KR20190027464A - Nuclear fusion device where nuclear fusion is achieved through the compression of high-temperature plasma between a target and a high-speed bullet - Google Patents

Abstract

The present invention relates to a nuclear fusion apparatus which compresses, greater than or equal to 100 times, deuterium and tritium plasma having the temperature of higher than or equal to 1 million °C between a target and a high-speed bullet having a concave front and the speed of greater than or equal to 7 km per second in order to make the temperature of the plasma higher than or equal to 100 million °C, thereby causing nuclear fusion; allows neutron energy generated by the nuclear fusion to be absorbed into liquid metal in which lithium and lead are dissolved; and transfers heat to water vapor or carbon dioxide through a heat exchanger so as to turn a turbine generator, thereby generating electricity. The plasma having the temperature of higher than or equal to 1 million °C is produced by heating, with a laser, the plasma discharged whenever the high-speed bullet is fired or the discharged plasma or heating, with a laser, a deuterium and tritium fuel capsule. In a tokamak or stellarator, the plasma can be maintained at higher than or equal to 1 million °C and compressed between the target and the high-speed bullet, thereby causing nuclear fusion. In order to increase the energy efficiency of fusion power generation, the plasma temperature, the collision speed between the target and the high-speed bullet, and the temperature at the fusion reaction can be further increased. The deuterium and tritium plasma having the temperature higher than or equal to 4 million °C can be made each time or maintained in a fusion reactor in order to create a fusion reaction. The target and the high-speed bullet each can be shot at the speed greater than or equal to 11 km per second to collide with each other at the speed greater than or equal to 22 km per second. When the target and the high-speed bullet collide with each other, the plasma having the temperature higher than or equal to 4 million °C can be compressed greater than or equal to 200 times between the target and the high-speed bullet to increase the plasma temperature to the temperature higher than or equal to 800 million °C, thereby creating a fusion reaction. The present invention can implement economical fusion power generation in a short time.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a nuclear fusion device capable of compressing a high-temperature plasma between a target and a high-speed bullet,

More particularly, the present invention relates to a fusion power generation apparatus for generating electricity by fusion of deuterium and tritium, and more particularly, to a fusion power generation apparatus capable of compressing deuterium and tritium plasma with a metal bullet of at least 7 km per second by 100 times or more, Or more, and generates electricity using energy generated at this time.

There are many plasma guns that fire high-temperature deuterium and tritium plasmas. There are several high-speed guns that fire metal bullets of various sizes at speeds of 7 to 11 km / sec. Devices that heat and maintain deuterium and tritium above 10 million degrees Celsius include tokamak such as KSTAR and stellarators such as Wendelstein 7-X. Sensor technology to track high-speed plasma and high-speed bullets, and technology to match fuel capsules by adjusting the angle of the laser reflector at high speed. Because the plasma is electricity, the high-temperature plasma jet can be shot at high speed by the rail gun type plasma gun. Plasma can be shot at a high velocity of 250 km / second or faster using a magnetic field pulse.

In order to generate fusion, deuterium and tritium plasmas of more than 100 million degrees Celsius have to be maintained for a long time in a nuclear fusion reactor such as a tokamak or stellarator, but have not yet succeeded. Fusion fusion by heating deuterium and tritium fuel capsules with a laser has not yet succeeded in generating fusion several times. There have been many attempts to initiate fusion by firing and compressing plasma, but they have not yet succeeded in generating fusion many times. It is difficult to maintain a plasma of more than 100 million degrees for a long time in a nuclear fusion tokamak or stellarator because of various problems, and it is uncertain whether it can be realized within 30 years.

In order to solve the above problem, the present invention causes fusion of high-temperature deuterium and tritium plasma during the collision of a slow or fast-moving target and a cup-like high-speed bullet. A slow-moving target may be a solid, like a cup or cone made of lead or lithium and lead that has fallen or fired into a fusion reactor, or a liquid metal with lead or lithium and lead melted metal curtains flowing from top to bottom like a waterfall. have. A slow moving target can be a solid lead, like a lead or a lead cup or cone, or a concave bullet, shot from across a high speed bullet. A fast-moving target may be the same as a high-speed bullet, or it may be larger than a high-speed bullet but the same weight. High-temperature plasmas can be as much as 1 million degrees centigrade or more when shooting with a plasma gun, and just before a target and a high-speed bullet collide, the plasma between them is shot with a laser gun to make more than a million degrees centigrade. A capsule containing deuterium and tritium fuel can be attached to a slow-moving solid target, and the capsule can be shot with a laser gun to raise it to over 1 million degrees Celsius. After dropping or launching the capsule between the target and the high-speed bullet, the capsule can be shot with a laser gun and raised to over 1 million degrees Celsius. The capsule can be placed in front of the target and the high-speed bullet and heated with a laser just before the target and high-speed bullet collide. Capsules can be left in front of high-speed bullets. Capsules can be placed in front of a target or a high-speed bullet, or placed in front of a target or a high-speed bullet. Just before the target collides with the high-speed bullet, a plasma of more than 1 million degrees centigrade is shot, or a laser is used to heat the plasma to make it more than 1 million degrees centigrade or to heat the capsule with laser to make it more than 1 million degrees centigrade. The plasma can be held between the fast moving target and the high-speed bullet by maintaining a plasma of more than 1 million degrees centigrade in the inertial stellator and causing fusion.

