 20 to a server that provides various microbial information, and is connected to the microcomputer (C), a frequency band that affects microorganisms, Output, exposure time, or similar information is provided to the electromagnetic wave generation module 10 including a microcomputer (C), a signal oscillator (G), and a power amplifier (AMP). For example, the searched frequency is transmitted to the signal oscillator (G). ), and accordingly, the signal oscillator (G) can generate electromagnetic waves in at least one frequency band, and the electromagnetic waves in the generated frequency band generate electromagnetic waves toward the target through an appropriate transmission means, This technology, which kills cells by destroying specific organs of microorganisms attached to the surface or stopping the operation of the organs of the microorganisms, can sterilize microorganisms with electromagnetic waves, but does not have the function of irradiating quantum energy into space.

2. The technology of Republic of Korea Patent Publication No. 10-1483843 (tinnitus/hearing loss treatment device using electromagnetic pulses) includes a ring coil (11) with a diameter of 4-5 cm, a headband (12), and an earpiece (13) designed to be inserted into the external auditory canal. ) and a power/control unit to supply PEMF pulse voltage to the ring coil. First, insert the earpiece into the external auditory canal and attach the elastic headband with the ring coil to the earlobe. When worn and the PEMF-type pulse voltage generated from the power supply is supplied to the ring coil attached to the headband through a conductor, a magnetic field pulse in the form of a pulse generated at a 90-degree angle to the current flow direction of the ring coil is transmitted to the cochlea. This technology, which treats ear loss and hearing loss by irradiating the inner ear tissue, promotes the metabolism of aged or degenerated auditory tissue cells and aids in the regeneration of nerve cells, does not have the function of sterilizing bacteria or generating quantum energy.

3. The technology of Republic of Korea Patent Publication No. 10-1868856 (Air purifier with built-in quantum energy generator) includes an outdoor supply pipe and an outdoor exhaust pipe connected to the outside of the housing, an indoor supply pipe and an indoor exhaust pipe, and an indoor exhaust pipe connected to the other side of the housing. A high voltage discharge unit installed inside and a vibration removal unit connected to the outdoor air supply pipe to remove fine dust in the incoming external air using an electric dust collection method, and a high voltage discharge unit connected to the vibration removal unit. A high-voltage discharge unit for applying the electronic energy generated in the generator, an air supply channel through which air in which the covalent bonds of nitrogen, oxygen, and hydrogen molecules are dissociated via the high-voltage discharge unit pass, and the indoor air supply pipe circulates through the room. Air is exhausted to the indoor exhaust pipe, passes through the exhaust channel of the total heat exchanger, and is exhausted to the outdoor exhaust pipe, the direction of current flow above and below the air supply channel is opposite, and a pair of Möbius coils embedded in the insulating layer are located above and below. A total heat exchanger arranged so that this structure is repeatedly arranged, a sliding door installed on the outdoor air supply pipe and the outdoor exhaust pipe to open and close the outdoor air supply pipe and the outdoor exhaust pipe by sliding, and a sliding door installed inside the housing and inside the outdoor air supply pipe. It consists of a flap to open and close the ventilation passage connecting the inside of the outdoor exhaust pipe, and sucks in outdoor air, collects and filters it, passes it through a high-pressure discharge space, induces ionization, excitation, oxidation, and reduction reactions, and then applies quantum energy to it. By supplying it indoors, it activates oxygen and hydroxyl ions to remove pollutants in the air and improves the sterilization rate of bacteria and viruses in the floating air. In addition, by irradiating quantum energy into the air supplied indoors, nitrogen oxide and oxidation are removed. This technology increases the purity of nitric oxide and improves its yield by allowing trace amounts of nitrous oxide contained in nitrogen to dissociate and then be reduced and regenerated into nitric oxide. The equipment is complex, the facility costs are high, and the main sterilization method for bacteria and microorganisms is Water molecules of oxygen, nitrogen, and water vapor, which are air components, are sterilized using the electrochemical reactions of dissociation, excitation, ionization, oxidation, and reduction reactions during the high-voltage discharge process, and separate high-voltage discharge means and separate devices for inflow and discharge of air are used. A means of supply and exhaust is required.

In other words, the quantum energy generation devices that irradiate electromagnetic fields and quantum energy in a specific space that have been developed so far are lacking in terms of efficiency and scalability due to the above-mentioned problems, and have a wide application range while ensuring economic stability and durability. Electromagnetic field and quantum energy generation and irradiation technologies are still underdeveloped.

Republic of Korea Patent Publication No. 10-2081951 Republic of Korea Patent Publication No. 10-1483843 Republic of Korea Patent Publication No. 10-1868856

The technical problem to be achieved by the present invention is to implement a quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space, and to irradiate electromagnetic fields and quantum energy to 2, 4, or 6 sides of the room dividing a specific space. The energy generating coil is printed with conductive ink all over the surface of the material or on each side (sides 1, 2, 3, 4, 5, and 6), or a thin conductive metal plate is processed into the shape of a quantum energy generating coil and attached to the surface of the material. Alternatively, the material on which the coated conductive metal wire is wound in the shape of a quantum energy generating coil is commercially available thin white paper such as window paper, sago paper, Yusam paper, Taemi paper, Sannae paper, Wansan paper, Kapyeong paper, and Gyeonyang paper, etc. It is a thick and strong paper such as small wallpaper, large paper, and interior wallpaper, and is made of two or more layers of paper such as gakji, taejangji, yeongchangji, daejangji, rice paper, raised paper, new fuji paper, exterior paper, hejongjungji, The first type is paper such as paper with a slightly thicker thickness, recycled paper such as insect repellent paper, colored paper such as jade paper, red paper, yellow paper, blue paper, dark blue paper, and blue paper, and corrugated paper. Material: PVC, PE, PC, acrylic, reinforced glass foam (FRP), Teflon, urethane, etc. Non-conductive material 2nd material; iron (Fe), copper (Cu), zinc (Zn), tin (Sn) , Aluminum (AL), stainless steel (STS304, STS316), Hastalloy, panels with insulation or cold insulation, etc. Third materials that are metal materials; general plywood, Douglas fir plywood, core plywood, larch plywood, MDF, particle board, etc. Fourth material such as wood plywood; Fifth material which is inorganic material such as concrete, tile, block, brick, board, stone (marble board, etc.); vegetable fiber, vegetable fiber, mineral fiber, recycled fiber, synthetic fiber, inorganic fiber, etc. 6th material; 7th material such as thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, and blocking glass; One material is selected from among the 8 transparent materials such as polyimide, PET (polyethyleneTerephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film. Materials used and

It is a thick and strong paper such as window paper, sago paper, Yusam paper, Taemi Basin paper, Sannae paper, Wansan paper, Kapyeong paper, and Gyeonyang paper, etc., which are thin on the market, small wallpaper paper, large angle paper, interior wallpaper paper, etc., and are made of two or more Hwan paper, which is a recycled paper such as paper with a slightly thicker thickness such as double-stitched paper such as gakji, wreath paper, yeongchang paper, cotton paper, rice paper, raised paper, new fuji paper, exterior paper, hejong paper, and seaweed paper, and insect repellent paper. Flexography and screen printing of conductive ink on the surface of the first material selected from paper materials such as mixed paper, jade paper, red paper, yellow paper, blue paper, dark blue paper, and blue paper, and corrugated cardboard. Select a printing method among offset printing, rotary press, inkjet printing, and dry printing to print solenoid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, and trigger on the paper surface. Coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil shape, Tesla coil, Mobius Coil, The first and second quantum energy forms a quantum energy generating coil by selecting one coil shape among Caduceus Coil, Rogoski coil, and combinations of these shapes, printing and drying. A first method of forming a generating coil; and

Select one material from among non-conductive secondary materials such as PVC, PE, PC, acrylic, bakelite, fiberglass foam (FRP), and Teflon, and apply electricity to one or both surfaces of the selected material. After grinding with a sanding machine and washing with a detergent, apply the previously prepared conductive ink to the surface of the material by selecting one of the printing methods among flexography, screen printing, offset printing, rotary grinder, inkjet printing, and dry printing. Coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil. Among the shapes of coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. A second method of forming first and second quantum energy generation coils by selecting one coil shape, printing and drying to form a quantum energy generation coil; and

Iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (Al), titanium (Ti), nickel (Ni), platinum (Pt), aluminum ( AL), one material is selected among the third materials such as metal materials such as hastalloy, insulation or cold-insulating panels, and one surface of the selected material is ground with an electric sanding machine and cleaned with a cleaning agent, Select one of the pre-manufactured conductive inks from flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to apply solenoid coil, toroid coil, cusp coil, and Helmheltz on the surface. Coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil shape, Tesla. Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, print and dry. A third method of forming the first and second quantum energy generation coils to form the quantum energy generation coil; and

Select one material among the fourth materials such as general plywood, Douglas fir plywood, core plywood, larch plywood, MDF, particle board, etc., and grind and clean one or both surfaces of the selected material with an electric sanding machine. After washing with ash, apply the pre-prepared conductive ink to the surface of the material by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing. Coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF. Coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and a combination of these shapes. A fourth method of forming the first and second quantum energy generation coils by selecting, printing and drying to form a quantum energy generation coil; and

After selecting one material among the fifth materials such as concrete, tile, block, brick, board, stone (marble exterior material, etc.) and other inorganic materials, grind one surface of the selected material with an electric sanding machine and wash it with a detergent. Select one of the pre-manufactured conductive inks from flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to apply soleroid coil, toroid coil, cusp coil, etc. to the surface of the material. Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil shape. , Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and combinations of these shapes for printing and printing. A fifth method of forming the first and second quantum energy generation coils by drying to form a quantum energy generation coil; and

Select one material among the sixth materials such as vegetable fiber, vegetable fiber, mineral fiber, regenerated fiber, synthetic fiber, and inorganic fiber, and apply a conductive solution to the surface of the selected material through flexography, screen printing, offset printing, and web printing. Select one of the live, inkjet, and dry printing methods to print soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag on the surface of the material. Shaped coils (up and down, left and right), extension-shaped coils, motor stator-shaped coils, square coils, RF coils, toroidal coils, Tesla coils, Mobius coils, caduceus coils ( A quantum energy generating coil is created by selecting one coil shape among the Caduceus Coil, Rogoski coil, and combinations of these shapes, printing and drying it, and printing or attaching the quantum energy generating coil to the material. 6th method of forming; and

Select one material among thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, and blocking glass, remove fine dust from the surface of the selected material with a vacuum cleaner, and then use a solvent such as ethyl alcohol or isopropyl alcohol. After removing the surface impurities, apply a conductive solution to one or both surfaces of the material by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to apply a soleroid to the surface of the material. Coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil. Which of the following shapes is a coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, or a combination of these shapes? A seventh method of forming a quantum energy generating coil by selecting one coil shape, printing and drying; and

Select one material among polyimide, PET (polyethyleneTerephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film, and vacuum the selected material surface. After removing the fine dust, the conductive solution is applied to one or both surfaces of the material using inkjet, flexographic, and gravure offset printing methods. The soleroid coil, toroid coil, and cusp coil are input to the control unit (microcomputer) of the printer. , Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil. , Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and a combination of these shapes, one coil shape is selected. Film thickness on the surface of the material; 4-10 μm, line width; 50-80 μm, volume resistivity; 8th method of forming a quantum energy generation coil by printing and drying under 4-10μΩ*cm conditions; and

Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle on the surfaces of the 1st material, 2nd material, 3rd material, 4th material, 5th material, 6th material, 7th material, and 8th material. Coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil. , Select one coil shape among the Mobius Coil, Caduceus Coil, Rogoski coil shapes, and combinations of these shapes, and add iron (Fe) as the selected shape. One material is selected from among materials such as copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), hastaloid, aluminum (Al), titanium (Ti), and platinum (Pt). A 9a method in which a plate processed into the selected coil shape is attached using a selected material using a laser to form a quantum energy generating coil; and

Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle on the surfaces of the 1st material, 2nd material, 3rd material, 4th material, 5th material, 6th material, 7th material, and 8th material. Coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil. , Mobius Coil, (Caduceus Coil), Rogoski coil (Rogoski coil) shapes and combinations of these shapes are selected, and a wire coated with the selected shape is selected. Forming a quantum energy generation coil by winding the quantum energy generation coil or winding it into the selected quantum energy generation coil shape using EL Wire (electroluminescence wire) manufactured using electroluminescence device manufacturing technology. Method 9b; and

Polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), Select one material from PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film, and remove fine dust from the surface of the selected material with a vacuum cleaner. After removal, conductive material is applied to one or both surfaces of the material. Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, and trigger input to the control unit (microcomputer) of the printer using the inkjet, flexographic, and gravure offset printing methods. Coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius coil, car. A film thickness on the surface of the material in a shape selected from among Caduceus coil, Rogoski coil, and combinations of these shapes; 4-10 μm, line width; 50-80 μm, volume resistivity; 4-10μΩ*cm Printed and dried under conditions to form the first and second quantum energy generation coils, manufactured using the 8th method of forming the first and second quantum energy generation coils 9c method of forming a quantum energy generating coil to which a quantum energy generating coil is attached, on the surface of the first material, second material, third material, fourth material, fifth material, sixth material, seventh material, and eighth material. It consists of a transparent substrate (1), a first electrode (2), an electroluminescent layer (3), and a second electrode (4) on a selected material plane. The first electrode (2) is on the transparent substrate (1). It is formed in the form of a stripe in the shape of a quantum energy generating coil, the organic electroluminescent layer (3) is formed on the first electrode (2), and the second electrode (4) is formed on the organic electroluminescent layer (3) to generate quantum energy. It consists of a structure formed in the form of a stripe in the shape of a generating coil. The shape of the quantum energy generating coil formed in the form of a stripe on the first electrode 2 and the second electrode 4 is a soleroid coil, Troroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, Any one of the following shapes: RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. A 9d method in which the shape is selected, the winding direction of the selected quantum energy generation coil is manufactured in a counterclockwise or clockwise direction, and the manufactured quantum energy generation coil is attached, and

Secondary materials that are non-conductive materials such as PVC, PE, PC, acrylic, bakelite, reinforced glass foam (FRP), Teflon, and urethane, iron (Fe), copper (Cu), zinc (Zn), tin (Sn) ), stainless steel (STS304, STS316), aluminum (AL), hastalloy, panels with insulation or cold insulation, third materials such as titanium (Ti) and platinum (Pt), concrete walls, tiles, blocks. , brick, board, etc., inorganic materials (5th material), thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, 7th material such as blocking glass, polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate) ), select one material from the 8th transparent material such as PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film,

It is selected among the second materials, which are non-conductive materials such as PVC and PE, the third materials, which are metallic materials such as iron (Fe) and copper (Cu), and the fifth materials, which are inorganic materials such as concrete walls, tiles, blocks, bricks, and boards. For the material, grind the part where the quantum energy generating coil will be formed using an electric sanding machine and remove dust using a vacuum cleaner, and select one of the 7th materials such as thick plate glass and the 8th materials such as polyimide. The selected material is used to remove foreign substances from the area where the quantum energy generating coil is to be formed using a cleaning solution such as isopropyl alkok, and then print using one of the following printing methods: flexography, screen printing, offset printing, rotary grinder, inkjet printing, and dry printing. Select a soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), and extension-shaped coil on the surface of the material. , Shape coil for motor stator, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil shape. And after selecting any one coil shape among the combinations of these shapes, printing and drying the pre-manufactured conductive ink in the pre-selected quantum energy generating coil shape using a printer.

Metal materials such as iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), hastalloy, titanium (Ti), and platinum (Pt). The third material is made by facing the front and back sides with the printed coil surface facing outwards so that it comes into contact with the liquid, or towards the inside so that it does not come into contact with the liquid, and then connecting the conductors (not shown) connected to each quantum energy generating coil to the outside. (projecting outward from the surface), the edge of the joint surface is welded by selecting one of the ARC welding, TIG welding, and MIG welding methods. For thin plate glass, the printed coil surface is in contact with the liquid. After interviewing the front and back surfaces by facing outward or inward so as not to come into contact with liquid, conductors (not shown) connected to each quantum energy generating coil are drawn outward (projecting outward from the joint surface) and then connected to the edge of the joint surface. Caulk with waterproof sealant,

The fifth material, which is an inorganic material such as concrete walls, tiles, blocks, bricks, boards, and stones (marble exterior materials, etc.), is polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), which have quantum energy emitting coils formed on the surface. Attaching any one of the 8th transparent materials such as PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film, or

Select and attach one material from among the non-conductive secondary materials such as PVC, PE, PC, acrylic, bakelite, and reinforced glass foam (FRP), which have a quantum energy-emitting coil formed on the surface, or attach iron (Fe), Copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), hastalloy, aluminum (Al), nickel (Ni), titanium (Ti), platinum (Pt) The third material, which is a type of metal material such as ), is the 9e method of selecting one shape among the shapes of the quantum energy generating coil and attaching the quantum energy generating coil processed by model picking technology using laser technology to the selected shape. A quantum energy generating coil in which one formation method is selected among; and

First rectifier, transformer, FET switch, second rectifier, PWM (pulse width modlation) control method and pulse frequency modulation PFM (pulse frequency modulation) and pulse frequency (density) control (PDM), pulse A first power supply consisting of a pulse control unit with a built-in repetition rate control (PRR) function, a switching control unit, and a post-regulator to supply the generated power to the quantum energy generation coil; and

Step-down (boost) transformer, rectifier circuit, input module, operation module, and PWM (pulse width modlation) control method and pulse frequency modulation (PFM) and pulse frequency (density) control (PDM), pulse A second power supply consisting of a control unit consisting of a control module with a built-in repetition rate control (PRR) function, a current detection sensor, and a magnetic field detection sensor;

A power transmitter consisting of a power supply unit, output power generation unit, frequency modulation unit, output time control unit, and transmission coil unit, and a power receiver consisting of a receiving coil unit, power generation unit, and feedback signal generation unit, and a converter unit, inverter unit, and resonance reactor. , a third power supply consisting of a high voltage generator consisting of a pulse transformer, a control unit, a gate driver, a first condenser, and a second condenser to supply the generated power to the quantum energy generation coil; and

A fourth power supply consisting of an input unit, a control unit, a switching converter unit, a high voltage generator unit, and a rectifier unit to supply the generated power to the quantum energy generation coil; and

Power supply unit consisting of an alternating current power (AC) supply or direct current power (DC: battery) supply, AC/DC conversion unit, automatic power supply switch (ATS), low frequency generation and output unit, switching element, PWM (pulse width modulation: pulse) Width modlation) control method and pulse frequency modulation PFM (pulse frequency modulation), pulse frequency (density) control (PDM), and pulse repetition rate control (PRR) function are built into the control unit to supply the generated power to the quantum energy generation coil. a fifth power supply; and

Power supply unit, overload detection unit, voltage adjustment unit, frequency modulation unit. Select one type from among the 6th power supplies consisting of the EL driving unit to supply power to the quantum energy generation coil, or use the first power supply, the second power supply, A power supply that supplies power by selecting and installing one of the third power supply, fourth power supply, fifth power supply, sixth power supply, and battery (not shown).

On the first material and the surface of the first material, select one of the following printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to produce soleroid coil, toroid coil, cusp coil, and Helmheltz. Coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil. Select one coil shape among (Tesla coil), Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, and use the selected shape. A quantum energy generation coil produced by a first method of printing and drying conductive ink, and a first power supply, a second power supply, a third power supply, a fourth power supply, and a fifth power supply that supplies power to the quantum energy generation coil. A first quantum energy generator consisting of a power supply selected from a power supply, a sixth power supply, and a battery (not shown),

Solenoid nose, toroid coil, cusp coil, and Helmheltz coil are selected by selecting one of the following printing methods: flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing on the second material and the surface of the second material. , Gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, and use the selected coil shape. A quantum energy generating coil produced by a second method of printing and drying, and a first power supply, a second power supply, a third power supply, a fourth power supply, and a fifth power supply that supplies power to the quantum energy generation coil. A second quantum energy generator consisting of a power supply in which one of the sixth power supply and a battery (not shown) is selected; and

On the third material and the third material surface, select one of the following printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to produce solenoid coil, toroid coil, cusp coil, and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil shape, Tesla coil. A product that prints and dries by selecting one coil shape among (Tesla coil), Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. A quantum energy generation coil manufactured by three methods, a first power supply, a second power supply, a third power supply, a fourth power supply, a fifth power supply, and a sixth power supply that supplies power to the quantum energy generation coil. A third quantum energy generator consisting of a power supply from which one type of battery (not shown) is selected; and

On the surface of the fourth material and the fourth material, select one of the following printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to create solenoid coil, toroid coil, cusp coil, and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Fourth, printing and drying by selecting one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and combinations of these shapes. The first power supply, second power supply, third power supply, fourth power supply, fifth power supply, sixth power supply, and battery that supply power to the quantum energy generation coil and quantum energy generation coil produced by the method. A fourth quantum energy generator consisting of a power supply of which one type (not shown) is selected; and

Solenoid coil, toroid coil, cusp coil, Helmheltz coil, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing on the surface of the fifth material and the fifth material. , Gradient saddle coil, uniform saddle coil, toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Fifth, printing and drying by selecting one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and combinations of these shapes. Quantum energy generation coil manufactured by the method and the first power supply, second power supply, third power supply, fourth power supply), fifth power supply, sixth power supply, which supplies power to the quantum energy generation coil. A fifth quantum energy generator consisting of a power supply from which one type of battery (not shown) is selected; and

On the sixth material and the sixth material surface, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print solenoid coil, toroid coil, cusp coil, and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Part 6, which prints and dries by selecting one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. The first power supply, second power supply, third power supply, fourth power supply, fifth power supply, sixth power supply, and battery that supply power to the quantum energy generation coil and quantum energy generation coil produced by the method. A sixth quantum energy generator consisting of a power supply of which one type (not shown) is selected; and

On the surface of the 7th material and the 7th material, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to produce solenoid coil, toroid coil, cusp coil, and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Chapter 7, which prints and dries by selecting one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. The first power supply, second power supply, third power supply, fourth power supply, fifth power supply, sixth power supply, and battery that supply power to the quantum energy generation coil and quantum energy generation coil produced by the method. A seventh quantum energy generator consisting of a power supply of which one type (not shown) is selected; and

On the surface of the 8th material and the 8th material, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to produce solenoid coil, toroid coil, cusp coil, and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Chapter 8, which prints and dries by selecting one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. The first power supply, second power supply, third power supply, fourth power supply, fifth power supply, sixth power supply, and battery that supply power to the quantum energy generation coil and quantum energy generation coil produced by the method. An eighth quantum energy generator consisting of a power supply of which one type (not shown) is selected; and

Soleroid coil, toroid coil, cusp coil, Helmheltz coil, Gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil (Tesla coil) coil, Mobius Coil, Caduceus Coil, Rogoski coil, and a combination of these shapes, select one coil shape and use the selected shape as iron ( Which of the following materials are Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS 304, STS316), hastaloid, aluminum (Al), titanium (Ti), and nickel (Ni). A quantum energy generating coil manufactured by method 9a in which one material is selected and a plate processed into the selected coil shape is attached using a laser using the selected material, and a first power supply that supplies power to the quantum energy generating coil. , a 9a quantum energy generator consisting of a power supply selected from the second power supply, the third power supply, the fourth power supply, the fifth power supply, and the sixth power supply; and

Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle on the surfaces of the 1st material, 2nd material, 3rd material, 4th material, 5th material, 6th material, 7th material, and 8th material. Coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil. , Select one coil shape among Mobius Coil, Caduceus Coil, Rogoski coil shapes, and combinations of these shapes, and conductive wire coated with the selected shape. The 9b method of winding a quantum energy generating coil using a method of winding a quantum energy generating coil or using an EL wire (electroluminescence wire) manufactured using electroluminescence device manufacturing technology to wind the quantum energy generating coil shape selected above. A first power supply, a second power supply, a third power supply, a fourth power supply, a fifth power supply, a sixth power supply, and a battery (not shown) that supply power to the quantum energy generation coil and the quantum energy generation coil being manufactured. ) 9b quantum energy generator consisting of a power supply of which one type is selected; and

One material is selected among the first material, second material, third material, fourth material, fifth material, sixth material, and seventh material, and polyimide or PET (polyethyleneterephthalate) is applied to the surface of the selected material. , PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film are selected, and a conductive solution is applied to one or both surfaces of the selected material by inkjet, flexographic, or gravure. Using the offset printing method, the soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag coil ( Up and down, left and right), extension type coil, motor stator type coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil , Film thickness on the surface of the material in a shape selected from among Rogoski coil shapes and combinations of these shapes; 4-10 μm, line width; 50-80 μm, volume resistivity; 4-10 μΩ*cm Manufactured using the 9c method in which the quantum energy generation coil is attached, which is produced by a forming method that forms a quantum energy generation coil by printing and drying under the conditions. A first power supply, a second power supply, a third power supply, a fourth power supply, a fifth power supply, a sixth power supply, and a battery (not shown) that supply power to the quantum energy generation coil and the quantum energy generation coil. 9c quantum energy generator consisting of a power supply for which one of the types is selected; and

A transparent substrate, a first electrode, an electroluminescent layer, a transparent substrate, a first electrode, an electroluminescent layer, It is composed of a second electrode. The first electrode is formed in the form of a quantum energy generating coil-shaped stripe on a transparent substrate, an organic electroluminescent layer is formed on the first electrode, and a second electrode is formed on the organic electroluminescent layer. This quantum energy generating coil is made of a structure formed in the form of a stripe, and the shape of the quantum energy generating coil formed in the form of a stripe on the first and second electrodes is a soleroid coil, a toroid coil, Cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, Select one coil shape from the toroidal coil, Tesla coil, Mobius coil, Caduceus coil, Rogoski coil, and combinations of these shapes. The winding direction of the selected quantum energy generation coil is counterclockwise or clockwise, and the quantum energy generation coil is manufactured by the 9d method of forming the quantum energy generation coil by attaching the manufactured quantum energy generation coil. A first power supply, a second power supply, a third power supply, a fourth power supply, a fifth power supply, a sixth power supply, and a battery (not shown) that supply power to the quantum energy generation coil and the quantum energy generation coil. The 9d quantum energy generator consisting of a power supply of which one type is selected, and

Any one of the first material, second material, third material, fourth material, fifth material, sixth material, seventh material, and eighth material is selected, flexography and screen printing on the surface of the selected material. .Select a printing method among offset printing, rotary press, inkjet printing, and dry printing to print cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag coil (top and bottom). , left and right), extension type coil, motor stator type coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Among Rogoski coil shapes and combinations of these shapes, one coil shape is selected, and pre-prepared conductive ink is printed and dried in the selected quantum energy generation coil shape using a printer to create a quantum energy generation coil. (First and second quantum energy generation coils) are formed, the first space is divided using the number of materials formed from the quantum energy generation coils, and the space is spaced a certain distance away from the first space to create a space with a reduced volume. The method of creating the space is to interview two materials on the side where the quantum energy generating coil is not formed, and then seal the edge of the interviewed edge by welding it using any type of welder among the ARC welder, TIG welder, MIG welder, and PVC welder. After forming the material using a material formed with a quantum energy generating coil or bonding it with an adhesive or sillint, the first device supplies power to each quantum energy generating coil formed on the surface of the material dividing the first space and the second space. The 9e quantum energy generator consisting of a power supply selected from the group consisting of a power supply, a second power supply, a third power supply, a fourth power supply, a fifth power supply, a sixth power supply, and a battery (not shown). A first quantum energy generator consisting of; and

A sealed glass tube, a thermionic emission cathode with a filament installed on the left side of the glass tube, a power supply that supplies direct current power to the cathode, and a first material made of copper (CU) or tungsten (W) installed at a certain distance from the cathode. An anode, a high voltage power supply that applies a high voltage to the first anode, a second anode made of rhodium or other material is installed in an opening with a certain area on the lower side of the sealed glass tube, and a direct current high voltage power supply is applied to the second anode. A power supply that supplies a quantum energy emission layer of a non-radiative material such as beryllium is installed on the externally exposed surface of the second anode, and power is supplied to the cathode through a power supply, and the first anode is provided. Connect the conductor connected to the first anode to the + terminal on the output side of the power supply, and connect the conductor connected to the output side - terminal of the negative power supply to the - terminal on the output side to create a bias between the negative power supply and the first anode power supply. A 2-1 quantum energy generator of the first bremsstrahlung type constituting the circuit and

A sealed glass tube, a cathode installed inside the glass tube on the right side, an electron emission source is installed in contact with the cathode, a gate electrode is installed in a shape that embraces the cathode and is spaced a certain distance to the left from the cathode, and is opposite to the gate electrode. A first anode is installed at the center of the left side inside the sealed glass tube, an X-ray target plate is installed at the center of the right inclined surface of the first anode, and an 2 An anode is installed, and a quantum energy emission layer of non-radiative material is installed on the second anode surface. In addition, a first power supply is installed at a certain distance from the left side of the sealed glass tube to apply a high voltage to the cathode and the first anode through a conductor, and a second power supply supplies power to the gate electrode at a downward interval. is installed, the output side terminals of the first power supply and the second power air are common wired to form a bias circuit between the first power supply and the second power air, and a second power supply is spaced downward from the second power supply. A third power supply that applies a high voltage to the anode is installed, and a second braking device that forms a bias circuit with the second power supply and the third power supply by wiring the output terminals of the second power supply and the third power supply in common. Manufacture a second quantum energy generator consisting of a 2-2 quantum energy generator in the form of radiation, and install the first and second quantum energy generator coils of the first and second quantum energy generators within a specific space. Print in the shape of a quantum energy generating coil selected on the surface of a material on 2 (left, right, front, back, top, bottom), 4, or 6 sides facing each other at a distance, or on the surface of the material, or both. A quantum energy generating coil made of a conductive metal material processed into the shape of an energy generating coil is attached, or adhesive is applied to the surface of the material and then wound into the shape of a quantum energy generating coil with a coated conductive metal wire to form a quantum energy generating coil. A first power supply installed so that the winding directions of the quantum energy generation coils formed on opposing surfaces are opposite to each other, and installed on one side of the material surface, installed at a certain distance apart, or installed on one external side (not shown), One type is selected from the second power supply, the third power supply, the fourth power supply, the fifth power supply, the sixth power supply, and the battery (not shown), and the power in the form of a pulse generated from the selected power supply or When direct current power output from the battery is supplied to the first and second quantum energy generation coils through a conductor (not shown), current flows in the first and second quantum energy generation coils installed so that the winding directions of the coils are opposite to each other. Pulse-type electromagnetic fields generated at a 90-degree angle are generated in opposite directions, and the electromagnetic fields in opposite directions overlap and disappear at the center distance between the first and second quantum energy generation coils, and pulsating quantum energy is generated in a zero magnetic field state. It is generated and irradiated to the indoor space to remove electromagnetic waves generated from home appliances or industrial machines installed indoors, sterilizes bacteria floating in the space, and improves health by irradiating quantum energy to occupants.

In order to achieve this purpose, a quantum energy generator that irradiates electromagnetic fields and quantum energy to the materials on which the quantum energy generation coil according to the present invention is printed, attached, or wound on the surface and to a specific space defined by these materials,

It is a thick and strong paper such as window paper, sago paper, Yusam paper, Taemi Basin paper, Sannae paper, Wansan paper, Kapyeong paper, and Gyeonyang paper, etc., which are thin on the market, small wallpaper paper, large angle paper, interior wallpaper paper, etc., and are made of two or more Hwan paper, which is a recycled paper such as paper with a slightly thicker thickness such as double-stitched paper such as gakji, wreath paper, yeongchang paper, cotton paper, rice paper, raised paper, new fuji paper, exterior paper, hejong paper, and seaweed paper, and insect repellent paper. The first material 110, which is paper such as colored paper such as mixed paper, jade paper, red paper, yellow paper, blue paper, dark blue paper, and blue paper, and corrugated paper; and

The second material (120) is a non-conductive material such as PVC, PE, PC, acrylic, bakelite, reinforced glass foam (FRP), Teflon, and urethane;

Iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS 304, STS316), hastalloy, panel with insulation or cold insulator, aluminum (Al), titanium (Ti) , the third material 130, which is a metal material such as nickel (Ni) and platinum (Pt);

4th material (140) such as wood plywood such as general plywood, Douglas fir plywood, core plywood, larch plywood, MDF, particle board, etc.;

Fifth material (150), which is an inorganic material such as concrete, tile, block, brick, board, stone (marble exterior material, etc.);

6th material (160) such as vegetable fiber, mineral fiber, recycled fiber, synthetic fiber, and inorganic fiber; and

7th material (170) such as thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, and blocking glass;

Any one of the 8th transparent materials (180) such as polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film. Materials selected and used (100); and

It is a thick and strong paper such as commercially available thin white paper such as window paper, sago paper, Yusam paper, Taemi Basin paper, Sannae paper, Wansan paper, Kapyeong paper, and Gyeonyang paper, small wallpaper paper, large angle paper, interior wallpaper paper, etc., made of two or more Hwan, a recycled paper such as double-stitched paper such as gakji, wreath paper, yeongchang paper, cotton paper, rice paper, raised paper, new fuji paper, exterior paper, hejong paper, and seaweed paper, etc., and insect repellent paper. Flexography, screen printing, and offset printing of conductive ink on the surface of a first material selected from color paper such as mixed paper, jade paper, red paper, yellow paper, blue paper, dark blue paper, and blue paper, and corrugated cardboard. , Select any one of the rotary press, inkjet printing, and dry printing methods to print solenoid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, and trigger on the surface of the first material. Coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius coil. Among the Caduceus Coil, Rogoski coil shapes, and combinations of these shapes, one coil shape is selected, printed, and dried to create a quantum energy generation coil (first and second quantum energy generation coils). A first method of forming 210; and

Select one material from secondary non-conductive materials such as PVC, PE, PC, acrylic, bakelite, fiberglass foam (FRP), Teflon, and urethane, and apply one or both surfaces of the selected material. After grinding with an electric sanding machine and washing with a detergent, the pre-manufactured conductive ink is used as a second material by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing. On the surface, soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator type. Coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and combinations of these shapes. A second method (220) of forming a quantum energy generation coil (first and second quantum energy generation coils) by selecting one coil shape from among the shapes, printing and drying; and

Iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), hastalloy, panel with insulation or cold insulator attached, aluminum (Al), After selecting one material from among the third materials such as titanium (Ti), nickel (Ni), and platinum (Pt), one surface of the selected material is ground with an electric sanding machine and cleaned with a cleaning agent, Using pre-manufactured conductive ink, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to apply solenoid coil, toroid coil, cusp coil, and Helmheltz on the surface. Coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil. Select one coil shape among (Tesla coil), Mobius Coil, Caduceus coil, (Caduceus Coil), Rogoski coil, and a combination of these shapes, print and dry it, A third method 230 of forming a quantum energy generation coil (first and second quantum energy generation coils); and

Select one material among the fourth materials such as general plywood, Douglas fir plywood, core plywood, larch plywood, MDF, particle board, etc., and grind and clean one or both surfaces of the selected material with an electric sanding machine. After washing with ash, apply the pre-prepared conductive ink to the surface of the material by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing. Coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF. Any one of the coil shapes, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. A fourth method (240) of selecting, printing and drying to form quantum energy generation coils (first and second quantum energy generation coils); and

Select one material among the fifth materials such as concrete walls or structures, tiles, blocks, bricks, boards, stones (marble exterior materials, etc.) and other inorganic materials, and grind one surface of the selected material with an electric sanding machine and wash it with a cleaner. After washing, apply a varnish and dry it, or apply pre-prepared conductive ink to the primer-coated surface using any of the following methods: flexography, screen printing, offset printing, rotary press, inkjet printing, or dry printing. Select one printing method and print soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), and extension coil on the surface of the material. Shaped coil, shaped coil for motor stator, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, (Caduceus Coil), Rogoski coil A fifth method (250) of forming quantum energy generation coils (first and second quantum energy generation coils) by selecting one coil shape from among the shapes and combinations of these shapes, printing and drying; and

Select one material among the sixth materials such as vegetable fiber, vegetable fiber, mineral fiber, regenerated fiber, synthetic fiber, and inorganic fiber, and apply a conductive solution to the surface of the selected material through flexography, screen printing, offset printing, and web printing. Select one of the live, inkjet, and dry printing methods to print soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag on the surface of the material. Shaped coils (up and down, left and right), extension-shaped coils, motor stator-shaped coils, square coils, RF coils, toroidal coils, Tesla coils, Mobius coils, caduceus coils. (Caduceus Coil), Rogoski coil (Rogoski coil) A quantum energy generating coil is created by selecting one coil shape among the shapes and combinations of these shapes and printing and drying the quantum energy generating coil on the material. Sixth method 260 of forming (first and second quantum energy generation coils); and

Select one material among thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, and blocking glass, remove fine dust from the surface of the selected material with a vacuum cleaner, and then use a solvent such as ethyl alcohol or isopropyl alcohol to clean the surface. After removing the impurities, apply conductive ink to one or both surfaces of the material and apply a soleroid coil to the surface of the material by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing. , toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil. , RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, or any one of these shapes combined. A seventh method (270) of forming quantum energy generation coils (first and second quantum energy generation coils) by selecting a coil shape, printing and drying, and

Select one material among polyimide, PET (polyethyleneTerephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film, and vacuum the selected material surface. After removing the fine dust, the conductive solution is applied to one or both surfaces of the material using inkjet, flexographic, and gravure offset printing methods. The soleroid coil, toroid coil, and cusp coil are input to the control unit (microcomputer) of the printer. , Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil. , Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and a combination of these shapes, one coil shape is selected. Film thickness on the surface of the material; 8th method (280) of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying under the following conditions: 4-10 μm, line width; 50-80 μm, volume resistivity; 4-10μΩ*cm ;class

Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle on the surfaces of the 1st material, 2nd material, 3rd material, 4th material, 5th material, 6th material, 7th material, and 8th material. Coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil shape, Tesla coil. ), Mobius Coil, Caduceus Coil, Rogoski coil, and a combination of these shapes, select one coil shape, and use iron (Fe) as the selected shape. ), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), hastaloid material, titanium (Ti), nickel (Ni), platinum (Pt). A 9a method (290a) in which a plate processed from a selected material into the selected coil shape is attached using a laser to form a quantum energy generating coil (first and second quantum energy generating coils); and

After applying adhesive to the surfaces of the 1st material, 2nd material, 3rd material, 4th material, 5th material, 6th material, 7th material, and 8th material, soleroid coil, toroid coil, cusp coil, and helm Hellz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla. Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, and select the selected shape. A method of winding a quantum energy generating coil with a wire covered with a wire or a method of winding the selected quantum energy generating coil shape using an EL wire (electroluminescence wire) manufactured using electroluminescence device manufacturing technology. 9b method (290b) of forming quantum energy generation coils (first and second quantum energy generation coils); and

One material is selected among the first material, second material, third material, fourth material, fifth material, sixth material, and seventh material, and polyimide or PET (polyethyleneterephthalate) is applied to the surface of the selected material. Select one material among PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film, remove fine dust from the surface of the selected material with a vacuum cleaner, and then remove the material. Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, and uniform input to the control unit (microcomputer) of the printer using inkjet, flexographic, and gravure offset printing methods with a conductive solution on one or both surfaces. Saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, l(Tesla coil), Mobius coil. (Mobius Coil), Caduceus Coil (Caduceus Coil), Rogoski coil (Rogoski coil) shape, and a shape selected from a combination of these shapes, the film thickness on the surface of the material in a shape selected from one of the coil shapes; 4-10 μm, line width; 50-80 μm, volume resistivity; 4-10 μΩ*cm Method of attaching the quantum energy generation coil produced by the 8th method (280) of forming a quantum energy generation coil by printing and drying under conditions. 9c method (290c) of forming quantum energy generation coils (first and second quantum energy generation coils); and

A transparent substrate (1), a first electrode ( 2), It is composed of an electroluminescent layer (3) and a second electrode (4). The first electrode (2) is formed in the form of a stripe in the shape of a quantum energy generating coil on the transparent substrate (1), and the first electrode (2) is formed in the form of a stripe in the shape of a quantum energy generating coil. An organic electroluminescent layer (3) is formed on the electrode (2), and the second electrode (4) is formed on the organic electroluminescent layer (3) in the form of a stripe in the shape of a quantum energy generating coil, The shape of the quantum energy generating coil formed in a stripe shape on the first electrode (2) and the second electrode (4) is a soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, and uniform saddle. Coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil shape, (Tesla coil), Möbius coil ( One coil shape is selected among Mobius Coil, Caduceus Coil, Rogoski coil, and a combination of these shapes, and the winding direction of the selected quantum energy generating coil is counterclockwise or A quantum energy generation coil is manufactured in a clockwise direction, and the manufactured quantum energy generation coil performs the functions of the first electrode (2) and the second electrode (4), thereby producing a quantum energy generation coil (first and second quantum energy generation). 9d method (290d) of forming a coil); and

Secondary materials (120), which are non-conductive materials such as PVC, PE, PC, acrylic, bakelite, reinforced glass foam (FRP), Teflon, and urethane, iron (Fe), copper (Cu), zinc (Zn), Tin (Sn), stainless steel (STS304, STS316), aluminum (AL), hastalloy, panels with insulation or cold insulation, aluminum (Al), titanium (Ti), nickel (Ni), platinum (Pt), etc. The third material (130) is a metal material, the fifth material (150) is an inorganic material such as concrete walls, tiles, blocks, bricks, boards, and stones (marble exterior materials, etc.), thin plate glass, thick plate glass, transparent polished plate glass, and solar shielding. 7th material (170) such as glass and barrier glass, polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, PVC film, etc. Select one material from the transparent 8th material (180),

The second material (120) is a non-conductive material such as PVC and PE, and the third material is a metal material (130) such as iron (Fe), copper (Cu), aluminum (Al), titanium (Ti), and nickel (Ni). ), Concrete walls, tiles, blocks, bricks, boards, etc. The selected materials among the 5th materials (150) are inorganic materials. Grind the part where the quantum energy generating coil will be formed using an electric sanding machine and remove dust using a vacuum cleaner. After removing the material selected from the seventh material 170 such as thick plate glass and the eighth material 180 such as polyimide, a quantum energy generating coil can be formed using a cleaning solution such as isopropyl alkoxy. After removing foreign substances from the area, select one of the printing methods among flexography, screen printing, offset printing, rotary grinder, inkjet printing, and dry printing and apply soleroid coil, toroid coil, cusp coil, and helm to the surface of the material. Hellz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, ( Select one coil shape from Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes and manufacture it in advance. After printing and drying the conductive ink into a pre-selected quantum energy generating coil shape using a printer,

Metal materials such as iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (Al), titanium (Ti), nickel (Ni), hastalloy, etc. The third material 130 is made by interviewing the front and back surfaces with the printed coil surface facing outward so that it contacts the liquid or facing inward so that it does not come into contact with the liquid, and then connecting a conductor (not shown) connected to each quantum energy generating coil. After drawing out the outside (projecting outward from the joint surface), the edge of the joint surface is welded by selecting one of the ARC welding, TIG welding, and MIG welding methods. For thin plate glass, the edge of the joint surface is welded.

