TWI460250B - Light and its material in energy power generation applications - Google Patents

Description

Light waves and their materials for energy generation applications

The invention relates to a mismatched metal or light wave power generation application, and is widely used in the technical fields of radiation, light wave power generation and electromagnetic.

The former raw material is made of metal nitrate, dissolved in water, and after adding a suitable reactant (such as triethylamine), the acid is added to adjust to an appropriate pH so that all metal ions can be completely precipitated. This is used for conductive applications and has temperature limitations. It can be seen that the above prior art still has many defects, and needs to be further improved.

Therefore, there is a need for a lightwave power generation application.

Generators generally require cooling, so a new system is needed to make it possible to generate electricity at ambient temperature.

In order to solve the shortcomings of the existing technology, the relevant manufacturers do not bother to find a solution, but the design that has not been applied for a long time has been developed, which is obviously an issue that the relevant industry is anxious to solve.

In view of the shortcomings of the above-mentioned prior art, the inventors actively research and innovate based on years of practical experience and expertise in designing and manufacturing such products, in order to create a new type of mismatched metal and its application, and can improve the general market. Existing conventional techniques have made it more practical. After continuous research, design, and repeated trials of samples and improvements, the invention has finally been created with practical value.

The object of the present invention is to overcome the shortcomings of the prior art, and the main technical problem to be solved by the mismatched metal is to have good radiation, light wave power generation, electromagnetic and the like.

Another object of the present invention is to provide a metal which is widely used in the electromagnetic field, radiation reaction, light wave power generation engineering, and electromagnetic wave generation.

It is still another object of the present invention to provide a light wave power generator that is more practical and can greatly improve economic efficiency, thereby having an overall improved efficiency and industrial value.

The object of the present invention and solving the main technical problems thereof are achieved by the following technical solutions.

The object of the present invention and solving the technical problems thereof can be further achieved by the following technical measures.

A miscible metal having electromagnetic wave characteristics, characterized in that the miscible metal is an inorganic or organic compound which is mixed with one or more monovalent, divalent or trivalent metal salts having a carboxyl group or an amino group and water, and an amino group or a carboxyl group. The base or acid is uniformly precipitated, and after the reaction, a divalent miscible metal or a miscible composite metal having an amino group and a carboxyl group is obtained, which includes one or more kinds of the complex metals.

A mismatched metal having electromagnetic properties, characterized in that the miscible metal is an inorganic or organic compound which is mixed with one or more monovalent, divalent or trivalent metal salts having a carboxyl group or an amino group and water, and an amino group or a carboxyl group. A base or an acid is uniformly precipitated, and after the reaction, a divalent miscible metal or a miscible composite metal having an amino group and a carboxyl group, which includes one or more kinds of a miscible metal, is obtained.

A light wave power generation generator characterized in that the structure of the light wave power generation generator is: "two pieces" have appropriate anti-electromagnetic radiation materials or mirrors, placed on both ends of a gas or solid or liquid or electromagnetic radiation medium, and emit electromagnetic Radiation medium or containing the previously described mis-synthesis metal, electromagnetic radiation back and forth between the "two pieces" of material or the lead or mirror of the enclosed light chamber, resulting in resonance energy transfer to ionization or current, "two pieces" of material Or the lead or mirror has both electrodes and is electrically conductive, and there is a magnetic field or a superconducting magnetic field around the electromagnetic wave resonance or the electronic part to make the magnet generate stronger electromagnetic force and generate stronger current.

The above-mentioned light wave power generation generator is characterized in that: the "two pieces" are a group, and one or more sets of anti-electromagnetic radiation materials having two planes or one plane, one concave surface or one convex surface, one concave surface or two concave surfaces. Or lead or face mirror.

The light wave power generation generator described above has a more special structure in which the "two pieces" of anti-electromagnetic radiation material or the mirror of the inner chamber is closed by a concave surface, and the other end is provided with a concave or convex surface, and the external light source is provided. Guided to the focal point of the concave surface and the spot light source is reflected by the concave surface to emit parallel light rays, and the parallel light rays are concentrated in the light-closed manner through the concave or convex surface at the other end to be concentrated, and the conductive and focused light rays can be integrated. The frequency and energy of the light ray improve.

The light wave power generator described above is characterized in that the electromagnetic radiation comprises a photon light source, or a misaligned metal that emits electromagnetic waves, or other radiation factor, or a free electron, or a gas, solid or liquid medium in ionization or electrophoresis. With the reflection fluctuation in the magnetic field, the light wave generator can be generated, or the power supply can be used in multiple sets and multiple sets in parallel.

The light wave power generation generator described above is characterized in that the magnetic field and structure of the light wave power generation generator are: the magnets are tightly arranged to form a magnetic field, and the magnetic field direction of each magnet is sequentially up, right, and down, as viewed from the side. Left, upper, right, lower, left..., every four magnets are in one cycle, and the other row of magnets is in the order of up, left, down, right; up, left, down, right... .., placed in parallel to form a linearly polarized magnetic field or arranged in the same direction, or two rows of linearly arranged magnets are concentrically arranged, the center of the surface is a small concentric circle simplified to a pure electrode, attached to the anti-electromagnetic radiation material or The electrons and electromagnetic radiation of the mirror are radiated. At the edge of the circumference of the magnet body, the electrode has an anti-electromagnetic radiation material or a mirror reflection, so that the coil can generate an induced current.

The light wave power generator described above can adjust the "two pieces" distance or the intensity of the light source or the light radiation to adjust the magnitude of the induced current.

The light wave power generation generator described above is characterized in that the light-closed inner chamber is filled with one or more kinds of gas or liquid or semiconductor or solid medium, and is uniformly mixed with a conductor or a superconductor or a misaligned metal that emits electromagnetic waves, and is received by light or A medium that is charged to an excited state to a source that emits stimulated radiation or that is exposed to light to produce a free body.

The light wave power generation generator described above is characterized in that the light-closed inner chamber has a complementary free electron or a light source or a medium, and the wire can be used to connect the solar energy and the conductive or superconducting medium to the device to absorb electrons, or the reflective conductive or super. The metal-containing mirror contains a light-absorbing catalyst to absorb some free electrons; or it can reflect the light from the semi-lens light into the device to supplement the light, or the fiber is dimmed or a rechargeable battery source or source is placed between the two pieces of the power generating device. The above-mentioned light-sealed inner chamber has a hole for opening a gas or solid or liquid medium to replenish the medium.

