CN110993126A - Low-temperature controllable nuclear fusion device - Google Patents

Abstract

Relates to a low-temperature controllable nuclear fusion device, which does not need extremely high-temperature resistant materials and can continuously and controllably generate nuclear fusion at lower temperature. The center of a cylindrical controllable nuclear fusion device is provided with a proton gun (1), a vacuum cavity (2), a needle-shaped focusing rod (3), a narrow-gap focusing cavity (4), an inner wall (5), and a nuclear fusion microchamber (6) which is arranged at the bottom and the inner wall of the narrow-gap nuclear focusing cavity, wherein a neutron adsorption layer (7) is arranged on the outer side of the inner wall, a heat exchange layer (8) is arranged on the outer side of the neutron adsorption layer, and an outer wall (9) of the controllable nuclear fusion device is arranged on the outer side of the heat exchange layer; deuterium or tritium or a deuterium-tritium mixed positive ion (10) sprayed by a proton gun moves at a high speed towards the direction of a needle-shaped focusing rod with negative electricity and an inner wall under the acceleration of an electric field, the deuterium-tritium mixed positive ion focuses at the bottom formed by the inner wall in a narrow-gap nuclear fusion cavity on the outer wall of the needle-shaped focusing rod, the density of the deuterium-tritium mixed positive ion is increased, the deuterium-tritium mixed particles collide with each other near the bottom of the narrow-gap nuclear fusion cavity, and a nuclear fusion reaction can be generated at a certain probability.

Description

Low-temperature controllable nuclear fusion device

The invention relates to a low-temperature controllable nuclear fusion device which can operate under a lower temperature condition, continuously and controllably generate nuclear fusion, output heat and perform power generation and heat supply.

The nuclear fusion can generate huge energy, but the controllable nuclear fusion reaction is very difficult to realize, at present, the human beings realize the nuclear fusion and are hydrogen bombs, the principle is that the hydrogen atom isotope is ignited to generate the thermonuclear fusion through the fission reaction of the uranium bombs and the instantaneous high temperature and high pressure generated by explosion. However, in the process of instantaneous explosion, the released energy is huge, destructive, completely uncontrollable and not continuous, and the generated energy cannot be recycled.

Calculating to realize nuclear fusion reaction according to a physics theory, wherein the conditions for generating nuclear fusion ignition are as follows: the product of temperature, density and confinement time is larger than Lawson criterion, and the high temperature and density of tens of millions of degrees or even hundreds of millions of degrees are needed to be reached, so that the movement speed of hydrogen isotope particles can overcome the coulomb force between atomic nuclei to collide with each other, and the nuclear fusion reaction with continuous commercial value is generated.

With the continuous development of industry and modern society, the demand of human civilization on energy is increasing day by day, but the existing non-renewable energy reserves such as petroleum, coal and the like are limited, so that the survival development needs of human beings can not be met soon, and nuclear energy which can generate huge energy in new energy can be used as future clean energy of human beings. The energy generated by nuclear fusion is more than that generated by nuclear fission, nuclear fuel is more easily obtained, and how to safely, efficiently, continuously and controllably utilize the energy of nuclear fusion becomes the problem which people need to solve at present.

At present, in China and countries around the world, a great deal of manpower and material resources are invested in the research of the controllable nuclear fusion technology, certain progress is achieved, but complete ignition cannot be achieved, continuous nuclear fusion is achieved, and the method is far from practical and commercial application and has a long way to go. So far, the main controllable nuclear fusion modes include 1, ultrasonic nuclear fusion, 2, laser confinement (inertial confinement) nuclear fusion, 3, magnetic confinement nuclear fusion (tokamak, star simulator, magnetic mirror, reversed field, spherical ring, etc.), and the controllable magnetic fusion reaction device tokamak device with high feasibility is available.

The main problem faced by the nuclear fusion technology is how to keep the high temperature generated by the continuous discharge of the plasma for a long time to generate stable and controllable nuclear fusion reaction, and in order to be put into practical use, the energy of the input device must be far less than the output energy, i.e. the energy gain factor Q value must be increased as much as possible, and the difficulty of research is also to develop the inner wall material capable of resisting high temperature.

In order to overcome the defects that the existing controllable thermal fusion device which is being researched can not realize ignition, can generate continuous controllable nuclear fusion, needs an inner wall with extremely high temperature resistance and the like, the invention provides a low-temperature controllable continuous nuclear fusion device.