After interviewing the front and back surfaces with the printed coil surface facing outward so that it comes into contact with liquid (including water) or facing inward so as not to come into contact with liquid, the conductors (not shown) connected to each quantum energy generating coil are joined to the outside (joined). After protruding from the surface to the outside, caulk the edges of the joint surface with waterproof sealant.

The fifth material (150) is an inorganic material such as concrete walls, tiles, blocks, bricks, and boards.

8th transparent materials such as polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film with quantum energy-emitting coils formed on the surface. Attaching any one material among the materials 180,

Select and attach one material among the second materials (120), which are non-conductive materials such as PVC, PE, PC, acrylic, bakelite, reinforced glass foam (FRP), Teflon, and urethane, on which a quantum energy-emitting coil is formed on the surface. or iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (Al), titanium (Ti), nickel (Ni), hastalloy, etc. The third material 130, which is a metal material, selects one shape among the shapes of the quantum energy generation coil, and the 9e method of attaching the quantum energy generation coil processed by model picking technology using laser technology to the selected shape. (200) Quantum energy generation coil forming method (200), in which one forming method is selected depending on the type of material among (290e);

First rectifier 311, transformer 312, FET switch 313, second rectifier 314, PWM (pulse width modulation) control method and pulse frequency modulation PFM (pulse frequency modlation) and a pulse control unit 315 with built-in pulse frequency (density) control (PDM) and pulse repetition rate control (PRR) functions, a magnetic field detection sensor 315a, a switching control unit 316, and a post-regulator 317. A first power supply 310 that supplies power to the quantum energy generation coil through a conductor (not shown); and

A step-down (boost) transformer (321), a rectifier circuit (322), an input module (323a), an operation module (323b), and a PWM (pulse width modulation) control method and pulse frequency modulation (PFM). and a control unit 323 consisting of a control module 323c with built-in pulse frequency (density) control (PDM) and pulse repetition rate control (PRR) functions, a current detection sensor 324, and a magnetic field detection sensor 325. A second power supply 320 that supplies the generated power to the quantum energy generation coil through a conductor (not shown); and

A power transmitter 330 consisting of a power supply unit 331, an output power generation unit 332, a frequency modulation unit 333, an output time control unit 334, and a transmission coil unit 335;

A power receiver (330a) consisting of a receiving coil unit (331a), a power generating unit (332a), and a feedback signal generating unit (333a); and

Converter unit (331b), inverter unit (332b), resonance reactor (333b), pulse transformer (334b), control unit (335b), gate driver (336b), magnetic field detection sensor (336b-1), first condenser (337b) ), and a third power supply 330 consisting of a high voltage generator 330b composed of a second condenser 338b and supplying the generated power to the quantum energy generation coil;

Input unit 341, control unit 342, magnetic field detection sensor 342a, switching converter unit 343, high voltage generator 344, and rectifier unit 345.

Consisting of a fourth power supply (340); and

Power supply unit 351 consisting of an alternating current power (AC) supply (351a) or a direct current power (DC: battery) supply (351b), AC/DC conversion unit (352), automatic power supply switcher (353) (ATS), low frequency Generation and output unit 354, switching element 355, surface temperature of quantum energy generation coil, PWM (pulse width modlation) control method and pulse frequency modulation PFM (pulse frequency modlation) and pulse frequency (density) A fifth power supply consisting of a control unit 356 with built-in control (PDM) and pulse repetition rate control (PRR) functions, and a magnetic field detection sensor 356a to supply the generated power to the quantum energy generation coil through a conductor (not shown). Feeder (350); and

Power supply unit 361, overload detection unit 362, which detects overcurrent exceeding the standard value in the EL driving unit and quantum energy generation coil, voltage adjustment unit 363, frequency modulation unit 364, magnetic field detection sensor 364a, EL driving unit Select one type from the sixth power supply 360 consisting of (365) to supply power to the quantum energy generation coil, or use the first power supply 310 to each of the first quantum energy generation coil and the second quantum energy generation coil. ), second power supply 320, third power supply 330, fourth power supply 340, fifth power supply 350, sixth power supply 360, battery (not shown). A power supply 300 that is selected and installed to supply power, and

The first material 110 and conductive ink are applied on the surface of the first material 110 by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print the solenoid coil and toroid. Coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF Select one coil shape among coil, toroidal coil shape, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil shape, and a combination of these shapes. A first power supply (310), a second power supply (320), and a third power supply ( 330), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), and the first quantum energy consisting of a power supply (300) in which one type of battery (not shown) is selected. Generating device 371; and

Apply conductive ink on the surface of the second material 120 and the second material 120 by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print the solenoid coil and toroid. Coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF Select one coil shape among coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. A first power supply (310), a second power supply (320), and a third power supply ( 330), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), and the second quantum energy consisting of a power supply (300) in which one type of battery (not shown) is selected. Generating device 372; and

Conductive ink is applied to the third material 130 and the surface of the third material 130 by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print the solenoid coil and toroid. Coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF Select one coil shape among coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. A first power supply (310), a second power supply (320), and a third power supply (310) that supply power to the quantum energy generation coil and the quantum energy generation coil produced by the third method (230) of printing and drying 330), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), and the third quantum energy consisting of a power supply (300) in which one type of battery (not shown) is selected. Generating device 373; and

The fourth material 140 and conductive ink are applied on the surface of the fourth material 140 by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print the cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, A product that prints and dries by selecting one coil shape among (Tesla coil), Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. The first power supply (310), the second power supply (320), the third power supply (330), and the fourth power supply that supply power to the quantum energy generation coil and the quantum energy generation coil manufactured by the four methods (240). A fourth quantum energy generator 374 consisting of a power supply 300 selected from the group consisting of a power supply 340, a fifth power supply 350, a sixth power supply 360, and a battery (not shown); and

Conductive ink is applied on the surfaces of the fifth material (150) and the first material (150) by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print the solenoid coil and toroid. Coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF Select one coil shape among coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil shapes, and combinations of these shapes. A quantum energy generating coil manufactured by the fifth method of printing and drying (250) and a first power supply (310), a second power supply (320), and a third power supply ( 330), the 4th power supply 340, the 5th power supply 350, the 6th power supply 360, and the 5th quantum energy consisting of a power supply 300 in which one type of battery (not shown) is selected. Generating device 375; and

Apply conductive ink on the surface of the sixth material (160) and the sixth material (160) by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print the solenoid coil and toroid. Coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF Select one coil shape among coil, toroidal coil, (Tesla coil), Mobius Coil, (Caduceus Coil), Rogoski coil shapes, and combinations of these shapes. A quantum energy generating coil manufactured by the sixth method of printing and drying (260) and a first power supply (310), a second power supply (320), and a third power supply ( 330), the 4th power supply 340, the 5th power supply 350, the 6th power supply 360, and the 6th quantum energy consisting of a power supply 300 in which one type of battery (not shown) is selected. Generating device 376; and

Conductive ink is applied on the surface of the 7th material 170 and the 7th material 170 by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print the solenoid coil and toroid. Coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF Select one coil shape among coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil shapes, and combinations of these shapes. A first power supply (310), a second power supply (320), and a third power supply (310) that supply power to the quantum energy generation coil and the quantum energy generation coil manufactured by the seventh method (270) of printing and drying 330), the 4th power supply 340, the 5th power supply 350, the 6th power supply 360, and the 7th quantum energy consisting of a power supply 300 in which one type of battery (not shown) is selected. Generator (377); and

Apply conductive ink on the surface of the 8th material (180) and the 8th material (180) by selecting one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print the solenoid coil and toroid. Coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF Select one coil shape among coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil shapes, and combinations of these shapes. A first power supply (310), a second power supply (320), and a third power supply ( 330), the 4th power supply 340, the 5th power supply 350, the 6th power supply 360, and the 8th quantum energy consisting of a power supply 300 in which one type of battery (not shown) is selected. Generating device 378; and

1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), 8 Materials (180) Adhesive on the surface: soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension form. Coil, shape coil for motor stator, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil ) Select one coil shape among shapes and combinations of these shapes, and the selected shape is iron (Fe), copper (Cu), zinc (Zn), tin (Sn), and stainless steel (STS 304, STS316). Quantum manufactured by method 9a (290a), in which one material is selected from aluminum (AL) and hastaloid materials, and a plate processed into the coil shape selected from among the coils is attached to the selected material using a laser. The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), and the fifth power supply (340) supply power to the energy generation coil and the quantum energy generation coil. 350), a 6th power supply 360, and a 9th quantum energy generator 379a consisting of a power supply 300 selected from a battery (not shown); and

Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle on the surfaces of the 1st material, 2nd material, 3rd material, 4th material, 5th material, 6th material, 7th material, and 8th material. Coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil shape, Tesla coil. ), Mobius Coil, Caduceus Coil, Rogoski coil, and a combination of these shapes, select one coil shape, and conductivity coated with the selected shape. A method of winding a quantum energy generating coil with a wire or a method of winding a quantum energy generating coil shape selected from the above coil shapes using an EL wire (electroluminescence wire) manufactured using electroluminescence device manufacturing technology. The first power supply 310, the second power supply 320, the third power supply 330, and the fourth power supply that supply power to the quantum energy generation coil and the quantum energy generation coil manufactured in method 9b (290b) of A 9b quantum energy generator (379b) consisting of a power supply (300) selected from the group consisting of a power supply (340), a fifth power supply (350), a sixth power supply (360), and a battery (not shown); and

One material is selected among the first material, second material, third material, fourth material, fifth material, sixth material, and seventh material, and polyimide or PET (polyethyleneterephthalate) is applied to the surface of the selected material. , PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film are selected, and a conductive solution is applied to one or both surfaces of the selected material by inkjet, flexographic, or gravure. Using the offset printing method, the soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag coil ( Up and down, left and right), extension type coil, motor stator type coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil , Film thickness on the surface of the material in a shape selected from among Rogoski coil shapes and combinations of these shapes; 4-10 μm, line width; 50-80 μm, volume resistivity; 4-10 μΩ*cm Article 9c, where the quantum energy generation coil manufactured by the forming method (280) of forming the quantum energy generation coil by printing and drying under the conditions is attached A first power supply (310), a second power supply (320), a third power supply (330), and a fourth power supply ( 340), the 9th quantum energy generator (379c) consisting of a power supply (300) selected from the fifth power supply (350), the sixth power supply (360), and a battery (not shown);

A transparent substrate (1), a first electrode ( 2), It is composed of an electroluminescent layer (3) and a second electrode (4). The first electrode (2) is formed in the form of a stripe in the shape of a quantum energy generating coil on the transparent substrate (1), and the first electrode (2) is formed in the form of a stripe in the shape of a quantum energy generating coil. An organic electroluminescent layer (3) is formed on the electrode (2), and the second electrode (4) is formed on the organic electroluminescent layer (3) in the form of a stripe in the shape of a quantum energy generating coil, The shape of the quantum energy generating coil formed in a stripe shape on the first electrode (2) and the second electrode (4) is a soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, and uniform saddle. Coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil, Möbius coil. One coil shape is selected among the shapes of (Mobius Coil), Caduceus Coil, Rogoski coil, and combinations of these shapes, and the first electrode (2) is formed in the selected shape. The second electrode 4 is manufactured, the winding direction of the manufactured first electrode 2 and the second electrode 4 is counterclockwise or clockwise, and the manufactured quantum energy generating coil is attached to the surface of the selected material. 9d method (290d) of forming a quantum energy generating coil in a manner that is

1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), One of the eight materials (180) is selected, and one printing method among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing is selected on the surface of the selected material to create a cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Select one coil shape among the Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil shapes, and combinations of these shapes, and select them in advance. Quantum energy generation coils (first and second quantum energy generation coils) are formed by printing and drying the prepared conductive ink into the selected quantum energy generation coil shape using a printer, and using a plurality of materials formed as quantum energy generation coils. The first space is divided and separated from the first space by a certain distance to create a space with a reduced volume. The method of creating the space is to interview the two materials on the side where the quantum energy generating coil is not formed, and then interview the edge of the interview. After sealing the border by welding it using any type of welder, such as an ARC welder, TIG welder, MIG welder, or PVC welder, or using a material formed with a quantum energy generating coil joined with an adhesive or sillint, the first space is created. , The first power supply (310), the second power supply (320), the third power supply (330), and the fourth power supply that supply power to each quantum energy generating coil formed on the surface of the material dividing the second space. (340), the 5th power supply (350), the 6th power supply (360), and the 9th quantum energy generator (379e), which consists of a power supply (300) in which one type of battery (not shown) is selected. A first quantum energy generator (300A) consisting of; and

A sealed glass tube 401, a thermionic emission cathode 404 having a filament installed on the left side of the glass tube, a power supply 402 that supplies direct current power to the cathode 404, and a predetermined distance away from the cathode 404. A first anode 413 made of copper (CU) or tungsten (W) is installed, a high voltage power supply 311 that applies high voltage to the first anode 413, and a certain area on one side of the lower part of the sealed glass tube 301. A second anode 423 made of a material such as rhodium is installed in the opened opening, a power supply 421 that supplies direct current high voltage power to the second anode 423, and a power supply of the second anode 423. A quantum energy emission layer 424 made of a material such as beryllium is installed on the externally exposed surface, and power is supplied to the cathode 404 through a power supply 402, and a power supply 411 for the first anode. The conductor 412 connected to the first anode 413 is connected to the + terminal on the output side, and the conductor 412 connected to the output side - terminal of the power supply 402 for the negative electrode 404 is connected to the output side - terminal to connect the negative electrode. A 2-1 quantum energy generator (400A) of a first braking radiation type constituting a bias circuit between the power supply for power supply 411 and the first anode power supply 411; and

A sealed glass tube 437, a cathode 433 installed inside the glass tube on the right side, an electron emission source 434 is installed in contact with the cathode 433, and the cathode 433 is spaced a certain distance to the left from the cathode 433. ) A gate electrode 443 is installed in a shape that embraces the gate electrode 443, and a first anode 435 is installed at the center of the inner side of the sealing glass tube 437 opposite to the gate electrode 443, and the first anode 435 A second anode ( 453) is installed, and a quantum energy dissipation layer 454 is installed on the surface of the second anode 453, and a cathode 433 and a first anode 435 are spaced a certain distance apart from the left side of the sealed glass tube. A first power supply 431 is installed to apply a high voltage through a conductor wire, and a second power supply 441 is installed to supply power to the gate electrode 443 at intervals in the downward direction. The first power supply A bias circuit is formed between the first power supply 431 and the second power air 441 by wiring the output terminals of the supply 431 and the second power air 441 in common. The second power supply 441 A third power supply 451 is installed to apply a high voltage to the second anode 453 at intervals in the downward direction, and the output side - terminal of the second power supply 441 and the third power supply 451 is common. A second quantum energy generator (430) of a second braking radiation type that is wired to form a bias circuit between the second power supply (441) and the third power supply (451). 400B).

The quantum energy generator according to the present invention irradiates electromagnetic fields and quantum energy to the materials on which the quantum energy generation coil is printed or attached to the surface and to a specific space divided by these materials. The quantum energy generation coil conducts quantum energy generation coils of various shapes on the surfaces of various materials. It is inexpensive and easy to form using the ink printing method.

In addition, various types of quantum energy generation coils are formed by printing conductive ink on various material surfaces of 2, 4, and 6 sides inside or outside the large space, small space, and microspace, and can be used in batteries, direct current, etc. Among various power supplies such as wireless power supplies, pulse-type power supplies, etc., which are composed of a power supply, a transmitter, a receiver, and a high-voltage power supply, a power supply suitable for space use is selected and installed on one side of the surface of the material or installed outside (not shown) to provide various power supplies. Quantum energy generation devices can be manufactured and installed, and quantum energy can be radiated into space without restrictions on the size of the space.

In addition, it is formed by printing with conductive ink on the surface of the material such as the 2nd, 4th, and 6th sides or each side (1, 2, 3, 4, 5, and 6 sides) inside the partitioned space, or generates various quantum energies. A magnetic field detection sensor installed in space on a quantum energy generation coil formed by attaching a metal quantum energy generation coil processed into a coil shape to the surface of a material or winding it into various quantum energy generation coil shapes using conductive coated wires on the surface of various materials. When the electromagnetic waves in the space are measured and transmitted to a real-time power supply, the power supply supplies power that can cancel out the electromagnetic waves generated by electric devices installed inside the space to the quantum energy generation coil, eliminating the electromagnetic waves in the room. can

In addition, high-frequency pulse-type power generated from a power supply is supplied to the quantum energy generation coils installed on the material surfaces of 2, 4, and 6 sides or on each side of the partitioned interior of the space, thereby generating high frequency waves from the quantum energy generation coils. By irradiating a pulse-shaped electromagnetic field into space and overlapping and extinguishing the pulse-shaped electromagnetic field, quantum energy generated in a zero magnetic field state is irradiated into space to sterilize harmful bacteria and viruses in the floating air in a specific space.

In addition, the quantum energy generated by the power supply is generated on the material surface of the 2nd, 4th, and 6th sides inside the space, or on the quantum energy generation coil installed on each side (1, 2, 3, 4, 5, and 6 sides). By supplying low-frequency pulse-type power, a high-frequency pulse-type electromagnetic field is radiated into space from a quantum energy generation coil, and the pulse-type electromagnetic fields are superimposed and extinguished, and the quantum energy generated in the self-magnetic field state is irradiated into space to the occupant's body organs. It promotes health by resonating with the natural frequency of.

Figure 1 is a cross-sectional view showing the overall configuration of a quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space according to a first preferred embodiment of the present invention.
Figure 2 is a cross-sectional view showing the type of material printed on the surface in the shape of a quantum energy generating coil.
Figure 3 is a cross-sectional view showing the shape of the first and second quantum energy generating coils implemented in a cusp coil shape.
Figure 4a is a cross-sectional view showing the shape of the first and second quantum energy generating coils implemented in a Helmheltz coil shape.
Figure 4b is a cross-section showing the shape of the first and second quantum energy generation coils implemented in a gradient saddle coil shape.
Figure 4c is a cross-sectional view showing the shape of the first and second quantum energy generating coils implemented in a uniform saddle coil shape.
Figure 4d is a cross-sectional view showing the shapes of the first and second quantum energy generating coils implemented in the shape of a toroid coil.
Figure 4e is a cross-sectional view showing the shape of the first and second quantum energy generation coils implemented in the shape of a trigger coil.
Figure 4f is a cross-sectional view showing the shapes of the first and second quantum energy generating coils in a zigzag shape.
Figure 4g is a cross-sectional view showing the shape of the first and second quantum energy generation coils implemented in the shape of an extension coil.
Figure 4h is a cross-sectional view showing the shape of the first and second quantum energy generating coils implemented in the shape of an electric motor stator-type coil.
Figure 4i is a cross-sectional view showing the shape of the first and second quantum energy generation coils implemented in a square or edge wise voice coil shape.
Figure 4j is a cross-sectional view showing the shape of the first and second quantum energy generating coils implemented in a toroidal coil shape.
Figure 4k is a cross-sectional view showing the shape of the first and second quantum energy generation coils implemented in the shape of a solenoid coil.
Figure 4l is a cross-sectional view showing the shape of the first and second quantum energy generation coils implemented in a modified RF coil shape.
Figure 4m is a cross-sectional view showing the shape of the first and second quantum energy generating coils implemented in a Tesla coil shape.
Figure 4n is a cross-sectional view showing the shape of the first and second quantum energy generation coils implemented in a Mobius coil shape.
Figure 4o is a cross-sectional view showing the shape of the first and second quantum energy generating coils implemented in a caduceus coil shape.
Figure 4p is a cross-sectional view showing the shape of the first and second quantum energy generating coils implemented in the Rogowski coil shape.
Figure 5 is a cross-sectional view showing the composition of conductive silver ink, which is material 1a, printed on the first to eighth material planes.
Figure 6a is a cross-sectional view showing the composition of conductive copper ink, which is the 1b material, printed on the first to 8th material planes.
Figure 6b is a cross-sectional view showing the composition of nanowire ink (Silver nanowire Ink), which is the 1c material printed on the first to eighth material planes.
Figure 6c is a cross-sectional view showing the manufacturing stage of the conductive silver ink composition of the 1d material printed on the plane of the 1st to 8th materials.
Figure 6d is a cross-sectional view showing the type of conductive metal as the second material attached to the first to eighth material planes.
Figure 6e is a cross-sectional view showing the type of conductive metal wire coated with the third material wound on the first to eighth material planes.
Figure 7 is a cross-sectional view showing the step of forming a quantum energy generation coil by printing the shape of the quantum energy generation coil with conductive ink on a first material plane.
Figure 8a is a cross-sectional view showing the step of forming a quantum energy generation coil by printing the shape of the quantum energy generation coil with conductive ink on the second material plane.
Figure 8b is a cross-sectional view showing the step of forming a quantum energy generation coil by printing the shape of the quantum energy generation coil with conductive ink on a third material plane.
Figure 8c is a cross-sectional view showing the step of forming a quantum energy generation coil by printing the shape of the quantum energy generation coil with conductive ink on the fourth material plane.
Figure 8d is a cross-sectional view showing the step of forming a quantum energy generation coil by printing the shape of the quantum energy generation coil with conductive ink on the fifth material plane.
Figure 8e is a cross-sectional view showing the step of forming a quantum energy generation coil by printing the shape of the quantum energy generation coil with conductive ink on the sixth material plane.
Figure 8f is a cross-sectional view showing the step of forming a quantum energy generation coil by printing the shape of the quantum energy generation coil with conductive ink on the seventh material plane.
Figure 8g is a cross-sectional view showing the step of forming a quantum energy generation coil by printing the shape of the quantum energy generation coil with conductive ink on the eighth material plane.
Figure 8h shows a method of attaching a conductive metal perforated in the shape of a quantum energy generating coil to the surfaces of the first material, second material, third material, fourth material, fifth material, sixth material, seventh material, and eighth material. This is a cross-sectional view showing the steps in manufacturing a quantum energy generation coil.
Figure 8i shows a quantum energy generating coil using a winding method using wires coated on the surfaces of the first material, second material, third material, fourth material, fifth material, sixth material, seventh material, and eighth material. This is a cross-sectional view showing the manufacturing steps.
Figure 8j shows conductive ink printed on the surfaces of the first material, second material, third material, fourth material, fifth material, sixth material, seventh material, and eighth material as shown in Figure 8g. The quantum energy generation coil manufactured by applying adhesive to the surfaces of the first material, second material, third material, fourth material, fifth material, sixth material, and seventh material and then attaching them creates a quantum energy generation coil. This is a cross-sectional view showing the manufacturing steps.
Figure 8k is a cross-sectional view showing a method of manufacturing a quantum energy generating coil using an electroluminescence device.
Figure 8l is a cross-sectional view showing a method of manufacturing a quantum energy generating coil with a sealed structure.
Figure 9 is a schematic diagram showing a first power supply that supplies power to quantum energy generating coils formed on first to eighth material planes.
Figure 10a is a schematic diagram showing a second power supply supplying power to quantum energy generating coils formed on first to eighth material planes.
Figure 10b is a schematic diagram showing a third power supply that supplies power to quantum energy generating coils formed on first to eighth material planes.
Figure 10c is a schematic diagram showing a fourth power supply that supplies power to quantum energy generating coils formed on first to eighth material planes.
Figure 10d is a schematic diagram showing a fifth power supply that supplies power to quantum energy generating coils formed on first to eighth material planes.
Figure 10e is a schematic diagram showing a sixth power supply that supplies power to a quantum energy generating coil formed using an electroluminescence device on the surface of the material shown in Figure 12k.
Figure 11 is a cross-sectional view showing a first quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
12a is a cross-sectional view of a second quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
Figure 12b is a cross-sectional view of a third quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
Figure 12c is a cross-sectional view of the fourth quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
Figure 12d is a cross-sectional view of the fifth quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
Figure 12e is a cross-sectional view of the sixth quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
Figure 12f is a cross-sectional view showing the seventh quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
Figure 12g is a cross-sectional view showing the 8th quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
Figure 12h is a cross-sectional view showing the 9a quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
Figure 12i is a cross-sectional view showing the 9b quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
Figure 12j is a cross-sectional view showing the 9c quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
Figure 12k is a cross-sectional view showing the 9d quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
Figure 12L is a cross-sectional view showing the 9e quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space.
Figure 13 is a cross-sectional view showing a configuration for irradiating quantum energy from a first quantum energy generating device inside a space partitioned by a material in which a quantum energy generating coil is formed.
Figure 14 is a cross-sectional view showing the first quantum energy generator 400A of the bremsstrahlung type.
Figure 15 is a cross-sectional view showing the second quantum energy generator 400B of the bremsstrahlung type.
Figure 16 is a cross-sectional view of a 2-1 quantum energy generator (400A) or 2-2 quantum energy generator (400B) of the bremsstrahlung type, which is a second quantum energy generator, installed on the material plane forming the four sides of space. .

With reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily carry out the present invention.

1 is a cross-sectional view showing the overall configuration of a quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawings, the quantum energy generator is a material on which a quantum energy generation coil is attached to the surface. (100), It is formed by printing and drying conductive ink on the surface of the material in the shape of a quantum energy coil using a printer, or attaching a metal plate processed into the shape of a quantum energy generating coil to the surface of the selected material, or using a coated conductive metal wire. A first quantum energy generation device (300A) consisting of a quantum energy generation coil coil (200) formed by winding it into the shape of a quantum energy generation coil, and a power supply (300) that supplies power to the quantum energy generation coil.

Sealed glass tube 401, thermionic emission cathode 404, power supply for cathode 402, conductor 403, first anode 413, high voltage power supply 411 for first anode 413, second The 2-1 quantum energy generator (400A) of the bremsstrahlung type consisting of an anode (423), a power supply for the second anode (421), and a quantum energy emission layer (424), and

Sealed glass tube 437, cathode 433, electron emission source 434, gate electrode 443, first anode 435, X-ray target plate 436, second anode 453, quantum energy emission Layer 454, first power supply 431 for cathode 433 and first anode 435, second power supply 441 for gate electrode 443, second anode 453, second anode This is a cross-sectional view showing the second quantum energy generator consisting of the 2-2 quantum energy generator 400B of the bremsstrahlung type consisting of the third power supply 451 for (453), with detailed information referring to the attached drawings. If I explain it clearly

It is a thick and strong paper such as commercially available thin white paper such as window paper, sago paper, Yusam paper, Taemi Basin paper, Sannae paper, Wansan paper, Kapyeong paper, and Gyeonyang paper, small wallpaper paper, large angle paper, interior wallpaper paper, etc., made of two or more Hwan, a recycled paper such as double-stitched paper such as gakji, wreath paper, yeongchang paper, cotton paper, rice paper, raised paper, new fuji paper, exterior paper, hejong paper, and seaweed paper, etc., and insect repellent paper. The first material 110, which is paper such as colored paper such as mixed paper, jade paper, red paper, yellow paper, blue paper, dark blue paper, and blue paper, and corrugated paper; and

The second material (120) is a non-conductive material such as PVC, PE, PC, acrylic, bakelite, fiberglass molded foam (FRP), Teflon, and urethane;

Iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), titanium (Ti), nickel (Ni), platinum (Pt), Hastal The third material 130, which is a metal material such as a panel with low heat insulation or cold insulation attached; and

4th material (140) such as wood plywood such as general plywood, Douglas fir plywood, core plywood, larch plywood, MDF, particle board, etc.;

Fifth material (150), which is an inorganic material such as concrete, tile, block, brick, board, stone (marble exterior material, etc.);

6th material (160) such as vegetable fiber, vegetable fiber, mineral fiber, regenerated fiber, synthetic fiber, and inorganic fiber; and

7th material (170) such as thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, and blocking glass;

Any one of the 8th transparent materials (180) such as polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film. Materials selected and used (100); and

It is a thick and strong paper such as commercially available thin white paper such as window paper, sago paper, Yusam paper, Taemi Basin paper, Sannae paper, Wansan paper, Kapyeong paper, and Gyeonyang paper, small wallpaper paper, large angle paper, interior wallpaper paper, etc., made of two or more Hwan, a recycled paper such as double-stitched paper such as gakji, wreath paper, yeongchang paper, cotton paper, rice paper, raised paper, new fuji paper, exterior paper, hejong paper, and seaweed paper, etc., and insect repellent paper. Flexography, screen printing, and offset on the surface of the first material (110), which is selected from materials such as mixed paper, jade paper, red paper, yellow paper, blue paper, navy paper, and blue paper, and corrugated cardboard. Select one of the printing methods among printing, rotary press, inkjet printing, and dry printing to apply solenoid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, and trigger coil to the surface of the material. , Zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Kadusse. A coil shape is selected among Caduceus Coil, Rogoski coil shapes, and combinations of these shapes, and the selected shape is printed and dried with pre-manufactured conductive ink to create a quantum energy generating coil. A first forming method 210 for forming (first and second quantum energy generating coils); and

Select one material from among the second materials 120 of non-conductive materials such as PVC, PE, PC, acrylic, bakelite, fiberglass molded foam (FRP), Teflon, and urethane, and press one surface of the selected material. Or, after grinding both surfaces with an electric sanding machine and cleaning them with a cleaner, select one of the printing methods among flexography, screen printing, offset printing, rotary grinder, inkjet printing, and dry printing to place soleroid coil, Troroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, Maxwell coil. Trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, flat. Among the shapes of square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, A second forming method 220 of selecting one coil shape, printing and drying it with conductive ink prepared in advance in the selected shape to form quantum energy generation coils (first and second quantum energy generation coils); and

Iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), titanium (Ti), nickel (Ni), platinum (Pt), Hastal Select one of the third materials 130, such as metal materials such as panels with low-cost insulation, insulation, or cold insulation, grind one surface of the selected material with an electric sanding machine, clean it with a cleaning agent, and then flexo. Select one of the following printing methods: graphic, screen printing, offset printing, rotary grinder, inkjet printing, and dry printing, and apply solenoid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, and uniform saddle coil to the surface. , toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil, Möbius coil ( Select one coil shape among Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, and print with conductive ink prepared in advance in the selected shape. A third forming method 230 of drying to form quantum energy generating coils (first and second quantum energy generating coils); and

Select any one of the fourth materials (140) such as general plywood, Douglas fir plywood, core plywood, larch plywood, MDF, particle board, etc. and wood plywood, and sand one or both surfaces of the selected material with an electric sanding machine. After grinding and cleaning with a cleaning agent, select one of the pre-manufactured flexography, screen printing, offset printing, rotary grinder, inkjet printing, and dry printing methods to apply soleroid coils and toroids to the surface of the material. Coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF. Any one of the coil shapes, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. A fourth forming method 240 of forming quantum energy generation coils (first and second quantum energy generation coils) by selecting and printing and drying with conductive ink prepared in advance in the selected shape; and

Select one material among the fifth materials (150), such as inorganic materials such as concrete walls or structures, tiles, blocks, bricks, boards, stones (marble exterior materials, etc.), and grind one surface of the selected material with an electric sanding machine. , After washing with a detergent, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to apply soleroid coil, toroid coil, cusp coil, etc. to the surface of the material. Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, One coil shape is selected among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil shapes, and combinations of these shapes, and the selected coil shape is selected. A fifth forming method 250 of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying with conductive ink prepared in advance into a shape; and

Select one material among the sixth materials (160) such as vegetable fiber, vegetable fiber, mineral fiber, regenerated fiber, synthetic fiber, and inorganic fiber, and apply flexography, screen printing, offset printing, and web printing on the surface of the selected material. Select one of the live, inkjet, and dry printing methods to print soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag on the surface of the material. Shaped coils (up and down, left and right), extension-shaped coils, motor stator-shaped coils, square coils, RF coils, toroidal coils, Tesla coils, Mobius coils, caduceus coils ( Among the Caduceus Coil and Rogoski coil shapes and combinations of these shapes, one coil shape is selected, and the selected shape is printed with pre-manufactured conductive ink and dried to create a quantum energy generating coil on the material. A sixth forming method 260 of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying; and

Select one material from among the 7th materials (170) such as thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, and blocking glass, remove fine dust from the surface of the selected material with a vacuum cleaner, and then use ethyl alcohol or isopropyl After removing surface impurities using a solvent such as alcohol, select a printing method among flexography, screen printing, offset printing, rotary press, inkjet printing, or dry printing on one or both surfaces of the material to surface the material. Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil. , square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. A seventh forming method (270) of selecting one coil shape from among the shapes, printing and drying the selected shape with conductive ink prepared in advance to form a quantum energy generation coil (first and second quantum energy generation coils). ;class

Select one material from the 8th material (180) such as polyimide, PET (polyethyleneTerephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film, After removing fine dust from the surface of the selected material with a vacuum cleaner, a conductive solution is applied to one or both surfaces of the material using an inkjet, flexographic, or gravure offset printing method. The soleroid coil is input to the control unit (microcomputer) of the printer. , toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil. , RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, or any one of these shapes. Select a shape, and film thickness on the surface of the material with conductive ink prepared in advance in the selected shape; 4-10 μm, line width; 50-80 μm, volume resistivity; 4-10 μΩ*cm Eighth forming method (280) of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying under conditions );class

1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), 8 materials (180): Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension-shaped coil on the surface. , Shape coil for motor stator, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil shape. And one coil shape is selected among the combinations of these shapes, and the selected shape is iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), and aluminum ( AL), one material from the hastaloid materials is selected, and a plate processed into the selected coil shape using a laser is attached to the selected material to form a quantum energy generation coil (first and second quantum energy generation coils). 9a method of forming (290a); and

1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), After applying adhesive to the surface of 8 materials (180), soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right) , Extension type coil, motor stator type coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogowski coil. (Rogoski coil) A coil shape is selected among shapes and combinations of these shapes, and a method of winding a quantum energy generating coil with a wire coated in the selected shape or using electroluminescence device manufacturing technology The 9b method (290b) of forming quantum energy generation coils (first and second quantum energy generation coils) by winding the manufactured EL wire (electroluminescent wire) into the selected quantum energy generation coil shape; and

1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), 8 Material (180) Select one material among polyimide, PET (polyethyleneTerephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film on the surface, After removing fine dust from the surface of the selected material with a vacuum cleaner, a conductive solution is applied to one or both surfaces of the material using an inkjet, flexographic, or gravure offset printing method. The soleroid coil is input to the control unit (microcomputer) of the printer. , toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, Maxwell coil. Trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, Select one coil shape among square coils, RF coils, toroidal coil shapes, and combinations of these shapes, and apply the selected shape to a film thickness on the surface of the material; 4-10 μm, line width; 50-80 μm, volume resistivity; 4-10 μΩ*cm Eighth forming method (280) of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying under conditions ) Quantum energy generation coil forming method (290c) in which a quantum energy generation coil made of ) is attached; and

1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), 8It consists of a transparent substrate (1), a first electrode (2), an electroluminescent layer (3), and a second electrode (4) on a material plane selected on the surface of the material (180). On the transparent substrate (1) The first electrode (2) is formed in the form of a stripe in the shape of a quantum energy generating coil, the organic electroluminescent layer (3) is formed on the first electrode (2), and the second electrode is formed on the organic electroluminescent layer (3). The electrode 4 has a structure formed in the form of a stripe in the shape of a quantum energy generating coil, and the quantum energy generating coil is formed in the form of a stripe on the first electrode 2 and the second electrode 4. The shapes are soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, and motor stator. Shapes of coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and their shapes. Among the combined shapes, one coil shape is selected, and the quantum energy generation coil is manufactured by winding it in the selected shape, but the winding direction is counterclockwise or clockwise, and the manufactured quantum energy generation coil (first and second quantum energy A 9d forming method (290d) in which a generating coil) is attached; and

Secondary materials (120), which are non-conductive materials such as PVC, PE, PC, acrylic, bakelite, reinforced glass foam (FRP), Teflon, and urethane, iron (Fe), copper (Cu), zinc (Zn), Tin (Sn), stainless steel (STS304, STS316), aluminum (AL), hastalloy, panels with insulation or cold insulation, aluminum (Al), titanium (Ti), nickel (Ni), platinum (Pt), etc. The third material (130) is a metal material, the fifth material (150) is an inorganic material such as concrete walls, tiles, blocks, bricks, boards, and stones (marble exterior materials, etc.), thin plate glass, thick plate glass, transparent polished plate glass, and solar shielding. 7th material (170) such as glass and barrier glass, polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, PVC film, etc. Select one material from the transparent 8th material (180),

The second material (120) is a non-conductive material such as PVC and PE, and the third material is a metal material (130) such as iron (Fe), copper (Cu), aluminum (Al), titanium (Ti), and nickel (Ni). ), Concrete walls, tiles, blocks, bricks, boards, etc. The selected materials among the 5th materials (150) are inorganic materials, and the part where the quantum energy generating coil is to be formed is ground using an electric sanding machine and dust is removed using a vacuum cleaner. After removing the material selected from the seventh material 170 such as thick plate glass and the eighth material 180 such as polyimide, a quantum energy generating coil can be formed using a cleaning solution such as isopropyl alkoxy. After removing foreign substances from the area, select one of the printing methods among flexography, screen printing, offset printing, rotary grinder, inkjet printing, and dry printing and apply soleroid coil, toroid coil, cusp coil, and helm to the surface of the material. Hellz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, ( Select one coil shape from Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, and manufacture it in advance. After printing and drying the conductive ink in a pre-selected quantum energy generating coil shape using a printer,

Metal materials such as iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (Al), titanium (Ti), nickel (Ni), hastalloy, etc. The third material 130 is faceted on the front and back sides with the printed coil surface facing outward so that it contacts the liquid or facing inward so as not to come into contact with the liquid, and then a conductor (not shown) connected to each quantum energy generating coil is used. After drawing out the outside (projecting outward from the joint surface), the edge of the joint surface is welded by selecting one of the ARC welding, TIG welding, and MIG welding methods. For thin plate glass, the edge of the joint surface is welded.