The light wave power generating generator described above is characterized in that the light-closed inner chamber is filled with one or more gases selected from the group consisting of: air, argon ions, helium ions, KTP frequency doubling, copper steam, gold steam, helium. , 钕雅克.铒雅克, 铒 铒 鈥, 鈥 克, hydrogen fluoride, carbon dioxide, carbon monoxide, halogen, argon, nitrogen, oxygen, rare rare gases, ArF, KrF, XeCl, XeF, cadmium, Xe ₂ , Kr ₂ , Ar ₂ , , , XeF ^* , XeBr ^* , ArCl ^* , XeCl ^* , ArF ^* , KrF ^* , HgCl ^* , HgBr ^* , Kr ₂ F ^* , Xe ₂ Cl ^* , KrO ^* , XeO ^* , ArO ^* or CF ₃ l, wherein ^* is an ionized body.

The light wave power generator according to the foregoing, characterized in that the light-closed inner chamber is filled with one or more liquids or solids, wherein the liquid is a liquid laser of an active medium, selected from the group consisting of: dye laser; The solid is a solid laser of the active medium, selected from the group consisting of: ruby laser, yttrium aluminum garnet laser, arsenic bismuth laser or strontium crystal laser; using semiconductor as material, selected from: gallium arsenide, arsenic gallium phosphide, Gallium arsenide aluminum, indium phosphide or two or six groups of zinc selenide and zinc sulfide, ternary or quaternary compound semiconductor, indium gallium nitride / indium gallium nitride / aluminum oxide, aluminum indium gallium phosphide / Indium gallium phosphide / gallium arsenide, aluminum gallium arsenide / gallium arsenide, aluminum gallium arsenide, Se, germanium atoms, barium strontium arsenate, germanium phosphide or gallium selenide semiconductor laser.

The object of the present invention and solving the main technical problems thereof are also achieved by the following technical solutions. A mismatched metal proposed in accordance with the present invention can be applied to applications such as radiation, power generation, and electromagnetics.

The present invention has significant advantages and advantageous effects over the prior art. According to the above technical solution, in order to achieve the foregoing object, the main technical content of the present invention is as follows: The present invention proposes a miscible metal in which a metal salt solution having a carboxyl group and/or an amino group is mixed with an amino group and/or a carboxyl group according to a conventional method. The inorganic base or acid is uniformly precipitated to form a mismatched metal having a carboxyl group and an amino group. The raw material is still metal. After it is dissolved in water, acetic acid or citric acid is added to react as a carboxyl metal, and then ammonia or ethylenediamine reagent is added to adjust to the appropriate pH value. At this time, the solution will form a micro-gelatinous liquid, called sol. (Sol). Then it is heated and concentrated or filtered. After most of the water disappears, the sol turns into a thicker gelatinous substance called gel. This gel is obtained as the desired power generating magnet. Some mismatched metals can emit electromagnetic radiation waves as shown in Figure 1, including one or more mismatched metals, such as mismatched composite metals. If the obtained powder is added with some external cement or other substances, the arrangement of positive and negative ions is not too neat, and the electromagnetic radiation waves are weak, and even only electromagnetic radiation waves are felt. A group of electrons in a ferrous iron will form a magnetization (field) due to the spin in the same direction (rotation like a gyro). After the reaction of the ruthenium lead through the amino group and the carboxyl group, only two valences remain. The electron pair will form a positive (negative) field of magnetization (field) due to spin in the same direction (rotation like a gyro). The two sides have positive and negative polar functional groups. The positive and negative polar functional groups are positive and negative, and react with amino and carboxyl groups. After the lead, the magnet is magnetized and arranged neatly. The electromagnetic radiation wave is not generated by the magnetic force. Similarly, only the divalent composite metal is easily emitted by the reaction of the amino group and the carboxyl group.

The powder obtained by the above method has a positive and negative ion orientation of the carboxyl group and the amino group, and the arrangement is like a positive and negative electrode arrangement of the magnet, and the positive and negative electrodes are connected in a straight line, and many small spins accumulate like a large substance electron to the spin electron flow to a convoluted form ( As shown in Fig. 2), as the coil is beveled, the electromagnetic force is emitted from the oblique direction of the oblique line. The linear magnetic field is arranged like the positive and negative poles of the magnet. When the superconductor is short-circuited to the electron flow, the magnetic field is emitted continuously (not the true magnetic field is positive or negative). For example, the electromagnetic radiation wave is as shown in Fig. 3. The electron will only emit the radiation when it is accelerated. The accelerating condition is that the internal electrons of the material are superconducting to the electron current. The reason for the electromagnetic radiation can be clearly understood. The positive and negative poles are arranged, relying on the principle of positive and negative attraction, and soon the positive and negative phases are attracted, and the negative and negative phases are repelled. The periodic transformation of surrounding electrical energy and magnetic energy is the basis of the quantum flow of the synchronously transformed electromagnetic wave. The internal electrons of the material are short-circuited in the forward and reverse directions of the electron flow. The electromagnetic energy excited by the bidirectional magnetic field is the short-circuit electron flow of the electromagnetic radiator in the state. The generated bidirectional magnetic field, the direction of the induced current is always such that the magnetic field it generates hinders the change of the magnetic field that causes the induced current. This kind of "inertia" phenomenon in the electromagnetic phenomenon, the electrons can be bidirectional magnetic field to the conductive substream. Excitation of electromagnetic energy in such a misaligned metal species.

Taking lead as an example, this is a radiation-resistant material. After reacting to lead acetate, ammonia and water are added to an appropriate pH to precipitate lead, so that lead has a carboxyl group and an amino group mismatched lead metal COOH-Pb-NH ₂ . When the water is removed, the free electrons have already operated on the body, and the lead metal is dissipated from time to time as electromagnetic waves and radiation waves. (The above lead material can be changed to magnesium and aluminum metal to react as COOH-Mg. Al-NH ₂ mismatched magnesium aluminum metal)

The electromagnetic wave material can be used for power generation under the action of a magnetic field. It is a high-efficiency power generation method. The light wave generator is a magnet composed of a wound coil, and its current density and magnetic field can be used as a high-power energy generating device.

The excitation and inductive winding made of the material, such as the use of a magnet around the winding of the wire coil, When the current senses, the current is in a swirling form. The coil is wound, that is, the magnet (including the wire) is designed to be cut into a magnetic field and the current is relatively large. The current of the current is thicker and the smaller current is thinner. The wire for the magnet can be changed to a core like a transformer to make a magnet (including a wire).