The technical scheme adopted by the invention for solving the technical problems is as follows: the center of a cylindrical controllable nuclear fusion device is provided with a proton gun (1), a vacuum cavity (2), a needle-shaped focusing rod (3), a narrow-gap focusing cavity (4), an inner wall (5), a nuclear fusion microchamber (6) arranged at the bottom and the inner wall of the narrow-gap nuclear focusing cavity, a neutron adsorption layer (7) arranged on the outer side of the inner wall, a heat exchange layer (8) arranged on the outer side of the neutron adsorption layer, and an outer wall (9) of the controllable nuclear fusion device arranged on the outer side of the heat exchange layer.

A power supply device is arranged outside a controllable nuclear fusion device to generate high-voltage electricity, a positive electrode (11) is connected with a proton gun, a negative electrode (12) is connected with an inner wall to enable a small part of the inner wall and a needle-shaped focusing rod to be charged negatively, deuterium or tritium or deuterium-tritium mixed positive ion (10) sprayed by the proton gun moves towards a narrow-gap focusing cavity and an inner wall of the outer wall of the needle-shaped focusing rod with negative electricity at high speed under the acceleration of a high-voltage electric field, most particles collide with the outer wall of the needle-shaped focusing rod at an acute angle during the period of the deuterium or tritium mixed positive ion, change a small amount of angle to continue to move forwards, and collide with the outer wall of the needle-shaped focusing rod at an acute angle at the opposite side until the density of the deuterium-tritium mixed particle in a nuclear fusion micro-chamber near the bottom of the narrow-gap nuclear focusing cavity reaches the position near the bottom, the density of the deuterium-tritium mixed, there is a certain probability that nuclear fusion reactions can be generated. The inner wall and the needle-shaped focusing rods are made of metal (such as tungsten and the like) or nonmetal materials with high melting point and high heat conductivity, the inner wall and the needle-shaped focusing rods can be made of the same material or different materials, the needle-shaped focusing rods are needle-shaped and have smooth surfaces, the needle-shaped focusing rods are densely arranged on the inner side surface of the inner wall, the needle points point to the center, and a small narrow gap is formed between the needle-shaped focusing rods. The inner side surface of the inner wall is made into a dense eccentric concave spherical surface, and the eccentric concave spherical surface and a small narrow gap at the lower end of the needle-shaped focusing rod form a nuclear fusion micro-chamber.

The inner wall can be an integral body and is connected with the cathode of the power supply; the inner wall can also be made into a bar shape, and each inner wall is respectively connected with the negative pole of the external power supply. The high-voltage accelerating electric field is controlled to rotate and scan the electric field in the vacuum cavity, so that the particle beams run in a scanning mode in the vacuum cavity, the particle beams are focused in each needle-shaped gap within a very short time, and the nuclear fusion chamber is compressed and collided with each other to generate the nuclear fusion with small controllable probability.

The operation is performed in a scanning mode: 1. the intensity of particle beams can be improved, and the nuclear fusion probability is increased; 2. the electric field intensity is improved, the particle motion speed is increased, and the nuclear fusion probability is increased; 3. the heat conduction and the heat dissipation of the needle-shaped focusing rod and the inner wall are increased, the safe use of the needle-shaped focusing rod and the inner wall material is protected, the needle-shaped focusing rod and the inner wall material are not melted and deformed, and the service life is prolonged; 4. during the beam scan interval, the products after nuclear fusion, unreacted species and impurities have time to be evacuated.

The density and the movement speed of the mixed particles of deuterium and tritium in the nuclear fusion micro-chamber are controlled by adjusting the particle intensity and the voltage of an electric field output by the proton gun, so that the intensity of the generated nuclear fusion reaction can be controlled, and the temperature of the needle-shaped focusing rod, the nuclear fusion micro-chamber and the inner wall can also be controlled, so that the nuclear fusion device can continuously and controllably operate at a certain temperature.

In addition, a power supply device is not needed to be arranged outside the controllable nuclear fusion device, a small proton accelerator can be arranged outside the controllable nuclear fusion device, deuterium or tritium or a mixed positive ion of deuterium and tritium is accelerated to megaelectron volt-level speed and guided to a proton gun to be sprayed out, the proton gun can rotate, so that a particle beam can run in a scanning mode in a vacuum cavity, the particle beam is focused in each needle-shaped gap within extremely short time, and the nuclear fusion chamber is compressed and collided with each other to generate nuclear fusion with small probability.