The front and back sides are interviewed with the printed coil surface facing outwards so that it is in contact with liquid (including water), or facing inwards so that it does not come into contact with liquid, and then the conductors (not shown) connected to each quantum energy generating coil are joined to the outside. After protruding from the surface to the outside, caulk the edges of the joint surface with waterproof sealant.

The fifth material (150) is an inorganic material such as concrete walls, tiles, blocks, bricks, and boards.

8th transparent materials such as polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film with quantum energy-emitting coils formed on the surface. Attaching any one material among the materials 180,

Select and attach one material among the second materials (120), which are non-conductive materials such as PVC, PE, PC, acrylic, bakelite, reinforced glass foam (FRP), Teflon, and urethane, on which a quantum energy-emitting coil is formed on the surface. or iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (Al), titanium (Ti), nickel (Ni), hastalloy, etc. The third material 130, which is a metal material, selects one shape among the shapes of the quantum energy generating coil, and the 9e method of attaching the quantum energy generating coil processed by model picking technology using laser technology to the selected shape. (200) Quantum energy generation coil forming method (200), in which one forming method is selected depending on the type of material among (290e);

First rectifier 311, transformer 312, FET switch 313, second rectifier 314, PWM (pulse width modulation) control method and pulse frequency modulation PFM (pulse frequency modlation) and a first pulse control unit 315 with built-in pulse frequency (density) control (PDM) and pulse repetition rate control (PRR) functions, a magnetic field detection sensor 315a, a switching control unit 316, and a post regulator 317. Power supply (310); and

A step-down (boost) transformer (321), a rectifier circuit (322), an input module (323a), an operation module (323b), and a PWM (pulse width modulation) control method and pulse frequency modulation (PFM). and a control unit 323 consisting of a control module 323c with built-in pulse frequency (density) control (PDM) and pulse repetition rate control (PRR) functions, a current detection sensor 324, and a magnetic field detection sensor 325. 2 power supply (320); and

A power transmitter 330 consisting of a power supply unit 331, an output power generation unit 332, a frequency modulation unit 333, an output time control unit 334, and a transmission coil unit 335;

A power receiver (330a) consisting of a receiving coil unit (331a), a power generating unit (332a), and a feedback signal generating unit (333a); and

Converter unit (331b), inverter unit (332b), resonance reactor (333b), pulse transformer (334b), control unit (335b), gate driver (336b), magnetic field detection sensor (336b-1), first condenser (337b) ), and a third power supply 330 consisting of a high voltage generator 330b consisting of a second condenser 338b; and

A fourth power supply 340 consisting of an input unit 341, a control unit 342, a magnetic field detection sensor 342a, a switching converter unit 343, a high voltage generator 344, and a rectifier unit 345;

Power supply unit 351 consisting of an alternating current power (AC) supply (351a) or a direct current power (DC: battery) supply (351b), AC/DC conversion unit (352), automatic power supply switcher (353) (ATS), low frequency Surface temperature of the generation and output unit 354, switching element 355, and quantum energy generation coils 521 and 522, PWM (pulse width modlation) control method, pulse frequency modulation (PFM), and pulse frequency. A fifth power supply 350 consisting of a control unit 356 with (density) control (PDM) and pulse repetition rate control (PRR) functions, and a magnetic field detection sensor 356a;

The overcurrent that detects the amount of current applied to the power supply unit 361, the EL driving unit, and the quantum energy generation coil is detected by the overload detection unit 362, the voltage adjustment unit 363, the frequency modulation unit 364, the magnetic field detection sensor 364a, and the EL driving unit ( 365), a sixth power supply (360), a power supply (300) that selects one type of battery (not shown) and supplies power to the quantum energy generation coil; and

On the first material 110 and the surface of the first material 110, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes and print with pre-prepared conductive ink. and a quantum energy generating coil manufactured by the first method of drying (210), and a first power supply (310), a second power supply (320), and a third power supply (330) that supply power to the quantum energy generating coil. , A first quantum energy generator consisting of a power supply (300) selected from the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), and a battery (not shown). (371);and

On the surface of the second material 120 and the second material 120, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes and use pre-prepared conductive ink. A quantum energy generating coil manufactured by the second method of printing and drying (220), and a first power supply (310), a second power supply (320), and a third power supply (330) that supply power to the quantum energy generating coil. ), a fourth power supply (340), a fifth power supply (350), a sixth power supply (360), and a power supply (300) selected from a battery (not shown) to generate a second quantum energy. device 372; and

On the third material 130 and the surface of the third material 130, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes and use pre-prepared conductive ink. A quantum energy generating coil manufactured by the third method of printing and drying (230), and a first power supply (310), a second power supply (320), and a third power supply (330) that supply power to the quantum energy generating coil. ), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), and the third quantum energy generation consisting of a power supply (300) in which one type of battery (not shown) is selected. device 373; and

On the surface of the fourth material 140 and the fourth material 140, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing, and use cusp coil, Helmheltz, etc. Coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil. Conductive ink prepared in advance by selecting one coil shape among (Tesla coil), Mobius Coil, Caduceus coil, (Caduceus Coil), Rogoski coil, and combinations of these shapes. A quantum energy generating coil manufactured by the fourth method of printing and drying (240) and a first power supply (310), a second power supply (320), and a third power supply ( 330), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), and the fourth quantum energy consisting of a power supply (300) in which one type of battery (not shown) is selected. Generating device 374; and

On the surface of the fifth material 150 and the fifth material 150, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes and use pre-prepared conductive ink. A quantum energy generation coil manufactured by the fifth method of printing and drying (250), and a first power supply (310), a second power supply (320), and a third power supply (330) that supply power to the quantum energy generation coil. ), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), and the fifth quantum energy generation consisting of a power supply (300) in which one type of battery (not shown) is selected. device 375; and

On the surface of the sixth material (160) and the sixth material (160), select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes and use pre-prepared conductive ink. A quantum energy generating coil manufactured by the sixth method of printing and drying (260), and a first power supply (310), a second power supply (320), and a third power supply (330) that supply power to the quantum energy generating coil. ), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), and the power supply (300) of which one type of battery (not shown) is selected. device 376; and

On the surface of the seventh material (170) and the seventh material (170), select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes and use pre-prepared conductive ink. A quantum energy generating coil manufactured by the seventh method of printing and drying (270), and a first power supply (310), a second power supply (320), and a third power supply (330) that supply power to the quantum energy generating coil. ), the 4th power supply 340, the 5th power supply 350, the 6th power supply 360, and the 7th quantum energy generator (battery), which consists of a power supply 300 selected from the group consisting of 377);

On the surfaces of the 8th material (180) and the 8th material (180), select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes and use pre-prepared conductive ink. A quantum energy generating coil manufactured by the eighth method of printing and drying (280), and a first power supply (310), a second power supply (320), and a third power supply (330) that supply power to the quantum energy generating coil. ), the fourth power supply 340, the fifth power supply 350, the sixth power supply 360, and the power supply 300, where one type of battery (not shown) is selected. device 378; and

1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), 8 After applying adhesive to a certain area on the surface of the material (180), soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension-shaped coil, motor stator-shaped coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, logo Among Rogoski coil shapes and combinations of these shapes, one coil shape is selected, and the selected shape is made of iron (Fe), copper (Cu), zinc (Zn), tin (Sn), and stainless steel ( One material is selected from among STS304, STS316), aluminum (AL), and hastaloid materials, and the selected material is manufactured using the 9a method (290a) in which a plate processed into the selected coil shape is attached. The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), and the fifth power supply that supply power to the quantum energy generation coil and the quantum energy generation coil. A 9th quantum energy generator (379a) consisting of a power supply (300) in which one type of supply (350), a sixth power supply (360), and a battery (not shown) is selected.

1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), After applying adhesive to a certain area on the surface of 8 materials (180), soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension-shaped coil, motor stator-shaped coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, logo A method of selecting one coil shape among Rogoski coil shapes and combinations of these shapes, and winding a quantum energy generating coil with a conductive wire covered in the selected shape, or electroluminescence device manufacturing technology. The 9b method (290b) of the method of winding the quantum energy generating coil shape selected above using EL Wire (electroluminescent wire) manufactured using the quantum energy generating coil and the method for supplying power to the quantum energy generating coil. 1st power supply (310), 2nd power supply (320), 3rd power supply (330), 4th power supply (340), 5th power supply (350), 6th power supply (360), battery (Mido 9b quantum energy generator (379b) consisting of a power supply (300) and a battery (not shown), of which one type is selected; and

Which of the first material (110), second material (120), third material (130), fourth material (140), fifth material (150), sixth material (160), and seventh material (170) A material is selected, a certain area of adhesive is applied to the surface of the selected material, and then polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, and polypropylene film are applied. , Select one material among PVC films, and apply a conductive solution to one or both surfaces of the selected material using inkjet, flexographic, and gravure offset printing methods to input the soleroid coil and toroid coil into the control unit (microcomputer) of the printer. , Cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil. ,Troidal coil, Tesla coil, Mobius coil, Caduceus coil, Rogoski coil, or any one of these coil shapes among the combinations of these shapes. Film thickness on the surface of the material in the selected shape; 4-10 μm, line width; 50-80 μm, volume resistivity; 4-10 μΩ*cm Article 9c, where the quantum energy generation coil produced by the forming method (280) of forming the quantum energy generation coil by printing and drying under the conditions is attached A first power supply (310), a second power supply (320), a third power supply (330), and a fourth power supply ( 340), the 9th quantum energy generator (379c) consisting of a power supply (300) selected from the fifth power supply (350), the sixth power supply (360), and a battery (not shown);

*1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), The surface of the eighth material (180) is composed of a transparent substrate (1), a first electrode (2), an electroluminescent layer (3), and a second electrode (4) after applying a certain area of adhesive on a selected material plane. .On the transparent substrate (1), the first electrode (2) is formed in the form of a quantum energy generating coil-shaped stripe, and the organic electroluminescent layer (3) is formed on the first electrode (2), and the organic electric field The second electrode 4 on the light emitting layer 3 is formed in the form of a quantum energy generating coil-shaped stripe. The first electrode 2 and the second electrode 4 have a stripe structure. The shapes of quantum energy generating coils are soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), Extension type coil, motor stator type coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogowski coil ( Rogoski coil) shape and a combination of these shapes, one coil shape is selected, the winding direction of the selected quantum energy generation coil is counterclockwise or clockwise, and the quantum energy generation coil is manufactured, and the manufactured quantum energy generation coil is produced. A quantum energy generation coil manufactured by the 9d method (290d) of forming a quantum energy generation coil by attaching a coil, and a first power supply (310) and a second power supply (320) that supply power to the quantum energy generation coil. ), the third power supply (330), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), and the power supply (300) in which one type of battery (not shown) is selected. The 9d quantum energy generator (379d) consisting of; and

1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), One of the eight materials (180) is selected, and one printing method among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing is selected on the surface of the selected material to create a cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, and pre-order Quantum energy generation coils (first and second quantum energy generation coils) are formed by printing and drying the prepared conductive ink in the shape of the selected quantum energy generation coil using a printer, and using the conservative materials formed in the quantum energy generation coil. The first space is divided and separated from the first space by a certain distance to create a space with a reduced volume. The method of creating the space is to interview the two materials on the side where the quantum energy generating coil is not formed, and then interview the edge of the interview. After sealing the border by welding it using any type of welder, such as an ARC welder, TIG welder, MIG welder, or PVC welder, or using a material formed with a quantum energy generating coil joined with an adhesive or sillint, the first space is created. , The first power supply (310), the second power supply (320), the third power supply (330), and the fourth power supply that supply power to each quantum energy generating coil formed on the surface of the material dividing the second space. (340), the 5th power supply (350), the 6th power supply (360), and the 9th quantum energy generator (379e), which consists of a power supply (300) in which one type of battery (not shown) is selected. A first quantum energy generator (300A) consisting of; and

A sealed glass tube 401, a thermionic emission cathode 404 having a filament installed on the left side of the glass tube, a power supply 402 that supplies direct current power to the cathode 404, and a predetermined distance away from the cathode 404. A first anode 413 made of copper (CU) or tungsten (W) is installed, a high-voltage power supply 411 that applies high voltage to the first anode 413, and a certain area on one side of the lower part of the sealed glass tube 401. A second anode 423 made of a material such as rhodium is installed in the opened opening, a power supply 421 that supplies direct current high voltage power to the second anode 423, and a power supply of the second anode 423. A quantum energy emission layer 424 made of a material such as beryllium is installed on the externally exposed surface, and power is supplied to the cathode 404 through a power supply 402, and a power supply 411 for the first anode. The conductor 412 connected to the first anode 413 is connected to the + terminal on the output side, and the conductor 412 connected to the output side - terminal of the power supply 402 for the negative electrode 404 is connected to the output side - terminal to connect the negative electrode. A 2-1 quantum energy generator (400A) of a first braking radiation type constituting a bias circuit between the power supply for power supply 411 and the first anode power supply 411; and

A sealed glass tube 437, a cathode 433 installed inside the glass tube on the right side, an electron emission source 434 is installed in contact with the cathode 433, and the cathode 433 is spaced a certain distance to the left from the cathode 433. ) A gate electrode 443 is installed in a shape that embraces the gate electrode 443, and a first anode 435 is installed at the center of the inner side of the sealing glass tube 437 opposite to the gate electrode 443, and the first anode 435 It is installed on the X-ray target plate 436 at the center of the right slope. In addition, the second anode 453 is installed on the sealed glass tube 437 projected vertically below the target plate 436 installed on the inclined surface of the first anode 435, and is interviewed on the surface of the second anode 453. A quantum energy emission layer 454 is installed. In addition, a first power supply 431 is installed at a certain distance from the left side of the sealed glass tube to apply a high voltage to the cathode 433 and the first anode 435 through a conductor, and the gate electrode is spaced downward at intervals. A second power supply 441 that supplies power to (443) is installed. The output terminals of the first power supply 431 and the second power air 441 are wired in common to form the first power supply 431. A bias circuit is formed between the second power supply 441 and the second power supply 441. A third power supply 451 that applies a high voltage to the second anode 453 is installed at a downward distance from the second power supply 441. and a second brake copying unit that configures a bias circuit between the second power supply 441 and the third power supply 451 by wiring the output terminals of the second power supply 441 and the third power supply 451 in common. It consists of a second quantum energy generating device (400B) consisting of a 2-2 quantum energy generating device (430).

Figure 2 is a cross-sectional view showing the types of materials printed on the surface in the shape of a quantum energy generating coil. When explained with reference to the attached drawings, the materials include window paper, sago paper, Yusam paper, Taemi Basin paper, Sannae paper, Wansan paper, It is a thick and strong paper such as commercially available thin white paper such as kapyeong paper, gyeongyang paper, small wallpaper paper, daegak paper, interior wallpaper paper, etc. It is a paper made by knitting two or more layers, such as gakji paper, wrapping paper, yeongchang paper, wallpaper paper, and non-wall paper. Slightly thicker paper such as line paper, raised paper, new Fuji paper, exterior paper, hejong paper, cast paper, etc., recycled paper such as insect repellent paper, Hwanghon paper, jade paper, red paper, yellow paper, blue paper, dark blue paper, The first material 110, which is colored paper such as blue paper, cardboard, etc.; and

The second material (120) is a non-conductive material such as PVC, PE, PC, acrylic, bakelite, fiberglass molded foam (FRP), Teflon, and urethane;

Iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), titanium (Ti), nickel (Ni), platinum (Pt), Hastal The third material 130, which is a metal material such as a panel with low heat insulation or cold insulation attached; and

4th material (140) such as wood plywood such as general plywood, Douglas fir plywood, core plywood, larch plywood, MDF, particle board, etc.;

Fifth material (150), which is an inorganic material such as concrete, tile, block, brick, board, stone (marble exterior material, etc.);

6th material (160) such as vegetable fiber, vegetable fiber, mineral fiber, regenerated fiber, synthetic fiber, and inorganic fiber; and

7th material (170) such as thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, and blocking glass; and

Any one of the 8th transparent materials (180) such as polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film. is selected and used.

The materials for forming the quantum energy generation coil by printing conductive ink on the surface in the shape of the quantum energy generation coil using a printer are the first material 110, the second material 120, the third material 130, and the first material 110. It is not limited to the 4th material (140), the 5th material (150), the 6th material (160), the 7th material (170), and the 8th material (180). Any material not listed herein may be conductive on the surface. Any ink can be used if it can be printed in the shape of a quantum energy generating coil using a printer.

Figure 3 and Figure 4a, Figure 4b, Figure 4c, Figure 4d, Figure 4e, Figure 4f, Figure 4g, Figure 4h, Figure 4i, Figure 4j, Figure 4k, Figure 4l, Figure 4m, Figure 4n, Figure 4o, Figure 4p is a cross-sectional view showing various shapes of quantum energy generating coils printed or attached to the first to eighth material surfaces.

Figure 3 is a cross-sectional view showing the shape of a quantum energy generation coil (first and second quantum energy generation coils) implemented in a cusp coil shape. When explained with reference to the attached drawings, the outer surface of a vertically standing cylinder with a constant diameter is shown. In the circumferential direction, the first quantum energy generating coil is wound with a certain number of turns clockwise or counterclockwise on the circumferential surface of the lower side, and the second quantum energy generating coil is spaced a certain distance upward from the first quantum energy generating coil. It has a shape in which a certain number of turns are wound counterclockwise or clockwise on the circumferential surface of one side of the upper side, and the winding directions of the first and second quantum energy generating coils are opposite to each other.

Figure 4a is a cross-sectional view showing the shape of a quantum energy generation coil (first and second quantum energy generation coils) implemented in a Helmheltz coil shape. When explained with reference to the attached drawings, the outer surface of a horizontal cylinder with a constant diameter is shown. In the circumferential direction, the first quantum energy generating coil is wound with a certain number of turns clockwise or counterclockwise on the circumferential surface of one side on the left, and the second quantum energy coil is spaced a certain distance to the right from the first quantum energy generating coil and is wound on one side of the right side. It has a shape in which a certain number of turns are wound in a counterclockwise or clockwise direction on the circumferential surface, and the winding directions of the first and second quantum energy generating coils are opposite to each other.

Figure 4b is a cross-sectional view showing the shape of a quantum energy generation coil (first and second quantum energy generation coils) implemented in a gradient saddle coil shape. When explained with reference to the attached drawings, the first coil shape is a horizontal shape with a constant diameter. Alternatively, a quantum energy generating coil line is printed from the left end of one side of the upper part of the outer surface area of a semi-cylindrical column to the right end in the circumferential direction, covering 1/2 the area of the entire circumferential surface of a section at a certain distance from the outer surface of a vertical cylinder. Extend the coil wire from the upper side of the right end to the lower end, extend the coil wire from the right end to the left end, and extend from the lower end to maintain a certain distance from the upper end in the downward direction (No. 1 winding), again at a certain distance from the first winding in the downward direction, extending the coil at intervals from the left to the right end to the left, again winding at a distance from the first winding in the direction from the top to the bottom, and again on one side on the right. It is wound clockwise to the center by extending the coil to the left side and upward from the left side (second winding).

The shape of the second quantum energy generation coil is such that the winding direction is opposite to that of the first quantum energy generation coil, and the entire section at a certain distance from the outer surface of a horizontal or vertical cylinder with a certain diameter A quantum energy generating coil line printed in an area of 1/2 the area of the circumferential surface, that is, the outer surface area of the semicylindrical column, is extended from the right side of the upper one end in the circumferential direction to the left end, and the coil line is extended from the upper side of the left end to the lower end, After extending the coil wire from the left end to the right end, extend it from the lower right end to the coil wire at the upper end to maintain a certain distance in the downward direction (first winding), and then extend it again at a certain distance from the first winding in the downward direction. The coil is extended at a distance from the right end to the left, and is wound again from the top to the bottom at a distance from the first winding, and the coil is again extended from the left side to the right side and from the right side to the top (second winding). It is a shape that is wound counterclockwise to the center using the winding method.

Figure 4c is a cross-sectional view showing the shape of a quantum energy generating coil (first and second quantum energy generating coils) implemented in a uniform saddle coil shape. When explained with reference to the attached drawing, the gradient saddle coil shape shown in Figure 4b and It has a similar shape, and the first coil shape is 1/2 the area of the entire circumferential surface of a section at a certain distance from the outer surface of a horizontal or vertical cylinder with a certain diameter, that is, the upper left end of the outer surface area of the semicylindrical cylinder. Extend the printed quantum energy generating coil line in the circumferential direction to the right end, extend the coil line from the upper part of the right end to the lower end, extend the coil line from the right end to the left end, and then extend the coil line from the lower end to the upper end. After extending the coil to maintain a certain distance from the line to the bottom (first winding), the coil is again extended from the left to the right end to the left at a certain distance from the first winding to the bottom, and again from the top to the bottom. It is wound in a clockwise direction to the center by winding it in a direction that is spaced apart from the first winding and then extending the coil from the right side to the left side and from the left side to the top (second winding).

The shape of the second quantum energy generation coil is such that the winding direction is opposite to that of the first quantum energy generation coil, and the entire section at a certain distance from the outer surface of a horizontal or vertical cylinder with a certain diameter A quantum energy generating coil line printed in an area of 1/2 the area of the circumferential surface, that is, the outer surface area of the semicylindrical column, is extended from the right side of the upper one end in the circumferential direction to the left end, and the coil line is extended from the upper side of the left end to the lower end, After extending the coil wire from the left end to the right end, extend it from the lower right end to the coil wire at the upper end to maintain a certain distance in the downward direction (first winding), and then extend it again at a certain distance from the first winding in the downward direction. The coil is extended at a distance from the right end to the left, and is wound again from the top to the bottom at a distance from the first winding, and the coil is again extended from the left side to the right side and from the right side to the top (second winding). It is a shape that is wound counterclockwise to the center using the winding method.

Figure 4d is a cross-sectional view showing the shape of a quantum energy generation coil (first and second quantum energy generation coils) implemented in the shape of a toroid coil. When explained with reference to the attached drawings, the first quantum energy generation coil is a ring with a certain diameter. It is a shape that is wound clockwise or counterclockwise in a helical coil manner in the circumferential direction of the outer surface of the shape.

The second quantum energy generation coil is wound in the opposite direction to the winding direction of the first quantum energy generation coil, and is wound counterclockwise or clockwise in a helical coil shape in the circumferential direction of the outer surface of a ring shape with a constant diameter. It is a shape that becomes,

Figure 4e is a cross-sectional view showing the shape of a quantum energy generation coil (first and second quantum energy generation coils) implemented in the shape of a trigger coil. When explained with reference to the attached drawings, the shape of the first quantum energy generation coil is shown in Figure 4e. As shown, it has a shape in which a certain number of turns are wound clockwise or counterclockwise from the outer edge to the center on the disk, and the second quantum energy generation coil is in the opposite direction to the winding direction of the first quantum energy generation coil. It has a shape in which a certain number of turns are wound counterclockwise or clockwise inside or outside the concentric circle of the first quantum energy generation coil.

Figure 4f is a cross-sectional view showing the shape of a zigzag quantum energy generation coil (first and second quantum energy generation coils). When explained with reference to the attached drawings, the shape of the first quantum energy generation coil is shown in Figure 4f. As described above, a certain number of turns are wound in a zigzag direction in the vertical or horizontal direction, and the shape of the second quantum energy generating coil is such that the winding direction of the first quantum energy generating coil is opposite and zigzagging in the vertical or horizontal direction. It has a shape in which a certain number of turns are wound in one direction.

Figure 4g is a cross-sectional view showing the shape of a quantum energy generation coil (first and second quantum energy generation coils) implemented in the shape of an extension coil. When explained with reference to the attached drawings, the extension coil shape is the zigzag shape shown in Figure 4f. Similar to the shape, the first extension coil shape is a zigzag coil wound in a circular shape to have a certain diameter, and the second extension coil shape is a zigzag shape inside or outside the concentric circle of the first extension coil shape. It is a coil wound in a circular shape to have a certain diameter, and is wound so that the current flow direction is opposite to each other.

Figure 4h is a cross-sectional view showing the shape of a quantum energy generation coil (first and second quantum energy generation coils) implemented in a motor stator-type coil shape. When explained with reference to the attached drawing, the shape of the first quantum energy generation coil is Is a circular shape formed by interviewing a plurality of small circles with a certain diameter to form a circle with a certain diameter, and the shape of the second quantum energy generating coil is such that the plurality of first quantum energy generating coils are formed by interviewing each other. It is a circular shape with a constant diameter formed by interviewing one side of a plurality of coils within or within a concentric circle, and is shaped so that the flow directions of the current are opposite to each other in the first and second quantum energy generating coils. .

Figure 4i is a cross-sectional view showing the shape of a quantum energy generation coil (first and second quantum energy generation coils) implemented in a square or edge wise voice coil shape. When described with reference to the attached drawings, the flat The square or edge wise voice coil shape is similar to the cusp coil shape shown in FIG. 3, and the shape of the first quantum energy generating coil is the circumferential direction of the outer surface of a horizontal cylinder with a constant diameter. It is wound clockwise or counterclockwise with a certain number of turns, and the second quantum energy work has a winding direction opposite to that of the first quantum energy generating coil, and is wound with a certain number of turns counterclockwise or clockwise in the circumferential direction of the outer surface of the cylinder. It has a winding shape.

Figure 4j is a cross-sectional view showing the shape of a quantum energy generation coil (first and second quantum energy generation coils) implemented in a toroidal coil shape. When explained with reference to the attached drawings, the shape of the first quantum energy generation coil is constant. In the shape of a concentric circle, a certain diameter is wound clockwise or counterclockwise in the circumferential direction of the outer surface of the ring, and then, at a certain distance, a certain number of turns are wound in a counterclockwise or clockwise direction in the circumferential direction of the outer surface of the ring. It is a shape in which a plurality of coils are wound at a certain distance apart from each other, and the shape of the second quantum energy generating coil is a concentric circle with a certain distance and a constant diameter in a constant counterclockwise or clockwise direction in the circumferential direction of the outer surface of the ring. It is a shape in which a plurality of coils are wound at a certain distance and then spaced apart from each other at a certain distance, and then wound at a certain distance clockwise or counterclockwise in the circumferential direction of the outer surface of the ring, and the first and second quantum energies are generated. The direction of current flow in the coil is in opposite directions.

Figure 4k is a cross-sectional view showing the shape of a quantum energy generating coil (first and second quantum energy generating coils) implemented in a solenoid coil shape. When explained with reference to the attached drawings, the solenoid coil shape has a spring shape or a helical shape. The first quantum energy generating coil is wound clockwise or counterclockwise in a certain number of turns in the circumferential direction of the outer surface of the center line of a horizontal cylinder with a similar shape and a constant diameter, and the second quantum energy generating coil is wound with the first quantum energy generating coil. It is wound in such a way that the winding directions are opposite to each other, so that a certain number of turns are wound counterclockwise or clockwise on the circumferential surface, and the directions of current flow in the first and second quantum energy generation coils are in opposite directions.

Figure 4l is a cross-sectional view showing the shape of a quantum energy generation coil (first and second quantum energy generation coils) implemented in a modified RF coil shape. When explained with reference to the attached drawings, the shape of the first quantum energy generation coil is A plurality of coils with a certain number of turns are wound clockwise or counterclockwise on the outer surface of a rectangular or oval shape with a certain area at intervals in a concentric circle, and the winding directions of adjacent coil groups are opposite to each other. The shape of the second quantum energy generating coil is a shape in which a certain number of coils are wound in a counterclockwise or clockwise direction on the outer surface of a rectangular or oval shape with a certain area, and a plurality of coils are spaced in a concentric circle. This is the formed shape. The winding directions of the first and second quantum energy generating coils are opposite to each other.

Figure 4m is a cross-sectional view showing the shape of the first and second quantum energy generating coils implemented in a Tesla coil shape. When explained with reference to the attached drawings, the Tesla coil shape is similar to the solenoid coil shape and has a cylindrical outer circumferential surface. It appears to be wound with a certain number of turns in a clockwise or counterclockwise direction. It can mainly be installed on the material surface outside or inside a cylindrical special space.

Figure 4n is a cross-sectional view showing the shapes of the first and second quantum energy generating coils implemented in a Mobius coil shape. When explained with reference to the attached drawings, there are two coil lines in the circumferential direction of the outer surface of a virtual cylinder or one coil line. The coil wire is wound in an 8-shaped or infinitely large (∞) shape, with a certain number of turns wound in a clockwise or counterclockwise direction at intervals from each other.

Figure 4O is a cross-sectional view showing the shape of the first and second quantum energy generating coils implemented in a caduceus coil shape. When explained with reference to the attached drawings, the caduceus coil shape is similar to the Moebius coil shape. Two coil wires or one coil wire in the circumferential direction of the outer surface of a virtual cylinder are wound in an 8-shaped or infinite shape (∞), and the intersection points of the lines are spaced evenly on the left or right side of the outer surface of the virtual cylinder. It has a shape in which a certain number of turns are wound clockwise or counterclockwise.

Figure 4P is a cross-sectional view showing the shapes of the first and second quantum energy generating coils implemented in a Rogowski coil shape. When explained with reference to the attached drawings, the Rogowski coil shape is a ring shape and the wire at the bottom is circular. It is wound or bent, so that the two ends are connected or intersected at a distance from each other, and two coupling fittings are fastened. The wire is drawn out to the right or left from the center of the welding area, and is in the shape of the first and second coils of the quantum energy generator. When forming, the winding directions are made to be opposite to each other.

The shape of the quantum energy generating coil is shown in Figure 3, Figure 4a, Figure 4b, Figure 4c, Figure 4d, Figure 4e, Figure 4f, Figure 4g, Figure 4h, Figure 4i, Figure 4j, Figure 4k, Figure 4l, Figure 4m, Figure 4 It is not limited to the shape shown in Figure 4n, Figure 4o, and Figure 4p, and various coil shapes such as poloidal coil (not shown), square, polygon, etc., and overlapping oval and circle can be selected and used.

Figure 5 is a cross-sectional view showing the composition of conductive silver ink, which is a material 1a printed on the first to eighth material planes. When explained with reference to the attached drawings, the composition of the conductive silver ink is shown. Composition and properties include viscosity (cp) in the range of 12 to 15 cp, silver content (%) of 10%, resistance (Ωcm) (Resistance) of <10 ^-4 (Ωcm), and adhesive strength. (B) Use AGS102CO with Adhesion >4, or Viscosity is in the range of 10 to 12 cp, Silver Content is 5%, and Resistance (Ωcm) is 5%. AGS105CO can be used, which is <10 ^-4 (Ωcm) and has an adhesion (B) >4.

Table 1 shows the characteristics, functions, and characteristics of conductive silver ink - Properties of silver ink

Product name Viscosity (cp) Silver Content (%) Resistance (Ωcm)(Resistance) Adhesion (B) AGS102CO 12-15 10 <10 ^-4 >4 AGS105CO 10-12 5 <10 ^-4 >4

-Function and features. Forms a dense silver thin film when reduced by heat.

.Reduced curing time

.Organic ligand and metal ion complex form, not nanoparticles

. Equivalent performance at lower cost compared to silver paste

Figure 6a is a cross-sectional view showing the composition of the conductive copper ink, which is the 1b material printed on the first to eighth material planes. When explained with reference to the attached drawings, the conductive copper ink The composition and properties have a viscosity (cp) in the range of 26 to 30 cp, and is similar to that of conductive copper ink.

Use CUS101cd, which has a copper content of 9-11%, resistance (Ωcm) <10 ^-3 (Ωcm), and adhesion (B) >4, or viscosity ( cp)(Viscosity) is in the range of 20 to 25cp, copper content (%) is 9-11%, resistance (Ωcm) is <10 ^-3 (Ωcm), and adhesive strength (B) ( Use CUS102cd with Adhesion >4, or

Viscosity (cp) is in the range of 15 to 20 cp, copper content (%) of conductive copper ink is 3-5%, and resistance (Ωcm) is <10 ^{- 3} (Ωcm), and you can select and use any one product among CUS131cd with Adhesion (B) >4.

Table 2 shows the properties, functions, and characteristics of conductive copper ink.

Product name Viscosity (cp) Copper Content (%) Resistance (Ωcm)(Resistance) Adhesion (B) cus101cd 26-30 9-11 <10 ^-3 >4 cus102cd 20-25 9-11 <10 ^-3 >4 cus131cd 15-20 3-5 <10 ^-3 >4

Functions and Features. Provides excellent mesh patterns.

.High conductivity realized with ink dedicated to optical sintering

.Low temperature hardening type

.Provides excellent adhesion and stable conductivity to glass, PET Flim, PI Flim, etc.

Figure 6b is a cross-sectional view showing the composition of the conductive silver nanowire ink, which is the 1c material printed on the first to eighth material planes, and when described with reference to the attached drawings,

The composition and characteristics of silver nanowire ink have a viscosity (cp) of <20,

A product of the AGNW 100 Series with a solid content of 0.1-1.0%, resistance of 40-200 (Ωcm), and drying temperature of 150 to 250 degrees Celsius. can be used.

Table 3 shows the properties, functions, and characteristics of silver nanowire ink.

Product name Viscosity (cp) Solid Content (%) Resistance (Ωcm)(Resistance) Drying Temperature AGNW 100 Series <20 0.1-1.0 40-200 120-250

-Function and features. Dispersion solution in which silver nanowires with a length of 20-30μm and a diameter of 25-40nm are dispersed in various solvents.

.High transmittance and excellent electrical conductivity

.Used for transparent conductive electrodes

Figure 6c is a cross-sectional view showing the manufacturing steps of the conductive silver ink composition as the 1d material printed on the first to eighth material planes. When explained with reference to the attached drawings, the conductive polymer composite ink composition is 100wt% of the total weight.

1. Amine compound selected from among amine compounds such as alkylamine, ethylene diamine, butylamine; 4.5 wt%

2. Short-chain carboxylic acid such as formic acid selected from the group consisting of formic acid, acetic acid, pentanoic acid, and butyric acid; 24.1 wt%

3. Silver powder or flake; 11-15wt%

4. Adhesion promoter such as hydroxyethyl cellulose; 1.4wt%

5. Viscosity regulators such as ethanol and ester; 51-55wt%

Manufacturing sequence of conductive ink

Step 1; Add 4.5 wt% of the total weight of an amine compound selected from among alkylamine, ethylene diamine, butylamine, etc. to a reactor (not shown) and stir with a stirrer (not shown).

Step 2; Add 11-15 wt% of the total weight of silver in powder or flakes to the reactor and dissolve the powder or flakes while stirring.

Step 3; If the viscosity of the solution is higher than the preset standard, adjust the viscosity by adding alcohol or ester in small amounts within the range of 51-55wt% of the total weight.

Step 4; Add 1.4 wt% of the total weight of an adhesion promoter such as hydroxyethyl cellulose and stir.

The adhesion promoter is the first material 110, the second material 120, the third material 130, the fourth material 140, the fifth material 150, the sixth material 160, and the seventh material ( 170), one of the eighth materials 180 promotes adhesion of the conductive ink printed on the surface of the selected material.

Step 5; Prepare conductive ink by adding 24.1 wt% of the total weight of a short-chain carboxylic acid such as formic acid selected from the group consisting of formic acid, acetic acid, pentanoic acid, and butyric acid and stirring for 1 hour and 2 hours. .

The silver powder is available from various commercial suppliers, such as Ames Goldsmith Corporation, Glens Falls, NY, USA, and Inframat Advanced Materials, Manchester, CT. Mixtures of different sizes of silver flakes can be used, such as a mixture of 1100-25, commercially available from Ames, and 47MR-23S, available from Inframat Advanced Materials, Manchester, Conn. there is. D50 and D95 are industry-accepted designations for silver with certain specific grain sizes.

D50 retains approximately 50% of silver particles below a certain size; D95 retains approximately 95% of silver particles below a certain size.

Adhesion promoters such as the above amine compounds, short-chain carboxylic acids, and hydroxyethylcellulose can be obtained from commercial sources such as Aldrich Chemical Co. (Milwaukee, Wl, USA) and Fisher Scienfic (Pittsburgh, PA, USA). .

The silver powder can be replaced with a metal powder selected from copper powder, carbon powder, and platinum powder.

The conductive ink is not limited to materials 1a, 1b, 1c, and 1d. If conductivity, adhesion, durability, etc. are secured, it can be replaced with a conductive solution of other composition.

Figure 6d is a cross-sectional view showing the type of conductive metal, which is a second material attached to the first to eighth material planes. When explained with reference to the accompanying drawings, a metal has malleability, has a luster inherent to metal, and conducts electricity. It is a general term for conductive materials. In general, metals are good conductors of heat and electricity, are opaque, have a metal-specific luster, and have the characteristic of being in a solid state with a crystalline structure at room temperature. In addition, it has the properties of being able to be spread thin like a plate and pulled out thin like a thread, that is, malleability and ductility. All of these characteristics appear due to a bond called metallic bond.

Metals that can be used in the present invention include beryllium and magnesium from groups 3.2 and 2 of the periodic table, neodymium, samarium, gadolinium and lutetium from groups 3.3 and 3, titanium, zirconium, hafnium and leaderpodium from groups 3.4.4 and 3.5.5. Tantalum, molybdenum in group 3.6.6, tungsten, manganese in group 3.7.7, technetium, iron and ruthenium in group 3.8.8, iridium in group 3.9.9, nickel, palladium, platinum in group 3.11.11. Copper, silver, gold of group 3.12.12, zinc of group 3.13.13, aluminum of group 3.14.14, silicon@, germanium@ of group 3.14.14, tin, antimony, bismuth of group 3.15.15, steel of alloys, duralumin, cupronickel, Stainless steel, bronze, shape memory alloy, brass, stainless steel (STS304, STS316), etc. can be used, but copper of group 3.11.11, silver, nickel of group 3.10.10, palladium, platinum, aluminum of group 13@, Alloy steel, duralumin, cupronickel, stainless steel, thin bronze, shape memory alloy, brass, stainless steel (STS304, STS316), etc. are suitable as materials for quantum energy generation coils. The @ above indicates a metalloid.

Figure 6e is a cross-sectional view showing the type of coated wire that is the third material of the quantum energy generating coil wound on the first to eighth material planes. When explained with reference to the attached drawings, the type of the coated conductive wire is

Classification codes A, A.A, ACSR wire, such as annealed copper wire (A), soft aluminum wire (A-AI), steel core aluminum stranded wire (ACSR), and lead-in steel core aluminum conductor polyethylene wire (ACSR-DV).

Copper vinyl wire for binding (BCV), iron vinyl wire for binding (BGV), butyl rubber insulated polyethylene sheath cable (BE), butyl rubber insulated polyethylene sheathed cable (BL), butyl rubber insulated soft chloroprene sheathed cable (BN), Type 2 butyl rubber insulated chloroprene cabtire cable (2BNCT), etc. Classification code BCV, BGV wire,

Classification codes for steel-coated aluminum wire (CA), polyethylene-insulated vinyl sheath cable (round) for direct burial in concrete (CB-EV), cross-linked polyethylene-insulated polyethylene sheathed cable (CE), copper-clad steel wire (CS), etc. CA, CV wire,

Classification codes DV, DVF for lead-in vinyl insulated wire, lead-in flat vinyl insulated wire, etc.

Classification code for polyethylene insulated polyethylene insulated external cables, etc. EE wire,

Classification codes for indoor large cords, vinyl wires for fluorescent discharge lights, etc. FF, FL wires,

Classification code for grounding vinyl wires, etc. GV wire,

Classification code H, HA wire for hard-dong wire, semi-dong wire, etc.

Classification codes for steel core A-type aluminum alloy wire, A-type aluminum alloy wire, etc. IACSR, I-AL wire,

Classification code MI wire for inorganic insulated cables (mineral insulation cables), etc.