Another: using the Josephson effect to produce a superconducting magnetic field instrument can detect very weak magnetic fields, very sensitive to some radiation, can detect weak infrared radiation, and provide a highly sensitive information system.

Another: Free electron lasers can use a beam of electrons to generate a wide range of photon frequencies or wavelengths against wave-type magnetic lines of force. Changing the beam speed, magnetic wavelength, and laser photon wavelength can be changed.

λ=λo(C/Vo-1)

In this formula: λ is the photon wavelength, λo is the magnetic field wavelength, C is the speed of light, and Vo is the electron beam velocity.

By changing the wavelength and density of the laser photons, the magnetic field strength in the loop changes and the current changes.

From the above two "other" categories, the reverse thinking can be inspired by the light wave generator, combined with the composition of the magnet (including the wire), electromagnetic radiation (including photons, light source), free electrons, the source of the magnetic field strength changes, The current constantly occurs. We use the electrons in the magnetic field to change the force of the electromagnetic radiation (including photons, light sources) and change the strength of the magnetic field to generate electricity. It also uses the free body to move in a strong magnetic field. The proper action of the magnetic field will make the free body The electrons in the movement cause current, which affects the change of the magnetic field strength and can extract the current online. Therefore, changing the magnetic field in space will generate an electric field. When the electric field changes in space, it will also generate a magnetic field. We know that the electric charge will be in space. Produce [electric field]; when the magnetic field changes in space, it will produce [electric field]! The current will pass through the wire to produce a [magnetic field]; the electric field generated by the charge in space will also change [magnetic field]! Mutual use of each other's loops, the design is as follows: For example, electrons are reciprocated by electromagnetic radiation (including photons, light sources) in a strong magnetic field, which is the source of electricity. Usually, the electromagnetic radiation (including photons, light sources) has a large scattering angle and a wide spectrum. The electromagnetic radiation (including photons, light sources) of the electromagnetic waves is placed in the middle or applied to the mirror surface, and the lead is surrounded by the magnetic field. Enclosure, electromagnetic radiation force (including photons, light sources) in the lead 钣 and reciprocating motion. If we are emitting electromagnetic waves, the electromagnetic radiation of the wrong metal The guiding section of the source (including the photon and the light source) is placed in a hand wobbler, and the electrons are periodically oscillated by the electromagnetic radiation force (including photons, light sources), and the generated electromagnetic radiation (including photons, Light source) will have a smaller angular distribution and a smaller spectrum, which is to increase the intensity of synchronous electromagnetic radiation (including photons, light sources), but the electromagnetic radiation (including photons, light sources) is continuously emitted, and electromagnetic radiation (including The source parts of the photon and the light source cancel each other out, and the energy is relatively high and low. Generally, electromagnetic radiation (including photons and light sources) with low energy and low gain value mostly uses stable resonance, which generates resonance energy transfer into ionized matter and becomes current. Basically, its structure is two pieces with appropriate anti-electromagnetic radiation materials such as lead bismuth and / or lead bismuth copper plating (copper mirror reflective photons) and / or lead bismuth plus conductive (including superconducting) coated mirror placed Both ends of the air (solid and / or liquid medium) and electromagnetic radiation (including photons, light sources), electromagnetic radiation (including photons, light sources) on both sides of lead and / or lead bismuth copper and / or lead bismuth The conductive (including superconducting) coated mirror is enlarged or offset back and forth between the mirrors. Lead-bismuth copper-plated and/or lead-bismuth plus conductive (including superconducting) coated mirrors also have a conduction current. Further, there is a two-plane or a plane-concave mirror or a convex-concave mirror or a two-concave mirror, and its further special structure or a concave mirror which is enclosed by a light in a glass chamber, a lead-bismuth plus conductive (including superconducting) mirror, lead a concave or convex mirror with a conductive (including superconducting) mirror, an external guiding light source (or a rechargeable battery source between the two mirrors of the power generating device), a positioning adjustment device and a fixed working table, said light blocking glass The inner chamber is provided with a concave mirror at one end and a concave or convex mirror at the other end. The external light source is guided to the focus of the concave mirror and the point source is reflected by the concave mirror to emit parallel light. The parallel light is recessed in the inner chamber of the light-sealed glass through the other end or The convex mirror converges inward to obtain a focus point; the light shielding glass inner chamber ends are assembled on the adjustable positioning adjustment device, and the positioning adjustment device is mounted on the fixed work table. Generally, light has no strength, but after superconducting and focusing light, it can integrate the frequency and energy of light to enhance the electric field under the electromagnetic radiation (including photons) and magnetic field traction. Further, the light-enclosed glass inner chamber has an openable and closable hole, and if carbon dioxide and/or Nd gas and/or other gases (solid and/or liquid medium are also available), the gas is irradiated with electromagnetic radiation and electrons and an approximate light laser. There is a plasma effect, and the use of electron cyclotron resonance to increase the electron kinetic energy to promote the activation reaction of the gas in the plasma, the generation of ionized gas, electron and electron holes, so that the lead-bismuth plus conductive (including superconducting) mirror has both The conduction current is greatly increased, and the loop is turned to the magnet due to the plasma. The charged particles are greatly increased in relative induction current under the action of a magnetic field. Similarly, the light-enclosed glass inner chamber is reflected in the solid and/or liquid medium/conductor in the form of light and radiation, and is placed in the form of a simulated and/or liquid laser, and the metal and/or the light source in the electromagnetic field is also placed in the magnetic field. The same induced current is greatly increased.

For the light wave generator, there are two rows of magnets between the north and the south, and the magnetic field formed between the two rows exhibits a periodic change direction. As electrons pass through this series of periodic magnetic fields, their trajectories will have the same periodic oscillation in a plane perpendicular to the magnetic field. During each swing period, electrons are constantly changing direction due to electromagnetic radiation (including photons, light sources). If the electromagnetic radiation force (including photons and light sources) emitted in each cycle is in phase, all electromagnetic radiation (including photons and light sources) will be regenerated by construction and generate large electromagnetic radiation (including photons, light sources). Conversely, when electromagnetic radiation (including photons, light sources) are out of phase, they cancel each other out and the energy is relatively reduced.

(magnetic field period / electron velocity) × electromagnetic radiation (including photons, light sources) speed of light = magnetic field period ten radiation (including photons, light source) wavelength

This is a basic formula for free electron lasers. The parameters that satisfy this relationship are called Resonant conditions, and the energy of the electrons is the resonance energy. From this formula, we can see that the energy of the main electron is determined by the period of the magnetic field and the wavelength of the electromagnetic radiation (including photons, light sources), as long as the wavelength of the radiation (including photons, light sources) is adjusted (if we are in the radiation (including The guiding section of the photon and light source is placed in a hand to swing. The energy of the electron will change. The intensity of the radiation (including photons and light sources) is greatly adjustable. One of the appealing features.