Energy Q1 generated by nuclear fusion reaction in the nuclear fusion micro chamber is mainly kinetic energy of neutrons and helium ions, the neutrons moving fast have strong penetrability, most of the neutrons moving fast pass through the inner wall, collide with the adsorption material in the neutron adsorption layer and are converted into slow neutrons which are absorbed, meanwhile, the kinetic energy of the neutrons is converted into heat energy, and the heat energy is transmitted to the heat exchange layer; the energy of helium ions moving at high speed is transferred to the inner wall and the needle-shaped focusing rods through multiple collisions with the inner wall and the needle-shaped focusing rods, the energy is converted into heat which reaches the liquid of the heat exchange layer through the inner wall material to the outer neutron adsorption layer, high-temperature steam is generated, and the high-temperature high-pressure steam is led out of the controllable continuous nuclear fusion device to push a steam turbine to do work and generate electricity. Deuterium or tritium or a deuterium-tritium mixed ion sprayed by the proton gun moves at a high speed towards the needle-shaped focusing rod and the inner wall with negative electricity under the acceleration of an electric field, the kinetic energy of the deuterium or tritium or the deuterium-tritium mixed ion is converted into heat energy Q2 mostly by colliding with the outer wall and the inner wall of the needle-shaped focusing rod, and the heat energy is conducted to the neutron absorption conversion layer and the heat exchange layer through the needle-shaped focusing rod and the inner wall; the total heat quantity Qc output by the heat exchange layer is Q1+ Q2.

One part of energy Qs input by an external power supply is heating deuterium or tritium or mixed ions of deuterium and tritium, and the other part of energy Qs is generating a high-voltage electric field to accelerate deuterium or tritium or deuterium and tritium particles to form particle kinetic energy.

When the output energy of the whole system is larger than the input energy, namely Qc is larger than Qs, namely the Q factor (Q factor: Qc/Qs) is larger than 1, the nuclear fusion device can be continuously operated, and the commercial practical value can be realized.

According to the controllable nuclear fusion device, input energy and energy generated by nuclear fusion are converted into heat energy in a closed cylindrical mode, the input energy is absorbed again to become a part of output heat energy, only a small probability of nuclear fusion reaction is generated, the Q value of an energy gain factor can be larger than 1, and sustainable nuclear fusion with commercial value is achieved.

The invention provides a low-temperature controllable continuous nuclear fusion device, which can realize continuous controllable nuclear fusion and does not need extremely high-temperature resistant materials on the inner wall of the device.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a cross-sectional configuration of one embodiment of the present invention.

FIG. 2 is an enlarged partial cross-sectional construction view of one embodiment of the present invention.

Fig. 3 is a cross-sectional configuration of a second embodiment of the present invention.

In the figure, 1 is a proton gun, 2 is a vacuum cavity, 3 is a needle-shaped focusing rod, 4 is a narrow-gap nuclear focusing cavity, 5 is an inner wall, 6 is a nuclear fusion micro-chamber, 7 is a neutron adsorption layer, 8 is a heat exchange layer, 9 is an outer wall, 10 is positive ions, 11 is a positive electrode, and 12 is a negative electrode.

Detailed Description

In figure 1, at the center of a cylindrical controllable nuclear fusion device, a proton gun (1), a vacuum cavity (2), a needle-shaped focusing rod (3), a narrow-gap focusing cavity (4), an inner wall (5), a nuclear fusion microchamber (6) at the bottom and the inner wall of the narrow-gap nuclear focusing cavity, a neutron adsorption layer (7) outside the inner wall, a heat exchange layer (8) outside the neutron adsorption layer, and an outer wall (9) outside the heat exchange layer of the controllable nuclear fusion device are arranged.