*Classification codes for polyethylene vinyl neon wire, rubber chloroprene neon wire, etc. NEV, NRC wire,

Classification codes for cross-linked polyethylene insulated wire, polyethylene insulated wire, etc. OC, OE wire

Butyl rubber insulated wire for high pressure reduction, polyethylene insulated wire for high pressure reduction, classification code PDE, PDB wire,

600V rubber insulated wire, indoor round (welcome) cord, classification code RB, RF wire,

Classification code SA, SB wire for pole-annealed copper wire, 600V SB rubber insulated wire, etc.

Classification code TA, TF wire for tin-plated annealed copper wire, indoor two-stranded annealed copper wire, etc.

Classification codes for vinyl cabtire cables, vinyl cabtire cords, etc. VCT VCTF wire,

Use at least one type of wire among the classification codes WFF and WRF wires such as indoor moisture-proof large cord and indoor moisture-proof round cord.

The diameter of the wire is selected from a range of diameters from 100 μm to 5 cm. Additionally, a wire-type shape memory alloy can be used instead of the coated conductive metal wire. Since the wire-type shape memory alloy can expand when power is supplied from a power supply, it can be wound on the outer surface of a rod-shaped material or inside a cylinder. use.

Figure 7 is a diagram showing the step of forming a quantum energy generation coil by printing and drying with conductive ink in the shape of a quantum energy generation coil on the plane of the first material. When explained with reference to the attached drawing, the first material (110) ) The first method 210 is to form a quantum energy generating coil in the shape of a quantum energy generating coil with conductive ink on the surface.

Step 1: Material selection

Thin white paper includes window paper, sago paper, Yusam paper, Taemi paper, Sannae paper, Wansan paper, Kapyeong paper, Gyeonyang paper, etc. Gakji, which is a thick and strong paper made of two or more layers, is small wallpaper paper and daegak paper. ,It is an inner wallpaper, and the paper with a slightly thicker thickness is a wrapping paper, a young paper, a paper paper, a cotton paper, a raised paper, a new fuji paper, an external paper, a hejong paper, a paper paper, and a Hwanhon paper which is a recycled paper such as an insect repellent paper. You can use any one material of your choice among colored paper such as jade paper, red paper, yellow paper, blue paper, dark blue paper, and dark blue paper, and corrugated paper.

Step 2; Conductive ink selection

Conductive silver ink, which is the first a material shown in Figure 5,

Conductive copper ink, which is the 1b material shown in Figure 6a,

Conductive silver nanowire ink, which is the 1c material shown in Figure 6b,

Select one type of conductive ink from the conductive silver ink composition, which is the first material shown in Figure 6c.

The types of conductive ink that form the quantum energy generating coil shape include conductive silver ink, conductive copper ink, silver nanowire ink, and conductive silver ink composition. It is not limited to this and is only an example, and all conductive inks with similar or higher qualities such as conductivity, physical and chemical properties, workability, dryness, and adhesion to the conductive ink exemplified above can be used.

Step 3; Printing step

Using Sprayable Tech technology and stencil technology, one material among copper, aluminum, tin, stainless steel (STS304), and coated steel plate is selected in advance, and the selected material is Using model picking technology using a laser, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, and motor stator coil. Coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and combinations of these shapes. Mark with a shape selected from among the coil shapes, or place a perforated model frame and apply conductive ink on the model frame using any of the following methods: flexography, screen printing, offset printing, rotary press, inkjet printing, or dry printing. Select one printing method and print with a thickness of 10 to 30 μm on the surface of the first material (paper), then remove the model frame. Alternatively, using the transfer printing (decalcomania) method, that is, the offset printing method, adhesive (special glue) is applied to the paper surface in advance, and the transfer paper with the quantum energy generating coil printed with a metal selected from gold foil, copper foil, or silver foil is printed on the paper. After attaching to the surface, peel off any excess paper except for the quantum energy generating coil part of the transfer paper and complete it.

The Sprayable Tech technology is a technology developed by researchers at the Massachusetts Institute of Technology (MIT) in the United States. It sprays conductive ink on the surface of an object (e.g. paper, wall, glass) desired by the user, allowing the necessary The goal is to create a form of interface (e.g. TV remote control, light switch).

The stencil technique is a type of printmaking technique that originated from the meaning of stamping letters as a design technique. Transfer the drawing onto thick paper or film, dig out the drawing part and punch a hole, or cut it out with a knife and place it on the desired location. Using acrylic paint, rub it with a roller, tap it with a plump, pointed brush, or paint it with a brush to create the shape of the object by rotating it.

Step 4: Drying step; Dry in a dryer (not shown) at a temperature ranging from 50 degrees to 150 degrees for 1 to 2 hours.

Or, on the surface of the quantum energy generating coil printed on the surface of the finished paper, melamine formaldehyde resin (MF), urea formaldehyde resin (UF), urea-melamine-formaldehyde resin (UMF), acrylic resin, phenol-based resin, polyester. Among resins and mixed resins, one type of resin can be selected and sprayed onto the printed quantum energy generating coil using a spray gun supplied with pneumatic pressure and dried in a dryer to form a protective layer for the quantum energy generating coil. .

Alternatively, the quantum energy generation coil is printed on the surface of the first material 110 with a conductive ink solution, but the special print is applied on the surface of the paper material, and then the eighth material 180 with the quantum energy generation coil printed on the transparent film is printed. It can be attached.

The number of quantum energy generating coils formed on the surface of one material by the first method may be one, or a plurality of quantum energy generating coils may be formed.

Figure 8a is a schematic diagram showing a method of forming a quantum energy generating coil by printing conductive ink in the shape of a quantum energy generating coil on the surface of the second material. When explained with reference to the attached drawing, the selected second material (120) ) The second method (220) is to form a quantum energy generation coil by printing and drying conductive ink on the surface in the selected quantum energy generation coil shape using a printer.

Step 1: Material selection

Select one of the secondary materials of non-conductive materials such as PVC, PE, PC, acrylic, and Beck.

Step 2: Surface grinding step;

The specific surface on which the quantum energy generating coil will be printed or the entire surface of the selected plate or bar is ground with a sand grinder.

Step 3: Washing step;

After removing fine dust from the ground part with a vacuum cleaner, use a solvent such as ethyl alcohol or isopropyl alcohol to remove surface impurities.

Step 4: Conductive ink selection step

Conductive silver ink, which is the first a material shown in Figure 5,

Conductive copper ink, which is the 1b material shown in Figure 6a,

Conductive silver nanowire ink, which is the 1c material shown in Figure 6b,

Select one type of conductive ink from the conductive silver ink composition, which is the first material shown in Figure 6c.

The types of conductive ink that form the quantum energy generating coil shape include conductive silver ink, conductive copper ink, silver nanowire ink, and conductive silver ink composition. It is not limited to this and is only an example, and all conductive inks with similar or higher qualities such as conductivity, physical and chemical properties, workability, dryness, and adhesion to the conductive ink exemplified above can be used.

Step 5: Printing step

Using Sprayable Tech technology and stencil technology, any one of the following materials can be prepared in advance: thick paper, film (PVC, PE), copper, aluminum, tin, stainless steel (STS304), or coated steel plate. This selected material was selected using model picking technology using laser to produce soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag coil. (Up and down, left and right), extension type coil, motor stator type coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil ), Marking with a shape selected from among Rogoski coil shapes and combinations of these shapes, or placing a perforated model frame and applying a conductive solution on the model frame through flexography and screen printing. Select one printing method among offset printing, rotary press, inkjet printing, and dry printing, select one type of material from non-conductive materials such as PVC, PE, PC, acrylic, and baking, and apply it to the surface of the selected material. After printing at a thickness of 10 to 30 μm, the model frame is removed.

Alternatively, using the decalcomania method, that is, the offset printing method, adhesive (special glue) is applied to the surface of the paper in advance, and the transfer paper with the quantum energy generating coil printed with a metal selected from gold foil, copper foil, or silver foil is printed on the paper. After attaching to the surface, peel off any excess paper except for the quantum energy generating coil part of the transfer paper and complete it.

Alternatively, instead of printing the quantum energy generating coil with a conductive solution (ink liquid) on the surface of the second material, apply a special adhesive or adhesive on the surface of the paper material and then attach the eighth material printed with the quantum energy generating coil on the transparent film. You can.

The Sprayable Tech technology is a technology developed by researchers at the Massachusetts Institute of Technology (MIT) in the United States. By spraying conductive ink on the surface of an object (e.g. paper, wall, glass) desired by the user, it can be freely used as needed. The goal is to create a form of interface (e.g. TV remote control, light switch).

The stencil technique is a type of printmaking technique that originated from the meaning of stamping letters as a design technique. Transfer the drawing onto thick paper or film, dig out the drawing part and perforate it, or cut it out with a knife and place it on the desired place with acrylic. Using paint, the shape of an object is stamped by rubbing it with a roller, tapping it with a plump, pointed brush, or painting it with a brush.

Step 6: Drying step;

Dry in a dryer (not shown) at a temperature ranging from 50 to 150 degrees Celsius for 1 to 2 hours.

Or, on the surface of the quantum energy generating coil printed on the surface of the finished paper, melamine formaldehyde resin (MF), urea formaldehyde resin (UF), urea-melamine-formaldehyde resin (UMF), acrylic resin, phenol-based resin, polyester. Among resins and mixed resins, one type of resin can be selected and sprayed on the printed quantum energy generating coil using a spray gun supplied with pneumatic pressure and dried in a dryer to form a protective layer for the quantum energy generating coil. .

In the second method, the number of quantum energy generating coils formed on the surface of one material may be one, or a plurality of quantum energy generating coils may be formed.

Figure 8b is a schematic diagram showing a method of forming a quantum energy generating coil by printing conductive ink in the shape of a quantum energy generating coil on the surface of the third material. When explained with reference to the attached drawing, the selected third material (130) ) The third method (230) is to form a quantum energy generation coil by printing and drying conductive ink on the surface in the selected quantum energy generation coil shape using a printer.

Step 1: Material selection

Iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel 304, 316, hastalloy, panel with insulation or cold insulating material, aluminum (AL), titanium (Ti), nickel (Ni), Select one of the three metal materials such as platinum (Pt).

Step 2: Washing step;

After removing fine dust from the metal surface with a vacuum cleaner, use a solvent such as ethyl alcohol or isopropyl alcohol to remove surface impurities.

Step 3: Preparing conductive ink

Conductive silver ink, which is the first a material shown in Figure 5,

Conductive copper ink, which is the 1b material shown in Figure 6a,

Conductive silver nanowire ink, which is the first c material shown in Figure 6b,

Select one type of conductive ink from the conductive silver ink composition, which is the first material shown in Figure 6c.

The types of conductive ink that form the quantum energy generating coil shape include conductive silver ink, conductive copper ink, silver nanowire ink, and conductive silver ink composition. It is not limited to this and is only an example, and all conductive inks with similar or higher qualities such as conductivity, physical and chemical properties, workability, dryness, and adhesion to the conductive ink exemplified above can be used.

Step 4: Printing step

Using Sprayable Tech technology and stencil technology, any of thick paper, film (PVC, PE), copper, aluminum, tin, stainless steel (STS304), or coated iron plate can be used in advance. One material is selected, and the selected material is used to create a cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, Troid coil, Maxwell coil, trigger coil, and zigzag-shaped coil (top and bottom) using model picking technology using a laser. , left and right), place a model frame perforated in a shape selected from among the extension-type coil, motor stator-type coil, square coil, RF coil, toroidal coil shape, and a combination of these shapes. Conductive ink is sprayed onto the model frame and printed to a thickness of 10 to 30 μm on the surface of the material, and then the model frame is removed, or the selected quantum energy generating coil shape is entered into the microcomputer for flexography, screen printing, offset printing, and rotary grinder. , Select one of the inkjet printing and dry printing methods and print with a thickness of 10 to 30μm on the surface of the material.

Alternatively, using the decalcomania method, that is, the offset printing method, adhesive (special glue) is applied to the surface of the paper in advance, and the transfer paper with the quantum energy generating coil printed with a metal selected from gold foil, copper foil, or silver foil is printed on the paper. After attaching to the surface, peel off the excess paper except for the quantum energy generating coil part of the transfer paper and complete it.

Step 5: Drying step

Dry in a dryer (not shown) at a temperature ranging from 50 to 150 degrees Celsius for 1 to 2 hours.

Or, print the quantum energy generation coil with a conductive solution (ink liquid) on the surface of the third material, apply a special adhesive or adhesive on the surface of the paper material without printing, and then attach the eighth material with the quantum energy generation coil printed on the transparent film. can do.

In the third method, the number of quantum energy generating coils formed on the surface of one material may be one, or a plurality of quantum energy generating coils may be formed.

Figure 8c is a schematic diagram showing a method of forming a quantum energy generating coil by printing conductive ink in the shape of a quantum energy generating coil on the surface of the fourth material. When explained with reference to the attached drawing, the selected fourth material (140) ) The fourth method (240) is to form a quantum energy generation coil by printing and drying conductive ink on the surface in the selected quantum energy generation coil shape using a printer.

Step 1: Material selection

Select a board with a certain thickness or a bar with a certain diameter from among the fourth materials such as general plywood, Douglas pine plywood, core plywood, larch plywood, MDF, and particle board.

Step 2: Grinding step

Using an electric woodworking sanding machine, grind the surface to be coated in the shape of a quantum energy generating coil of wood plywood selected from wood plywood such as general plywood, Douglas fir plywood, core plywood, larch plywood, MDF, and particle board.

Step 3: Washing step

After removing fine dust from the ground part with a vacuum cleaner, use a solvent such as ethyl alcohol or isopropyl alcohol to remove surface impurities.

Step 4: Varnish application (resin) step

After selecting one type of varnish among wood varnish, oil-based varnish for wood, urethane varnish, urethane varnish for wood, and wood varnish, distribute an appropriate amount of varnish into a small container, add solvent (thinner) to adjust the viscosity, and then apply pneumatic pressure. Using a spray gun, varnish is sprayed to a certain thickness on the ground surface.

Step 5: Drying step

Remove the model frame and dry naturally or at low temperature using a dryer (not shown).

Step 6: Preparing conductive ink

Conductive silver ink, which is the first a material shown in Figure 5,

Conductive copper ink, which is the 1b material shown in Figure 6a,

Conductive silver nanowire ink, which is the 1c material shown in Figure 6b,

Select one type of conductive ink from the conductive silver ink composition, which is the first material shown in Figure 6c.

The types of conductive ink that form the quantum energy generating coil shape include conductive silver ink, conductive copper ink, silver nanowire ink, and conductive silver ink composition. It is not limited to this and is only an example, and all conductive inks with similar or higher qualities such as conductivity, physical and chemical properties, workability, dryness, and adhesion to the conductive ink exemplified above can be used.

Step 7: Printing step

Using Sprayable Tech technology and stencil technology, any one of the following materials can be prepared in advance: thick paper, film (PVC, PE), copper, aluminum, tin, stainless steel (STS304), or coated steel plate. This selected material was selected using model picking technology using laser to produce soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag coil. (Up and down, left and right), extension type coil, motor stator type coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil ), Rogoski coil shapes and combinations of these shapes, place a model frame perforated in a shape selected from among the coil shapes, spray a conductive solution on the model frame, and remove the model frame, or select the selected coil shape. The shape of the quantum energy generating coil is entered into the microcomputer, and a printing method of 10 to 30 μm is printed on the surface of the material by selecting one of the following printing methods: flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing.

Alternatively, using the decalcomania method, that is, the offset printing method, adhesive (special glue) is applied to the surface of the paper in advance, and the transfer paper with the quantum energy generating coil printed with a metal selected from gold foil, copper foil, or silver foil is printed on the paper. After attaching to the surface, peel off any excess paper except for the quantum energy generating coil part of the transfer paper and complete it.

Step 8: Drying step

Dry in a dryer (not shown) at a temperature ranging from 50 to 150 degrees Celsius for 1 to 2 hours.

Or, without printing a quantum energy generating coil using a conductive solution (ink liquid) on the surface of the fourth material.

After applying a special adhesive or adhesive on the surface of the paper material, the eighth material printed with a quantum energy generation coil can be attached to the transparent film.

In the fourth method, the number of quantum energy generating coils formed on the surface of one material may be one, or a plurality of quantum energy generating coils may be formed.

Figure 8d is a schematic diagram showing a method of forming a quantum energy generating coil by printing conductive ink in the shape of a quantum energy generating coil on the surface of the fifth material. When explained with reference to the attached drawing, the selected fifth material (150) ) The fifth method (250) is to form a quantum energy generation coil by printing and drying conductive ink on the surface in the selected quantum energy generation coil shape using a printer.

Step 1: Material selection

The fifth material is a plate with a certain thickness or a bar with a certain diameter made of one of the inorganic materials such as concrete, tiles, blocks, boards, stones (marble exterior materials, etc.).

How to print a quantum energy generating coil

1Surface sanding step

Using an electric sanding machine, sand the surface of a concrete wall, tile, or stone (marble exterior material, etc.) to remove irregularities or create scratches on the surface to facilitate adhesion of the resin layer.

Step 2: Washing step

After removing fine dust from the ground part with a vacuum cleaner, use a solvent such as ethyl alcohol or isopropyl alcohol to remove surface impurities (excluding tiles).

Step 3: Water-soluble resin or primer application step

On the ground and cleaned surface, mix an appropriate amount of solvent and hardener with water-soluble resin (acrylic resin) or a commercially available base primer from each paint manufacturer, apply twice, and dry naturally or in a dryer for small tiles.

Step 4: Manufacturing step of conductive resin

The production of conductive resin is based on 100wt% of total dry weight.

A binder selected from acrylic polymer, polymetal methacrylate, styrene butadiene, vinyl acetate, polyamide, nitrocellulose, polyvinyl alcohol, starch, etc.; 30-50wt%, with

Polyvinyl alcohol (PVA), carboxymethyl cellulose (CMC), hydroxy methyl cellulose (HMC), acrylic copolymer, gelatin, alginate, soybean, protein, galactomannan, nanocellulose, polysaccharide Thickening agents such as ride, crosslinked polyacrylate, polyvinyl pidolidol, and hydrothoxylated urethane; 5 to 13 wt% and

Metal fine powders with conductivity and oxygen absorption properties such as silver (Ag), copper (Cu), carbon powder (C), zinc (Zn), polyaniline (PAni), iron (Fe), and conductive polymers; It is prepared by adding 37 to 65 wt% into the reactor and stirring to adjust the viscosity.

Step 5: Preparing conductive ink

Conductive silver ink, which is the first a material shown in Figure 5,

Conductive copper ink, which is the 1b material shown in Figure 6a,

Conductive silver nanowire ink, which is the 1c material shown in Figure 6b,

Select one type of conductive ink from the conductive silver ink composition, which is the first material shown in Figure 6c.

The types of conductive ink that form the quantum energy generating coil shape include conductive silver ink, conductive copper ink, silver nanowire ink, and conductive silver ink composition. It is not limited to this and is only an example, and all conductive inks with similar or higher qualities such as conductivity, physical and chemical properties, workability, dryness, and adhesion to the conductive ink exemplified above can be used.

Step 6: Printing step

Using Sprayable Tech technology and stencil technology, any of thick paper, film (PVC, PE), copper, aluminum, tin, stainless steel (STS304), or coated iron plate can be used in advance. One material is selected, and the selected material is made into soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag shape using model picking technology using laser. coils (up and down, left and right), extension coils, motor stator coils, square coils, RF coils, toroidal coils, Tesla coils, Mobius coils, Caduceus coils ( Place a model frame perforated in a shape selected from among Caduceus Coil, Rogoski coil and combinations of these shapes and pour a conductive solution onto the model frame.

After spraying, remove the model frame or select one of the printing methods among flexography, screen printing, offset printing, rotary grinder, inkjet printing, and dry printing with the selected quantum energy generating coil shape entered into the microcomputer. It is printed at a thickness of 10 to 30 μm on the surface of the material (paper).

Alternatively, an adhesive (not shown) is applied to the surface of the paper in advance using a transfer printing (decalcomania) method, that is, an offset printing method, and the transfer paper on which the quantum energy generating coil is printed using a metal selected from gold foil, copper foil, silver foil, etc. After attaching to the surface, peel off any excess paper except for the quantum energy generating coil part of the transfer paper and complete it.

The adhesive is a transparent adhesive and is used by selecting one of bisphenol A-based acrylate compounds, alkoxysilyl-based acrylate compounds, and silicone adhesives.

Step 7: Drying step

Dry in a dryer (not shown) at a temperature ranging from 50 to 150 degrees Celsius for 1 to 2 hours.

Step 8: Protective layer formation step

Apply acrylic resin for surface protection twice to the surface where the conductive coating liquid was sprayed in the shape of a quantum coil to form a protective layer and then dry naturally.

Or, instead of printing the quantum energy generating coil with a conductive solution (ink liquid) on the surface of the fifth material 150, apply a special adhesive or adhesive on the surface of the material, and then print the quantum energy generating coil on the transparent film. 180) can be attached.

The number of quantum energy generating coils formed on the surface of one material by the fifth method may be one, or a plurality of quantum energy generating coils may be formed.

Figure 8e is a schematic diagram showing a method of forming a quantum energy generating coil by printing conductive ink in the shape of a quantum energy generating coil on the surface of the sixth material. When explained with reference to the attached drawing, the selected sixth material (160) ) The sixth method (260) is to form a quantum energy generation coil by printing and drying conductive ink on the surface in the selected quantum energy generation coil shape using a printer.

Step 1; Material selection

One of the 6 materials (160) such as vegetable fiber, vegetable fiber, mineral fiber, regenerated fiber, synthetic fiber, and inorganic fiber is selected.

Step 2: Washing step

After removing fine dust with a vacuum cleaner, remove surface impurities using a solvent such as ethyl alcohol or isopropyl alcohol.

Step 3: Preparing conductive ink

Conductive silver ink, which is the first a material shown in Figure 5,

Conductive copper ink, which is the 1b material shown in Figure 6a,

Conductive silver nanowire ink, which is the 1c material shown in Figure 6b,

Select one type of conductive ink from the conductive silver ink composition, which is the first material shown in Figure 6c.

The types of conductive ink that form the quantum energy generating coil shape include conductive silver ink, conductive copper ink, silver nanowire ink, and conductive silver ink composition. It is not limited to this and is only an example, and all conductive inks with similar or higher qualities such as conductivity, physical and chemical properties, workability, dryness, and adhesion to the conductive ink exemplified above can be used.

Step 4: Printing step

Using Sprayable Tech technology and stencil technology, any of thick paper, film (PVC, PE), copper, aluminum, tin, stainless steel (STS304), or coated iron plate can be used in advance. One material is selected, and the selected material is used to create cusp coils, Helmheltz coils, gradient saddle coils, uniform saddle coils, toroid coils, trigger coils, and zigzag coils (up and down, left and right) using model picking technology using lasers. , Extension type coil, motor stator type coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogowski coil. (Rogoski coil) shape or a combination of these shapes, place a model frame perforated in a selected shape among coil shapes, spray conductive ink on the model frame, and then remove the model frame, or select a quantum energy generating coil. Select one of the following printing methods from flexography, screen printing, offset printing, rotary grinder, inkjet printing, and dry printing, where the shape is entered into the microcomputer, and print it on the surface of the material with a thickness of 10 to 30 μm.

Step 5: Drying step

Dry in a dryer (not shown) at a temperature ranging from 50 to 150 degrees Celsius for 1 to 2 hours. Or, instead of printing a quantum energy generating coil with a conductive solution (ink liquid) on the surface of the sixth material 160, a special adhesive or adhesive is applied to the surface of a paper material, and then the quantum energy generating coil is printed on a transparent film. (180) can be attached.

The number of quantum energy generating coils formed on the surface of one material by the sixth method may be one, or a plurality of quantum energy generating coils may be formed.

Figure 8f is a schematic diagram showing a method of forming a quantum energy generating coil by printing conductive ink in the shape of a quantum energy generating coil on the surface of the seventh material. When explained with reference to the attached drawing, the selected seventh material (170 ) The seventh method (270) is to form a quantum energy generation coil by printing and drying conductive ink on the surface in the selected quantum energy generation coil shape using a printer.

Step 1: Material selection

Select and use one material among the 7th materials (170) such as thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, and blocking glass.

Step 2: Washing step

After removing fine dust from the metal surface with a vacuum cleaner, use a solvent such as ethyl alcohol or isopropyl alcohol to remove surface impurities.

Step 3: Preparing conductive ink

Conductive silver ink, which is the first a material shown in Figure 5,

Conductive copper ink, which is the 1b material shown in Figure 6a,

Conductive silver nanowire ink, which is the 1c material shown in Figure 6b,

Select one type of conductive ink from the conductive silver ink composition, which is the first material shown in Figure 6c.

The types of conductive ink that form the quantum energy generating coil shape include conductive silver ink, conductive copper ink, silver nanowire ink, and conductive silver ink composition. It is not limited to this and is only an example, and all conductive inks with similar or higher qualities such as conductivity, physical and chemical properties, workability, dryness, and adhesion to the conductive ink exemplified above can be used.

Step 4: Printing step

Using Sprayable Tech technology and stencil technology, any of thick paper, film (PVC, PE), copper, aluminum, tin, stainless steel (STS304), or coated iron plate can be used in advance. One material is selected, and the selected material is made into soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag shape using model picking technology using laser. coils (up and down, left and right), extension coils, motor stator coils, square coils, RF coils, toroidal coils, Tesla coils, Mobius coils, Caduceus coils ( Place a model frame perforated in a shape selected from among Caduceus Coil, Rogoski coil shapes, and combinations of these shapes, spray conductive ink on the model frame, and then remove the model frame. Alternatively, select one of the printing methods among flexography, screen printing, offset printing, web press, inkjet printing, and dry printing with the selected quantum energy generating coil shape input into the microcomputer and print it on the surface of the material at a thickness of 10 to 30 μm. do.

Alternatively, an adhesive (not shown) is applied to the surface of the paper in advance using a transfer printing (decalcomania) method, that is, an offset printing method, and the transfer paper on which the quantum energy generating coil is printed using a metal selected from gold foil, copper foil, silver foil, etc. After attaching to the surface, peel off any excess paper except for the quantum energy generating coil part of the transfer paper and complete it.

Step 5: Drying step

Dry in a dryer (not shown) at a temperature ranging from 1 hour to 2 hours.

Alternatively, instead of printing the quantum energy generating coil with a conductive solution (ink liquid) on the surface of the seventh material 170, adhesive is applied on the surface of the paper material and then the seventh material printed with the quantum energy generating coil is attached to the transparent film. You can.

The number of quantum energy generating coils formed on the surface of one material by the seventh method may be one, or a plurality of quantum energy generating coils may be formed.

Figure 8g is a schematic diagram showing a method of forming a quantum energy generating coil by printing conductive ink on the surface of the eighth material in the shape of a quantum energy generating coil using a printer. When explained with reference to the attached drawings, the selected material The eighth method (280) is to form a quantum energy generation coil by printing and drying conductive ink on the surface of the material (180) in the selected quantum energy generation coil shape using a printer.

Step 1: Material selection

Select and use one material among transparent 8 materials such as polyimide, PET (polyethyleneTerephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film. .

Step 2: Surface cleaning step

Use a vacuum cleaner to remove dust or foreign substances attached to the surface of the material.

Step 3: Preparing conductive ink

Conductive silver ink, which is the first a material shown in Figure 5,

Conductive copper ink, which is the 1b material shown in Figure 6a,

Conductive silver nanowire ink, which is the 1c material shown in Figure 6b,

Select one type of conductive ink from the conductive silver ink composition, which is the first material shown in Figure 6c.

The types of conductive ink that form the quantum energy generating coil shape include conductive silver ink, conductive copper ink, silver nanowire ink, and conductive silver ink composition. It is not limited to this and is only an example, and all conductive inks with similar or higher qualities such as conductivity, physical and chemical properties, workability, dryness, and adhesion to the conductive ink exemplified above can be used.

Step 4: Printing step

Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, Zigzag coil Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil (up and down, left and right), extension coil, motor stator type Coil, square coil, RF coil, toroidal coil, shape, and a combination of these shapes. A shape selected from among coil shapes, and a film thickness on the surface of the material; Print under the following conditions: 4-10 μm, line width; 50-80 μm, volume resistivity; 4-10μΩ*cm

Step 5: Drying step

Photo Sintering firing method is used to dry at a firing time of 0.1-10m/sec, or Reflow Using formic acid vapor is used to make a transparent material by firing (drying) at 200 degrees Celsius for 10 minutes in a nitrogen gas with formic acid vapor atmosphere. A quantum energy generating coil completes the printed material.

Alternatively, apply adhesive (special glue) to the surface of the material from which dust or foreign substances attached to the material surface have been removed or to the surface of the paper using a transfer printing (decalcomania) method, that is, an offset printing method, and then apply one type of gold foil, copper foil, silver foil, etc. The type of metal selected is soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, and electric motor. Stator coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and their shapes The transfer paper with the quantum energy generating coil printed in a shape selected from among the combinations of shapes is attached to the surface of the paper, and then the transfer paper is completed by peeling off all the excess paper except for the quantum energy generating coil part.

The number of quantum energy generating coils formed on the surface of one material by the eighth method may be one, or a plurality of quantum energy generating coils may be formed.

Figure 8h shows a conductive metal plate such as copper (Cu) on the surfaces of the first material, second material, third material, fourth material, fifth material, sixth material, seventh material, and eighth material in the shape of a quantum energy generating coil. As the 9a method of manufacturing a quantum energy generating coil by attaching it to the surface of a material by punching it, when explained with reference to the attached drawing,

Step 1: Material selection

1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), Select one material out of 8 materials (180).

Step 2: Quantum energy generation coil shape selection step:

Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, Square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. Select one of the coil shapes.

Step 3: Quantum energy generation coil manufacturing steps:

Iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), titanium (Ti), nickel (Ni), platinum (Pt), Hastal One material is selected from among the Lloyd materials, and a quantum energy generating coil processed into the selected coil shape is manufactured using the selected material using a laser.

Step 4: Quantum energy generation coil attachment steps:

After applying adhesive (not shown) to the surface of the material selected in step 1, the quantum energy generating coil manufactured in step 3 is attached using a compression press (not shown) or by manpower.

Step 5: Drying step

In step 4, the quantum energy generating coil and material attached to the surface of the material are dried in a dryer (not shown) at a temperature in the range of 50 to 150 degrees Celsius for 1 to 2 hours or naturally dried.

The adhesive is a transparent adhesive and is used by selecting one of bisphenol A-based acrylate compounds, alkoxysilyl-based acrylate compounds, and silicone adhesives.

The number of quantum energy generating coils formed by perforating the surface of one metal material using the method of 9a may be one, or a plurality of quantum energy generating coils may be formed.

Figure 8i shows materials in the form of quantum energy generating coils using wires coated on the surfaces of the first material, second material, third material, fourth material, fifth material, sixth material, seventh material, and eighth material. The 9b method of manufacturing a quantum energy generating coil by applying adhesive (not shown) to the surface and then winding it into the selected quantum energy generating coil shape. When explained with reference to the attached drawings, the 9b method is

Step 1: Material selection

1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), Select one material out of 8 materials (180).

Step 2: Quantum energy generation coil shape selection step:

Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, Square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and combinations of these shapes. Select one of the coil shapes.

Step 3: Adhesive application step:

Apply adhesive to the area where the selected quantum energy generating coil will be formed.

Step 4: Quantum energy generation coil manufacturing steps:

A quantum energy generating coil is manufactured by winding a conductive metal wire covered with the selected coated conductive metal wire in the shape of the quantum energy generating coil selected in step 2 over the area to which the adhesive was applied in step 3, or

Alternatively, another method of manufacturing a quantum energy generating coil using an electroluminescence device is commercially available from Nistech Co., Ltd. (427 Gosan-ri, Opo-eup, Gwangju-si, Gyeonggi-do), a specialized manufacturer of electroluminescence devices. Quantum energy generating coils are manufactured by winding using ELWire, which consists of a center electrode, light-emitting layer, surface electrode, protection tube, wire, and color layer.

Step 5: Drying step

In step 4, the quantum energy generating coil and material attached to the surface of the material are dried in a dryer (not shown) at a temperature in the range of 50 to 150 degrees Celsius for 1 to 2 hours or naturally dried.

The adhesive is a transparent adhesive and is used by selecting one of bisphenol A-based acrylate compounds, alkoxysilyl-based acrylate compounds, and silicone adhesives.

Figure 8j shows conductivity on the surface of the 8th material (first material, 2nd material), 3rd material, 4th material, 5th material, 6th material, 7th material, and 8th material as shown in Figure 8g. This is a cross-sectional view showing the 9c method of manufacturing a quantum energy generating coil by printing ink. When explained with reference to the attached drawing,

Step 1: Material selection

Which of the first material (110), second material (120), third material (130), fourth material (140), fifth material (150), sixth material (160), and seventh material (170) Select one material.

Step 2: Adhesive application step:

Method 8: Apply adhesive to the area where the quantum energy generating coil will be attached by printing conductive ink on the surface of the material (method 8).

Step 3: Quantum energy generation coil attachment step:

After applying adhesive (not shown) to the surface of the material selected in step 1, the quantum energy generating coil manufactured by method 8 in step 2 is laminated on the surface of the material to which the adhesive has been applied, and then used a compression press (not shown). Or attach it by manpower.

Step 4: Drying step

In step 4, the quantum energy generating coil and material attached to the surface of the material are dried in a dryer (not shown) at a temperature in the range of 50 to 150 degrees Celsius for 1 to 2 hours or naturally dried.

The number of quantum energy generating coils formed on the surface of one material by the method of the 9th c may be one, or a plurality of quantum energy generating coils may be formed.

The adhesive is a transparent adhesive and is used by selecting one of bisphenol A-based acrylate compounds, alkoxysilyl-based acrylate compounds, and silicone adhesives.

Figure 8k is a cross-sectional view showing the 9d method of manufacturing a quantum energy generating coil using an electroluminescence device. When explained with reference to the attached drawings,

Step 1: Configuration of Electroluminescence Device

The electroluminescence device consists of a transparent substrate (1), a first electrode (2), an electroluminescence layer (3), a second electrode (4), and a protective layer (5).

Step 2: Select the shape of the first and second electrodes

Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, Caduceus coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, (Caduceus Coil), Rogoski coil, and combinations of these shapes. Select one coil shape among

Step 3: Processing and stacking of the first and second electrodes

A first electrode (2) is formed in the form of a quantum energy generating coil-shaped stripe on the transparent substrate (1), and an organic electroluminescent layer (3) is formed on the first electrode (2). On (3), the second electrode (4) is a structural layer formed in the form of a stripe in the shape of a quantum energy generating coil.

Step 4: Patterning (oattering) step

ITO (Indium Tin Oxide) is generally used as the first electrode 2, and ITO can be easily and precisely patterned using a photolithography process used in the semiconductor manufacturing process.

Step 5: Organic electroluminescent layer (3) layer step

An organic electroluminescent layer (3) is formed on the first electrode (2).

A shadow mask is used on the organic electroluminescent layer (3) on the first electrode (2) to form a shape identical to that of the quantum energy generating coil formed on the first electrode (2) on the second electrode (4). do.

Step 6: Etching step

The organic electroluminescent layer in the middle area between the second electrode 4 and the second electrode 4 using dry etching methods such as plasma etching, ion milling, and laser etching. A quantum energy generating device that emits electroluminescence is manufactured by etching (3) to a depth sufficient to remove the second electrode material (4).

Alternatively, another method of manufacturing a quantum energy generating coil using an electroluminescence device is commercially available from Nistech Co., Ltd. (427 Gosan-ri, Opo-eup, Gwangju-si, Gyeonggi-do), a specialized manufacturer of electroluminescence devices. The protective layer, the back electrode made of carbon, the insulating layer, the light-emitting layer made of ZnS, the back electrode and surface electrode of the EL sheet made of PET are composed of soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, Uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil, Moe. Any one coil shape can be selected among Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, and transformed to have the selected shape. .

The number of quantum energy generating coils formed on the material surface of each of the first and second electrodes manufactured by the method of the 9d may be one, or a plurality of quantum energy generating coils may be formed.

Figure 8L is a cross-sectional view showing a method of manufacturing a quantum energy generation coil of the sealed structure. When explained with reference to the attached drawings, the 9e method of manufacturing the quantum energy generating coil of the sealed structure is

Step 1: Selection of material

Second material (120), iron (Fe), copper (Cu), zinc (Zn), tin (Sn), which is a non-conductive material such as PVC, PE, PC, acrylic, bakelite, and reinforced glass foam (FRP). , The third material (130) is a metal material such as stainless steel (STS304, STS316), aluminum (AL), hastalloy, a panel with insulation or cold insulation, and inorganic materials such as concrete wall, tile, block, brick, and board. 5th material (150), thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, 7th material (170) such as blocking glass, polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS Select one material from the 8th material (180) of transparent materials such as (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film.

Step 2: Grinding and cleaning step

The second material (120) is a non-conductive material such as PVC and PE, the third material (130) is a metal material such as iron (Fe) and copper (Cu), and the inorganic material such as concrete wall, tile, block, brick, and board. The material selected among the fifth materials 150 is a seventh material 170 such as thick plate glass, which is made by grinding the part where the quantum energy generating coil will be formed using an electric sanding machine and removing dust using a vacuum cleaner, and polyimide. For the material selected from among the eighth materials 180, such as (polyimide), foreign substances are removed from the area where the quantum energy generating coil is to be formed using a cleaning solution such as isopropyl alkoxy.

Step 3: Preparing conductive ink

Conductive silver ink, which is the first a material shown in Figure 5,

Conductive copper ink, which is the 1b material shown in Figure 6a,

Conductive silver nanowire ink, which is the first c material shown in Figure 6b,

Select one type of conductive ink from the conductive silver ink composition, which is the first material shown in Figure 6c.

The types of conductive ink that form the quantum energy generating coil shape include conductive silver ink, conductive copper ink, silver nanowire ink, and conductive silver ink composition. It is not limited to this and is only an example, and all conductive inks with similar or higher qualities such as conductivity, physical and chemical properties, workability, dryness, and adhesion to the conductive ink exemplified above can be used.

Step 4: Printing step

Using Sprayable Tech technology and stencil technology, any of thick paper, film (PVC, PE), copper, aluminum, tin, stainless steel (STS304), or coated iron plate can be used in advance. One material is selected, and the selected material is made into soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag shape using model picking technology using laser. coils (up and down, left and right), extension coils, motor stator coils, square coils, RF coils, toroidal coils, Tesla coils, Mobius coils, Caduceus coils ( Place a model frame perforated in a shape selected from among Caduceus Coil, Rogoski coil shapes, and combinations of these shapes, spray conductive ink on the model frame, and then remove the model frame. Alternatively, select one of the printing methods among flexography, screen printing, offset printing, web press, inkjet printing, and dry printing with the selected quantum energy generating coil shape input into the microcomputer and print it on the surface of the material at a thickness of 10 to 30 μm. do.

Alternatively, using the decalcomania method, that is, the offset printing method, adhesive (special glue) is applied to the surface of the paper in advance, and the transfer paper with the quantum energy generating coil printed with a metal selected from gold foil, copper foil, or silver foil is printed on the paper. After attaching to the surface, peel off the excess paper except for the quantum energy generating coil part of the transfer paper to complete it.

Step 5: Drying step

Dry in a dryer (not shown) at a temperature ranging from 1 hour to 2 hours.

Step 6;Sealing structure production step

The second material 120, which is a non-conductive material such as PVC, PE, PC, acrylic, bakelite, and reinforced glass foam (FRP), with a quantum energy generating coil formed on the surface, is oriented outward so that the printed coil surface is in contact with the liquid. After interviewing the front and back sides by facing inwards so as not to come into contact with liquid, the conductors (not shown) connected to each quantum energy generating coil are drawn outward (projecting outward from the joint surface) and then interviewed with adhesive or solvent. Join the parts into an airtight structure, or if it is made of PVC, weld the edges of the joint surface with a PVC welder.

The third material 130, which is a metal material such as iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), and hastalloy, is a printed coil. After interviewing the front and back surfaces with the surface facing outward so that it contacts the liquid or facing inward so that it does not come into contact with the liquid, the conductors (not shown) connected to each quantum energy generating coil are drawn outward (protruding outward from the joint surface). After that, the edge of the joint surface is welded by selecting one of the ARC welding, TIG welding, and MIG welding methods. For thin plate glass, the printed coil surface is directed outward so that it is in contact with the liquid, or the edge of the joint surface is welded with the liquid. After interviewing the front and back surfaces by facing inward without contact, the conductors (not shown) connected to each quantum energy generating coil are drawn outward (projecting outward from the joint surface), and the edges of the joint surface are caulked with a waterproof sealant.