The electron cloud in nature cannot be completely uniform, and there is a statistically random distribution, so that the generated radiation (including photons, light sources) will not completely cancel out. Total radiation (including photons, light sources) is proportional to the average density of electrons. Spontaneous radiation (including photons, light sources) causes electrons to move. The electrons have lateral motion components, while radiation (including photons, light sources) itself. It is also a periodic transverse electromagnetic field, so in the wavelength of one radiation (including photons, light sources), half of the electrons have the same lateral motion and electric field direction, and the other half are opposite. Because the electrons are negatively charged, the electric field in the same direction slows down the electrons, and the opposite electric field accelerates the electrons. As a result of this acceleration and deceleration, the density of electrons increases in some places, and some places decrease, and its dense period and wavelength (including photons, light sources) Nearly the same. Because electrons have significant periodic density changes, their radiation (including photons, light sources) fields make it impossible to cancel each other out. The higher the total radiation (including photons, light sources), the higher the electric field strength. Under the condition of weak radiation (including photon, light source), the general radiation (including photons, light sources) is in resonance (Reson- Ant), that is, the energy of the radiation (including photons, light sources) is exactly equal to the difference between the electron energy levels, and has the greatest gain. When the energy of the radiation (including photons, light sources) deviates from the resonance condition, the gain gradually decreases.

In this respect, free electrons have completely different characteristics. In the case of the resonance mentioned above, the number of electrons that increase and decrease energy is completely equal, with the result that there is no transfer of net energy. When the energy of electrons is slightly higher than the resonance energy, the electrons lose a greater chance of energy, and the radiation (including photons) gain increases. Conversely, when the electron energy is reduced, the gain is reduced, and finally the resonance energy is transferred to the ionized substance and becomes the current.

Usually used for the movement of free electrons in the oscillation of radiation (including photons, light sources), the generated electron pulses are about ten microseconds, so the change of the magnetic field in a series of induction coils is used to generate an accelerating electric field. The use of static electricity to accelerate electrons is affected by the side magnets, so it is easy to predict the distribution of the magnetic field based on the arrangement of the magnets. The method of composing a magnetic field is usually arranged by a magnet. This arrangement is to arrange a series of magnets tightly together. From the side, the magnetic field direction of each magnet is sequentially up, right, down, left, up, right, down, left, etc. Each four magnets form a cycle. The order of the other rows of magnets is up, left, down, and right; up, left, down, right, etc... The two rows of magnets are placed in parallel, forming a linearly polarized magnetic field between them. The magnetic field changes formed by this arrangement are very close to the ideal sinusoidal (Sinusoidal), and the amplification of the resonant radiation (including photons, light sources) is reduced. .

If the distance between the two rows of magnets is too far, the combined magnetic field strength will be too small. Conversely, if the distance is too close, the change in the magnetic field will deviate from the ideal sine. Usually the most suitable distance is about half a cycle, just suitable for the passage of electrons and radiation (including photons, light sources). If we change the shape of the magnet and use a more complicated arrangement, we can also get a circularly polarized magnetic field. Another design is to change the two rows of linear magnets into concentric circles, which can increase the effective use distance of the magnetic field, so that the circular body in the permanent magnet magnetic field forms a surface rotating circular magnetic field on the surface. And the inductor to oppose the external magnetic field into the conductor magnet, resulting in complete diamagnetism. Ring magnetic field and inductance The electrons in the electrons are subjected to centrifugal force and have a polarization effect. When the radius r of the conductor magnet is less than or equal to the radius R formed by the force generated by the external magnetic field on the electrons, the electrons are concentrated by the edge of the magnet under the action of the centrifugal force, and the inner side The surface is relatively lacking in electrons, and the inner surface is an electrode with electrons and electromagnetic waves that are attached to lead-bismuth copper and/or lead-bismuth plus conductive (including superconducting) coated mirrors (concave small concentric circles). The radiation (including photons, light sources) is emitted at the edge of the circumference of the magnet. The electrodes are anti-electromagnetic radiation materials such as concave lead-bismuth copper plating and/or lead-bismuth plus conductive (including superconducting) coated mirrors. The magnetic field constantly changes and can generate current. If carbon dioxide and/or Nd gas and/or other gases (solid and/or liquid media are also available), the gas has a plasma effect in electromagnetic radiation and electrons and near-optical lasers, producing ionized gases, electrons and electron holes. The production of the lead-bismuth plated conductive (including superconducting) mirror has a large increase in the conduction current, and the loop is applied to the magnet, and the relative induction current is greatly increased. Similarly, the light-enclosed glass inner chamber is uniformly mixed with the metal powder coating of the solid and/or liquid medium/conductor and the electromagnetic wave, and is irradiated to the excited state to release the laser or fluorescent medium and/or the light-transmitting radiation. Producing a medium of free body, and making it easy to emit radiation and easy to conduct, in the case of multiple reflections, imitation and / or liquid laser, so that the wrong metal and / or light source placed in the electromagnetic wave is also in the magnetic field The same induced current is greatly increased.

The concentric circle magnet is composed of a magnetic outer ring, and the optical outer ring can reflect the optical magnetic radiation. The opening is a small concentric circle and the outer ring of the outer ring is connected to the outside, and can cross each other to absorb the external factor, and the coupling electric field between the magnetic fields of the magnet is utilized. The capacitor is formed, and the rest of the outer loop constitutes an inductor. The small concentric outer ring has a conductive (including superconducting) film that acts as a flux concentrator. The magnetic field structure can adjust the resonance frequency by increasing or decreasing the number of magnetic fields and the arc degree and length of the magnet. In the application, since high resonance frequency and magnetic focusing efficiency can be maintained, high magnetic flux and magnetic field sensitivity can be obtained. Initiating current.

In general, the benefits of magnets are that they are easy to design, handle, change, maintain, and cheap, so they are the most popular. However, the problem to be noted is the uniformity of the magnetization of the magnet, the accuracy of the alignment, and the weakening of the magnetic field due to the impact of the electron. Therefore, shortening the period of alignment, the distance between the arrays, increasing the strength of the magnetic field, and reducing the possibility of electrons directly striking the magnet. But the downside is that it is not easy to design, and the magnetic field changes contain many parts of the resonance.