A power supply device is arranged outside a controllable nuclear fusion device to generate high-voltage electricity, an anode (11) is connected with a proton gun, a cathode (12) is connected with an inner wall to enable a small part of the inner wall and a needle-shaped focusing rod to be negatively charged, deuterium or tritium or a mixed deuterium-tritium positive ion (10) sprayed out of the proton gun moves towards a narrow-gap focusing cavity and the inner wall of the outer wall of the needle-shaped focusing rod with negative electricity at high speed under the acceleration of an electric field, most particles collide with the outer wall of the needle-shaped focusing rod during the period of the deuterium or tritium or mixed deuterium-tritium positive ion, the particles collide at an acute angle, a small amount of angle is changed to continue moving, and then collide with the outer wall of the needle-shaped focusing rod at an acute angle to move forwards until the bottom is near, the density of the mixed deuterium-tritium particles in a, the density is increased, the speed is high, the mixed particles of deuterium and tritium collide with each other in the nuclear fusion micro-chamber, and the nuclear fusion reaction can be generated at a certain probability. The inner wall and the needle-shaped focusing rods are made of metal (such as tungsten and the like) or nonmetal materials with high melting point and high heat conductivity, the inner wall and the needle-shaped focusing rods can be made of the same material or different materials, the needle-shaped focusing rods are needle-shaped and have smooth surfaces, the needle-shaped focusing rods are densely arranged on the inner side surface of the inner wall, the needle points point to the center, and a small narrow gap is formed between the needle-shaped focusing rods. The inner side surface of the inner wall is made into a dense eccentric concave spherical surface, and the eccentric concave spherical surface and a small narrow gap at the lower end of the needle-shaped focusing rod form a nuclear fusion micro-chamber.

The inner wall can be an integral body and is connected with the cathode of the power supply; the inner wall can also be made into a bar shape, and each inner wall is respectively connected with the negative pole of the external power supply. The high-voltage accelerating electric field is controlled to rotate and scan the electric field in the vacuum cavity, so that the particle beams run in a scanning mode in the vacuum cavity, the particle beams are focused in each needle-shaped gap within a very short time, and the nuclear fusion chamber is compressed and collided with each other to generate the nuclear fusion with small controllable probability.

In another embodiment shown in fig. 3, in the center of a cylindrical controllable nuclear fusion device, there are a proton gun (1), a vacuum cavity (2), a needle-shaped focusing rod (3), a narrow-gap focusing cavity (4), an inner wall (5), a nuclear fusion microchamber (6) in the area of the bottom and the inner wall of the narrow-gap nuclear focusing cavity, a neutron absorbing layer (7) outside the inner wall, a heat exchange layer (8) outside the neutron absorbing layer, and an outer wall (9) outside the heat exchange layer of the controllable nuclear fusion device.

In the embodiment, a power supply device is not needed to be arranged outside the controllable nuclear fusion device, a small proton accelerator is arranged outside the controllable nuclear fusion device, deuterium or tritium or mixed positive ions of deuterium and tritium are accelerated to megaelectron volt-level speed and are guided to the proton gun to be sprayed out, the proton gun can rotate, a particle beam can run in a scanning mode in a vacuum cavity, the particle beam is focused in each needle-shaped gap in extremely short time, and nuclear fusion with small controllable probability is generated by compression and mutual collision in a nuclear fusion chamber.

Claims (10)

1. The utility model provides a controllable nuclear fusion device of low temperature, the device not only can realize lasting controllable nuclear fusion, and the inner wall of device does not need the material of resistant extremely high temperature moreover, characterized by: the center of a cylindrical controllable nuclear fusion device is provided with a proton gun (1), a vacuum cavity (2), a needle-shaped focusing rod (3), a narrow-gap focusing cavity (4), an inner wall (5), a nuclear fusion microchamber (6) arranged at the bottom and the inner wall of the narrow-gap nuclear focusing cavity, a neutron adsorption layer (7) arranged on the outer side of the inner wall, a heat exchange layer (8) arranged on the outer side of the neutron adsorption layer, and an outer wall (9) of the controllable nuclear fusion device arranged on the outer side of the heat exchange layer.

2. A low temperature controllable nuclear fusion device as in claim 1 wherein: a power supply device is arranged outside a controllable nuclear fusion device to generate high-voltage electricity, an anode (10) is connected with a proton gun, a cathode (12) is connected with an inner wall to enable a small part of the inner wall and a needle-shaped focusing rod to be charged negatively, deuterium or tritium or a mixed deuterium-tritium positive ion (10) sprayed by the proton gun moves towards a narrow-gap focusing cavity and an inner wall of the outer wall of the needle-shaped focusing rod with negative electricity at high speed under the acceleration of an electric field, most particles collide with the outer wall of the needle-shaped focusing rod at an acute angle during the period of the deuterium or tritium or mixed deuterium-tritium positive ion, a small amount of angle is changed to continue to move forwards, and then collide with the outer wall of the needle-shaped focusing rod at an acute angle till the bottom is near, the density of the mixed deuterium-tritium particle in a nuclear fusion micro-chamber near the bottom of the narrow-gap nuclear focusing cavity is focused, the density of the mixed deuterium-tritium particle is, there is a certain probability that nuclear fusion reactions can be generated.