The fifth material (150) is an inorganic material such as concrete walls, tiles, blocks, bricks, and boards.

8th transparent materials such as polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film with quantum energy-emitting coils formed on the surface. Attaching any one material among the materials 180,

Select and attach a second material (120) from among the second materials (120), which are non-conductive materials such as PVC, PE, PC, acrylic, bakelite, and reinforced glass foam (FRP) with a quantum energy-emitting coil formed on the surface, or iron ( The third material 130, which is a metal material such as Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), and hastalloy, is a quantum energy generation coil. One of the shapes is selected, and the selected shape is manufactured by attaching a quantum energy generating coil processed through model picking technology using laser technology.

The number of quantum energy generating coils formed on the surface of one material by the method 9e may be one, or a plurality of quantum energy generating coils may be formed.

Figure 9 is a schematic diagram showing a first power supply that supplies power to quantum energy generation coils formed on the first to eighth material planes. When explained with reference to the attached drawings, the first power supply 310 is the first power supply. Rectifier 311, transformer 312, FET switch 313, second rectifier 314, PWM (pulse width modlation) control method and pulse frequency modulation PFM (pulse frequency modlation) and pulse It consists of a pulse control unit 315 with built-in frequency (density) control (PDM) and pulse repetition rate control (PRR) functions, a magnetic field detection sensor 315a, a switching control unit 316, and a post-regulator 317, and is a first rectifying unit. When AC voltage (A.C) is supplied to (311), the AC voltage (A.C) supplied from the first rectifier 311 is converted into DC voltage and the converted DC voltage is supplied to the transformer (Transformer) 312. When the transformer (312) reduces the pressure to a low voltage of 220V or less or transforms it to a high voltage in the range of 1KV to 300KV and supplies it to the FET switch (313), alternating current modulated with high frequency generated by high frequency switching in the FET switch (313). When voltage is supplied to the second rectifier 314, the second rectifier 314 converts the high-frequency modulated alternating current voltage into direct current voltage, and when the converted direct current voltage is supplied to the pulse control unit 315, the pulse control unit 315 ) by adjusting the WM (Pulse width modlation) control method, pulse frequency modulation (PFM), pulse frequency (density) control (PDM), pulse repetition rate control (PRR), etc. to control the FET switch (313). In addition, the switching control unit 316 stops the high-frequency switching operation of the FET switch 313 before the transmission pulse is generated in the pulse control unit 315. The pulse control unit 315 ) operates at the same time as the transmission pulse is generated to produce a direct current voltage printed on the surface of the first to eighth materials, a metal plate perforated in the shape of a quantum energy generating coil is attached, or a coated wire is wound in the shape of a quantum energy generating coil. A direct current voltage is output to the first and second quantum energy generation coils, or a direct current voltage is output to each of the first and second quantum energy generation coils. The frequency modulation range in the first power supply 310 is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, 1MKHz to 100MHz, and 100MKHz to 10GHz.

Figure 10a is a schematic diagram showing a second power supply that supplies power to quantum energy generating coils formed on the first to eighth material planes. When explained with reference to the attached drawings,

The second power supply (320) includes a step-down (boost) transformer (321), a rectifier circuit (322), an input module (323a), an operation module (323b), and a PWM (pulse width modulation) control method. A control unit 323 consisting of a control module 323c with built-in pulse frequency modulation (PFM), pulse frequency (density) control (PDM), and pulse repetition rate control (PRR) functions, a current detection sensor 324, It consists of a magnetic field detection sensor 325 and supplies single-phase 220V, 60Hz AC power to the step-up transformer 321. The step-up transformer 321 boosts the voltage to single-phase 1-10KV, 60Hz AC power and supplies it to the rectifier 322. The rectifier 322 converts it into single-phase direct current power in the range of 1-10KV and 60Hz.

The input module 323a of the control unit 323 controls the step-by-step voltage value (V) of the direct current power supplied to the first and second magnetic field generating coils 121 and 122, that is, the first and second magnetic field generating coils 121 , 122) supply of the minimum (mA) and maximum value (A) of the variable current flowing through the device, the minimum value (mT) and maximum value (T) of the variable magnetic field, and power supply time for each step (seconds to minutes, or minutes to hours). Current value, voltage value, pulse width, pulse density pulse period, frequency burst length, main power supply time and stop time (timer function), switching device function, surface temperature control function of quantum energy generation coils (121, 122), etc. The user inputs the variables (parameters) into the program built inside the monitor (not shown) of the input module (323a). For example, the operation stage among the steps divided into steps 1 to 10 is displayed. After setting, enter the data of the selected stage.

The calculation module 323b executes an operation program for a plurality of variables entered by the user in the input module 323a to generate the first magnetic field generation coil 121 and the second magnetic field generation coil 122 for generating variable quantum energy. ), calculate the amount of current corresponding to the magnetic field intensity to be generated, and generate the corresponding data in advance to generate the current value in the form of one-to-one matching of the input frequency band, magnetic field intensity value, and current value, and the magnetic field sensor (325) ), the magnetic field of the first quantum energy generation coil of the first quantum energy generator is measured and overlapped with the magnetic field generated from the first and second quantum energy generation coils of the first quantum energy generator by real-time transmitted data to achieve a zero magnetic field state. You can calculate the resonance frequency value that can be created and generate a current value proportional to the calculated resonance frequency value. For example, if the magnetic field strength value is between 1 and 10, the current corresponding to between 1 and 10. By generating data about the value, if the magnetic field intensity value is 1, a current value corresponding to 1 may be generated. In addition, the first and second quantum of the magnetic field sensor 325 and the first quantum energy generator 320 The magnetic field of the energy generating coil is measured and the magnetic field strength and current values are corrected and calculated based on the data transmitted in real time.

The current control module 323c generates a current corresponding to the strength of the magnetic field to be generated in the first magnetic field generation coil 121 and the second magnetic field generation coil according to the current value transmitted from the calculation module 323b, thereby generating the first magnetic field generation coil 121. A current detection sensor installed on one of the incoming lines of the first and second quantum energy generation coils 121 and 122 or on each line while supplying power to the quantum energy generation coil 121 and the second quantum energy generation coil 122. When (324) detects the current value flowing in one or each line of the incoming lines of the first and second quantum energy generation coils and transmits it to the operation module 323b in real time, the variable entered by the user in the input module 323a ( Compared to the set value for each parameter, when the set value deviates from the upper and lower limits of the set value, a calculation program is executed to determine the current set value for each variable (parameter) modified so that the deviation from the upper and lower limit values can be restored to the original set value. It is transmitted to the control module 323c to supply power in a pulse form (PEMF) suitable for the current modified for each step variable in the current control module 323c to the first quantum energy generation coil and the second quantum energy generation coil, or to detect a magnetic field. The first quantum energy generation coil 121 generates power in a pulse form (PEMF) suitable for the resonance frequency value, the magnetic field value corresponding to the resonance frequency, and the corrected current value corresponding to the magnetic field value according to the data transmitted by the sensor. and the second quantum energy generation coil 122, or supply power in pulse form (PEMF) to each of the first and second quantum energy generation coils.

In addition, the calculation module 323b compares the generated current value with the current digitized current value received from the current first quantum energy generation coil and the second quantum energy generation coil received from the current detection sensor 324, and compares the difference between them. The required current value is transmitted to the current control module 323c through PID control according to .

In addition, the quantum energy generation coil transmits the temperature measured in real time by the temperature detection sensor 324 to the control unit 323 through a conductor (not shown), and analyzes the measured temperature data transmitted from the control unit 233 to determine the set temperature. The output power supplied to the first quantum energy generation coil 121 and the second quantum energy generation coil 122 of the power supply 320 is controlled to maintain .

The magnetic field detection sensor 325 is a SQUID (Super conducting Quantum Interference Device) sensor, Nuclear Magnetic Resonance (NMR), Atomic Magnetic Resonance (AMR) sensor, Fluxgate sensor, MR ( You can select and use one of the following types: Magnetic Resistance sensor, MI (Magnetic Impedance) sensor, Hall effect sensor, optical fiber magnetic sensor, and search coil.

The frequency modulation range in the second power supply 320 is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, 1MKHz to 100MHz, and 100MKHz to 10GHz.

Effects of electromagnetic waves

Thanks to the development of the electrical and electronic industries and information and communication technology, the world has become able to use various wireless communications and broadcasting services using radio waves. And these technologies that apply radio waves are commonly used in fields ranging from mobile communications to medical fields. The scope of development is gradually expanding to the industrial field, and further to the aviation and space industries. The use of such radio waves has eliminated various visual and spatial constraints that exist in our lives in a functional sense.

On the other hand, the rapid increase in the use of electromagnetic waves has resulted in a decrease in the performance of electrical / electronic equipment due to communication difficulties or malfunctions due to interference between devices. This has caused the problem of worsening the electromagnetic environment due to various electromagnetic waves. .In particular, most of the various contents provided in the U-City environment using ubiquitous technology use wireless communication infrastructure, so the environment for electromagnetic waves becomes worse and the space where radio waves are concentrated increases. Therefore, the You must be able to diagnose electromagnetic interference by measuring and analyzing electromagnetic waves.

In general, electromagnetic waves are known to be harmful to the human body when exposed to low-frequency electromagnetic waves for a long period of time, even if the level is small. When the human body is exposed to low-frequency electromagnetic waves for a long time, an induced current is generated within the human body, causing Na ⁺ , K ⁺ , Cl existing inside and outside the cell membrane. ^- It is known to cause various ion imbalances, such as affecting hormone secretion and immune cells.

The extent of such electromagnetic waves varies depending on the various electrical devices used inside a building. Therefore, electromagnetic wave blocking devices and electromagnetic wave blocking and absorbing compositions are developed and used to protect the human body from electromagnetic waves.

Since the degree of absorption and blocking of electromagnetic waves cannot be known for such electromagnetic wave blocking devices or electromagnetic wave blocking and absorbing compositions, there is a problem in that the electric field strength and magnetic field must be measured by placing electric devices and home appliances inside the building identical to the actual situation. There are inconvenient problems, such as having to rearrange electronic products and electrical devices one by one to suit the electromagnetic wave situation.

Electromagnetic interference measurements are mainly conducted at an open area test site with a ground plane, a full/semi anechoic chamber, a TEM cell (Transverse Electromagnetic cell), a Pallel Plate Line, and a Helmholtz coil. coil), electromagnetic wave reverberating chamber, etc. However, in the case of an outdoor test site, it is affected by the weather, requires a very large space, and in addition to the disadvantages of high installation costs, the measurement facility is connected to the outside. Since it is not isolated, it has the disadvantage of being easily affected by the surrounding electromagnetic environment. In addition, in the case of electromagnetic wave anechoic facilities, there is a disadvantage in that a large installation space is required and it is necessary to maintain the measurement facility even after installation. Therefore, a null space is not required and measurement facilities and new measurement technology that enable faster and more accurate measurement at low cost are being developed. Efforts are continuing.

Figure 10b is a schematic diagram showing a third power supply that supplies power to quantum energy generation coils formed on the first to eighth material planes. When explained with reference to the attached drawings,

The third power supply 330 is a power transmitter consisting of a power supply unit 331, an output power generator 332, a frequency modulator 333, an output time controller 334, and a transmission coil unit 335. (330);and

A power receiver (330a) consisting of a receiving coil unit (331a), a power generating unit (332a), and a feedback signal generating unit (333a); and

Converter unit (331b), inverter unit (332b), resonance reactor (333b), pulse transformer (334b), control unit (335b), gate driver (336b), first condenser (337b), and second condenser (338) ) a high voltage generator (330b) consisting of b; and

It consists of a quantum energy irradiation unit 340 consisting of a first quantum energy generation coil (335b-1), a second quantum energy generation coil (335b-2), and a conductor (335b-3).

The power supply unit 331 of the power transmitter supplies alternating current power of 220V 60Hz through a conductor.

The output power generator 332 generates a high-frequency signal of 1MHz-15 MHz by implementing the 220V 60Hz AC power provided from the power supply unit 331 in the form of an inverter or an amplifier.

The frequency modulator 333 determines the optimal transmission frequency using the feedback signals FB1 and FBn input from the receiver 341 and modulates the transmission frequency of the output signal.

Here, the feedback signals FB1 and FBn include information corresponding to the received power value.

In an embodiment, the frequency modulator 333 may be modulated at around 10% of the independent resonance frequency. Here, the independent resonance frequency is a frequency that causes resonance between the wireless power transmitter 330 and the wireless power receiver 340 for wireless power transmission. If the independent resonance frequency is 9.6MHz, the optimal frequency is 8.7MHz-9.7. It can be MHz.

The output time control unit 334 adjusts the output time of the high frequency signal output from the wireless power transmitter 330. For example, when the wireless power transmitter 330 searches for an optimal frequency, the output time controller 334 controls the high-frequency signal to be output only for a short period of time. On the other hand, after the optimal frequency of the wireless power transmitter 330 is determined, the output time controller 334 controls the wireless power transmitter 330 to output a high frequency signal for most of the time.

The transmitting coil unit 335 transmits the high-frequency signal generated by the output power generator 332 to the receiving coil units 441. The transmitting coil unit 335 includes a power coil 335-1 and a transmitting coil ( 335-2).

The power coil 335 receives a high-frequency current corresponding to the high-frequency signal generated by the output power generator 332. The power coil 335-1 can use a coil with a diameter of 3 mm or more to reduce loss due to resistance. there is.

The transmitting coil 335-2 induces a high-frequency current of the power coil 335-1 by magnetic induction, and generates a high-frequency signal, that is, a non-radiative electromagnetic wave, to the plurality of receiving devices 330.

The transmitting coil 335-2 may use a coil with a diameter of 3 mm or more to reduce loss due to resistance. The number of turns and the turn interval of the transmitting coil 335-2 are adjusted to match the target resonance frequency. The transmitting coil 335-2 may be implemented as a solenoid coil structure.

When the power supply 331 supplies AC power of 220V 60Hz to the output power generator 332 through a conductor, the output power generator 332 implements the AC power of 220V 60Hz provided from the power supply unit 331 in the form of an inverter. , Implemented in the form of an amplifier, a high frequency signal of 1MHz-15 MHz is generated and then transmitted to the frequency modulator 333. The frequency modulator 333 uses the feedback signals (FB1) input from the receiver 341 to determine the optimal signal. Determines the transmission frequency of the output signal and modulates the transmission frequency of the output signal. At the same time, when the wireless power transmitter 330 searches for the optimal frequency, the output time controller 334 adjusts the output time for a short period of time. Controlled to output a high-frequency signal only for a while, on the other hand, after the optimal frequency of the wireless power transmitter 334 is determined, the output time control unit 334 adjusts the output time to output a high-frequency signal for most of the time, so that the transmitter ( 335), the power coil 235-1 of the transmission unit 335 receives a high-frequency current corresponding to the high-frequency signal generated by the output power generator 332, and sends it to the transmission coil 335-2. In -2), a high-frequency current in the power coil 335-1 is induced by magnetic induction, and a high-frequency signal, that is, a non-radiative electromagnetic wave, is generated in the power receiving device 330a and transmitted to the receiving coil unit 331a.

The power receiver 330a consists of a receiving coil unit 331a, a power generating unit 332a, and a feedback signal generating unit 333a. The receiving coil unit 331a includes a receiving coil 331a-1 and a load coil ( 331a-2).

The receiving coil 331a receives the high frequency signal transmitted from the transmitting coil 335-2. In an embodiment, the receiving coil 331a may have a spiral structure. In another embodiment, the receiving coil 241 may have a helical structure.

Since power is transmitted by magnetic induction, the load coil (332a) is implemented to be located as close as possible to the receiving coil (231a).

The power generator 332a receives high-frequency current from the load coil 332a and produces direct current power. The generated direct current power is supplied to the first and second quantum energy generation coils,

The load unit 333 is a device that uses generated direct current power.

The feedback signal generator 333a generates a feedback signal FB1 corresponding to the received power value.

The feedback signal generator 333a may be implemented as a passive RFID (Radion Frequency IDentification).

The power receiver 330a receives non-radiative electromagnetic waves transmitted from the transmission unit 335 of the power transmitter 330 at the receiving coil 331a and supplies them to the power generation unit 332a. Supply power directly to the first and second quantum energy generation coils or generate direct current power appropriate for the power required by the high voltage generator 330b, and simultaneously respond to the power value received from the feedback signal generator 333a. A feedback signal is generated and supplied to the high voltage generator.

The wireless power receiver 330a corresponds to the load and feedback signal generator 333a of the receiving coil unit 331a, the power generator 332a, the first and second quantum energy generation coils, and the high voltage supply unit 330b, respectively. corresponds to

A general resonant wireless power transmission method requires matching the resonant frequency to increase power transmission efficiency, but there is a problem in that this resonant frequency changes depending on the positions of the wireless power receivers.

On the other hand, the wireless power transmission system 330 of the present invention determines the optimal transmission frequency for power transmission based on feedback signals from wireless power receivers input in real time, and transmits a high frequency signal modulated to the determined optimal transmission frequency. It is implemented to transmit.

The high voltage generator (330b) includes a DC voltage regulator (331b), a converter unit (332b), an inverter unit (333b), a resonance reactor (334b), a pulse transformer (335b), and a PWM (pulse width modlation) control method. A control unit (336b) with built-in pulse frequency modulation (PFM), pulse frequency (density) control (PDM), and pulse repetition rate control (PRR) functions, a magnetic field detection sensor (336b-1), and a gate driver (337b) , a first condenser yarn (338b), and a second condenser yarn (339b).

In addition, the control unit 336b measures the magnetic field inside the specific space in real time from the magnetic field detection sensor 336b-1 installed on one side of the wall of the specific space and transmits the data to the control unit 336b. It includes a receiving unit (not shown) that receives data.

The DC voltage regulator 331b adjusts the DC voltage generated by the power generator 332b to be constant with the target voltage previously input to the control unit using a voltage regulator (not shown) or a shunt regulator.

In most cases, the reference voltage is kept constant using a shunt regulator such as a zendiode, breakdown diode, or voltage adjustment tube.

The converter unit 332b boosts the direct current voltage to a high voltage through a switching operation.

The inverter unit 333b modulates the DC voltage boosted by the converter unit 332b into a voltage in the form of an alternating current pulse (Pulsed electromagnetic field (PEMF)).

The resonance reactor 334b matches the loads of the first quantum energy generation coil 341 and the second quantum energy generation coil 342.

The pulse transformer 335b boosts the output voltage of the inverter 333b. Pulse amplitude modulation of the switching output of the first quantum energy generation coil (335a-1), the second quantum energy generation coil (335a-2) and the inverter unit (333b) that receive the output voltage of the pulse transformer (335b) To perform (PAM), a signal is formed to control the output voltage of the converter unit 332b, and a signal generated from the first quantum energy generation coil 335a-1 and the second quantum energy generation coil 335a-2 is generated. A control unit 336b that forms a signal capable of pulse frequency (density) control (PDM) independently of the amplitude of the pulse to control the amount of quantum energy generated by adjusting the strength of the magnetic field, and a control signal applied from the control unit 336b. It includes a gate driver 337b that amplifies the voltage and applies it to the converter 332b and the inverter 333b.

The first condenser (338b) inputs the voltage of the first condenser (338b) to the converter unit (332b) and the second condenser (339b) by reducing the ripple of the DC voltage boosted through the converter unit (332b). It includes a second condenser (339b) that provides input to unit (333b).

After boosting the supplied DC voltage through a switching operation in the converter unit 332b, the boosted DC voltage in the inverter unit 333b is modulated into a voltage in the form of an alternating current pulse (Pulsed electromagnetic field; PEMF), and then the pulse transformer ( In 335b), the output voltage of the inverter unit 333b is boosted and applied to the first quantum energy generation coil 335a-1 and the second quantum energy generation coil 335a-2.

In addition, an input unit (not shown) is separately built inside the control unit 336b so that the user can control the current value and voltage supplied to the first quantum energy generation coil 335a-1 and the second quantum energy generation coil 335a-2. Value, frequency value, power supply time, and stop time (timer function) can be entered into the input section.

Power in the form of a pulsed electromagnetic field (PEMF) generated in the high voltage generator 330b is transmitted to the first quantum energy generation coil 335a-1 and the second quantum energy generation coil 335a through the conductor 339b-1. -2) or when power is supplied to each of the first quantum energy generation coil and the second quantum energy generation coil, the current flow direction is 90°C in opposite directions between the first quantum energy generation coil and the second quantum energy generation coil. A magnetic field in the form of a pulse (Pulsed electromagnetic field (PEMF)) is generated at an angle of 100 degrees, the Lorentz force acts, and the magnetic field in the form of a pulse (Pulsed electromagnetic field (PEMF)) is overlapped between the first and second quantum energy generation coils and disappears, reaching zero. Pulsating quantum energy is irradiated in a magnetic field state.

The frequency modulation range in the third power supply 330 is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, 1MKHz to 100MHz, and 100MKHz to 10GHz.

The intensity of the magnetic field (B) is proportional to the number of turns (n) of the coil wound around the square sotten or solenoid and the intensity of the current (I) flowing in the coil, and is expressed as the magnetic field strength B = μI / 2πr. The internal magnetic field is much larger than the magnetic field generated externally.

In addition, since inserting a magnetic material instead of air into the solenoid creates a strong magnetic field, in the present invention, a solenoid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, and trigger coil are used to generate a strong magnetic field. , Zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Kadusse. Among the Caduceus Coil, Rogoski coil, and combinations of these shapes, a conductive ink containing a ferromagnetic material is added to a selected coil shape using a printer to produce an additional shape (Mido). You can print them overlapping or surrounding them.

All atoms that make up matter are composed of electrons and protons and generate their own magnetic fields, and these particles have spin within the magnetic field and have a spin magnetic dipole moment. However, iron, nickel, cobalt, etc. are a type of transition source and have a unique electronic structure in which the outer electron group contains electrons even if the inner electrons are not filled, so in general, cancellation of electron spin and electron magnetic moment does not occur. Because these atoms have a greater magnetic moment than other atoms.

The intensity B of the magnetic field is B = μ ₀ I/2πr in the case of a long straight wire, and B ^qt = μ ₀ I/2πr in the case of a long solenoid coil. The units of the intensity B of the magnetic field are N/AM, Kg/ C and S are expressed as Tesla (T), and are generally expressed as gauss (G), where 1gauss = 10 ^-4 T.

The force F acting on a charge active in a magnetic field is expressed as F=ΔF/n(ΔL)A=qv x B.

Here, n = number of free charges per unit volume, g = moving charge, v = moving speed of positive charge.

Figure 10c is a schematic diagram showing a fourth power supply that supplies power to quantum energy generating coils formed on the first to eighth material planes. When explained with reference to the attached drawings,

The fourth power supply 340 consists of an input unit 341, a control unit 342, a magnetic field detection sensor 342a, a switching converter unit 343, a high voltage generator 344, and a rectifier unit 345.

The input unit 341 is supplied with DC power of 220V and 3-12V by the D.C. power supply, and the user can select the pulse width, trigger period, and relay to be applied to the first and second quantum energy generation coils in advance. Enter variable settings and set values.

The control unit 342 has a built-in microcomputer and performs a central control function. It is connected so that the output signal of the input unit 341 is input, and data from the switching converter unit 343 and the booster unit 344, which are described below, are connected to the control unit 342. A communication function is built in to enable communication for sending and receiving.

In addition, the control unit 342 measures the magnetic field inside the specific space in real time from the magnetic field detection sensor 342a and the magnetic field detection sensor 342a installed on one side of the wall of the specific space and transmits the data to the control unit 342. It includes a receiving unit (not shown).

The switching converter unit 343 receives data from the control unit 342 based on menu settings and adjusted values according to the user's input at the input unit 341, and adjusts the PWM signal of the frequency according to the received data to produce a square waveform. It outputs a pulse, controls the current according to the controlled pulse width, provides a relay signal, measures voltage, current, and temperature, and transmits data to the control unit 342 at regular intervals. It has a built-in microcomputer and communicates. Features are built-in.

The switching converter unit 343 is equipped to exchange data with the control unit 412 and the booster unit 344 through communication, and outputs square wave pulses for DC voltage, but allows a current to flow according to the controlled pulse width. It controls and provides ON/OFF signals to the relay and has a voltage or duty control function.

The switching converter unit 343 receives data from the control unit 342 based on menu settings and adjusted values according to user input, and adjusts the PWM (pulse width modulation) signal of the frequency according to the received data to create a square wave pulse. It outputs a current corresponding to the controlled pulse width, adjusts the duty according to this amount of current, and provides an ON/OFF signal to the relay.

The switching converter unit 343 is responsible for measuring the current state of voltage, current, temperature, etc. to the control unit at regular intervals and transmitting the same data, so that the duty ratio can be adjusted according to the amount of current controlled. do.

The high voltage generator 344 (20KHz-100KHz) is connected to supply high voltage to the first and second quantum energy generation coils 321 and 322, or is connected to each of the first and second quantum energy generation coils 321 and 322. It is connected to determine whether there is a rectification (trigger) signal from the control unit 342, outputs the rectification (trigger) signal in the form of a pulse, and measures the voltage to transmit data to the control unit 342 at regular intervals. A microcomputer is built in and communication functions are provided.

The high voltage generator 344 is equipped to exchange data with the control unit 342 and the switching converter unit 343 through communication, and when a rectification (trigger) signal is received from the control unit 342, rectification (trigger) is performed. It is equipped to output a signal in pulse form.

The high voltage generator 344 is connected to the first and second quantum energy generation coils 321-1 and 321-2 and the rectifier 345, respectively, or is connected to the first and second quantum energy generation coils 321-1 and 321-2, respectively. connected to

The constant high voltage generator 344 determines whether there is a rectification (trigger) signal, which is a synchronization signal, when receiving data from the control unit 342 based on the menu settings and adjusted values in the user's input. Only when there is a signal, the rectification (trigger) signal is output in pulse form and sent to the rectifier 345.

At this time, it is desirable to set up the rectification (trigger) signal so that it occurs within a certain period according to user input or a preset type.

Additionally, the high voltage generator 344 measures the current voltage and sends voltage data to the control unit 342 at regular intervals.

In this way, in configuring the control unit 342, the switching converter unit 343, and the high voltage generator 344, a digital method according to each equipped with a microcomputer is applied to control the pulse width of the pulse-shaped power supplied to the quantum energy generation coil. Characteristics can be adjusted more easily.

The rectifier 345 receives a rectified (trigger) signal output in the form of a pulse from the high voltage generator 344 and extracts a trigger waveform through rectification.

The rectifier 345 is provided to receive a rectification (trigger) signal output in the form of a pulse from the high voltage generator 344, rectify it, and generate its own rectification (trigger) signal for providing a synchronization signal.

At this time, the rectifier 345 extracts the waveform of only the positive side in the ON state or only the negative side in the OFF state from the repetitive ON/OFF pulse output through rectification. Depending on the direction of installing the diode in the forward or reverse direction, You can select and extract the trigger waveform (in the form of ON/OFF or +/-).

The frequency modulation range in the fourth power supply 340 is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, 1MKHz to 100MHz, and 100MKHz to 10GHz.

Figure 10d is a schematic diagram showing a fifth power supply that supplies power to quantum energy generation coils formed on the first to eighth material planes. When explained with reference to the attached drawings, the power supply 350 uses alternating current power (AC). ) Power supply unit 351 consisting of a supply (351a) or a direct current power (DC: battery) supply (351b), an AC/DC conversion unit (352), an automatic power supply switcher (353) (ATS), and a low frequency generation and output unit. (354), switching element 355, PWM (pulse width modlation) control method and pulse frequency modulation (PFM) and pulse frequency (density) control (PDM), pulse repetition rate control (PRR) function It consists of a built-in control unit 356 and a magnetic field detection sensor 356a.

In addition, the control unit 356 measures the magnetic field inside the specific space in real time from the magnetic field detection sensor 356a and the magnetic field detection sensor 356a installed on one side of the wall of the specific space and transmits the data to the control unit 356. It includes a receiving unit (not shown).

When AC power of 220V 60Hz is supplied from the AC power supply (351a) of the power supply unit 351 to a step-down transformer (not shown), the step-down transformer (not shown) is in the range of 6 to 50V in single phase and is converted to AC power of 60Hz. The pressure is reduced and supplied to the AC/DC converter 352 via the automatic power switch 233 (ATS), rectified into single-phase DC power in the range of 6 to 50V, and supplied to the oscillator via the automatic power switch 353 (ATS). (354a), frequency distribution unit (354b), control unit (354c), and amplification unit (354d) are supplied to the low-frequency or high-frequency generation and output unit 354, or 6 to 6 from the DC power supply 351b (battery). Generate and output low or high frequencies consisting of an oscillator (354a), a frequency divider (354b), a control unit (354c), and an amplifier (334d) using direct current power in the 50V range via an automatic power switch (353) (ATS). When supplied to the unit 354, the oscillator 354a pre-programs the power to be supplied to the quantum energy generation coil formed on the surface of the material dividing a specific space, is input to the control unit 356, and generates the first and second quantum energies. When an electromagnetic wave suitable to be applied to the coil is generated and applied to the frequency distribution unit 354b, the frequency distribution unit 354b converts the electromagnetic wave generated by the oscillator 354a into frequencies in different directions in the first and second quantum energy generation coils. The quantum energy generated in the zero magnetic field state is overlapped and converted into a low-frequency signal so that it can be sufficiently generated, and when applied to the control unit 354c, the control unit 354c produces a frequency distribution unit ( When the intensity of the low frequency or high frequency is adjusted by adjusting the pulse of the low frequency signal generated in 354b) and applied to the amplifying unit 354d, the amplifying unit 354d outputs the low frequency pulse signal through the adjusting unit 354c into the first and second 2 The quantum energy generation coils 521 and 522 detect and detect in real time the magnetic field corresponding to the electromagnetic wave, frequency, or converted value of the measured electromagnetic wave and frequency inside the specific space from the magnetic field detection sensor 356a installed on one side of the wall dividing the specific space. When data is transmitted to the receiver (not shown) of the real-time control unit 356, it is amplified to suit the transmitted data or to meet the input data value entered in advance, and generates a pulse (pulsed electromagnetic field; Power in the form of PEMF is supplied to the first and second quantum energy generation coils through the switching element 355.

Additionally, power supply time, stop time (timer function), switching element function, etc. can be added to the control circuit of the control unit 356.

The batteries are rechargeable secondary batteries such as nickel-cadmium (Ni-Cd), alkaline batteries, nickel hydride (Ni-MH) batteries, sealed lead acid (SLA), lithium ion (Li-ion), and lithium polymer (Li- polymer), etc., one type is selected and used.

The shapes of the first quantum energy generation coil and the second quantum energy generation coil are solenoid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag coil ( Up and down, left and right), extension type coil, motor stator type coil, square coil, RF coil, toroidal coil shape, Tesla coil, Mobius Coil, Caduceus Coil ), Rogoski coil, and a combination of these shapes, one coil shape is selected and used.

The frequency modulation range in the fifth power supply 350 is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, 1MKHz to 100MHz, and 100MKHz to 10GHz.

FIG. 10E is a schematic diagram showing a sixth power supply that supplies power to a quantum energy generating coil formed using an electroluminescence device on the surface of the material shown in FIG. 12K. When explained with reference to the attached drawings, the sixth power supply The power supply 360 is composed of the power supply unit 361, overload detection unit 362, voltage adjustment unit 363, frequency modulation unit 364, magnetic field detection sensor 364a, and EL driver 365. In addition, The frequency modulator 364 is connected to a magnetic field detection sensor 356a installed on one side of the wall of a specific space, and receives magnetic field information of a specific space from the magnetic field detection sensor 356a. The power supply unit 361 supplies DC power in the range of 6 to 50V to the voltage regulator 363 through the overload detection unit 362, reduces the voltage in the range of 10 to 20V in the voltage regulator, and sends the reduced voltage to the frequency modulator. When supplied to (364), the power applied to the quantum energy generation coil by the signal oscillating from each oscillator circuit (not shown) in the two or more oscillator circuits built in the frequency modulator 364 is converted into a pulse width modulation signal. Through a switching operation, DC power is converted into AC power and supplied to the EL element 365 and the quantum energy generation coil. The overload detection unit 362 measures the amount of current applied to the quantum energy generation coil during operation in real time, and detects the amount of current applied to the quantum energy generation coil during operation. In this case, the power is cut off, and if the current amount is below the standard value, the circuit is connected electrically to supply power.

The frequency modulation range in the sixth power supply 360 is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, 1MKHz to 100MHz, and 100MKHz to 10GHz.

Batteries that are power supplies not shown include lead acid batteries (Pb) batteries, nickel cadmium (Ni-cd) batteries, nickel hydrogen (Ni-Mh) batteries, lithium ion (Ni-ion) batteries, and lithium ion batteries that are easily available on the market. Select and use one type among polymer (LiPB) battery and lithium iron phosphate (LiFePO4) battery. In terms of stability and capacity, battery, lithium ion polymer (LiPB) battery, and lithium iron phosphate (LiFePO4) battery are suitable.

Since the above battery has already been commercialized and is widely used in all of my electronic devices, detailed explanation will be omitted.

In addition, the power supplies that supply pulse-type power to the quantum energy generation coils (first and second quantum energy generation coils) include a first power supply 310, a second power supply 320, and a third power supply ( 330), the fourth power supply 340, the fifth power supply 350, and the sixth power supply 360, and power supplies of other configurations not described herein may also be used in the quantum energy generation coil (first, It can be used if a pulse-type electromagnetic field can be generated by supplying pulse-type power to the second quantum energy generation coil.

The material of the first quantum energy generation coil and the second quantum energy generation coil is selected from conductive silver, copper, brass, bronze, nickel, gold, etc.

The conductors use high-voltage wires and low-voltage wires.

The power supply 300 that supplies pulse-type power and immediate power to the quantum energy generation coil includes a first power supply 310, a second power supply 320, a third power supply 330, and a fourth power supply. It is not limited to (340), the fifth power supply (350), the sixth power supply (360), and the battery (not shown). Even with other circuit configurations, pulse-type power or direct current power is supplied to the quantum energy generation coil of the present invention, but the frequency modulation range is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, and 1MKHz to 1MKHz. Any power supply that supplies power in the 100MHz range, 100MKHz to 10GHz range, and the low voltage applied to the quantum energy generation coil is AC or DC power in the 3V to 240V range, and the high voltage power in the 380 to 500KV range can be used.

The original name of electromagnetic wave is electromagnetic wave, and waves composed of electric and magnetic fields repeat each other and spread at the speed of light in the air.

Electromagnetic waves are transmitted through photons and are divided into radio waves, infrared rays, visible rays, ultraviolet rays, X-rays, and gamma rays, depending on the length of the wavelength.

Electromagnetic waves are classified according to frequency and wavelength. Frequency means the number of waves that vibrate per second, and the unit is Hz (hertz).

*Wavelength refers to the distance between crests (troughs) when a certain wave progresses periodically and repeatedly.

Evaluate health hazards by referring to the indoor air quality pollution level measured and announced by indoor air quality measurement institutions, and create an operation program for the control unit of the power supply (310, 320, 330, 340, 350, 360) based on the evaluation results. (Center for sterilizing bacteria and viruses in the floating air and related thereto) Frequency modulation range from the power supply that supplies power to the quantum energy generation coil formed on the surface of the material)

1) Air quality pollution of a department store in Seoul

CO2:77ppm NO2: 49ppb HCHO: 0.16ppb TSP: 0.023μg/m3 Fungi: 297CFU/m3, Total bacteria: 1622CFU/m3

(2) Indoor air quality pollution in PC rooms and karaoke rooms

CO2: 1589ppm NO2: 00ppb HCHO: 00pp Citing data measured on indoor air quality pollution by an accredited measuring agency,

(b TSP: 0.33μg/m3 Fungi: 00CFU/m3, Microorganisms: 16CFU/m3

(3) Radon concentration in offices, apartments, hospitals, and houses in Seoul

31.6Bq/m3,53.2Bq/m3,24.4Bq/m3,29.4Bq/m3,88.6Bq/m3,

Refer to such survey data and use information on the level of exposure to hazardous substances based on this to quantitatively predict specific adverse health reactions in specific population groups. Adverse health effects due to exposure to hazardous substances Evaluate.

The health hazard assessment process is divided into hazard identification, dose response assessment, exposure assessment, and risk characterization.

Health hazard assessment methods include single point estimate analysis (PEA) and Monte Carlo analysis (MCA) methods. In the present invention, probability density functions (PDFs: Probabilistic Density Functions) are used for each exposure variable. By referring to the Monte Carlo analysis method that evaluates human health hazards, we were able to include uncertainty and variability in the level of exposure.

In assessing health hazards, the calculation of cancer risk (CR:Canser Risk) and hazard index (Hi:Hazard Index) is based on the potential dose for inhalation processes such as breathing and ingestion, that is, the concentration of pollutants according to time changes. The cumulative amount of the product of the concentration and the absorption rate of the medium is used, and the relational formula is as follows.

Dpot =

=

=

Here, Dpot is the potential capacity and IR(t) is the Inhalation Rate, which is the intake or respiration rate.

t1-t2 is exposure time (ED: Exposure Duration).

ADDs =

Here, ADDs are Average Daily Doses ( ^mg/kg-day ), C is Concentration ( ^mg/㎥ ), IR is Inhalation Rate ( ^㎥/day ), BW is Body Weight (kg), and AT is Average Time ( ^year ).

In cases of carcinogenic activity, doses are often expressed as Lifetime Average Daily Doses (LADDs), even if exposure does not occur over a lifetime.

LADDs =

The essential condition for conducting a health risk assessment due to inhalation of indoor air pollutants in a specific space is the exposure amount using the exposure coefficient (body weight, respiratory rate, life expectancy, exposure time, and exposure frequency) that can reflect various characteristics of the population. By calculating and creating exposure scenarios for various indoor environments (department stores, hospitals, offices, transportation, residential and underground shopping malls, banks, restaurants, factory lounges, and factory processes), the evaluation for each scenario is re-performed to increase reliability. Complex function by dividing the Hazard Index (HI) into 4 to 7 levels: 25%, 50%, 75%, 100% or 0%, 25%, 50%, 70%, 90%, 95%, 100% An operation program for the air purification system is created and embedded in the control unit 40. An example of the step-by-step operation situation of the control unit with the step-by-step programmed operation function is as follows.

For the purpose of assessing health hazards, dose measurement uses dose-response data. Assuming that there is no carcinogenic effect and that there is no instantaneous exposure of acute action, it is sufficient to evaluate the average exposure or dose over the exposure cycle, which is Average Daily Doses (ADDs), which is the average potential dose with respect to body weight and average time. Calculate using

Figure 11 is a cross-sectional view showing a first quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawings, the first quantum energy generator 371 is made of thin white paper, window paper, Sagoji, Yusamji, Taemi Basin, Sannaeji, Wansanji, Kapyeongji, Gyeonyangji, etc. Gakji, which is a thick and strong paper made of two or more layers, is small byeokji, daegakji, inner byeokji, and thick paper. Slightly thick paper coverings include wreath paper, Yeongchang paper, black paper, cotton paper, raised paper, new fuji paper, exterior paper, hejong paper, and sijeon paper, and recycled paper such as insect repellent paper such as hwanghon paper, jade paper, red paper, and yellow paper. A first material 110 made of colored paper such as paper, blue paper, dark blue paper, or blue paper, or cardboard, a quantum energy generation coil formed on the plane of the first material 110, and power to the quantum energy generation coil. It consists of a power supply that supplies

How to irradiate quantum energy in a specific space

The first material on which quantum energy generating coils (first and second quantum energy generating coils) are formed is divided into a specific space so that the winding directions of the quantum energy generating coils are opposite to each other, or the first quantum energy is applied to the surface of the partitioned wall. Attach the material on which the quantum energy generation coil of the generator (300A) is formed, and print on the surface of the material on two facing sides (left, right, front, back, top, bottom), four sides, or six sides spaced apart from each other. A first power supply 310, a second power supply installed so that the winding directions of the plurality of quantum energy generating coils are opposite to each other, and installed on one side of the first material plane or on one external side (not shown). A power source selected from among the power supply 320, the third power supply 330, the fourth power supply 340, the fifth power supply 350, the sixth power supply 360, and the battery (not shown). When power is supplied to the plurality of first and second quantum energy generation coils through a conductor (not shown) with pulse-type power generated from a supply or direct current power output from a battery (not shown), the first quantum energy generation coil Pulse electromagnetic fields generated at an angle of 90 degrees to the direction of current flow are generated in opposite directions, and electromagnetic fields in opposite directions overlap and disappear at the center distance between the first quantum energy generating coils, causing pulsating quantum energy in a zero magnetic field state. It is created and irradiated into the indoor space.