In order for electromagnetic radiation (including photons, light sources) to effectively act on electrons, the electrons must be very close to the surface of the electromagnetic radiation (including photons, light sources) at a distance of a few microns. Right, so the electrons are usually foggy, and electromagnetic radiation (including photons, light sources) is very accurate across the electronic surface. Because the period of electromagnetic radiation (including photons, light sources) is very short, the energy of the electrons does not have to be high. However, when the electron energy is low, the effect of space charge is obvious.

There are two problems that must be paid special attention to when the electrons use a similar resonant cavity. One problem is the sensitivity of the resonance control to the alignment. Another issue is the control of the length of the cavity. But we can use the dispersion magnet. This method is to put four segments of the same magnet together, the direction of the magnetic field is up, down, down, and up (note that the order is different from the arrangement of the cavity). Most of the electrons entering such a combination of magnetic fields will form a curved trajectory, and at the exit, the radiation (including photons, light sources) bounces back to the original forward direction, and some of the loops are guided away to the magnet to generate stronger electromagnetic force and generate stronger current. Stop the power generation method to remove the lead bismuth and/or the emission of electromagnetic radiation (including photons, light sources), or cover the light source and put the lead bismuth plus conductive (including superconducting) mirror as close as possible to the side. Or the light-enclosed glass inner chamber is made of a transparent transparent tube (circular shape). According to the above principle, the lead alloy and the conductive (including superconducting) copper mirror concave and convex and fixed electromagnetic waves are in the inner alloy. The transparent tube can be removed and the solid or liquid tube can be removed. Electrons with relatively large energy are less likely to be redirected by the magnetic field. The trajectory is shorter and the time to reach the exit is faster. Therefore, the use of the dispersion magnet to create unequal length trajectories can also achieve the same electron concentration effect. More conveniently, we can change the strength of the magnetic field to change the equivalent length.

In terms of supplementing free electrons, it is possible to connect solar enthalpy and conductive (including superconducting) medium (multiple reflections can be reflected into the device) to absorb electrons or reflective conductive (including superconducting) metal mirrors coated with photocatalyst (may be The semi-lens reflex can be a semi-lens to the device) and/or the fiber is dimmed or a rechargeable battery source and/or illuminating source and/or gas is added between the two mirrors of the power generating device (solid and/or liquid media can also be The gas has a plasma effect in electromagnetic radiation and an approximate light laser, which produces an ionized body that can be replenished by absorbing some free electrons.

These are the characteristics of light-wave generators, which must occupy a very important position in the future technology of energy transmission. The phonon activity of electromagnetic radiation (including photons, light sources), the thermal electrons in electromagnetics and semiconductors. Lightwave generators can help us further apply this aspect. Similarly, the above film is changed to superconducting film, and the wire is changed. For superconducting wires, the magnets are changed to superconducting magnets to work more effectively.

According to the above technical solution, the present invention has the following advantages compared with the conventional technology:

1. The light wave generator of the invention only needs a small light source to react quickly to the ionized gas. Unlike the solar energy, the large-scale sunlight is required, and the laser-like function can generate the current without spending a lot of financial resources and economic benefits.

2. The light wave power generation generator of the invention has high safety, does not require high temperature reaction in the production process, and has no industrial safety concerns. The new technology of the new light wave power generation system has been created, which does not take up space, and can greatly control the advantages of quantification or creating large currents on a large scale.

3. The invention realizes the reaction mode of the light wave power generation generator and generates the application of various laser free bodies, solves the problem of dealing with the loss of laser light and converts it into current, the equipment has a long storage period and is not easy to be damaged, can be permanently used, and the generator has no noise. Exhaust gas is produced.

4. The invention utilizes the application of the mismatched metal object in emitting electromagnetic radiation.

5. The invention invents new technologies for mismatching metal objects in radiation, light wave power generation, electromagnetics, and electromagnetic energy.

The above is an overview of the technical solution of the present invention, which can be implemented according to the contents of the specification. Hereinafter, the following is a detailed description of the preferred embodiment of the present invention with reference to the accompanying drawings.

In order to further illustrate the technical means and efficacy of the present invention for achieving the intended purpose of the invention, the following detailed description will be made in conjunction with the accompanying drawings and preferred embodiments.

A mismatched metal proposed by the present invention is a mixed metal having a carboxyl group and an amino group obtained by mixing a metal salt solution having a carboxyl group and/or an amino group according to a conventional method, and an inorganic base or an acid of an amino group and/or a carboxyl group is uniformly precipitated.

Example 1:

Magnesium acetate 2%

Aluminum acetate 2%

Water 92%

Mix first and add ammonia or ethylenediamine 4%, adjust to the appropriate pH 2--11. At this time, the solution will be a sol, which will be heated and concentrated. After most of the water disappears, the gel is dried. COOH The mismatched magnesium aluminum metal of -Mg.Al-NH ₂ is desirable.

Example 2:

Lead acetate 4%

Water 92%

Mix first and add ammonia or ethylenediamine 4%, adjust to the appropriate pH 2--11. At this time, the solution will be a sol, which will be heated and concentrated. After most of the water disappears, the gel is dried. The lead metal COOH-Pb-NH _{2 is} required.

Taking lead as an example, after reacting to lead acetate, ammonia and water are added to an appropriate pH to precipitate lead, so that the lead has a carboxyl group and an amino group in which the lead metal is removed, and the water is removed. At this time, the free electrons have been operated on the conductor. Lead-lead metals have electromagnetic phenomena.

Example 3

Light wave generator:

As shown in Fig. 4, the magnet composed of the light-wave generator uses a wire, which has strong current density and magnetic field, and can be used as a high-power energy generating device. The device 1 comprises: a casing carrier 2, a coil 3, a magnet 4, a misaligned metal 5 that emits electromagnetic waves, a lead-plated conductive (including superconducting) mirror 6 at both ends, and a lead-bismuth plus conductive (including superconducting) surface. The concave mirror 62 of the mirror, the concave or convex mirror 61 of the lead-bismuth plus conductive (including superconducting) mirror, and the housing carrier 2 are arranged with the magnet 4 arranged up and down, and the number of wound coils of the coil 3 can be set according to the actual size of the induced electromagnetic. The two ends of the winding can be respectively connected to the product to be charged or the power supply system line. Basically, its structure is two concave mirrors 62 with appropriate lead and conductive (including superconducting) mirrors and concave or convex mirrors 61 with lead and conductive (including superconducting) mirrors placed in air and electromagnetic waves. The misaligned metal 5 emits radiation (including photons) 15 at both ends of the medium, and the radiation (including photons) 15 is amplified or cancelled back and forth between the two lead and the conductive (including superconducting) mirrors 6. Further, there is a two-plane or a plane-concave mirror or a convex-concave mirror or a two-concave mirror, and the lead-bismuth plated conductive (including superconducting) mirror 6 has a conduction current to the coil 3 of the magnet 4. Its further special structure is either externally guided light source 18, wire-connected solar energy, conductive (including superconducting) medium 8 or reflective conductive (including superconducting) metal mirror coated with photocatalyst 9 with multiple reflections of reflective conductivity The (including superconducting) mirror 8 or 9 is reflected into the device, and the guiding light is enclosed in the glass inner chamber 7, which can be supplemented by absorbing some free electrons. Light blocking glass One end of the inner chamber 7 is provided with a concave mirror 62 of a lead-bismuth plus conductive (including superconducting) mirror, and the other end is provided with a concave or convex mirror 61 of a lead-bismuth plus conductive (including superconducting) mirror, and the external light source 18 is guided to the concave mirror 62. At the focus of the point, the point source 18 is reflected by the concave mirror 62 to emit parallel light. The parallel light is concentrated inward in the light-sealing glass inner chamber 7 via the concave or convex mirror 61 mounted at the other end to obtain a focus point; the light closes the glass inner chamber 7 The lead-plated conductive (including superconducting) mirror 6 at both ends is mounted on the adjustable positioning adjustment device 12, and the positioning adjustment device 12 is mounted on the fixed table 13. Further, the light-sealed glass inner chamber 7 has an openable and closable gas (solid and/or liquid also) hole 10 if it is filled with carbon dioxide and/or Nd gas and/or other gases 11 (for example, Nd gas 0.5% plus CO2 gas) 10%), the gas 11 has a plasma effect 14 in the electromagnetic radiation 15 and the approximate light laser, and uses electron cyclotron resonance to increase the electron kinetic energy to promote the activation reaction of the gas 11 in the plasma effect 14 to generate the ionized gas 11, electron And the generation of the electron hole, the lead-bismuth plated conductive (including superconducting) mirror 6 has a large increase in the conduction current, and the loop is applied to the magnet 4, because the charged particles in the plasma effect 14 are under the action of the magnetic field, the relative induction The current is greatly increased. Similarly, the light-enclosed glass inner chamber is uniformly mixed in a solid and/or liquid medium and a conductor/electromagnetic wave misaligned metal powder coating, and is irradiated to an excited state to emit a laser or fluorescent medium and/or a light-transmitting radiation. Producing a medium of free body, and making it easy to emit radiation and easy to conduct, in the case of multiple reflections, imitation and / or liquid laser 22, so that the wrong metal 5 and / or light source 18 placed in the electromagnetic wave In the magnetic field, the induced current is also greatly increased.

The method of composing the magnetic field is usually arranged by using a magnet 4. The arrangement is such that a series of magnets 4 are closely arranged together. From the side, the magnetic field direction of each magnet 4 is sequentially up, right, down, left, up, right, down, left... .. etc. Each of the four magnets 4 constitutes one cycle. The order of the other rows of magnets 4 is up, left, down, and right; up, left, down, right, etc., and the two rows of magnets 4 are placed in parallel.

If yes, the electromagnetic wave is mixed with metal 5 emitting radiation (including photons) 15 source is placed in the middle, surrounded by lead enamel inside the casing carrier 2, radiation force (including photons) 15 lead bismuth plating conductive (including superconducting) The mirror 6 moves back and forth. The electrons are periodically oscillated by the radiation force (including photons) 15, and further electrons are transported by the radiation force (including photons) 15 in a strong magnetic field. Movement, is the relative increase of radiation (including photons) 15, the intensity of ionized gas 11, but the radiation (including photons) 15 source, ionized gas 11 is continuously emitted, the radiation (including photons) 15 source parts cancel each other, generating resonance energy Transfer to ionization and current, the energy is relatively high and low, if we are in the electromagnetic wave of the wrong metal 5 emission radiation (including photons) 15 source of the guiding section into a hand swinger 16, adjustable energy and The gain of the radiation (including photons) 15 and the source 18 achieves a stable resonance. After the superconducting and focusing light, the frequency and energy of the light can be integrated to enhance the magnetic flux of the coil 3 under the radiation (including photon) 15 and the magnetic field to generate an induced electromotive force, which is periodic with the magnetic field. The fluctuating traction accelerates the change of the magnetic flux, so that the instantaneous magnetic flux variable becomes larger, resulting in a large induced electric potential to generate a larger capacity of the induced current, thereby providing a source of electric power. Similarly, the arrangement of the magnets 4 to the concentric circles 21 has the same effect.

At the same time, the two winding wires of the coil 3 are further connected to the rectifying device 80 and connected to the plug cable 81. If so, the plug cable 81 can be plugged into the socket of the charging socket or the charger for charging, or for the power supply system. line. A concave or convex mirror 61 further provided with a lead-bismuth plus conductive (including superconducting) mirror is mounted on the adjustable positioning adjustment device 12 to adjust the distance between the concave or convex mirror 61 and the electromagnetic wave of a hand swinger 16 5 (spreading radiation source) and light source 18, the magnitude of the induced current can be adjusted.

Usually used for the movement of free electrons in the oscillation of the radiation (including photons) 15, the generated electron pulses are about ten microseconds, so the acceleration field is generated by the change of the magnetic field in a series of induction coils. Stop the power generation method to cover the light source 18 and the lead-free and conductive (including superconducting) mirrors 6 on both sides as close as possible to the side, or the light-sealed glass inner chamber to be an inflated transparent tube 19 (round also) Similarly, according to the above principle, the lead xenon plus conductive (including superconducting) mirror 6 is concave and convex and fixed with the wrong metal 5 of the electromagnetic wave, and the transparent lamp tube 19 can be removed. The above-mentioned light wave power generation generator can be used in parallel in multiple sets and multiple sets.

For example, the light wave generator is composed of upper and lower parts, with an inner diameter of 21 cm, an outer diameter of 30.5 cm and a height of 7.5 cm. The interval between the two parts is 16 mm to 32 mm, and the electrons are in the gap. Through, the total number of turns of the coil is 8400, the maximum current is expected to be 20A, and the central magnetic field is 0.5 Tesla. The magnet for clustering has an inner diameter of 10 cm, a length of 60 cm, a maximum magnetic field of 0.6 Tesla, and a magnetic field gradient of 0.12 Tesla/cm. Such a large magnetic field predicts the gradient to favor the distance required for the bundle.