3. A low temperature controllable nuclear fusion device as in claim 1 wherein: the inner wall and the needle-shaped focusing rods are made of metal (such as tungsten and the like) or nonmetal materials with high melting point and high heat conductivity, the inner wall and the needle-shaped focusing rods can be made of the same material or different materials, the needle-shaped focusing rods are needle-shaped and have smooth surfaces, the needle-shaped focusing rods are densely arranged on the inner side surface of the inner wall, the needle points point to the center, and a small narrow gap is formed between the needle-shaped focusing rods. The inner side surface of the inner wall is made into a dense eccentric concave spherical surface, and the eccentric concave spherical surface and a tiny narrow gap at the lower end of the needle-shaped focusing rod form a nuclear fusion microchamber (6).

4. A low temperature controllable nuclear fusion device as in claim 1 wherein: the density and the movement speed of the mixed particles of deuterium and tritium in the nuclear fusion micro-chamber are controlled by adjusting the particle intensity and the voltage of an electric field output by the proton gun, so that the intensity of the generated nuclear fusion reaction can be controlled, and the temperature of the needle-shaped focusing rod, the nuclear fusion micro-chamber and the inner wall can also be controlled, so that the nuclear fusion device can continuously and controllably operate at a certain temperature.

5. A low temperature controllable nuclear fusion device as in claim 1 wherein: the inner wall can be an integral body and is connected with the cathode of the power supply; the inner wall can also be made into a block shape, and each block inner wall is respectively connected with the negative pole of the external power supply. The high-voltage accelerating electric field is controlled to rotate the electric field in the vacuum cavity, so that the particle beams run in a scanning mode in the vacuum cavity, the particle beams are focused in each needle-shaped gap in a very short time, and the nuclear fusion chamber is compressed and collided with each other to generate nuclear fusion.

6. A low temperature controllable nuclear fusion device as in claim 1 wherein: the scanning mode is characterized in that: 1. the intensity of particle beams is improved, and the nuclear fusion probability is increased; 2. the electric field intensity is improved, the particle motion speed is increased, and the nuclear fusion probability is increased; 3. the heat conduction and the heat dissipation of the needle-shaped focusing rod and the inner wall are increased. The needle-shaped focusing rod and the inner wall material are protected from being melted and deformed, and the service life is prolonged; 4. during the beam scan interval, the products after nuclear fusion, unreacted species and impurities have time to be evacuated.

7. A low temperature controllable nuclear fusion device as in claim 1 wherein: the power supply device is not needed to be arranged outside the controllable nuclear fusion device, a small proton accelerator can be arranged outside the controllable nuclear fusion device, deuterium or tritium or mixed positive ions of deuterium and tritium are accelerated to megaelectron volt-level speed and guided to the proton gun to be sprayed out, the proton gun can rotate, particle beams can run in a scanning mode in a vacuum cavity, the particle beams are focused in each needle-shaped gap in extremely short time, and the nuclear fusion chamber is compressed and collided with each other to generate nuclear fusion.

8. A low temperature controllable nuclear fusion device as in claim 1 wherein: deuterium or tritium or a deuterium-tritium mixed ion sprayed by the proton gun moves at a high speed towards the needle-shaped focusing rod and the inner wall with negative electricity under the acceleration of an electric field, the kinetic energy of the deuterium or tritium or the deuterium-tritium mixed ion is converted into heat energy mostly by colliding with the outer wall and the inner wall of the needle-shaped focusing rod, and the heat energy is conducted to the neutron absorption conversion layer and the heat exchange layer through the needle-shaped focusing rod and the inner wall.

9. A low temperature controllable nuclear fusion device as in claim 1 wherein: according to the controllable nuclear fusion device, input energy and energy generated by nuclear fusion are converted into heat energy in a closed cylindrical mode, the input energy is absorbed again to become a part of output heat energy, as long as a small probability of nuclear fusion reaction is generated, the Q factor is larger than 1, and sustainable nuclear fusion is achieved.

10. A low temperature controllable nuclear fusion device as in claim 1 wherein: the invention provides a low-temperature controllable continuous nuclear fusion device, which can realize continuous controllable nuclear fusion and does not need extremely high-temperature resistant materials on the inner wall of the device.

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