The frequency modulation range in the first, second, third, fourth, fifth, and sixth power supplies (310, 320, 330, 340, 350, and 360) is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, and 1MKHz. to 100MHz range, and 100MKHz to 10GHz range.

Figure 12a is a cross-sectional view of a second quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawings, the second quantum energy generator 372 is made of PVC, PE, PC, acrylic, The second material 120 is selected from non-conductive materials such as bakelite, fiberglass foam (FRP), Teflon, and urethane, and the quantum energy generation coil formed on the plane of the second material 120 generates quantum energy. It consists of a power supply 300 that supplies power to the coil, and the method of irradiating quantum energy to a specific space is to use a second material on which quantum energy generation coils (first and second quantum energy generation coils) are formed. It is divided into a specific space so that the winding directions are opposite to each other, or a material on which the quantum energy generation coil of the first quantum energy generator (300A) is formed is attached to the surface of the partitioned wall, but the two sides are spaced apart from each other and face each other ( (left, right, front, rear, top, bottom), or on 4 or 6 sides, the winding directions of a plurality of quantum energy generating coils printed on the surface of the material are installed in opposite directions, and one side of the second material plane The first power supply 310, the second power supply 320, the third power supply 330, the fourth power supply 340, and the fifth power supply installed in or on one external side (not shown). (350), the sixth power advanced device (360), and a battery (not shown). A pulse-type power generated from a power supply or a direct current power output from a battery (not shown) is connected (not shown). When power is supplied to a plurality of first and second quantum energy generation coils, pulse-type electromagnetic fields generated at an angle of 90 degrees to the direction of current flow in the first and second quantum energy generation coils are generated in opposite directions, and Electromagnetic fields in opposite directions overlap and disappear at the center distance between the first and second quantum energy generating coils, and pulsating quantum energy is generated in a zero magnetic field state and irradiated to the indoor space.

The frequency modulation range in the first, second, third, fourth, fifth, and sixth power supplies (310, 320, 330, 340, 350, and 360) is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, 1MKHz to 100MHz range,100MKHz to 10GHz range.

Figure 12b is a cross-sectional view showing a third quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawing, the third quantum energy generator 373 is made of iron (Fe) and copper ( Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), titanium (Ti), nickel (Ni), platinum (Pt), hastalloy, insulating material or cold insulating material attached. It consists of a third material 130, which is selected from metal materials such as panels, a quantum energy generating coil formed on the surface of the third material 130, and a power supply 300 that supplies power to the quantum energy generating coil. , The method of irradiating quantum energy to a specific space is to divide the third material on which the quantum energy generating coils (first and second quantum energy generating coils) are formed into a specific space so that the winding directions of the quantum energy generating coils are opposite to each other. Alternatively, attach the material on which the quantum energy generating coil of the first quantum energy generating device (300A) is formed to the surface of the partitioned wall, with two sides spaced apart from each other (left, right, front, back, top, bottom), or A plurality of quantum energy generating coils printed on the surface of the material on 4 or 6 sides are installed so that the winding directions are opposite to each other, and are installed at a certain distance from the material, or are installed on one side of the third material plane, or A first power supply (310), a second power supply (320), a third power supply (330), a fourth power supply (340), a fifth power supply (350) installed on one external side (not shown), The sixth power advanced device 360 and a battery (not shown) are connected to a plurality of pulse-type power generated by a selected power supply or direct current power output from a battery (not shown) through conductors (not shown). When power is supplied to the first and second quantum energy generation coils, a pulse-type electromagnetic field generated at an angle of 90 degrees to the direction of current flow in the first and second quantum energy generation coils is generated in opposite directions, and the first and second quantum energy generation coils are generated in opposite directions. Electromagnetic fields in opposite directions overlap and disappear at the center distance between quantum energy generating coils, and pulsating quantum energy is generated in a zero magnetic field state and irradiated to the indoor space.

The frequency modulation range in the first, second, third, fourth, fifth, and sixth power supplies (310, 320, 330, 340, 350, and 360) is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, and 1MKHz. to 100MHz range, and 100MKHz to 10GHz range.

Figure 12c is a cross-sectional view showing the fourth quantum energy generator that irradiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawing, the fourth quantum energy generator 374 is made of general plywood, Douglas pine plywood, and core. The fourth material 140, which is selected from wood plywood such as plywood, larch plywood, MDF, and particle board, a quantum energy generation coil formed on the plane of the fourth material 140, and a power supply that supplies power to the quantum energy generation coil. It consists of a supply device 300, and the method of irradiating quantum energy to a specific space is to use a fourth material on which quantum energy generation coils (first and second quantum energy generation coils) are formed so that the winding directions of the quantum energy generation coils are opposite to each other. To achieve this, the material on which the quantum energy generating coil of the first quantum energy generating device (300A) is formed is attached to the surface of the partitioned wall or divided into two sides spaced apart from each other (left and right or front and rear). , top, bottom), or 4 or 6 sides, are installed so that the winding directions of a plurality of quantum energy generating coils printed on the surface of the material are opposite to each other, and are installed at a certain distance from the material or a fourth material. (140) A first power supply (310), a second power supply (320), a third power supply (330), and a fourth power supply (340) installed on one side of the plane or on one external side (not shown). ), the fifth power supply 350, the sixth power advanced unit 360, and the battery (not shown), a pulse-type power generated from a power supply selected from the group or DC power output from a battery (not shown) When power is supplied to a plurality of first and second quantum energy generation coils through a conductor (not shown), pulse-type electromagnetic fields generated at an angle of 90 degrees to the direction of current flow in the first and second quantum energy generation coils are mutually transmitted. Generated in opposite directions, electromagnetic fields in opposite directions overlap and disappear at the center distance between the first and second quantum energy generating coils, and pulsating quantum energy is generated in a zero magnetic field state and irradiated to the indoor space.

The frequency modulation range in the first, second, third, fourth, fifth, and sixth power supplies (310, 320, 330, 340, 350, and 360) is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, and 1MKHz. to 100MHz range, and 100MKHz to 10GHz range.

Figure 12d is a cross-sectional view showing the fifth quantum energy generator that irradiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawing, the fifth quantum energy generator 375 is used in concrete walls, tiles, etc., and blocks. , the fifth material 150, which is selected from among inorganic materials such as board, stone (marble exterior material, etc.), a quantum energy generating coil formed on the surface of the fifth material 150, and a power supply that supplies power to the quantum energy generating coil. It consists of a supply device, and the method of irradiating quantum energy to a specific space is to specify the fifth material on which the quantum energy generation coils (first and second quantum energy generation coils) are formed so that the winding directions of the quantum energy generation coils are opposite to each other. The material on which the quantum energy generating coil of the first quantum energy generating device (300A) is formed is attached to the surface of a wall divided into a space or divided into two sides spaced apart from each other (left, right, or front, rear, top, Bottom), or installed so that the winding directions of a plurality of quantum energy generating coils printed on the surface of the material on the 4th or 6th sides are in opposite directions, and are installed at a certain distance from the material, or on one side of the fifth material plane. Installed in the first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), A plurality of first and second quantum energies are generated through a conductor (not shown) using pulse-type power generated from a power supply selected from batteries (not shown) or direct current power output from a battery (not shown). When power is supplied to the coil, a pulse-type electromagnetic field generated at a 90-degree angle to the direction of current flow in the first and second quantum energy generation coils is generated in opposite directions, and is generated at the center distance between the first and second quantum energy generation coils. Electromagnetic fields in opposite directions overlap and disappear, creating pulsating quantum energy in a zero magnetic field state and irradiating it to the indoor space.

The frequency modulation range in the first, second, third, fourth, fifth, and sixth power supplies (310, 320, 330, 340, 350, and 360) is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, and 1MKHz. to 100MHz range, and 100MKHz to 10GHz range.

Figure 12e is a cross-sectional view showing the sixth quantum energy generator 376 that radiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawing, the sixth quantum energy generator 376 is made of vegetable fiber, vegetable fiber, and mineral fiber. The sixth material (160), which is selected from fiber materials such as fibers, recycled fibers, synthetic fibers, and inorganic fibers, a quantum energy generating coil formed on the sixth material (160) plane, and a power supply that supplies power to the quantum energy generating coil. It consists of a supply device 300, and the method of irradiating quantum energy to a specific space is to use the sixth material on which quantum energy generation coils (first and second quantum energy generation coils) are formed so that the winding directions of the quantum energy generation coils are opposite to each other. To achieve this, the material on which the quantum energy generating coil of the first quantum energy generating device (300A) is formed is attached to the surface of the partitioned wall or divided into two sides spaced apart from each other (left and right or front and rear). , top, bottom), or 4 or 6 sides, are installed so that the winding directions of a plurality of quantum energy generating coils printed on the surface of the material are opposite to each other, and are installed at a certain distance from the material, or a fifth material. The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply (350) installed on one side of the plane. 360), a pulse-type power generated from a power supply for which one type of battery (not shown) is selected or direct current power output from a battery (not shown) is connected to a plurality of first and second plurality of first and second power supplies through conductors (not shown). When power is supplied to the quantum energy generation coil, a pulse-type electromagnetic field generated at an angle of 90 degrees to the direction of current flow in the first and second quantum energy generation coils is generated in opposite directions, and is generated in the opposite direction between the first and second quantum energy generation coils. Electromagnetic fields in opposite directions overlap and disappear at the center distance, and pulsating quantum energy is generated and irradiated in a zero magnetic field state.

The frequency modulation range in the first, second, third, fourth, fifth, and sixth power supplies (310, 320, 330, 340, 350, and 360) is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, and 1MKHz. to 100MHz range, and 100MKHz to 10GHz range.

Figure 12f is a cross-sectional view of the 7th quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawings, the 7th quantum energy generator 377 is made of thin plate glass, thick plate glass, and transparent polishing. The seventh material 170 is made of one material selected from plate glass, solar shielding glass, and blocking glass, a quantum energy generation coil formed on the plane of the seventh material 170, and a power supply 300 that supplies power to the quantum energy generation coil. The method of irradiating quantum energy to a specific space is to place the seventh material on which the quantum energy generating coils (first and second quantum energy generating coils) are formed into a specific space so that the winding directions of the quantum energy generating coils are opposite to each other. The material on which the quantum energy generating coil of the first quantum energy generating device (300A) is formed is attached to the surface of the partition or partitioned wall, with two sides spaced apart from each other and facing each other (left, right, front, rear, top, bottom). , or installed so that the winding directions of a plurality of quantum energy generating coils printed on the surface of the material on 4 or 6 sides are in opposite directions, and are installed at a certain distance from the material or installed on one side of the fifth material plane. 1st power supply 310, 2nd power supply 320, 3rd power supply 330, 4th power supply 340, 5th power supply 350, 6th power supply (360), battery ( Pulse power generated from a selected power supply or direct current power output from a battery (not shown) is connected to a plurality of first and second quantum energy generating coils through conductors (not shown). When power is supplied, pulse-type electromagnetic fields generated at a 90-degree angle to the current flow direction in the first and second quantum energy generation coils are generated in opposite directions, and the center distance between the first and second quantum energy generation coils is opposite to each other. Directional electromagnetic fields overlap and disappear, creating pulsating quantum energy in a zero magnetic field state and irradiating it to the indoor space.

The frequency modulation range in the first, second, third, fourth, fifth, and sixth power supplies (310, 320, 330, 340, 350, and 360) is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, and 1MKHz. to 100MHz range, and 100MKHz to 10GHz range.

Figure 12g is a cross-sectional view showing the 8th quantum energy generator 378 that irradiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawing, the 8th quantum energy generator 378 is made of (polyimide, The eighth material is selected from PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film. A quantum energy generating coil formed on the plane of the eighth material. , It consists of a power supply 300 that supplies power to the quantum energy generation coil, and the material on which the quantum energy generation coil (first and second quantum energy generation coils) is formed is wound so that the winding directions of the quantum energy generation coil are opposite to each other. The material on which the quantum energy generating coil of the first quantum energy generating device (300A) is formed is attached to the surface of a wall divided into a specific space or divided into two sides spaced apart from each other (left, right, or front, rear, top). , bottom), or installed so that the winding directions of a plurality of quantum energy generating coils printed on the surface of the material on the 4th or 6th sides are in opposite directions, and are installed at a certain distance from the material, or the 8th material (180 ) The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply installed on one side of the plane. (360), pulse-type power generated from a power supply for which one type of battery (not shown) is selected or direct current power output from a battery (not shown) is supplied to a plurality of first and second power sources through conductors (not shown). 2 When power is supplied to the quantum energy generation coil, a pulse-type electromagnetic field generated at an angle of 90 degrees to the direction of current flow in the first and second quantum energy generation coils is generated in opposite directions, and the first and second quantum energy generation coils Electromagnetic fields in opposite directions overlap and disappear at the center distance between each other, and pulsating quantum energy is generated in a zero magnetic field state and irradiated to the indoor space.

In addition, the first material 110, the second material 120, and the third material are placed on two sides (left, right, front, back, top, bottom), four sides, or six sides spaced apart from each other in a specific space. Select one of the material (130), fourth material (140), fifth material (150), sixth material (160), seventh material (170), and eighth material (180) and print on the surface of the material. The winding directions of the quantum energy generating coils are installed to face each other, and a power supply installed at a certain distance from the material or installed on one side of the surface of the material, that is, a step-down (step-up) transformer (321), a rectifier circuit (322), and an input module ( 323a), calculation module 323b, and PWM (pulse width modlation) control method and pulse frequency modulation (PFM) and pulse frequency (density) control (PDM) and pulse repetition rate control (PRR) functions. Home appliances installed inside the space from the magnetic field detection sensor 325 of the second power supply 220 consisting of the control unit 323 consisting of the built-in control module 323c, the current detection sensor 324, and the magnetic field detection sensor 325. When the magnetic field generated by a device or industrial device is detected in real time and transmitted to the control unit 323, the operation module 323b of the control unit 323 performs PWM (pulse width modulation) of the magnetic field transmitted from the magnetic field detection sensor 325. ) The first and second quantum energy generation coils of the quantum energy generator are analyzed by analyzing detailed information such as control method and pulse frequency modulation (PFM), pulse frequency (density) control (PDM), and pulse repetition rate control (PRR). The calculation module 223b of the control unit 223 calculates the resonance frequency value that can be created into a zero magnetic field state by overlapping the magnetic field generated in the control unit 223, and transmits the calculated resonance frequency value to the control module 223c. By controlling the step-up transformer 321 and the rectifier circuit 322 to generate a proportional current value, power is supplied to the first and second quantum energy generation coils printed on the material from the second power supply 220. When supplied, the magnetic field generated from the first and second quantum energy generation coils of the first quantum energy generator is irradiated into the space and overlaps and annihilates the magnetic field generated from home appliances or industrial devices installed inside the space, producing quantum energy in a zero magnetic field state. creates

The magnetic field detection sensor 325 is a SQUID (Super conducting Quantum Interference Device) sensor, Nuclear Magnetic Resonance (NMR), Atomic Magnetic Resonance (AMR) sensor, Fluxgate sensor, MR ( You can select and use one of the following types: Magnetic Resistance sensor, MI (Magnetic Impedance) sensor, Hall effect sensor, optical fiber magnetic sensor, and search coil.

The frequency modulation range in the first, second, third, fourth, fifth, and sixth power supplies (310, 320, 330, 340, 350, and 360) is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, and 1MKHz. to 100MHz range, and 100MKHz to 10GHz range.

Figure 12h is a cross-sectional view showing the 9a quantum energy generator that irradiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawings, the 9a quantum energy generator 379a includes a first material 110, Which of the second material (120), third material (130), fourth material (140), fifth material (150), sixth material (160), seventh material (170), and eighth material (180) One material is selected, and adhesive is applied or sewn on the surface of the selected material to create a soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag shape. coils (up and down, left and right), extension coils, motor stator coils, square coils, RF coils, toroidal coils, Tesla coils, Mobius coils, Caduceus coils ( Among the Caduceus Coil and Rogoski coil shapes and combinations of these shapes, one coil shape is selected, and the selected shape is made up of iron (Fe), copper (Cu), zinc (Zn), and tin (Sn). ), stainless steel (STS304, STS316), aluminum (AL), titanium (Ti), nickel (Ni), platinum (Pt), and hastaloid materials are selected, and the selected material is selected using a laser. It consists of a quantum energy generation coil (first, first quantum energy generation coil) processed into the selected coil shape, and a power supply 300 that supplies power to the quantum energy generation coil. The method of irradiating quantum energy to a specific space is quantum energy generation coil. A first quantum energy generator (300A) in which the material on which the energy generation coils (first and second quantum energy generation coils) are formed is divided into a specific space so that the winding directions of the quantum energy generation coils are opposite to each other, or on a partitioned wall. A material with a quantum energy generating coil is attached to the surface of the material, and a plurality of prints are printed on the surface of the material on two sides (left, right, front, back, top, bottom), four sides, or six sides that are spaced apart and facing each other. A first power supply (310), a second power supply (320) installed so that the winding directions of the quantum energy generating coils are opposite to each other, and installed at a certain distance from the material or installed on one side of the eighth material plane, A pulse generated by a power supply selected from the third power supply 330, the fourth power supply 340, the fifth power supply 350, the sixth power supply 360, and the battery (not shown). When DC power output from a type of power source or battery (not shown) is supplied to a plurality of first and second quantum energy generation coils through conductors (not shown), current is generated in the first and second quantum energy generation coils. Pulse electromagnetic fields generated at an angle of 90 degrees to the flow direction are generated in opposite directions, and electromagnetic fields in opposite directions overlap and disappear at the center distance between the first and second quantum energy generation coils, creating pulsating quantum energy in a zero magnetic field state. is created and irradiated to the indoor space.

The frequency modulation range in the first, second, third, fourth, fifth, and sixth power supplies (310, 320, 330, 340, 350, and 360) is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, and 1MKHz. to 100MHz range, and 100MKHz to 10GHz range.

Figure 12i is a cross-sectional view showing the 9b quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawings, the 9b quantum energy generator 379b includes a first material 110, On the surfaces of the second material (120), third material (130), fourth material (140), fifth material (150), sixth material (160), seventh material (170), and eighth material (180). After applying adhesive, soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, and electric motor. Stator coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and their shapes EL Wire is manufactured by selecting one coil shape from a combination of shapes and winding the quantum energy generating coil with a conductive wire covered in the selected shape or using electroluminescence device manufacturing technology. The winding directions of the quantum energy generation coils are opposite to each other using the material on which the quantum energy generation coil (first, first quantum energy generation coil) is formed by winding the selected quantum energy generation coil shape using (electroluminescence wire). The material on which the quantum energy generating coil of the first quantum energy generating device (300A) is formed is attached to the surface of the partitioned wall or partitioned into a specific space so that it is oriented, but is spaced apart from two sides (left, right or front, (back, top, bottom), or 4 or 6 sides, are installed so that the winding directions of a plurality of quantum energy generating coils printed on the surface of the material are opposite to each other, and are installed at a certain distance from the material, or The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply installed on one side of the material plane. (360), pulse-type power generated from a power supply for which one type of battery (not shown) is selected or direct current power output from a battery (not shown) is supplied to a plurality of first and second power sources through conductors (not shown). 2 When power is supplied to the quantum energy generation coil, a pulse-type electromagnetic field generated at an angle of 90 degrees to the direction of current flow in the first and second quantum energy generation coils is generated in opposite directions, and the first and second quantum energy generation coils Electromagnetic fields in opposite directions overlap and disappear at the center distance between each other, and pulsating quantum energy is generated in a zero magnetic field state and irradiated to the indoor space.

The frequency modulation range in the first, second, third, fourth, fifth, and sixth power supplies (310, 320, 330, 340, 350, and 360) is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, and 1MKHz. to 100MHz range, and 100MKHz to 10GHz range.

Figure 12j is a cross-sectional view showing the 9c quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawings, the 9c quantum energy generator 379c includes a first material 110, Select from the 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), and 8th material (180). It consists of a material, a quantum energy generating coil with an eighth quantum energy generating device attached to it manufactured by the method shown in FIG. 12g on the surface of the selected material, and a power supply 300 that supplies power to the quantum energy generating coil, and a specific The method of irradiating quantum energy into space is to partition the material on which the quantum energy generating coils (first and second quantum energy generating coils) are formed into a specific space or to separate the material on the partitioned wall so that the winding directions of the quantum energy generating coils are opposite to each other. Attach the material on which the quantum energy generation coil of the first quantum energy generator (300A) is formed to the surface, but spaced apart from each other and facing two sides (left, right, front, rear, top, bottom), or four sides, or six sides. A first power supply (310) installed so that the winding directions of a plurality of quantum energy generating coils printed on the surface of the material are opposite to each other, and installed at a certain distance from the material or installed on one side of the eighth material plane. , a second power supply (320), a third power supply (330), a fourth power supply (340), a fifth power supply (350), a sixth power supply (360), or a battery (not shown). When the pulse-type power generated by the selected power supply or the direct current power output from the battery (not shown) is supplied to the plurality of first and second quantum energy generation coils through conductors (not shown), the first and second quantum energy generation coils are supplied. In the second quantum energy generation coil, pulse-type electromagnetic fields generated at an angle of 90 degrees to the current flow direction are generated in opposite directions, and electromagnetic fields in opposite directions overlap and disappear at the center distance between the first and second quantum energy generation coils. As a result, pulsating quantum energy is generated in a zero magnetic field state and irradiated to the indoor space.

The frequency modulation range in the first, second, third, fourth, fifth, and sixth power supplies (310, 320, 330, 340, 350, and 360) is 1Hz to 100Hz, 100Hz to 1KHz, 1KHz to 10KHz, 10KHz to 1MHz, and 1MKHz. to 100MHz range, and 100MKHz to 10GHz range.

Figure 12k is a cross-sectional view showing the 9d quantum energy generator that irradiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawings, the 9d quantum energy generator 379d includes a first material 110, Among the 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), and 8th material (180) It consists of a selected material, a quantum energy generating coil using an electroluminescence device manufactured by the method shown in Figure 8k on the surface of the selected material, and a power supply 300 that supplies power to the quantum energy generating coil, The method of irradiating quantum energy to a specific space is to partition the material on which the quantum energy generating coils (first and second quantum energy generating coils) are formed into a specific space or wall partitioned so that the winding directions of the quantum energy generating coils are opposite to each other. Attach the material on which the quantum energy generating coil of the first quantum energy generating device (300A) is formed to the surface of the 2 sides (left, right, front, back, top, bottom) or 4 sides spaced apart from each other, or A first power supply (310) is installed so that the winding directions of a plurality of quantum energy generating coils printed on the surface of the material on six sides are opposite to each other, and is installed at a certain distance from the material or installed on one side of the eighth material plane. ), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), or a battery (not shown). When power is supplied to the plurality of first and second quantum energy generating coils through conductors (not shown) with pulse-type power generated from a power supply of the selected model or direct current power output from a battery (not shown), the first and second quantum energy generating coils are supplied with power. , Pulse-type electromagnetic fields generated at a 90-degree angle to the direction of current flow in the second quantum energy generation coil are generated in opposite directions, and electromagnetic fields in opposite directions overlap and overlap at the center distance between the first and second quantum energy generation coils. It disappears, and pulsating quantum energy is generated in a zero magnetic field state and irradiated to the indoor space.

The electroluminescence device includes a power supply unit 361, an overload detection unit 362, a voltage adjustment unit 363, and a frequency modulation unit 364. It is composed of an EL driver 365, and the power supply unit 361 supplies DC power in the range of 6 to 50V to the voltage regulator 363 through the overload detection unit 362, and reduces the voltage to the voltage regulator 363 to the range of 10 to 20V. When the reduced voltage is supplied to the frequency modulator 364, the quantum energy generation coil is generated by signals oscillating from each oscillator circuit (not shown) in two or more oscillator circuits built in the frequency modulator 364. The power applied to the device is switched by a pulse width modulation signal to convert direct current power into alternating current power and supply it to the EL element 365 and the quantum energy generation coil. The amount of current applied to the quantum energy generation coil during operation is measured by an overload detection unit ( 362) measures in real time, and if the current amount is above the standard value, it cuts off the power. If the current amount is below the standard value, it connects the circuit electrically and supplies power.

The first power supply 310, the second power supply 320, the third power supply 330, the fourth power supply 340, the fifth power supply 350, the sixth power supply 360, and the battery. In the power supply (1st, 2nd, 3rd, 4th, 5th, 6th power supply (310, 320, 330, 340, 350, 360)) selected from (not shown), the frequency modulation range is 1Hz to 100Hz, 100Hz to 1KHz, If you set a level in the 1KHz to 10KHz range, 10KHz to 0.1MHz range, 0.1MKHz to 10MHz range, and 100MKHz to 10GHz range, modulate it to the set range and irradiate the electromagnetic field to the space through the quantum energy generation coil, it will be transmitted into the air in the space. It can sterilize bacteria and viruses floating or attached to the surface of an instrument (not shown) installed in a space.

Bacteria are single-celled organisms that are found almost everywhere, exist in large numbers, and can divide and multiply rapidly. Most bacteria are harmless, but there are three harmful groups: cocci, spiral bacteria, and bacilli. Coccal bacteria are The cells are round, spiral bacteria are coiled cells, and bacillus bacteria are rod-shaped. Harmful bacteria cause diseases such as tetanus and typhoid.

Viruses can survive and multiply only by taking over other cells, meaning they cannot survive on their own. Viruses cause infectious diseases such as colds, flu, mumps, MERS, and COVID-19.

The sterilization frequency of bacteria and airborne viruses is shown in Table 4 below.

number Bacteria and virus names Sterilization frequency (Hz) One actinomycosis 678,000 2 anthrax 900,000 3 Anthrax Symptoms 400,000 4 B coli (rod type) 683,000 5 B coli (filterable virus) 8,581,000 6 Bacillus 11,780,000 7 catarrh 1,800,000 8 Cholera Spirillum 851,000 9 infectious conjunctivitis 1,206,000 10 sun paste 160,000 11 diphtheria 800,000 12 glanders 986,,000 13 gonorrhea 600,000 14 influenza 1,674,000 15 leprosy 743,000 16 pneumonia 1,200,000 17 spinal meningitis 927,800 18 yellow glucose cocci 998,740 19 Stephylococcus Py0genes Albus 549,070 20 Steptococcus Py0genes 1,214,000 21 Syphilis (Treponema Pallidum) 900,000 22 tetanus 700,000 23 Tuberculosis (rod type) 583,000 24 Typhus (rod type) 900,000 25 Typhoid (passed filter) 9,680,000

Sterilization frequency (Hz) for each bacteria and virus

In addition, in the first power supply 310, the second power supply 320, the third power supply 330, the fourth power supply 440, the fifth power supply 350, and the sixth power supply 360. The health of occupants can be improved by modulating the frequency of power applied to quantum energy from a selected type of power supply to a range of 1Hz to 10KHz and irradiating an electromagnetic field into the space as shown in Table 5 through a quantum energy generation coil.

Frequency (Hz) that promotes physical health number Normalization of waves and stimulation of waves Frequency (Hz) One Normalization of kidney function 1335 2 Normalization of pituitary function 635 3 Stimulation of increase and normalization of high production (pituitary gland) 1725,645,1342 4 Stimulation of normal pineal gland function 662 5 Normalization of endocrine function 537 6 Stimulation and normalization of immune system function 835 7 Stimulation of normal colon function 635 8 Stimulation of normal thyroid function 763 9 Normalization of progesterone levels (according to levels) 763,1446,1443,763 10 Normalization of estrogen production levels (men and women) 1351 11 Normalization of testosterone production levels (men) 1444 12 Normalization of testosterone production levels (women) 1445 13 Stimulation of normal pancreatic function 654 14 Stimulation of normal liver function 751 15 Stimulation of normal kidney function 625 16 Stimulation of normal heart function 696 17 normalization of blood pressure 15 18 Stimulation of normal nervous system function 764 19 Stimulation of supralymphatic function 676 20 Stimulation of increased lymphatic circulation 153 21 Stimulation of normalized blood circulation 337 22 Increased blood volume/stimulation of circulation 17 23 Normalization of erythropoiesis 1524 24 Normalization of white blood cell production 1434 25 Normalization of hemoglobin production 2452 26 Stimulation of enhancement of DNA integrity 528 27 Stimulation of Enhancement of RNA Integrity 637 28 Stimulates clarity of thought/mental function 35 29 Stimulation of stability of emotional state 15 30 Removal of emotional trauma/energy blockage Stimulation 15 31 Stimulating the balance of well-being 1565 32 .Reduces chemical hypersensitivity 440 33 Reduces sensitivity to electrical substances 440 34 Stimulation of normalization of calcium metabolism 328 35 stimulation of nerve treatment 2 36 stimulation of bone healing 7 37 Stimulation of ligament healing 9.6 38 stimulation of muscle healing 13.6 39 Stimulation of capillary healing 15.3 40 Reduces disc swelling 25.3,324,15 41 Reduces excess fluid retention in joints and tissues 24.3 42 Reduces generalized back pain (fibromuscular pain syndrome) 326 43 Miraculous frequency, DNA repair, resonance with the human body and nature 528 44 Verdi's A' Frequency most consistent with nature 432 45 Free from guilt and fear, change sadness into joy 369 46 Clearing traumatic experiences and promoting change 417 47 Strengthens relationships, promotes communication, understanding, patience and love 639 48 Guided by the power of self-expression that leads to a life of purity and stability. 741 49 Awakening intuition and returning your frequency to spiritual order 852 50 Helps restore the spirit to its original form, connects directly with light and God 963

Source:The Rife Machine Report(November,2018,Edition);100P

(Beam Ray Clinical Instrument Sideband Sine Wave Audio Frequencies)

B.F. Sisken said that because the quantum wave fields of tissues and organs of the human body have unique frequencies, it is important to understand the natural frequencies of tissues and organs when performing wave therapy. The natural frequencies of each organ of the human body are nerves. Cell: 2Hz, bone; 7Hz, ligament; 10Hz, skin; It is said that resonance occurs well at 15Hz, 20Hz, and 72Hz.

Figure 12L is a cross-sectional view showing the 9e quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space. When explained with reference to the attached drawings, the 9e quantum energy generator 379e is a second material 120. , Material selected from the third material (130), fifth material (150), seventh material (170), and eighth material (180), quantum energy generation coil formed on the surface of the selected material, quantum energy generation It consists of a power supply that supplies coil power, and the method of irradiating quantum energy to a specific space is a selected material from which quantum energy generation coils (first and second quantum energy generation coils) are formed. The winding directions of the quantum energy generation coils are different from each other. Divide them into a specific space so that they face in opposite directions, or interview two materials with additional quantum energy generation coils formed at a certain distance in the center direction from the partitioned wall, with the sides on which the quantum energy generation coils are not formed, and create an outer border facing each other. Depending on the type of material, select a welder suitable for the material among ARC welding, TIG welding, MIG welding, and PVC welding and weld it, or seal it by caulking it with a sealant or applying an adhesive to join it.

The front and back or both sides or 2 sides of the top and bottom, or the front and back and both sides, or the 4 sides of the top and bottom and both sides, or the 6 sides of the front and back, both sides, and the top and bottom, that is, another space with a reduced volume is created and installed on one side of the surface of each material. The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), and the fifth power supply (310), the second power supply (320), the third power supply (330), or installed on one side inside a specific space or on one side outside the specific space and spaced apart from the specific space. A pulse-type power generated from a power supply selected from the power supply 350, the sixth power advanced unit 360, and a battery (not shown) or the direct current power output from a battery (not shown) is connected to a conductor (not shown). When power is supplied to a plurality of first and second quantum energy generation coils, pulse-type electromagnetic fields generated at an angle of 90 degrees to the direction of current flow in the first and second quantum energy generation coils are generated in opposite directions. At the center distance between the first and second quantum energy generating coils, electromagnetic fields in opposite directions overlap and disappear, creating pulsating quantum energy in a zero magnetic field state, creating a space filled with liquid (including water) divided by a material, and It is irradiated into a space filled with fluid.

When water molecules are irradiated with magnetic fields and quantum energy, they gain electrostatic attraction, causing interference over long distances, the hydrogen bonds between water dipoles are reduced, resulting in higher order, and the lumps of water molecules become smaller, forming so-called 'microclusters'. It creates a 'microcluster' phenomenon and is easy to evaporate, improving cooling efficiency with the latent heat energy of evaporation of water when evaporating. It causes electric polarization by giving small electric disturbance to water, and the water dipoles are rotated and aligned by magnetic fields and quantum energy. Ensures that the existing underlying state is permanently preserved.

American biochemist Lee H. Lorenzen uses special ceramics and laser technology to transform the molecular structure of water into a microcluster. This changes the quantum wave field of the water, making it more beneficial to the human body than ordinary water. They said it would become water. Therefore, drinking water that maintains these microclusters is said to be beneficial to your health.

Figure 13 is a cross-sectional view showing a configuration for irradiating quantum energy from the first quantum energy generating device 300A inside a space partitioned by a material in which a quantum energy generating coil is formed, which will be described with reference to the attached drawings.

The material from which the quantum energy generating coil is formed is a first material 110 such as paper, a second material 120 such as PVC plate, a third material 130 such as iron (Fe), and a fourth material such as general plywood ( 140), fifth material such as concrete wall (150), sixth material such as vegetable fiber (160), seventh material such as thin plate glass (170), eighth material such as transparent material such as polypropylene film, PVC film, etc. Select one material from (180), select a plurality of selected materials, and divide the space into the front and back, both sides, top and bottom, and form both sides on surfaces facing each other (e.g. front and back, both sides, top and bottom). The energy generating coils are divided so that the winding directions are opposite to each other.

In addition, a first power supply (310), a second power supply (320), a third power supply (330), a fourth power supply (340) installed on one side of each partitioned side or on one side outside the space or on the outside away from the space, The pulse-type power generated by the power supply 300, which is selected from the fifth power supply 350, the sixth power supply 360, and the battery (not shown), or the direct current power output from the battery is connected to the conductor (not shown). When power is supplied to the quantum energy generation coil formed on each material that divides the space, a magnetic field (direct current power is supplied) at a 90-degree angle in the direction of current flow to the quantum energy generation coil formed on the surface of the material on the facing side. When a magnetic field is generated in the form of a pulse, the winding directions of the quantum energy generating coils formed on the facing material surfaces are in opposite directions, so magnetic fields in opposite directions or pulse-shaped magnetic fields are generated on the facing surfaces, overlapping at the center of space. It disappears and quantum energy is created in a zero magnetic field state and irradiated into the space.

The term electromagnetic field used in the present invention is a phenomenon in which a periodically changing electromagnetic field propagates through space and has the same meaning as an electromagnetic wave. The magnetic field used in the present invention can be implemented in the form of a pulse wave, a continuous wave (sine wave), and a shock wave. there is.

Pulsed Electro Magnetic Field (PEMF)

Various studies have been reported to promote differentiation of stem cells using electromagnetic fields. Studies on bone regeneration using electromagnetic fields have also been reported. (Ceccarelli et al., A comparative analysis of the In In vitro Effects of pulsed Electro Magnetic Field treatment on Osteogenic Differentiation of Two Different Mesenchymal Cell Lineages,BioResearch Open Access,2013,2(4):283-294,) is an electromagnetic field of 75Hz and 2mT for osteogenic differentiation of various mesenchymal stem cells. Sun et al. cultivated bone marrow-derived mesenchymal stem cells in an electromagnetic field of 15 Hz and 1.8 mT, and the expression of alkaline phosphatase (ALP) and bone morphogenetic protein (BMP-2) was promoted, leading to bone cells. reported that differentiation was promoted, and Schwartz et al. promoted osteogenic differentiation of mesenchymal stem cells with an electromagnetic field of 15 Hz and 1.6 mT. The study on promoting osteogenic differentiation using electromagnetic fields used an electric field of 7.5-15 Hz and 0.5-5 mT. .

(schwartz Z, Simon BJ, Duran MA, Barabino G, Chonyeoogya R, Boyan BD, pulsed Electro Magnetic Fields enhance BMP-2 dependent osteoblastic Differentiation of human

Mesenchymal stem cell fields. J Orthop Res,2008;26(9);1250-1255).

As such, much research has been done on stimulation by electric and electromagnetic fields and their effects on the growth and recovery of bone and cartilage, and the field in which pulsed electromagnetic fields (PEMF) are currently most actively applied is the musculoskeletal clinical field. As for rheumatism, orthopedic spine disease, knee joint disease, tendinitis, avascular necrosis, etc., it is known that pulsed electromagnetic fields increase the expression of BMP in cartilage tissue in areas known to be incurable with conventional drug therapy. There is a report.

On the other hand, living tissue usually has a complex DC potential that forms a steady state biological potential, but when a part of this tissue is damaged due to disease or trauma, the equilibrium state is broken and damage occurs. A small current in the range of 10 μA, called Current of Injury (COI), flows. It is known that this current disappears when the damaged area is healed, and by using this phenomenon to flow a pseudo-damaging current (mimic COI) of about 10 μA from the outside to the damaged area, healing of the damaged area is promoted. In this way, it is possible to expect restoration of the function of cellular tissue that has decreased function or is in the process of degeneration, and even rejuvenate the tissue.

However, applying a small DC current of a certain value inside the living body requires implanting electrodes, which places a burden on the patient, so patients tend to avoid it, so it is not applied in clinical practice for skin care. Therefore, instead of this invasive therapy, applying a low-frequency pulsed electromagnetic field (PEMF) from outside the body generates an induced electromotive force within the body, and the resulting eddy current is a non-invasive treatment that promotes metabolism. Wet therapy is disclosed.

To explain in more detail, it has recently been proven through clinical experiments that applying a pulsed electromagnetic field (PEMF) of a specific waveform to biological tissue increases the creation of capillaries. In particular, capillaries are the body of all cells. Since it plays an absolute role in ensuring the metabolism of cellular tissue by supplying nutrients and oxygen to the cells, maintaining the active activity of cells and promoting the creation of new cells, using this feature of the pulsed electromagnetic field can effectively activate skin tissue. there is.

In addition, a plurality of small spaces (loading containers, boxes, lock-and-lock containers, drums, etc.) are spaced apart from each other within large and medium-sized spaces such as containers, logistics warehouses, refrigerated and refrigerated warehouses, and specific spaces such as the affected area of hospitalized patients. First material (110), second material (120), third material (130), fourth material on two facing sides (left, right, front, back, top, bottom), four sides, or six sides. (140), 5th material (150), 6th material (160), 7th material (170), and 8th material (180) are selected and wound on the quantum energy generating coil printed on the surface of the material. When the power supply 331 of the third power supply 330, which is installed so that the directions face each other and is installed at a certain distance from the material, supplies alternating current power of 220V 60Hz to the output power generator 332 through a conductor wire, the output power is generated. The generator 332 generates a high-frequency signal of 1MHz-15 MHz by implementing the 220V 60Hz AC power provided from the power supply unit 331 in the form of an inverter or amplifier, and then transmits it to the frequency modulator 333. The frequency modulator 333 determines the optimal transmission frequency using the feedback signals FB1 input from the receiver 341 and modulates the transmission frequency of the output signal. At the same time, the output time controller 334 performs wireless When the power transmitter 330 searches for the optimal frequency, the output time controller 334 controls the high-frequency signal to be output only for a short period of time, while the wireless power transmitter 334 controls the output after the optimal frequency is determined. , The output time control unit 334 adjusts the output time to output a high-frequency signal for most of the time and sends it to the transmitter 335, where the output power generator 332 generates power from the power coil 235-1 of the transmitter 335. When the high-frequency current corresponding to the high-frequency signal is input and sent to the transmission coil 335-2, the high-frequency current in the power coil 335-1 is induced by magnetic induction in the transmission coil 335-2, and the power receiving device ( 330a), a high-frequency signal, that is, a non-radiative electromagnetic wave, is generated and transmitted to the receiving coil unit 331a.