Example 4

Another design according to FIG. 5 is to change the two rows of linearly arranged magnets 4 into an arrangement of concentric circles 21, which can increase the effective use distance of the magnetic field, so that the circular conductor in the permanent magnet magnetic field is on the surface. A surface-turning toroidal magnetic field and inductance are formed to oppose the external magnetic field into the conductor magnet 4, thereby generating diamagnetism. The electrons in the toroidal magnetic field and the inductance are subjected to centrifugal force. When the radius r of the conductor magnet 4 is less than or equal to the radius R formed by the force generated by the external magnetic field on the electrons, the electrons are concentrated toward the edge of the magnet 4 by the centrifugal force. On the inner side, there is a relatively lack of electrons, and the inner surface has electrons and radiation (including photons) 15 attached to the concave lens 61 (concave small concentric circle 21) of the lead-bismuth plus conductive (including superconducting) mirror, which is emitted above the circumference. The external guiding light source 18 is incident on the gap between the circumference and the conductor magnet 4, and the circumference and the small concentric circle 21 are mutually conducting current to the coil 3 of the magnet 4, and the wire is connected to the solar energy 钣 containing conductive (including superconducting) medium 8 or The reflective conductive (including superconducting) metal mirror is coated with photocatalyst 9 and reflected by multiple reflections of conductive (including superconducting) mirror 8 or 9 is reflected into the device, and there is anti-radiation coating/material at the edge of the circumference of magnet 4. The back-reflection of the concave mirror 62 of the lead-bismuth plus conductive (including superconducting) mirror, the gas 11 has a plasma effect 14 in the electromagnetic radiation 15, and the ionized gas 11 is generated, and the magnetic field is constantly changing, and current can be generated. Similarly, the light-enclosed glass inner chamber 7 is in the form of a solid and/or liquid medium, in the manner of a solid and/or liquid laser 22, placed in the conductor/electromagnetic wave of the miscible metal 5 and/or the light source is also in the magnetic field. The induced current is greatly increased.

for example. The concentric circle 21 magnet 4 is composed of a magnetic field outer ring, and the optical outer ring 15 can be reflected in the outer ring, and the opening is a nip gap between the outer ring magnets 4, which can be externally absorbed to absorb external factors (including the light source 18), and the magnet is used. The coupled electric field between the magnetic fields constitutes a capacitor, and the remainder of the outer ring constitutes an inductance. The outer ring of the small concentric circle 21 has a conductive film 17, and the mirror reflection serves as a flux concentrator. The magnetic field structure can adjust the resonance frequency by increasing or decreasing the number of magnetic fields and the arc degree and length of the magnet. In the application, since high resonance frequency and magnetic focusing efficiency can be maintained, high magnetic flux and magnetic field can be obtained.

The above description is only a preferred embodiment of the present invention, and does not form any shape for the present invention. The present invention has been disclosed in the above preferred embodiments, but is not intended to limit the present invention, and those skilled in the art can utilize the above disclosed technology without departing from the scope of the present invention. The content is modified or modified to be equivalent to the equivalent embodiment, but any simple modifications, equivalent changes and modifications made to the above embodiments in accordance with the technical spirit of the present invention remain without departing from the technical scope of the present invention. Within the scope of the technical solution of the present invention.

Description of the figure:

1‧‧‧Lightwave generator

2‧‧‧Shell carrier

3‧‧‧ coil

4‧‧‧ magnet

5‧‧‧Electric electromagnetic wave mismatched metal

6‧‧‧ lead bismuth plus conductive (including superconducting) mirror

7‧‧‧Light-sealed glass interior

8‧‧‧Wire-connected solar cells containing conductive (including superconducting) media

9‧‧‧ Conductive (including superconducting) reflective metal mirror coated with photocatalyst

10‧‧‧Switchable gas (solid and / or liquid can also be) holes

11‧‧‧Ionized gas (carbon dioxide and / or Nd gas and / or helium or other gases)

12‧‧‧ Positioning adjustment device

13‧‧‧Fixed workbench

14‧‧‧ Plasma effect

15‧‧‧Electromagnetic radiation (including photons)

16‧‧‧Hand swinger

17‧‧‧Electrical film (including superconducting film)

18‧‧‧Light source

19‧‧‧Transparent tube

20‧‧‧Electronic pair electron flow direction

21‧‧‧Concentric circles

22‧‧‧Solid and/or liquid laser

62‧‧‧Concave mirror with lead and conductive (including superconducting) mirror

61‧‧‧Concave or convex mirrors with lead and conductive (including superconducting) mirrors

80‧‧‧Rectifier

81‧‧‧plug cable

Figure 1 is a top plan view of a miscible metal capable of emitting electromagnetic radiation waves.

Fig. 2 shows the arrangement of the misaligned metal as the arrangement of the positive and negative poles of the magnet. The positive and negative electrodes are connected in a straight line, and the electron convection is folded into a convoluted form.

Figure 3 is a side view of a short-circuited electron-to-superconducting electron in a misaligned metal. The electron-to-superconducting bi-directional magnetic field excites a side view of the electromagnetic energy in the misaligned metal species.

The upper part of Fig. 4 is the reaction diagram of the external guiding light source in the light-sealed glass inner chamber, and the lower part is the schematic diagram of the light wave power generating generator.

Figure 5 is a schematic view of a light wave generator (concentric arrangement).

1‧‧‧Lightwave generator

2‧‧‧Shell carrier

3‧‧‧ coil

4‧‧‧ magnet

5‧‧‧Electric electromagnetic wave mismatched metal

6‧‧‧ lead bismuth plus conductive (including superconducting) mirror

7‧‧‧Light-sealed glass interior

8‧‧‧Wire-connected solar cells containing conductive (including superconducting) media

9‧‧‧ Conductive (including superconducting) reflective metal mirror coated with photocatalyst

10‧‧‧Switchable gas (solid and / or liquid can also be) holes

11‧‧‧Ionized gas (carbon dioxide and / or Nd gas and / or helium or other gases)

12‧‧‧ Positioning adjustment device

13‧‧‧Fixed workbench

14‧‧‧ Plasma effect

15‧‧‧Electromagnetic radiation (including photons)

16‧‧‧Hand swinger

17‧‧‧Electrical film (including superconducting film)

18‧‧‧Light source

19‧‧‧Transparent tube

20‧‧‧Electronic pair electron flow direction

21‧‧‧Concentric circles

22‧‧‧Solid and/or liquid laser

62‧‧‧Concave mirror with lead and conductive (including superconducting) mirror

61‧‧‧Concave or convex mirrors with lead and conductive (including superconducting) mirrors

80‧‧‧Rectifier

81‧‧‧plug cable

Claims (12)

A miscible metal having electromagnetic wave characteristics, characterized in that the miscible metal is an inorganic or organic compound which is mixed with one or more monovalent, divalent or trivalent metal salts having a carboxyl group or an amino group and water, and an amino group or a carboxyl group. The base or acid is uniformly precipitated, and after the reaction, a divalent miscible metal or a miscible composite metal having an amino group and a carboxyl group is obtained, which includes one or more kinds of the complex metals. A mismatched metal having electromagnetic properties, characterized in that the miscible metal is an inorganic or organic compound which is mixed with one or more monovalent, divalent or trivalent metal salts having a carboxyl group or an amino group and water, and an amino group or a carboxyl group. A base or an acid is uniformly precipitated, and after the reaction, a divalent miscible metal or a miscible composite metal having an amino group and a carboxyl group, which includes one or more kinds of a miscible metal, is obtained. A light wave power generation generator characterized in that the structure of the light wave power generation generator is: "two pieces" have appropriate anti-electromagnetic radiation materials or mirrors, placed on both ends of a gas or solid or liquid or electromagnetic radiation medium, and emit electromagnetic Radiation medium or a miscible metal containing the scope of claim 1 of the patent, electromagnetic radiation is transferred back and forth between the "two pieces" of material or lead or mirror of the enclosed light chamber, causing resonance energy transfer to ionization or current, "two The piece of material or lead or mirror has both electrodes and is electrically conductive, and there is a magnetic field or superconducting magnetic field around the electromagnetic wave resonance or electronic part to make the magnet generate stronger electromagnetic force and generate stronger current. The light power generation generator according to claim 3, wherein the "two pieces" are a group, and one or more sets have two planes or a plane, a concave surface or a convex surface, a concave surface or two. Concave anti-electromagnetic radiation material or lead or mirror. The light-wave power generation generator according to claim 3, wherein the more special structure is that the "two-piece" anti-electromagnetic radiation material or the mirror of the inner chamber enclosed by the light is concave at one end and concave or at the other end. a convex surface, the external light source is guided at the focal point of the concave surface and the point light source is reflected by the concave surface to emit parallel light rays, and the parallel light rays are concentrated in the light-sealed manner by the concave or convex surface at the other end to be focused, after conduction and focusing The light of the light can be integrated to increase the frequency and energy of the light. The light power generation generator according to claim 3, wherein the electromagnetic radiation comprises a photon light source, or a misaligned metal that emits electromagnetic waves, or other radiation factor, or a free electron, or a gas in ionization or electrophoresis, Solid or liquid medium, which can oscillate back and forth in a magnetic field, can generate a light wave generator, or power supply can Multiple sets of multiple sets are used in parallel. The light wave power generation generator according to claim 3, wherein the magnetic field and structure of the light wave generator are: the magnets are tightly arranged to form a magnetic field, and the magnetic field direction of each magnet is sequentially viewed from the side. Up, right, down, left, up, right, down, left..., every four magnets are in one cycle, and the other row of magnets is in the order of up, left, down, right; up, left, down And right..., placed in parallel to form a linearly polarized magnetic field or arranged in the same direction, or two rows of linearly arranged magnets are arranged in a concentric circle, and the center of the surface is a small concentric circle simplified to a pure electrode, with attachment The electron and electromagnetic radiation in the anti-electromagnetic radiation material or the mirror are radiated, and the electrode has an anti-electromagnetic radiation material or a mirror reflection at the edge of the circumference of the magnet body, so that the coil generates an induced current. For example, the light wave power generator described in claim 3 of the patent application can adjust the "two pieces" distance or the intensity of the light source or the light radiation to adjust the magnitude of the induced current. The light power generation generator according to claim 3, characterized in that the light-closed inner chamber is filled with one or more kinds of gas or liquid or semiconductor or solid medium, and is mismatched with a conductor or a superconductor or an electromagnetic wave. Uniformly mixed, irradiated or charged to an excited state to a medium that emits stimulated radiation or a medium that is exposed to light to produce a free body. The light power generation generator according to claim 3, wherein the light-closed inner chamber has a complementary free electron or a light source or a medium, and the wire can be connected to the solar energy and the conductive or superconducting medium can be used to absorb electrons in the device, or A reflective conductive or superconducting metal mirror containing a photocatalyst absorbs some free electrons; or a semi-lens light can be reflected into the device to supplement the light, or the fiber is dimmed or placed between the two pieces of the power generating device. A battery light source or a light source material; the light-enclosed inner chamber has a hole for opening a gas or a solid or liquid medium to replenish the medium. The light power generation generator according to claim 3, wherein the light-closed inner chamber is filled with one or more gases selected from the group consisting of: air, argon ions, helium ions, KTP frequency doubling, copper steam. , gold vapor, strontium, yttrium, yak, yttrium, yttrium fluoride, yttrium, hydrogen fluoride, carbon dioxide, carbon monoxide, halogen, argon, nitrogen, oxygen, rare rare gases, ArF, KrF, XeCl, XeF, Cadmium, , , , , , XeF ^* , XeBr ^* , ArCl ^* , XeCl ^* , ArF ^* , KrF ^* , HgCl ^* , HgBr ^* , Kr ₂ F ^* , Xe ₂ Cl ^* , KrO ^* , XeO ^* , ArO ^* or CF ₃ l, wherein ^* is an ionized body. The light power generation generator according to claim 3, wherein the light-sealed inner chamber is filled with one or more liquids or solids, wherein the liquid is a liquid laser of an active medium, and is selected from the group consisting of: Dye laser; the solid laser in which the solid is an active medium, selected from the group consisting of: ruby laser, yttrium aluminum garnet laser, arsenic bismuth laser or strontium crystal laser; using semiconductor as material, selected from: gallium arsenide, Arsenic phosphide indium gallium arsenide, aluminum gallium arsenide, indium phosphide or two or six groups of zinc selenide and zinc sulfide, ternary or quaternary compound semiconductor, indium gallium nitride / indium gallium nitride / aluminum oxide , aluminum indium gallium phosphide / indium gallium phosphide / gallium arsenide, aluminum gallium arsenide / gallium arsenide, aluminum gallium arsenide, Se, germanium atoms, barium strontium arsenate, germanium zinc phosphide or gallium selenide Semiconductor laser.