The power receiver 330a installed on one side outside a plurality of small spaces is composed of a receiving coil unit 331a, a power generator 332a, and a feedback signal generator 333a. The receiving coil unit 331a is a receiving coil ( It includes a load coil (331a-1) and a load coil (331b-1). The receiving coil (331a) receives a high-frequency signal transmitted from the transmitting coil (335-2). In an embodiment, the receiving coil 331a may have a spiral structure. In other embodiments, the receiving coil 241 may have a helical structure. Since power is transmitted by magnetic induction, the load coil 332a is implemented to be located as close to the receiving coil 231a as possible. Power generation The unit 332a receives high-frequency current from the load coil 332a and produces direct current power. The generated direct current power can be used to charge the battery of the wireless power receiver 330a. The feedback signal generator 333a generates a feedback signal FB1 corresponding to the received power value. Generating the feedback signal The unit 333a may be implemented as a passive RFID (RadionFrequency IDentification).

The power receiver 330a receives non-radiative electromagnetic waves transmitted from the transmission unit 335 of the power transmitter 330 at the receiving coil 331a and supplies them to the power generation unit 332a. The high voltage generator 330b generates direct current power appropriate for the required power, and at the same time, the feedback signal generator 333a generates a feedback signal FB1 corresponding to the power value received and supplies it to the high voltage generator.

The wireless power receiver has the same operation and configuration corresponding to the receiving coil unit 231a, power generator 332a, load unit 333, and feedback signal generator 333a shown in the wireless power receiver 330a. It has a receiving coil unit (not shown), a power generating unit (not shown), a load unit, and a feedback generating unit (not shown).

A typical resonant wireless power transmission method requires matching the resonant frequency to increase power transmission efficiency, but there is a problem in that this resonant frequency changes depending on the positions of the wireless power receivers.

On the other hand, the wireless power transmission system 330a of the present invention determines the optimal transmission frequency for power transmission based on feedback signals from power receivers input in real time and transmits a high frequency signal modulated at the determined optimal transmission frequency. It is implemented to do so.

The high voltage generator (330b) includes a DC voltage regulator (331b), a converter unit (332b), an inverter unit (333b), a resonance reactor (334b), a pulse transformer (335b), and a PWM (pulse width modlation) control method. A control unit (336b) with built-in pulse frequency modulation (PFM), pulse frequency (density) control (PDM), and pulse repetition rate control (PRR) functions, a gate driver (337b), and a first condenser (338b). and a second condenser yarn 339b.

The DC voltage regulator 331b uses a series or shunt regulator to adjust the DC voltage generated by the power generation unit 332b to be constant with the target voltage previously input to the control unit.

In most cases, the reference voltage is kept constant using a shunt regulator such as a zendiode, breakdown diode, or voltage adjustment tube.

The converter unit 332b boosts the direct current voltage to a high voltage through a switching operation.

The inverter unit 333b modulates the DC voltage boosted by the converter unit 332b into a voltage in the form of an alternating current pulse (Pulsed electromagnetic field (PEMF)).

The resonance reactor 334b matches the loads of the first quantum energy generation coil 341 and the second quantum energy generation coil 342.

The pulse transformer 335b boosts the output voltage of the inverter 333b. Pulse amplitude modulation (PAM) of the switching output of the first quantum energy generation coil 341 and the second quantum energy generation coil 342 and the inverter unit 353 that receives the output voltage of the pulse transformer 335b. In order to perform this, a signal is formed to control the output voltage of the converter unit 332b, and the intensity of the magnetic field generated from the first quantum energy generation coil 341 and the second quantum energy generation coil 342 is adjusted to generate quantum energy. In order to control the amount of production, a control unit 336b forms a signal capable of pulse frequency (density) control (PDM) independently of the amplitude of the pulse, and the voltage of the control signal applied from the control unit 336b is amplified to convert the converter ( 332b) and a gate driver 337b that applies power to the inverter 333b.

The first condenser (338b) inputs the voltage of the first condenser (338b) to the converter unit (332b) and the second condenser (339b) by reducing the ripple of the DC voltage boosted through the converter unit (332b). It includes a second condenser (339b) that provides input to unit (333b).

After boosting the supplied DC voltage through a switching operation in the converter unit 332b, the boosted DC voltage in the inverter unit 333b is modulated into a voltage in the form of an alternating current pulse (Pulsed electromagnetic field; PEMF), and then the pulse transformer ( In 335b), the output voltage of the inverter unit 333b is boosted and applied to the first quantum energy generation coil 341 and the second quantum energy generation coil 342.

In addition, an input unit (not shown) is separately built inside the control unit 336b so that the user can control the current value, voltage value, and frequency value supplied to the first quantum energy generation coil 341 and the second quantum energy generation coil 342. , power supply time and stop time (timer function) can be entered into the input unit.

Power in the form of a pulsed electromagnetic field (PEMF) generated in the high voltage generator 330b is supplied to the first quantum energy generation coil 341 and the second quantum energy generation coil 342 through the conductor 339b-1. When supplied, a magnetic field in the form of a pulsed electromagnetic field (PEMF) is generated in opposite directions between the first quantum energy generation coil 341 and the second quantum energy generation coil 342 at an angle of 90 degrees to the direction of current flow, and Lorentz The force acts and the magnetic field in the form of a pulsed electromagnetic field (PEMF) overlaps and disappears at the center distance between the first quantum energy generation coil 341 and the second quantum energy generation coil 342, causing a pulsating quantum in a zero magnetic field state. Energy is investigated.

Figure 14 is a cross-sectional view showing the 2-1 quantum energy generator (400A) of the bremsstrahlung type. When explained with reference to the attached drawings, the 2-1 quantum energy generator (400A) is a sealed glass tube (401). A thermionic emission cathode 404 having a filament is installed inside the left side of the main body, and a power supply 402 and a conductor 403 that supply direct current power to the cathode 404 are connected to the cathode 404, A first anode 413 made of copper (CU) or tungsten (W) is installed at a certain distance from the cathode 404, and a high voltage power supply 411 and a conductor (411) apply a high voltage to the first anode 413. 412) is connected to the first anode 413, and the center distance between the thermionic emission cathode 404 inside the sealed glass tube 401 and the first anode 413 placed on the left side at a certain distance is a sealed glass tube. A second anode 423 made of a material such as rhodium is installed in an opening with a certain area at the bottom of the 401, and a power supply 421 that supplies direct current high voltage power to the second anode 423 and A conductive wire 422 is connected to the second anode 423, a quantum energy dissipation layer 424 made of a material such as beryllium is formed on the externally exposed surface of the second anode 423, and the cathode 404 is formed. Power is supplied through the power supply 402, and the conductor 412 connected to the first anode 413 is connected to the + terminal on the output side of the first anode power supply 411, and the conductor 412 connected to the output side - terminal is connected to the negative terminal. Connect the conductor 403 connected to the output side - terminal of the power supply 402 for (404) to form a bias circuit between the power supply 411 for the cathode and the power supply 411 for the first anode and the first anode. A high voltage of 10 to 30 KV is applied between (413) and the cathode (404).

Additionally, a high voltage of 20 to 50 KV is applied between the first anode 413 and the second anode 423.

In addition, the conductor 422 connected to the second anode 423 is connected to the output side + terminal of the second anode power supply 421, and the power supply 411 for the first anode 413 is connected to the output side - terminal. The output side of - connects the conductor 422 connected to the terminal to form a bias circuit between the first anode power supply 411 and the second anode power supply 421, and the first anode 413 and the second anode power supply 421. A high voltage of 10 to 30 KV is applied between the anodes 423.

According to the third embodiment of irradiating quantum energy into this space, hot electrons are generated in the cathode 404 as power is supplied to the cathode 404, and the generated hot electrons are sent to the first anode high voltage generator 411 and the cathode 404. It is accelerated toward the first anode 413 by the bias circuit with the cathode power supply 402, and collides with the first anode (target) 413 made of tungsten (W) material by electric attraction, generating X-rays. At the same time, it is accelerated toward the second anode 413 by the high voltage generator 411 for the first anode, the high voltage generator 421 for the second anode, and the bias circuit, and reaches the anode 423 made of rhodium, etc., causing impact. Afterwards, a certain amount of kinetic energy is destroyed through attenuation as it collides with the extranuclear electrons of the anode material, and the remaining energy generates wave-like X-rays and quantum energy. As energy is incident on the emission layer 424 of non-radiative material, it is converted into photoelectrons and quantum energy with waves, and quantum energy is irradiated into space through radiation moderation.

In addition, the material of the sealed glass tube 401 is hard glass, and the vacuum degree of the sealed glass tube 401 is maintained in the range of 10 ^-6 to 10 ^-8 mmHg.

The material of the cathode 404 is tungsten (W) or any material containing tungsten (W), rhenium, tantalum (Tr), etc.

In addition, one material is selected and used among carbon nanotubes, carbon nanofibers (CNF), nano-wires, graphene, and nano-diamonds.

Figure 15 is a cross-sectional view showing the 2-2 quantum energy generator (400B) of the bremsstrahlung type. When explained with reference to the attached drawings, the 2-2 quantum energy generator (400B) is a sealed glass tube (437). A cathode 433 is installed in a fixture (not shown) at the center inside the right side of the main body, an electron emission source 434 is installed facing the cathode 433, and the cathode is spaced a certain distance to the left from the cathode 433. The gate electrode 443 is installed in a shape embracing (433). A first anode 435 with an inclined right side is installed at the center of the inner side of the sealing glass tube 437 opposite to the gate electrode 443, and an X-ray target plate is placed at the center of the right inclined surface of the first anode 435. It is installed at (436). In addition, the second anode 453 is installed on the sealed glass tube 437 projected vertically below the target plate 436 installed on the inclined surface of the first anode 435, and is interviewed on the surface of the second anode 453. A quantum energy emission layer 454 is installed. In addition, a first power supply 431 is installed at a certain distance from the left side of the sealed glass tube to apply a high voltage to the cathode 433 and the first anode 435 through a conductor, and the gate electrode is spaced downward at intervals. A second power supply 441 that supplies power to (443) is installed. The output terminals of the first power supply 431 and the second power air 441 are wired in common to form the first power supply 431. A bias circuit is formed between the second power supply 441 and the second power supply 441. A third power supply 451 that applies a high voltage to the second anode 453 is installed at a downward distance from the second power supply 441. do.

The output terminals of the second power supply 441 and the third power supply 451 are wired in common to form a bias circuit between the second power supply 441 and the third power supply 451.

When a high voltage in the range of 10KV to 30KV generated by the first power supply 431 is applied to the cathode 433 and the first anode 435 on which the electron emission source 434 is disposed through the conductor 432, the electron emission source ( A high potential difference is formed between the cathode 433 on which 434) is disposed and the first anode 435. Therefore, the first anode 435 serves as an accelerating electrode and simultaneously emits electrons from the electron emission source 434. It also serves as an X-ray target that emits X-rays through collisions of accelerated electrons.

For this purpose, the first anode has an There is. The target member is tungsten (W), copper (CU), molybdenum (Mo), cobalt (Co), chromium (Cr), iron (Fe), which emits X-rays when struck by an accelerated electron beam (E). It can be made of silver (Ag), tantalum (Tr), or yttrium (Y), but tungsten (W), which has a high melting point and excellent X-ray emission efficiency, is mainly used.

The gate electrode 443, which receives the power generated by the second power supply 441 through a conductor 442, is spaced a certain distance away from the first anode 435 in the right direction, and has a face surface on the surface of the cathode 433. It is installed close to the installed electron emission source 434 and is installed at intervals in a shape surrounding the electron emission source 434 and the cathode 433.

The gate electrode 434 may take the form of a horizontal electrode in the form of a thin metal perforated plate or metal mesh with a plurality of gate holes formed to allow the Braille beam to pass through.

When electrons accelerated by the high voltage applied to the first anode 435 by receiving a high voltage from the first power supply 431 collide with the X-ray target surface 436 of the first anode 435, some energy is emitted in the form of

The second anode 453 is connected to a power supply 451 and a conductor 452 that supplies direct current high voltage power, and quantum energy is radiated from a material such as beryllium on the externally exposed surface of the second anode 423. A layer 454 is formed, and a high voltage of 20 to 50 KV is applied between the first anode 413 and the second anode 423.

In addition, the conductor 422 connected to the second anode 423 is connected to the output side + terminal of the second anode power supply 451, and the power supply 431 for the first anode 431 is connected to the output side - terminal. The output side of - connects the conductor 422 connected to the terminal to form a bias circuit between the first anode power supply 431 and the second anode power supply 451, and the first anode 435 and the second anode power supply 451. A high voltage of 20 to 50KV is applied between the anodes (453).

According to the embodiment of the 400B configuration that irradiates quantum energy into this space,

As power is supplied to the cathode 433, electrons are generated in the electron emission source 434 installed in close contact with the cathode 433, and the generated electrons are formed between the first anode 435 and the electron emission source 434. It is accelerated toward the first anode 435 by a high potential difference (10 to 30 KV), and collides with the first anode (target) 436 made of tungsten (W) to generate X-rays, and at the same time, it is used for the first anode. It is accelerated toward the second anode 453 by the high voltage generator 431, the high voltage generator 451 for the second anode, and the bias circuit, reaches the second anode 453 made of rhodium, etc., and impacts the anode. As it collides with the extranuclear electrons of the material, a certain amount of kinetic energy is destroyed through attenuation, and the remaining energy generates wave-like X-rays and quantum energy, and the As it enters the emission layer 454 of the fibrous material, it is converted into photoelectrons and quantum energy with waves, and quantum energy is irradiated into space by radiation moderation.

In addition, the material of the sealed glass tube 437 is hard glass, and the vacuum degree of the sealed glass tube 437 is maintained in the range of 10 ^-6 to 10 ^-8 mmHg.

An electron emission source is installed on the cathode 404. The electron emission source may be provided on a separate substrate and coupled to the cathode 404, or may be formed directly on the surface of the cathode 304.

In addition, the electron emission source 443 is a substrate or cathode using one material selected from carbon nanotubes, carbon nanofibers, nano-wires, graphene, and nano-diamonds. (304) It can be formed by growing a number of carbon nanotubes directly on the surface using a chemical vapor deposition method or by applying carbon nanotube paste and then firing it.

The second quantum energy generator is composed of the 2-1 quantum energy generator 400A) and the 2-2 quantum energy generator 400B) as described above.

Figure 16 is a cross-sectional view showing a method of installing the 2-1, 2-2 quantum energy generators (400A, 400B) on the material dividing a specific space, which will be described with reference to the attached drawings.

The material for installing the 2-1, 2-2 quantum energy generators (400A, 400B) is a second material 120 such as non-conductive plates such as PVC, PE, PC, acrylic, and Beck, or iron (Fe), Copper (Cu), zinc (Zn), tin (Sn), stainless steel (304, 316), aluminum (AL), titanium (Ti), platinum (Pt), hastalloy, heat insulator or cold insulator is attached to the third panel. Material (130) or fourth material (140) such as wood plywood such as general plywood, Douglas fir plywood, core plywood, larch plywood, MDF, particle board, concrete, tile, etc., block, board, stone (marble exterior material, etc.), One of the fifth materials 150, such as inorganic materials, is selected, and a hole is made in the selected flat material so that the second anodes 423, 453 and the diffusion layers 424, 454 of the non-radiative material can be inserted at intervals from each other. Then, the second anodes 423 and 453 and the diffusion layers 424 and 454 of non-radiative material are inserted and installed into the perforated holes (not shown).

As power is supplied to the cathode 404 of the 2-1 quantum energy generator (400A), the cathode 404 is heated and hot electrons are generated on the surface, and the generated hot electrons are connected to the first anode high voltage generator 411 and It is accelerated toward the first anode 413 by a bias circuit with the cathode power supply 402, and strongly collides with the first anode (target) 413 made of tungsten (W) by electrical attraction to generate X-rays, At the same time, the ) accelerates toward, reaches and impacts the anode 423 made of rhodium, etc., then collides with the extranuclear electrons of the anode material, and a certain amount of kinetic energy is dissipated through attenuation, and the remaining energy has a wave -Line and quantum energy are generated, and as the Quantum energy generated by (Radiation Moderation) is irradiated into space.

As power is supplied to the cathode 433 of the 2-2 quantum energy generator 400B, electrons are generated at the electron emission source 434 installed in close contact with the cathode 433, and the generated electrons are generated at the first anode 435. ) is accelerated toward the first anode 435 by the high potential difference (10 to 30KV) formed between the electron emission source 434 and collides with the first anode (target) 436 made of tungsten (W). X-rays are generated at the first anode 436, and the and is accelerated toward the second anode 453 by the bias circuit, reaches the second anode 453 made of rhodium, etc., impacts it, and then collides with the extranuclear electrons of the second anode 453 material, producing a certain amount of electrons. The kinetic energy is dissipated by attenuation, and the remaining energy generates wave-like X-rays and quantum energy, and the ), it is converted into photoelectron and quantum energy with waves, and the quantum energy generated by radiation moderation is irradiated into space.

In the above, the technical idea of the present invention has been described along with the accompanying drawings, but this is an illustrative description of the best embodiment of the present invention and does not limit the present invention, and any person skilled in the art will It is a clear fact that anyone can make various modifications and imitations of dimensions, shapes, and structures without departing from the scope of the technical idea of the present invention, and such modifications and imitations are included in the scope of the technical idea of the present invention.

100:Material
110: first material 120: second material
130: Third material 140: Fourth material
150: Fifth material 160: Sixth material
170: 7th material 180: 8th material
200: Quantum energy generation coil formation method
210: First method of forming a quantum energy generating coil
220: Second method of forming a quantum energy generating coil
230: Third method of forming a quantum energy generating coil
240: Fourth method of forming a quantum energy generating coil
250: Fifth method of forming a quantum energy generating coil
260: Sixth method of forming a quantum energy generating coil
270: Seventh method of forming a quantum energy generating coil
280: Eighth method of forming a quantum energy generating coil
290a: 9a method of forming a quantum energy generating coil
290b: 9b method of forming a quantum energy generating coil
290c: 9c method of forming a quantum energy generating coil
290d: 9d method of forming a quantum energy generating coil
290d: 9d method of forming a quantum energy generating coil
290e: 9e method of forming a quantum energy generating coil
300: Power supply unit 310: First power supply unit
311: first rectifier 312: transformer
313: FET switch 314: second rectifier
315: Control unit 315a: Magnetic field measurement sensor
316: Switching control unit
317:Post regulator
320: Second power supply
321: Step-down (step-up) transformer 322: Rectifier
323a: Input module 323b: Operation module
323c: Control module 323: Control unit
324: Current detection sensor 325: Magnetic field detection sensor
330: Third power supply
331: input unit 332: output power generation unit
333: Frequency modulation unit 334: Output time control unit
335: Transmission coil unit
330a: Power receiver 331a: Receiving coil part
332a: Power generation unit 333a: Feedback signal generation unit
330b: High voltage generator
331b: converter unit 332b: inverter unit
333b: Resonant reactor 334b: Pulse transformer
335b: driving unit 336b: control unit
336b-1: Magnetic field detection sensor 337b: First condenser
338b: second condenser 319-1; gate driver
340: Fourth power supply
341: input unit 342: control unit
342a: Magnetic field detection sensor 343: Switch converter unit
344: high voltage generator 345: rectifier
350: Fifth power supply
351: Power supply unit 352: AC/DC conversion unit
353: Automatic power supply converter 354: Output unit
355: switching element 356: control unit
356a: Magnetic field detection sensor
360:6th power supply
361: Power supply unit 362: Overload detection unit
363: voltage adjustment unit 364: frequency modulation unit
364a;Magnetic field detection sensor 365: EL driving unit
371: First quantum energy generator 372: Second quantum energy generator
373: Third quantum energy generator 374: Fourth quantum energy generator
375: Fifth quantum energy generator 376: Sixth quantum energy generator
377: 7th quantum energy generator 378: 8th quantum energy generator
379a: 9a quantum energy generator 379b: 9b quantum energy generator
379c: 9c quantum energy generator
400A:2-1 quantum energy generator
400B:2-2 Quantum Energy Generator
401: Sealed glass tube 402: Power supply for cathode
404: Cathode 411: Power supply for anode
413: first anode 421: power supply for second anode
423: Second anode 424: Quantum energy emission layer
431: first power supply 433: cathode
434: Electron emission source 435: First anode
436: X-ray target plate 437: Sealed glass tube
441: Second power supply 443: Gate electrode
451: Third power supply 453: Second anode
454: Quantum energy emission layer

Claims (27)

It is a thick and strong paper such as commercially available thin white paper such as window paper, sago paper, Yusam paper, Taemi Basin paper, Sannae paper, Wansan paper, Kapyeong paper, and Gyeonyang paper, small wallpaper paper, large angle paper, interior wallpaper paper, etc., made of two or more Hwan, a recycled paper such as double-stitched paper such as gakji, wreath paper, yeongchang paper, cotton paper, rice paper, raised paper, new fuji paper, exterior paper, hejong paper, and seaweed paper, etc., and insect repellent paper. The first material 110, which is paper such as colored paper such as mixed paper, jade paper, red paper, yellow paper, blue paper, dark blue paper, and blue paper, and corrugated paper; and
A second material (120) that is a non-conductive material such as PVC, PE, PC, acrylic, bakelite, reinforced glass foam (FRP), Teflon, urethane, etc.;
Iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), titanium (Ti), platinum (Pt), hastalloy, insulation or cold insulator The third material 130, which is a metal material such as a panel attached; and
4th material (140) such as wood plywood such as general plywood, Douglas fir plywood, core plywood, larch plywood, MDF, particle board, etc.;
Fifth material (150), which is an inorganic material such as concrete, tile, block, brick, board, stone (marble exterior material, etc.);
6th material (160) such as vegetable fiber, vegetable fiber, mineral fiber, regenerated fiber, synthetic fiber, and inorganic fiber; and
7th material (170) such as thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, and blocking glass;
Any one of the 8th transparent materials (180) such as polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film. Materials selected and used (100); and
It is a thick and strong paper such as commercially available thin white paper such as window paper, sago paper, Yusam paper, Taemi Basin paper, Sannae paper, Wansan paper, Kapyeong paper, and Gyeonyang paper, small wallpaper paper, large angle paper, interior wallpaper paper, etc., made of two or more Hwan, a recycled paper such as double-stitched paper such as gakji, wreath paper, yeongchang paper, cotton paper, rice paper, raised paper, new fuji paper, exterior paper, hejong paper, and seaweed paper, etc., and insect repellent paper. Flexography, screen printing, and offset printing on the surface of the first material (110), which is selected from color paper such as mixed paper, jade paper, red paper, yellow paper, blue paper, dark blue paper, and blue paper, and corrugated cardboard. , Select any one of the rotary press, inkjet printing, and dry printing methods to print solenoid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, etc. on the surface of the material. Zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius coil, Caduceus. Among the Caduceus Coil, Rogoski coil, and combinations of these shapes, one coil shape is selected and the pre-manufactured conductive ink is converted into a pre-selected quantum energy generating coil shape using a printer. A first method 210 of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying; and
Select one material from among the second materials 120 of non-conductive materials such as PVC, PE, PC, acrylic, bakelite, reinforced glass foam (FRP), Teflon, urethane, etc., and apply one surface of the selected material. Or, after grinding both surfaces with an electric sanding machine and washing them with a cleaner, select one of the printing methods among flexography, screen printing, offset printing, rotary grinder, inkjet printing, and dry printing to create the surface of the second material (120). Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil. , Square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. A second method (220) of forming quantum energy generation coils (first and second quantum energy generation coils) by selecting one coil shape from among the shapes and printing and drying it with pre-manufactured conductive ink;
Iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), titanium (Ti), platinum (Pt), hastalloy, insulation or cold insulator Select one material among the third materials 130, such as metal materials such as panels attached, grind one surface of the selected material with an electric sanding machine, clean it with a cleaning agent, and then perform flexography and screen printing. Select one of the printing methods among offset printing, rotary press, inkjet printing, and dry printing to print solenoid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, and trigger on the surface. Coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square caduceus coil, RF coil, toroidal coil, Tesla coil, Mobius coil. Coil), (Caduceus Coil), Rogoski coil (Rogoski coil) shapes, and combinations of these shapes, one coil shape is selected and pre-manufactured conductive ink is used using a printer to generate quantum energy. A third method 230 of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying in a shape; and
Select one material among the fourth materials 9140) such as general plywood, Douglas fir plywood, core plywood, larch plywood, MDF, particle board, etc. and wood plywood, and grind one or both surfaces of the selected material with an electric sanding machine. , After washing with a cleaning agent, select one of the printing methods among flexography, screen printing, offset printing, rotary grinder, inkjet printing, and dry printing and apply soleroid coil, toroid coil, and cusp coil to the surface of the material. , Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil. , Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes are selected in advance. A fourth method (240) of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying the manufactured conductive ink into a pre-selected quantum energy generation coil shape using a printer; and
Select one material among the fifth materials (150) such as concrete, tile, block, brick, board, stone (marble exterior material, etc.) and other inorganic materials, and grind one surface of the selected material with an electric sanding machine and use a cleaner. After washing, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing, and apply soleroid coil, toroid coil, cusp coil, and Helmheltz to the surface of the material. Coil, gradient saddle coil, uniform saddle coil, toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil. Pre-manufactured by selecting one coil shape among (Tesla coil), Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. A fifth method (250) of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying the conductive ink into a pre-selected quantum energy generation coil shape using a printer; and
Select one material from the 6th material (160) such as vegetable fiber, vegetable fiber, mineral fiber, regenerated fiber, synthetic fiber, inorganic fiber, flexography, screen printing, offset printing, rotary press, inkjet printing, Select one of the dry printing methods and print soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag coil (top and bottom) on the surface of the material. , left and right), extension type coil, motor stator type coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Among Rogoski coil shapes and combinations of these shapes, one coil shape is selected, and pre-manufactured conductive ink is used to print and dry the pre-selected quantum energy generating coil shape using a printer. A sixth method 260 of forming quantum energy generation coils (first and second quantum energy generation coils); and
Select one material among the 7th material (170) of thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, and blocking glass lead, remove fine dust from the surface of the selected material with a vacuum cleaner, and then use ethyl alcohol or isopropyl After removing surface impurities using solvents such as alcohol, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing on one surface or both surfaces of the material. On the surface, soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator type. Coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and combinations of these shapes. Select one coil shape among the shapes and print and dry the pre-manufactured conductive ink into the pre-selected quantum energy generation coil shape using a printer to produce quantum energy generation coils (first and second quantum energy generation). A seventh method of forming a coil (270); and
Select one material from the 8th material (180) such as polyimide, PET (polyethyleneTerephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film. , After removing fine dust from the surface of the selected material with a vacuum cleaner, the soleroid coil and toroid are input to the control unit (microcomputer) of the printer using inkjet, flexographic, and gravure offset printing methods on one or both surfaces of the material. Coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF Coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and a combination of these shapes. Film thickness on the surface of the material in a pre-selected quantum energy generating coil shape using a printer using a conductive solution prepared in advance in a shape selected from among; 8th method (280) of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying under the following conditions: 4-10 μm, line width; 50-80 μm, volume resistivity; 4-10μΩ*cm ;class
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), Select one of the 8 materials (180) or apply a soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, or zigzag-shaped surface to the surface of each material. Coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus coil. Coil, Rogoski coil, and a combination of these shapes, select one coil shape, and select iron (Fe), copper (Cu), zinc (Zn), and tin (Sn) as the selected shape. , One material is selected from stainless steel (STS 304, STS316), aluminum (AL), titanium (Ti), platinum (Pt), and hastaloid, and the selected material is converted into the selected coil shape using a laser. Method 9a (290a) in which the processed quantum energy generating coil is attached after an adhesive is applied to the surface of the material to form a quantum energy generating coil (first and second quantum energy generating coils);
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), Select one material from among the 8 materials (180), or apply soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag shape to the surface of each material. Coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus coil. Coil), Rogoski coil (Rogoski coil), or a combination of these shapes, one coil shape is selected, and an adhesive is applied to the surface of the material, then a conductive metal wire coated in the selected shape is used to generate quantum energy. Quantum energy generation coils (first and second) are produced by winding them into the selected quantum energy generation coil shape using an EL wire (electroluminescence wire) manufactured using electroluminescence device manufacturing technology. 2 9b method (290b) of forming a quantum energy generation coil); and
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), Select one of the eight materials (180) or apply polyimide, PET (polyethyleneTerephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, or polypropylene film on the surface of each material. , Select one material among PVC films, remove fine dust from the surface of the selected material with a vacuum cleaner, and then use an inkjet, flexographic, or gravure offset printing method on one or both surfaces of the material to print the control unit ( Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension-shaped coil, electric motor input to microcomputer) Stator coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and their shapes A conductive solution prepared in advance in a shape selected from among the combinations of shapes is used to form a film thickness on the surface of the material using a selected printer; 8th method (280) of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying under the following conditions: 4-10 μm, line width; 50-80 μm, volume resistivity; 4-10μΩ*cm 9c method (290c) in which quantum energy generation coils (first and second quantum energy generation coils) made of are attached; and
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), Select one of the eight materials (180) or place a transparent substrate (1), first electrode (2), electroluminescent layer (3), and second electrode (4) on the plane of a material selected on the surface of each material. It is composed of. A first electrode (2) is formed in the form of a quantum energy generating coil-shaped stripe on the transparent substrate (1), and an organic electroluminescent layer (3) is formed on the first electrode (2). , The second electrode 4 is formed on the organic electroluminescent layer 3 in the form of a stripe in the shape of a quantum energy generating coil, where the first electrode 2 and the second electrode 4 are formed as a stripe. The shape of the quantum energy generating coil, which is formed in the form of a (stripe), is a soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag coil (up and down, left and right), extension-shaped coil, motor stator-shaped coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, logo Among Rogoski coil shapes and combinations of these shapes, one coil shape is selected, processed into the selected shape, and the stripes are insulated with an insulating material (not shown), and the winding direction is The 9d method (method 9d) in which a quantum energy generating coil is manufactured in a counterclockwise or clockwise direction, and the manufactured quantum energy generating coils (first and second quantum energy generating coils) are attached after an adhesive is applied to the surface of the selected material. 290d); and
Second material (120), iron (Fe), copper (Cu), zinc (Zn), tin (Sn), which is a non-conductive material such as PVC, PE, PC, acrylic, bakelite, and glass fiber molded foam (FRP). , Stainless steel (STS304, STS316), aluminum (AL), titanium (Ti), platinum (Pt), Hastalloy, the third material (130), which is a metal material such as panels with insulation or cold insulators, concrete walls, tiles. , the 5th material (150), which is an inorganic material such as block, brick, board, stone (marble exterior material, etc.), the 7th material (170), such as thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, and blocking glass, etc. Any one of the 8th transparent materials (180) such as polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film. Select the second material (120), which is a non-conductive material such as PVC and PE, and the third material (130), which is a metal material such as iron (Fe) and copper (Cu), concrete wall, tile, block, brick, board, etc. The material selected among the fifth material (150), which is an inorganic material, is used to grind the part where the quantum energy generating coil will be formed using an electric sanding machine and remove dust using a vacuum cleaner, and to use the seventh material (170) such as thick plate glass. , Any one of the 8th materials 180, such as polyimide, is selected by using a cleaning solution such as isopropyl alcohol to remove foreign substances from the area where the quantum energy generating coil is to be formed, followed by flexography and screen printing. Select one of the printing methods among offset printing, rotary press, inkjet printing, and dry printing to apply soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, and toroid coil to the surface of the material. , Trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil. , one coil shape is selected among the Caduceus Coil, Rogoski coil, and combinations of these shapes, and the pre-selected quantum is printed using a printer using pre-manufactured conductive ink. After printing and drying in the shape of an energy generating coil, iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), titanium (Ti), platinum (Pt) ), the third material 130, which is a metal material such as hastalloy, is faceted on the front and back sides with the printed coil surface facing outwards so that it contacts the liquid, or towards the inside so as not to come into contact with the liquid, and then each quantum energy is generated. After drawing the conductor (not shown) connected to the coil to the outside (projecting outward from the joint surface), weld the edge of the joint surface by selecting one of the ARC welding, TIG welding, and MIG welding methods. The thin plate glass is faceted on the front and back sides with the printed coil surface facing outwards so that it comes into contact with the liquid, or towards the inside so that it does not come into contact with the liquid, and then a conductor (not shown) connected to each quantum energy generating coil is placed on the outside (joint surface). After being drawn out (projecting outward), the edges of the joint surface are caulked with waterproof sealant, and the fifth material (150), which is an inorganic material such as concrete walls, tiles, blocks, bricks, boards, and stones (marble exterior materials, etc.), has quantum energy on the surface. The eighth material (180) made of transparent materials such as polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film, in which spinning coils are formed. Attaching any one of the materials,
Select and attach any one material among the second materials 120, which are non-conductive materials such as PVC, PE, PC, acrylic, bakelite, and reinforced glass foam (FRP) with a quantum energy-emitting coil formed on the surface, or iron ( Third metal materials such as Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), aluminum (AL), titanium (Ti), platinum (Pt), hastalloy, etc. The material 130 is a material selected from the 9th method 290e, which involves selecting one of the shapes of the quantum energy generating coil and attaching the quantum energy generating coil processed by model picking technology using laser technology to the selected shape. A quantum energy generating coil (200) manufactured by selecting a formation method depending on the type; and
First rectifier 311, transformer 312, FET switch 313, second rectifier 314, PWM (pulse width modulation) control method and pulse frequency modulation PFM (pulse frequency modlation) and a first pulse control unit 315 with built-in pulse frequency (density) control (PDM) and pulse repetition rate control (PRR) functions, a magnetic field detection sensor 315a, a switching control unit 316, and a post regulator 317. Power supply (310); and
A step-down (step-up) transformer (321), a rectifier circuit (322), an input module (323a), an operation module (323b), and a PWM (pulse width modulation) control method and pulse frequency modulation (PFM). and a control unit 323 consisting of a control module 323c with built-in pulse frequency (density) control (PDM) and pulse repetition rate control (PRR) functions, a current detection sensor 324, and a magnetic field detection sensor 325. 2 power supply (320); and
A power transmitter 330 consisting of a power supply unit 331, an output power generation unit 332, a frequency modulation unit 333, an output time control unit 334, and a transmission coil unit 335;
A power receiver (330a) consisting of a receiving coil unit (331a), a power generating unit (332a), and a feedback signal generating unit (333a); and
Converter unit (331b), inverter unit (332b), resonance reactor (333b), pulse transformer (334b), control unit (335b), gate driver (336b), magnetic field detection sensor (336b-1), first condenser (337b) ), and a third power supply 330 consisting of a high voltage generator 330b consisting of a second condenser 338b; and
A fourth power supply 340 consisting of an input unit 341, a control unit 342, a magnetic field detection sensor 342a, a switching converter unit 343, a high voltage generator 344, and a rectifier unit 345;
Power supply unit 351 consisting of an alternating current power (AC) supply (351a) or a direct current power (DC: battery) supply (351b), AC/DC conversion unit (352), automatic power supply switcher (353) (ATS), low frequency Generation and output unit 354, switching element 355, surface temperature measurement sensor of quantum energy generation coil, PWM (pulse width modlation) control method and pulse frequency modulation PFM (pulse frequency modlation) and pulse frequency ( A fifth power supply 350 consisting of a control unit 356 with built-in density) control (PDM) and pulse repetition rate control (PRR) functions, and a magnetic field detection sensor 356a;
The sixth power supply consisting of a power supply unit 361, an overload detection unit 362 of the EL driving unit and quantum energy generation coil, a voltage adjustment unit 363, a frequency modulation unit 364, a magnetic field detection sensor 364a, and an EL driving unit 365. A power supply unit 300 that selects one type from among the supply unit 360 and batteries (not shown) and supplies power to the quantum energy generation coil;
On the first material 110 and the surface of the first material 110, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil shape, Tesla coil. Select one coil shape among (Tesla coil), Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, and conductivity prepared in advance. Quantum energy produced by the first method 210 of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying ink in the shape of the quantum energy generation coil selected by the above-described printing method. The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), and the fifth power supply (350) supply power to the generation coil and the quantum energy generation coil. ), a sixth power supply (360), and a first quantum energy generator (371) consisting of a power supply (300) in which one type of battery (not shown) is selected; and
On the surfaces of the second material 120 and the first material 120, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and combinations of these shapes, and conductive ink prepared in advance. Quantum energy generation produced by the second method 220 of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying the selected quantum energy generation coil shape using the above-described printing method. The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), and the fifth power supply (350) supply power to the coil and the quantum energy generating coil. , a second quantum energy generator 372 consisting of a sixth power supply 360 and a power supply 300 in which one type of battery (not shown) is selected;
On the surfaces of the third material 130 and the first material 130, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and combinations of these shapes, and conductive ink prepared in advance. A quantum energy generation coil produced by the third method 230 of forming a quantum energy generation coil (first and second quantum energy generation coils) by printing and drying the selected quantum energy generation coil shape using the above-described printing method. and a first power supply (310), a second power supply (320), a third power supply (330), a fourth power supply (340), and a fifth power supply (350) that supply power to the quantum energy generation coil. A third quantum energy generator (373) consisting of a sixth power supply (360) and a power supply (300) selected from a battery (not shown).
On the surface of the fourth material 140 and the fourth material 140, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal, Tesla coil (Tesla) coil, Mobius Coil, Caduceus Coil, Rogoski coil, and a combination of these shapes, select one coil shape and prepare conductive ink in advance. A quantum energy generation coil produced by the fourth method 240 of forming a quantum energy generation coil (first and second quantum energy generation coils) by printing and drying the selected quantum energy generation coil shape using the above-described printing method. and a first power supply (310), a second power supply (320), a third power supply (330), a fourth power supply (340), and a fifth power supply (350) that supply power to the quantum energy generation coil. A fourth quantum energy generator (374) consisting of a sixth power supply (360) and a power supply (300) in which one type of battery (not shown) is selected;
On the surfaces of the fifth material 150 and the first material 150, select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and combinations of these shapes, and conductive ink prepared in advance. A quantum energy generation coil produced by the fifth method 250 of forming a quantum energy generation coil (first and second quantum energy generation coils) by printing and drying the selected quantum energy generation coil shape using the above-mentioned printing method. and a first power supply (310), a second power supply (320), a third power supply (330), a fourth power supply (340), and a fifth power supply (350) that supply power to the quantum energy generation coil. A fifth quantum energy generator (375) consisting of a sixth power supply (360) and a power supply (300) in which one type of battery (not shown) is selected.
On the surface of the sixth material (160) and the sixth material (160), select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, and conductive ink prepared in advance. A quantum energy generation coil produced by the sixth method (260) of forming a quantum energy generation coil (first and second quantum energy generation coils) by printing and drying the selected quantum energy generation coil shape using the above-described printing method. and a first power supply (310), a second power supply (320), a third power supply (330), a fourth power supply (340), and a fifth power supply (350) that supply power to the quantum energy generation coil. A sixth quantum energy generator (376) consisting of a sixth power supply (360) and a power supply (300) selected from a battery (not shown).
On the surface of the seventh material (170) and the seventh material (170), select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroidal coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, and conductive ink prepared in advance. A quantum energy generation coil produced by the seventh method (270) of forming a quantum energy generation coil (first and second quantum energy generation coils) by printing and drying the selected quantum energy generation coil shape using the above-described printing method. and a first power supply (310), a second power supply (320), a third power supply (330), a fourth power supply (340), and a fifth power supply (350) that supply power to the quantum energy generation coil. A seventh quantum energy generator (377) consisting of a sixth power supply (360) and a power supply (300) in which one type of battery (not shown) is selected;
On the surfaces of the 8th material (180) and the 8th material (180), select one of the printing methods among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing to print cusp coil and Helmheltz coil. , Gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil ( Select one coil shape among Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes, and conductive ink prepared in advance. A quantum energy generation coil produced by the first method 210 of forming a quantum energy generation coil (first and second quantum energy generation coils) by printing and drying the selected quantum energy generation coil shape using the above-mentioned printing method. and a first power supply (310), a second power supply (320), a third power supply (330), a fourth power supply (340), and a fifth power supply (350) that supply power to the quantum energy generation coil. An eighth quantum energy generator (378) consisting of a sixth power supply (360) and a power supply (300) in which one type of battery (not shown) is selected;
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), 8 Materials (180) Adhesive on the surface: soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension form. Coil, shape coil for motor stator, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil ) Select one coil shape among shapes and combinations of these shapes, and the selected shape includes iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS304, STS316), One material is selected from aluminum (AL), titanium (Ti), platinum (Pt), and hastaloid materials, and a quantum energy generating coil is attached that processes the selected material into the selected coil shape using a laser. Quantum energy generation coils (first and second quantum energy generation coils) manufactured by the 9a method (290a) and a first power supply (310) and a second power supply (320) that supply power to the quantum energy generation coils, The power supply (300) is selected from the third power supply (330), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), and (battery (not shown)). The 9th quantum energy generator 379a is comprised; and
One type of material is selected from the first material, second material, third material, fourth material, fifth material, sixth material, seventh material, and eighth material, or a soleroid coil, Troroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, Any one of the following shapes: RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. Select the shape, apply adhesive to the surface of the selected material, and then wind the quantum energy generating coil with a conductive wire covered in the selected shape, or EL Wire (EL Wire) manufactured using electroluminescence device manufacturing technology. The 9b method (290b) of the method of winding the selected quantum energy generating coil shape using an electroluminescent wire) supplies power to the manufactured quantum energy generating coils (first and second quantum energy generating coils) and the quantum energy generating coil. The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), The 9b quantum energy generator 379b consisting of a power supply 300 from which one type of battery (not shown) is selected; and
One material is selected among the first material, second material, third material, fourth material, fifth material, sixth material, and seventh material, and polyimide or PET (polyethyleneterephthalate) is applied to the surface of the selected material. Select one material among PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film, and use inkjet, flexographic, or gravure offset printing methods on one or both surfaces of the selected material. Using the soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, and zigzag coil (up and down, left and right) input to the control unit (microcomputer) of the printer. ), extension type coil, motor stator type coil, square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogowski Film thickness on the surface of the material with a conductive solution prepared in advance in a shape selected from among coil (Rogoski coil) shapes and combinations of these shapes; 8th method (280) of forming quantum energy generation coils (first and second quantum energy generation coils) by printing and drying under the following conditions: 4-10 μm, line width; 50-80 μm, volume resistivity; 4-10μΩ*cm A quantum energy generation coil manufactured by the 9c method (290c) to which quantum energy generation coils (first and second quantum energy generation coils) manufactured by are attached, and a first power supply (310) that supplies power to the quantum energy generation coil. ), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), and a battery (not shown). The 9c quantum energy generator (379c) consisting of the selected power supply (300); and
A transparent substrate (1), a first electrode ( 2), It is composed of an electroluminescent layer (3) and a second electrode (4). The first electrode (2) is formed in the form of a stripe in the shape of a quantum energy generating coil on the transparent substrate (1), and the first electrode (2) is formed in the form of a stripe in the shape of a quantum energy generating coil. An organic electroluminescent layer (3) is formed on the electrode (2), and the second electrode (4) is formed on the organic electroluminescent layer (3) in the form of a stripe in the shape of a quantum energy generating coil, The shape of the quantum energy generating coil formed in a stripe shape on the first electrode (2) and the second electrode (4) is a soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, and uniform saddle. Coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Tesla coil, Möbius coil. One coil shape is selected among the shapes of (Mobius Coil), Caduceus Coil, Rogoski coil, and combinations of these shapes, and the winding direction of the selected quantum energy generating coil is counterclockwise. Quantum energy generation coils (first and second) manufactured by the 9d method (290d) of forming a quantum energy generation coil by manufacturing a quantum energy generation coil in a direction or clockwise direction and attaching the manufactured quantum energy generation coil. Quantum energy generation coil) and the first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), and the fifth power supply that supply power to the quantum energy generation coil. A 9d quantum energy generator (379d) consisting of a power supply (300) in which one type of supply (350), a sixth power supply (360), and a battery (not shown) is selected.
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), One of the eight materials (180) is selected, and one printing method among flexography, screen printing, offset printing, rotary press, inkjet printing, and dry printing is selected on the surface of the selected material to create a cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF coil, toroidal coil, Select one coil shape among the Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil shapes, and combinations of these shapes, and select them in advance. Quantum energy generation coils (first and second quantum energy generation coils) are formed by printing and drying the prepared conductive ink in the shape of the selected quantum energy generation coil using a printer, and using the conservative materials formed in the quantum energy generation coil. The first space is divided and separated from the first space by a certain distance to create a space with a reduced volume. The method of creating the space is to interview the two materials on the side where the quantum energy generating coil is not formed, and then interview the edge of the interview. After sealing the border by welding it using any type of welder, such as an ARC welder, TIG welder, MIG welder, or PVC welder, or using a material formed with a quantum energy generating coil joined with an adhesive or sillint, the first space is created. , The first power supply (310), the second power supply (320), the third power supply (330), and the fourth power supply that supply power to each quantum energy generating coil formed on the surface of the material dividing the second space. (340), the 5th power supply (350), the 6th power supply (360), and the 9th quantum energy generator (379e), which consists of a power supply (300) in which one type of battery (not shown) is selected. A first quantum energy generator (300A) consisting of; and

A sealed glass tube 401, a thermionic emission cathode 404 having a filament installed on the left side of the glass tube, a power supply 402 that supplies direct current power to the cathode 404, and a predetermined distance away from the cathode 404. A first anode 413 made of copper (CU) or tungsten (W) is installed, a high-voltage power supply 411 that applies high voltage to the first anode 413, and a certain area on one side of the lower part of the sealed glass tube 401. A second anode 423 made of a material such as rhodium is installed in the opened opening, a power supply 421 that supplies direct current high voltage power to the second anode 423, and a power supply of the second anode 423. A quantum energy emission layer 424 made of a material such as beryllium is installed on the externally exposed surface, and power is supplied to the cathode 404 through a power supply 402, and a power supply 411 for the first anode. The conductor 412 connected to the first anode 413 is connected to the + terminal on the output side, and the conductor 412 connected to the output side - terminal of the power supply 402 for the negative electrode 404 is connected to the output side - terminal to connect the negative electrode. A 2-1 quantum energy generator (400A) of a first braking radiation type constituting a bias circuit between the power supply for power supply 411 and the first anode power supply 411; and
A sealed glass tube 437, a cathode 433 installed inside the glass tube on the right side, an electron emission source 434 is installed in contact with the cathode 433, and the cathode 433 is spaced a certain distance to the left from the cathode 433. ) A gate electrode 443 is installed in a shape that embraces the gate electrode 443, and a first anode 435 is installed at the center of the inner side of the sealing glass tube 437 opposite to the gate electrode 443, and the first anode 435 It is installed on the X-ray target plate 436 at the center of the right slope. In addition, the second anode 453 is installed on the sealed glass tube 437 projected vertically below the target plate 436 installed on the inclined surface of the first anode 435, and is interviewed on the surface of the second anode 453. A quantum energy emission layer 454 is installed. In addition, a first power supply 431 is installed at a certain distance from the left side of the sealed glass tube to apply a high voltage to the cathode 433 and the first anode 435 through a conductor, and the gate electrode is spaced downward at intervals. A second power supply 441 that supplies power to (443) is installed. The output terminals of the first power supply 431 and the second power air 441 are wired in common to form the first power supply 431. A bias circuit is formed between the second power supply 441 and the second power supply 441. A third power supply 451 that applies a high voltage to the second anode 453 is installed at a downward distance from the second power supply 441. and a second brake copying unit that configures a bias circuit between the second power supply 441 and the third power supply 451 by wiring the output terminals of the second power supply 441 and the third power supply 451 in common. A quantum energy generating coil, characterized in that it consists of a second quantum energy generating device (400B) consisting of a 2-2 quantum energy generating device (430) of the form, a material printed or attached to the surface, and a material divided by these materials. A quantum energy generator that radiates quantum energy to a specific space.
In paragraph 1:
The first material 110, on which conductive ink is printed on the surface in the shape of a quantum energy generating coil of which one shape is selected among various quantum energy generating coil shapes, is window paper, sago paper, Yusam paper, Taemi paper, Sannae paper, and Wansan paper. , Thick and strong paper such as commercially available thin white paper such as kapyeong paper and doggyang paper, small wallpaper paper, daegak paper, interior wallpaper paper, etc., which are two or more layers of paper such as gakji paper, wrapping paper, yeongchang paper, large paper paper, etc. Recycled papers such as agricultural paper, raised paper, new Fuji paper, exterior paper, hejong paper, sewn paper, paper with slightly thicker thickness, insect repellent paper, etc., jade paper, red paper, yellow paper, blue paper, dark blue paper. , One type of material is selected from colored paper such as Acheong paper and paper materials such as corrugated cardboard.
The second material 120 is selected from non-conductive materials such as PVC, PE, PC, acrylic, and Beck,
The third material is iron (Fe), copper (Cu), zinc (Zn), tin (Sn), stainless steel (STS 304, STS 316), aluminum (AL), hastalloy, and panels with insulation or cold insulation materials. A material is selected from among the metal materials, such as
The fourth material 140 is selected from wood plywood such as general plywood, Douglas fir plywood, core plywood, larch plywood, MDF, and particle board.
The fifth material 150 is selected from among inorganic materials such as concrete walls, tiles, blocks, bricks, and boards,
The sixth material 160 is selected from fibers such as vegetable fiber, vegetable fiber, mineral fiber, regenerated fiber, synthetic fiber, and inorganic fiber,
The seventh material 170 is selected from glass materials such as thin plate glass, thick plate glass, transparent polished plate glass, solar shielding glass, and blocking glass,
The eighth material 180 is any of transparent materials such as polyimide, PET (polyethyleneterephthalate), PMMA (polymethyl methacrylate), PDMS (polymethylsiloxane), polyester film, polyethylene film, polypropylene film, and PVC film. A quantum energy generating device that irradiates quantum energy to a material on which a quantum energy generating coil is printed or attached to the surface, and a specific space partitioned by these materials, characterized in that one material is selected and used.
In paragraph 1:
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), One material is selected among the 8 materials (180), and the shape of the quantum energy generating coil is printed with conductive ink on the surface of the selected material, processed with a laser from conductive metal, or wound with a coated conductive wire. Coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, square coil, RF Any one coil shape among coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil, and combinations of these shapes. A quantum energy generating device that irradiates quantum energy to a material on which a quantum energy generating coil is printed or attached and to a specific space partitioned by these materials, characterized in that it is selected and used.
In paragraph 1:
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), The method of forming a quantum energy generating coil using one of the 8 materials (180) is selected or the quantum energy generating coil shape is selected on the surface of each material.
The first material 110 removes dust from the surface of the material with a vacuum cleaner, the second material 120 removes and cleans the dust from the surface of the material with a sanding machine and a vacuum cleaner, and the third material 130 Dust is removed and cleaned from the surface with a vacuum cleaner, the fourth material 140 is used to grind the surface with a sanding machine and dust from the surface of the material is removed and cleaned with a vacuum cleaner, and the fifth material 150 is used to grind the surface with a sanding machine. Dust on the surface of the material is removed and cleaned with grinding and a vacuum cleaner, and a vaniss or primer is applied and dried naturally. For the sixth material 160, fine dust on the surface of the material is removed with a vacuum cleaner.
The seventh material 170 removes dust from the surface of the material with a vacuum cleaner, the eighth material 180 removes dust from the surface of the material with a vacuum cleaner, and the eighth material 180 removes dust from the surface of the material with a vacuum cleaner. Soleroid coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil, Square coil, RF coil, toroidal coil, Tesla coil, Mobius Coil, Caduceus Coil, Rogoski coil and combinations of these shapes. Select one of the input flexography, screen printing, offset printer, rotary press, inkjet printer, and dry printer to print and dry the conductive ink in the selected quantum energy generating coil shape, or form a soleroid. Coil, toroid coil, cusp coil, Helmheltz coil, gradient saddle coil, uniform saddle coil, toroid coil, Maxwell coil. Trigger coil, zigzag coil (up and down, left and right), extension coil, motor stator coil. , square coils, RF coils, toroidal coils, and combinations of these shapes are perforated with a laser and are placed in close contact with the surface of a material selected from the first to eighth materials, or the above. A quantum energy generating coil is formed by selecting one of the quantum energy generating coil shapes and winding it with a conductive metal wire or electroluminescence wire (EL wire) coated in the selected shape. The quantum energy generating coil is printed or attached to the surface. A quantum energy generator that irradiates quantum energy to materials and a specific space divided by these materials.
In paragraph 1:
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), 8The power supply that supplies power to the quantum energy generating coil formed on the surface of the material (180)
First rectifier 311, transformer 312, FET switch 313, second rectifier 314, PWM (pulse width modulation) control method and pulse frequency modulation PFM (pulse frequency modlation) and a first pulse control unit 315 with built-in pulse frequency (density) control (PDM) and pulse repetition rate control (PRR) functions, a magnetic field detection sensor 315a, a switching control unit 316, and a post regulator 317. power supply (310),
A step-down (step-up) transformer (321), a rectifier circuit (322), an input module (323a), an operation module (323b), and a PWM (pulse width modulation) control method and pulse frequency modulation (PFM). and a control unit 323 consisting of a control module 323c with built-in pulse frequency (density) control (PDM) and pulse repetition rate control (PRR) functions, a current detection sensor 324, and a magnetic field detection sensor 325. 2 power supply (320),
A power transmitter 330 consisting of a power supply unit 331, an output power generation unit 332, a frequency modulation unit 333, an output time control unit 334, and a transmission coil unit 335;
A power receiver (330a) consisting of a receiving coil unit (331a), a power generating unit (332a), and a feedback signal generating unit (333a); and
Converter unit (331b), inverter unit (332b), resonance reactor (333b), pulse transformer (334b), control unit (335b), gate driver (336b), magnetic field detection sensor (336b-1), first condenser (337b) ), and a third power supply 330 consisting of a high voltage generator 330b consisting of a second condenser 338b; and
A fourth power supply (340) consisting of an input unit (341), a control unit (342), a magnetic field detection sensor (342a), a switching converter unit (343), a high voltage generator (344), and a rectifier unit (345).
Power supply unit 351 consisting of an alternating current power (AC) supply (351a) or a direct current power (DC: battery) supply (351b), AC/DC conversion unit (352), automatic power supply switcher (353) (ATS), low frequency Generation and output unit 354, switching element 355, surface temperature of quantum energy generation coil, PWM (pulse width modlation) control method and pulse frequency modulation PFM (pulse frequency modlation) and pulse frequency (density) The fifth power supply 350, which consists of a control unit 356 with built-in control (PDM) and pulse repetition rate control (PRR) functions, a magnetic field detection sensor 356a, a power supply unit 361, an EL driver, and quantum energy generation. The sixth power supply unit 360, which consists of a coil overload detection unit 362, a voltage adjustment unit 363, a frequency modulation unit 364, a magnetic field detection sensor 364a, and an EL driver 365, and a battery (not shown). A material on which a quantum energy generation coil is printed, attached or wound on the surface, and a quantum energy generation coil divided by these materials are printed or attached on the surface, characterized in that a power supply is selected to supply power to the quantum energy generation coil. Or a quantum energy generator that irradiates electromagnetic fields and quantum energy to the material being wound and a specific space divided by these materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is
First material 110, quantum energy generation coil manufactured by the first method 210 of forming a quantum energy generation coil (first and second quantum energy generation coils) on the surface of the first material 110, quantum energy generation The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply that supply power to the coil. (360), a material on which a quantum energy generating coil is printed or attached to the surface, and A quantum energy generator that irradiates quantum energy into a specific space divided by these materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is a second material 120, which forms quantum energy generation coils (first and second quantum energy generation coils) on the surface of the second material 120. Quantum energy generation coil manufactured by method 2 (220), first power supply (310), second power supply (320), third power supply (330), and fourth power supply ( 340), a fifth power supply (350), a sixth power supply (360), and a battery (not shown), which is a second quantum energy generator (372) consisting of a power supply (300) selected from one of the following. A quantum energy generating device that irradiates quantum energy to materials on which a quantum energy generating coil is printed or attached to the surface and a specific space defined by these materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is
Third material 130, quantum energy generation coil manufactured by the third method 230 of forming quantum energy generation coils (first and second quantum energy generation coils) on the surface of the first material 130, quantum energy generation The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply that supply power to the coil. (360), a material on which a quantum energy generating coil is printed or attached to the surface, and A quantum energy generator that irradiates quantum energy into a specific space divided by these materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is
Fourth material 140, quantum energy generation coil manufactured by the fourth method 240 of forming a quantum energy generation coil (first and second quantum energy generation coils) on the surface of the fourth material 140 The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply that supply power to the coil. (360), a fourth quantum energy generator (374) consisting of a power supply (300) selected from one type of battery (not shown), a material on which a quantum energy generating coil is printed or attached to the surface, and these. A quantum energy generator that irradiates quantum energy into a specific space divided by materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is
Fifth material 150, quantum energy generation coil manufactured by the fifth method 250 of forming quantum energy generation coils (first and second quantum energy generation coils) on the surface of the fifth material 150 The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply that supply power to the coil. (360), a material on which a quantum energy generating coil is printed or attached to the surface, and A quantum energy generator that irradiates quantum energy into a specific space divided by these materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is
Quantum energy generation coil, quantum energy generation, manufactured by the sixth material 160, the sixth method 260 of forming a quantum energy generation coil (first and second quantum energy generation coils) on the surface of the sixth material 160 The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply that supply power to the coil. (360), a material on which a quantum energy generating coil is printed or attached to the surface, and A quantum energy generator that irradiates quantum energy into a specific space divided by these materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is
7th material 170, quantum energy generation coil manufactured by the 7th method 270 of forming a quantum energy generation coil (first and second quantum energy generation coils) on the surface of the 7th material 170 The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply that supply power to the coil. (360), a material on which a quantum energy generating coil is printed or attached to the surface, and A quantum energy generator that irradiates quantum energy into a specific space divided by these materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is
8th material 180, quantum energy generation coil manufactured by the 8th method 280 of forming a quantum energy generation coil (first and second quantum energy generation coils) on the surface of the 8th material 180 The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply that supply power to the coil. (360), a material on which a quantum energy generating coil is printed or attached to the surface, and A quantum energy generator that irradiates quantum energy into a specific space divided by these materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space,
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), It is manufactured by the 9th method (290a) of selecting one material among the eight materials (180) or forming a quantum energy generating coil (first and second quantum energy generating coils) on the surface of each material or selected material. Quantum energy generation coil, the first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), and the fifth power supply that supply power to the quantum energy generation coil. The quantum energy generation coil is characterized as the 9th quantum energy generator 379a, which consists of a power supply 300 selected from the group consisting of (350), the 6th power supply (360), and a battery (not shown). A quantum energy generator that radiates quantum energy to materials printed or attached to the surface and to a specific space divided by these materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), It is manufactured by the 9th method (290b) of selecting one material among the eight materials (180) or forming a quantum energy generating coil (first and second quantum energy generating coils) on the surface of each material or selected material. Quantum energy generation coil, the first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), and the fifth power supply that supply power to the quantum energy generation coil. The quantum energy generating coil is characterized in that it is the 9b quantum energy generator 379b consisting of a power supply 300 selected from the group consisting of (350), a sixth power supply (360), and a battery (not shown). A quantum energy generator that radiates quantum energy to materials printed or attached to the surface and to a specific space divided by these materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), It is manufactured by the 9th method (290c) of selecting one material among the eight materials (180) or forming a quantum energy generation coil (first and second quantum energy generation coils) on the surface of each material or the selected material. Quantum energy generation coil, the first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), and the fifth power supply that supply power to the quantum energy generation coil. The quantum energy generating coil is characterized as the 9c quantum energy generator 379c, which consists of a power supply 300 selected from the group consisting of (350), the 6th power supply (360), and a battery (not shown). A quantum energy generator that radiates quantum energy to materials printed or attached to the surface and to a specific space divided by these materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), It is manufactured using the 9d method (290d) of selecting one material from among the eight materials (180) or forming a quantum energy generating coil (first and second quantum energy generating coils) on the surface of each material or selected material. Quantum energy generation coil, the first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), and the fifth power supply that supply power to the quantum energy generation coil. A quantum energy generation coil characterized in that it is a 9d quantum energy generator (379d) consisting of a power supply (300) selected from one of (350), a sixth power supply (360), and a battery (not shown). A quantum energy generator that radiates quantum energy to materials printed or attached to the surface and to a specific space divided by these materials.
In paragraph 1:
A quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is
Among the 2nd material (120), 3rd material (130), 5th material (150), 7th material (170), and 8th material (180)
Quantum energy generation coil, quantum, manufactured by the e method (290e) of selecting one material or forming a quantum energy generation coil (first and second quantum energy generation coils) on the surface of each material or selected material. The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply that supply power to the energy generating coil. A quantum energy generating coil is printed or attached to the surface, characterized in that it is the 9e quantum energy generator 379e, which consists of a power supply 300 selected from a power supply 360 or a battery (not shown). A quantum energy generator that irradiates quantum energy to materials and a specific space divided by these materials.
In paragraph 1:
The 2-1 quantum energy generator, which radiates electromagnetic fields and quantum energy to a specific space, includes a sealed glass tube (301), a thermionic emission cathode (304) with a filament installed on the left side of the glass tube, and a direct current power supply to the cathode (304). A power supply 302 that supplies voltage, a first anode 313 made of copper (CU) or tungsten (W) installed at a certain distance from the cathode 304, and a high voltage is applied to the first anode 313. A second anode 323 made of a material such as rhodium is installed in an opening with a certain area on the lower side of the high voltage power supply 311 and the sealed glass tube 301, and a direct current high voltage is applied to the second anode 323. A power supply 321 that supplies power, a quantum energy radiating layer 324 made of a material such as beryllium is installed on the externally exposed surface of the second anode 323, and a power supply supplies power to the cathode 304. It is supplied through (302), and the conductor 312 connected to the first anode 313 is connected to the + terminal on the output side of the first anode power supply 311, and the power supply for the negative electrode 304 is connected to the output side - terminal. 2-1 of the first bremsstrahlung type, which configures a bias circuit between the cathode power supply 311 and the first anode power supply 311 by connecting the conductor 303 connected to the output side - terminal of the supply 302. It is a quantum energy generating device (400A), which is characterized in that the quantum energy generating coil is installed by inserting into a hole perforated of a certain size on a selected surface. The material printed or attached to the surface and the material divided by these materials are used. A quantum energy generator that radiates quantum energy to a specific space.
In paragraph 1:
The 2-2 quantum energy generator that radiates electromagnetic fields and quantum energy to a specific space is a sealed glass tube (337), a cathode (333) installed inside the glass tube on the right side, and an electron emission source (334) by interviewing the cathode (333). is installed, and a gate electrode 343 is installed in a shape that embraces the cathode 333 at a certain distance from the cathode 333 in the left direction, and is located inside the sealing glass tube 337 opposite to the gate electrode 343. A first anode 335 is installed at the center of the side, an X-ray target plate 336 is installed at the center of the right inclined surface of the first anode 335, and a target plate 336 is installed on the inclined surface of the first anode 335. A second anode 353 is installed on the sealed glass tube 337 projected vertically downward, and a quantum energy emission layer 354 is installed on the surface of the second anode 353, the left side of the sealed glass tube. A first power supply 331 is installed at a certain distance away from the cathode 333 and the first anode 335 to apply a high voltage through a conductor, and supplies power to the gate electrode 343 at a downward interval. A second power supply 341 is installed, and the output side terminals of the first power supply 331 and the second power air 341 are commonly wired to connect the first power supply 331 and the second power air 341. It constitutes a bias circuit between the second power supply 341 and a third power supply 351 that applies a high voltage to the second anode 353 at a downward distance from the second power supply 341. 2-2 quantum energy generator of the second braking radiation type, which configures a bias circuit between the second power supply 341 and the third power supply 351 by wiring the output terminal of the third power supply 351 to a common connection. (400B), characterized in that the quantum energy generating coil is installed by inserting into a hole drilled of a certain size on the surface.
A quantum energy generating device that irradiates quantum energy to materials on which quantum energy generating coils are printed or attached to the surface and to a specific space defined by these materials.
In paragraph 1:
The first way to irradiate quantum energy in a specific space is
On two sides facing each other (left, right, front, back, top, bottom), or four sides, or six sides, or two sides facing each other (left, right, front, back, top) that divide a specific space , bottom), or the shape of the quantum energy generating coil is printed on the surface of 4 or 6 sides, or the quantum energy generating coil of the first quantum energy generating device (300A) is printed using the first method 210, the second method ( 220), 3rd method (230), 4th method (240), 5th method (250), 6th method (260), 7th method (270), 8th method (280), 9th method (290a) ), any one of the 9b method (290b), the 9c method (290c), the 9d method (290d), and the 9e method is selected, and the first material 110 on which the quantum energy generating coil is formed by the selected method , 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), 8th material (180) After attaching one material so that the winding directions of the materials attached to the surfaces facing each other are opposite to each other, the first power supply 310 and the second power supply 320 are installed on one side of the surface of the material or installed on one side of the outside. ), the third power supply (330), the fourth power supply (340), the fifth power supply (350), the sixth power supply (360), and the battery (not shown). When power in the form of a pulse is supplied through (not shown), electromagnetic fields in the form of pulses in opposite directions are generated at an angle of 90 degrees to the direction of current flow in quantum energy generating coils installed on opposite sides (2, 4, and 6). Materials and these materials on which quantum energy generating coils are printed or attached to the surface, characterized in that the electromagnetic fields in the form of pulses in opposite directions are generated and extinguished at the center of space, thereby generating quantum energy in a zero magnetic field state and irradiating it into space. A quantum energy generator that radiates quantum energy to a specific space divided by .
In paragraph 1:
The second method of irradiating quantum energy in a specific space is
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), 8. On the surface of the material (180), circular holes of a certain diameter are made at intervals on the plane of the selected material, and the quantum energy of the 2-1 quantum energy generator (400A) of the first bremsstrahlung type is radiated into the hole. It is a structure in which the layer 324 is inserted, and with this structure, 1 side or 2 sides, or 4 sides, or 6 sides, or each side (1, 2, 3, 4, 5, 6) is placed in a specific space divided into 6 sides. The 2-1 method of irradiating quantum energy into space and
1st material (110), 2nd material (120), 3rd material (130), 4th material (140), 5th material (150), 6th material (160), 7th material (170), 8. On the surface of the material (180), circular holes of a certain diameter are made at intervals on the plane of the selected material, and the quantum energy of the second bremsstrahlung type 2-2 quantum energy generator (400B) is emitted at the holed portions. It is a structure in which the layer 354 is inserted, and with this structure, 1 side or 2 sides, or 4 sides, or 6 sides, or each side (1, 2, 3, 4, 5, 6) is placed in a specific space divided into 6 sides. Quantum energy generating coil, which is constructed on a surface and consists of a 2-2 method of irradiating quantum energy into space, is printed or attached to the surface, and quantum energy is irradiated into a specific space partitioned by these materials. Energy generating device.
In paragraph 1:
How to remove harmful electromagnetic waves in a specific space
Among the six sides that divide a specific space, on two sides (left, right, front, back, top, bottom) that are spaced apart and facing each other, or four sides, or six sides of the material, or on each side (1, 2, 3, Quantum energy generating coils are installed on the surfaces of (4, 5, and 6 sides) the first method (210), the second method (220), the third method (230), the fourth method (240), and the fifth method (250). Which of the 6th method (260), 7th method (270), 8th method (280), 9a method (290a), 9b method (290b), 9c method (290c), and 9d method (290d) One method is selected, and the quantum energy generation coil is formed by the selected method. The first material (110), the second material (120), the third material (130), the fourth material (140), and the fifth material (150) , Attach one of the sixth material (160), the seventh material (170), and the eighth material (180) so that the winding directions of the materials attached to the surfaces facing each other are opposite to each other, and then attach them to the surface of the material. The magnetic field sensor 325 installed on one side or on one side of the space detects the electromagnetic field (electromagnetic field) in the space generated by home appliances or industrial devices installed inside the space, and sends the real-time detected electromagnetic wave value to the first Power supply to one power supply selected from the power supply (310), the second power supply (320), the third power supply, the fourth power supply (340), the fifth power supply (350), and the sixth power supply (360). When transmitted to the control unit of the supply unit, the electromagnetic waves transmitted from the control unit are modulated to a frequency that can be canceled and removed, and the power of the modulated frequency is transmitted through a conductor (not shown) in the form of a pulse to the surfaces (2) facing each other in a specific space. When supplied to the quantum energy generation coil installed on the (side, 4th, 6th side), electromagnetic fields in the form of pulses in opposite directions are generated at an angle of 90 degrees to the direction of current flow in the quantum energy generation coil, and when the generated electromagnetic fields are irradiated, they are generated inside the space. A quantum energy generating device that irradiates quantum energy to a material on which a quantum energy generating coil is printed or attached to the surface and to a specific space defined by these materials, which is characterized in that it overlaps with and removes electromagnetic waves.
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Residential space, treatment space, sports facility space, educational facility space, public building space, industrial manufacturing facility space, livestock breeding facility space, or transportation space for ships, aircraft, vehicles, etc., or containers, logistics warehouses, frozen and refrigerated warehouses, etc. The first quantum energy generation and irradiation method to sterilize bacteria, viruses, and microorganisms floating inside a specific space such as a plurality of small spaces (loading containers, boxes, lock&lock containers, drums, etc.) within large or medium spaces is the first quantum energy. Energy generator (371), second quantum energy generator (372), third quantum energy generator (373), fourth quantum energy generator (374), fifth quantum energy generator (375), sixth quantum energy generator Energy generating device (376), 7th quantum energy generating device (377), 8th quantum energy generating device (378), 9a quantum energy generating device (379a), 9b quantum energy generating device (379b), 9c quantum One type of quantum energy generator is selected from the first quantum energy generator (300A) of the energy generator (379c), the 9d quantum energy generator (379d), and the 9th quantum energy generator (379e), and the selected The first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply (360) of the quantum energy generator. ), a power supply of one type is selected, and the current value, voltage value, frequency value, and power supply supplied to the first quantum energy generation coil and the second quantum energy generation coil of the quantum energy generation device selected from the selected power supply. The time and stop time (timer function) are entered into the input unit, and the input frequency-modulated power in the range of 0.1 MHz to 15 MHz is applied to the quantum energy generation coil to kill microorganisms attached to the surface of the facility inside the space or floating in the air. A quantum energy generating device that irradiates quantum energy to a material on which a quantum energy generating coil, characterized by sterilizing bacteria and viruses, is printed or attached to the surface, and to a specific space partitioned by these materials.
In paragraph 1:
A bioreactor in a residential space, treatment space, sports facility space, educational facility space, public building space where people live or work, or receive education or treatment, or a manufacturing facility space of an industrial company that processes strains or microorganisms in the bioreactor, or Spaces of livestock breeding facilities where livestock are raised, transportation spaces of ships, aircraft, and vehicles where people board, or large and medium-sized spaces and interiors such as containers, logistics warehouses, and frozen and refrigerated warehouses where food, protein preparations, flowers, etc. are stored. The method of generating quantum energy that improves the health of occupants, raised livestock, and living organisms stored inside a specific space such as a plurality of small spaces (loading containers, boxes, lock-and-lock containers, drums, etc.) is first quantum energy generation. Device 371, second quantum energy generator 372, third quantum energy generator 373, fourth quantum energy generator 374, fifth quantum energy generator 375, sixth quantum energy generator Device 376, 7th quantum energy generator 377, 8th quantum energy generator 378, 9a quantum energy generator 379a, 9b quantum energy generator 379b, 9c quantum energy generator A type of quantum energy generator is selected from the first quantum energy generator 300A of the device 379c, the 9d quantum energy generator 379d, and the 9e quantum energy generator 379e, and the selected quantum energy generator is selected. Among the first power supply (310), second power supply (320), third power supply (330), fourth power supply (340), fifth power supply (350), and sixth power supply (360) of the generator. A power supply of a certain type is selected, and the current value, voltage value, frequency value, power supply time, and Input the stop time (timer function), etc. to the input unit, and apply the frequency-modulated power in the range of 1Hz to 100Hz, 100Hz to 1KHz, or 1KHz to 1000KHz to the quantum energy generation coil, which is attached to the surface of the facility inside the space or A quantum energy generating device that irradiates quantum energy to a material on which a quantum energy generating coil is printed or attached to the surface and to a specific space partitioned by these materials, which is characterized by sterilizing microorganisms, bacteria and viruses floating in the air.
In paragraph 1:
It is installed in specific spaces such as residential spaces, treatment spaces, sports facility spaces, educational facility spaces, public building spaces, and ships, aircraft, and vehicles where people live, perform work, or receive education or medical treatment. 1st quantum energy generator (371), 2nd quantum energy generator (372), 3rd quantum energy generator (373), 4th quantum energy generator (374), 5th quantum energy generator (375), The 6th quantum energy generator (376), the 7th quantum energy generator (377), the 8th quantum energy generator (378), the 9th quantum energy generator (379a), the 9th quantum energy generator (379b), One type of quantum energy generator is selected from the first quantum energy generator (300A) of the 9c quantum energy generator (379c), the 9d quantum energy generator (379d), and the 9e quantum energy generator (379e). , the first power supply (310), the second power supply (320), the third power supply (330), the fourth power supply (340), the fifth power supply (350), and the sixth power supply of the selected quantum energy generator. Among the supply devices 360, a certain type of power supply is selected, and the frequency value of the power supplied to the first quantum energy generation coil and the second quantum energy generation coil of the quantum energy generator selected from the selected power supply is determined by the kidney function. Frequency required for normalization; 1335 Hz, Frequency required for normalization of pituitary function; 635 Hz, Frequency required for stimulation of increase and normalization of pituitary gland; 1725 Hz, 645 Hz, 1342 Hz, Frequency required for stimulation of normal pineal function; 662 Hz, Normalization of endocrine function Frequency required for; 537Hz, frequency required for stimulation and normalization of immune system function; 835Hz, the frequency required for stimulation of normal colonic function; 635 Hz, the frequency required for stimulation of normal thyroid function; 763 Hz, the frequency required for normalization of progesterone levels (as per level) 763 Hz, 1446 Hz, 1443 Hz, 763 Hz, the frequency required for normalization of estrogen production levels (men and women) 1351 Hz, testosterone production levels Frequency required for normalization (male); 1444 Hz, frequency required for normalization of testosterone production levels (female); 1445 Hz, frequency required for stimulation of normal pancreatic function; 654 Hz, frequency required for stimulation of normal liver function; 751 Hz, frequency required for stimulation of normal renal function Frequency required for stimulation of;625Hz, frequency required for stimulation of normal cardiac function; 696Hz, the frequency required for normalization of blood pressure; 15 Hz, frequency required for stimulation of normal nervous system function; 764 Hz, frequency required for stimulation of supralymphatic function; 676 Hz, frequency required for stimulation of increased lymphatic circulation; 153 Hz, frequency required for stimulation of normalized blood circulation; 337Hz, the frequency required for stimulation of increased blood volume/circulation; 17Hz, the frequency required for normalization of red blood cell production1524Hz, the frequency necessary for normalization of leukocyte production; 1434 Hz, the frequency required for normalization of hemoglobin production; 2452Hz, the frequency required to stimulate the enhancement of DNA integrity528Hz, the frequency necessary to stimulate the enhancement of RNA integrity; 637Hz, the frequency necessary for stimulation of transparency of thoughts/mental functions; 35Hz, the frequency necessary for stimulation of stability of emotional state; 15Hz, the frequency necessary for stimulation of removal of emotional trauma/energy disturbance; 15Hz, the frequency necessary for stimulation of balance of well-being; 1565Hz, . Frequency required to reduce hypersensitivity to chemical substances; 440 Hz, frequency required to reduce hypersensitivity to electrical substances; 440 Hz, frequency required to stimulate normalization of calcium metabolism; 328 Hz, frequency required to stimulate nerve healing; 2 Hz, frequency required to stimulate bone healing. ;7Hz, the frequency required for stimulation of ligament therapy;9.6Hz, the frequency necessary for stimulation of muscle therapy;13.6Hz, the frequency necessary for stimulation of capillary therapy;15.3Hz, the frequency necessary for reducing intervertebral disc swelling;25.3, 324, 15Hz, joint Frequency needed to reduce excess fluid retention in the body and tissues; 24.3Hz, frequency needed to reduce generalized back pain (fibromuscular pain syndrome); 326Hz, frequency needed for miracles, DNA repair, and resonance with the human body and nature; 528Hz, Verdi A' Frequency needed for the frequency most consistent with nature; 432 Hz, the frequency needed to liberate from guilt and fear, and transform sadness into relief; 369 Hz, the frequency needed to purify experiences of trauma and promote change; 417 Hz, communication, understanding , the frequency needed to promote patience and love, and strengthen relationships; 639 Hz, the frequency needed to guide you with the power of self-expression that leads to a pure and stable life; 741 Hz, the frequency needed to awaken intuition and restore your frequency to spiritual order; 852Hz, the frequency necessary to help restore the spirit to its original form and directly connect with light and God; 963Hz, the power of the above frequency is supplied to the first and second quantum energy generation coils, creating a pulse-shaped magnetic field at a 90-degree angle to the current flow. Quantum energy, which is generated and irradiated into the room of a specific space by overlapping and dissipating magnetic fields in the form of pulses in opposite directions at the center of space (center of surfaces facing each other), thereby generating quantum energy in a zero magnetic field state and irradiating it to the interior of a specific space. A quantum energy generator that radiates quantum energy to the material on which the generating coil is printed or attached to the surface and to a specific space divided by these materials.
In paragraph 1:
The method of irradiating electromagnetic fields and quantum energy to a specific space filled with liquid (underwater) or fluid (a mixture of gas and liquid) such as a swimming pool, fish farm, fumigation sauna, microbial reaction tank, or food factory fermentation tank is Method 9e (290e). ) Select any one material among the second material (120), third material (130), fifth material (150), seventh material (170), and eighth material (180) in which the quantum energy generating coil is formed. And, it is divided into a specific space or attached to the surface of a partitioned wall so that the winding directions of the quantum energy generating coils formed on the surface of the selected material are opposite to each other on the opposite sides, and are spaced apart from each other on two opposing sides (left, Install the winding directions of a plurality of quantum energy generating coils printed on the surface of the material (right, front, back, top, bottom), or on 4 or 6 sides, in opposite directions, and 2-1 quantum energy generator. In the case of (400A) and the 2-2 quantum energy generator (400B), one side or each side (side 1, side 1 and side 2, side 1 and side 2 and side 3, side 1 and 2) dividing the space Then, after drilling holes on all 6 sides (in the order of 3 and 4) with a certain diameter, insert the quantum energy emission layers of the 2-1 quantum energy generator (400A) and the 2-2 quantum energy generator (400B) into the drilled holes. and a first power supply (310), a second power supply (320), a third power supply (330), and a fourth power supply installed externally at a certain distance from the material after sealing the gap with a caulking material (not shown). Pulse-type power generated from a power supply selected from among the power supply 340, the fifth power supply 350, the sixth power supply 360, and the battery (not shown), or output from a battery (not shown) When direct current power is supplied to a plurality of first and second quantum energy generation coils through conductors (not shown), a pulse type is generated at a 90-degree angle to the direction of current flow in the first and second quantum energy generation coils. Electromagnetic fields are generated in opposite directions, and the electromagnetic fields in opposite directions overlap and disappear at the center distance between the first and second quantum energy generating coils, and pulsating quantum energy is generated in a zero magnetic field state, dissolving the liquid (water) partitioned into materials. (including) is irradiated into the filled space and the fluid-filled space, the 2-1 quantum energy generator (400A) supplies power generated by the power supply (402, 411, 421), and the 2-2 quantum energy generator (400B) ) is supplied with the power generated by the power supply (431, 441, 451) through a conductor (not shown), the emission layer 424 of the non-radiative material of the 2-1 quantum energy generator (400A) and the 2- 2 Quantum energy in the form of bremsstrahlung radiation is generated in the emission layer 454 of the non-radiative material of the quantum energy generator 400B and is irradiated to the space filled with liquid (including water) divided by the material and the space filled with fluid. A quantum energy generating device that irradiates quantum energy to a material on which a quantum energy generating coil is printed or attached to the surface and a specific space partitioned by these materials.