If you keep 1 million degrees of plasma in a nuclear fusion tokamak or stellarator and compress it more than 100 times with a high speed bullet more than 7km per second, it becomes more than 100 million degrees centigrade. It compresses more than 1 million degrees centigrade plasma by more than 200 times by high speed bullet more than 7km per second and becomes more than 200 million degrees. When a bullet exceeds 7 km per second, the plasma is compressed between the two bullets at a velocity of 14 km per second, resulting in a fusion reaction. As the two cup-shaped bullets advance through the plasma, the plasma is compressed into the cup, and the temperature of the plasma increases. As the two bullets collide, the plasma trapped in the two cups is compressed. When compressed 100 times, the temperature increases more than 100 times. Plasma particles are faster than bullets, but plasma collides against each other and can not escape bullets. They are compressed into a cup in front of the bullet, trapped between the two cups, compressed after the two bullets collide, and compressed between deuterium and tritium at high temperature and pressure. Nuclear fusion occurs. Plasma is rarely in the range of 100 million degrees Celsius, but the pressure is about 2 atmospheres. A million degrees Celsius pressure is much less. You can reduce the error by colliding a heavy target with a speed of 1km / sec and a light bullet of 7km / sec.

Deuterium and tritium fuel capsules are attached in front of two bullets, and immediately before the two bullets collide, they are heated with a laser to produce deuterium and tritium plasma of more than 1 million degrees Celsius, which is compressed 100 times or more And fusion reaction can be achieved by energy extraction method of conventional laser fusion method.

Speed dexterous bullet that is 10 times faster and weighs 10 times slower and 10 times slower and weighs 10 times faster when hit on a slow bullet target. The deuterium and tritium fuel capsules attached to the slow targets are laser heated to 100 degrees Celsius When the target and bullet collide with each other, they generate a plasma of more than 100 times, and they are compressed more than 100 times to become the fusion reaction by more than 100 million degrees centigrade, and achieve fusion fusion by the energy extraction method of the conventional laser fusion method.

Immediately before the bullet collides, plasma guns fire deuterium and tritium plasma at over 1 million degrees Celsius, and when they collide with each other, they collapse 100 times or more to cause a fusion reaction.

Using two bullets of the same size, shape and weight, collide at the center of the fusion reactor at the same speed.

One of the two bullets of the same size can be 10 times heavier and 10 times slower than the other, reducing the variation in position where the bullets hit each other and making the fuel capsule easier to align with the laser. Apart from the deuterium tritium fuel capsule attached to the bullet, the size of the space containing deuterium and tritium in the space inside the bullet can be adjusted to the same size and weight. The diameter of the slower bullet may be larger to increase the area where the faster bullet impacts, thereby increasing the probability that the two bullets will compress the plasma.

Lithium and lead-molten liquid metal flow down the inner wall of a fusion reactor or the center of a fusion reactor, or curtain down from the ceiling of a fusion reactor to the bottom, or drop a solid target of cup, cone lead, or lithium and lead Or fired to create a target with which a high speed bullet will strike and fire plasma above 1 million degrees Celsius before the plasma gun collides with the target and high speed bullet, compressing it between the impacting target and the bullet, raising the temperature to more than 100 million degrees and causing fusion .

When a plasma of more than one million degrees centigrade is fired, if a bullet fires in the middle of a conical plasma gun, the later plasma will speed up, so the bullet will overtake the bullet before it hits the target. At this point, the plasma can push the bullet and increase the speed of the bullet. The bullet is recessed at the front and pointed at the back, making it better for the plasma to pass over from behind. You can make a wing that narrows from the back to the front of the bullet, allowing the plasma to overtake and gather it in front of the bullet. In FIG. 19, a plurality of plasma rings are drawn on one line, but in reality, it is a ring and is drawn like a plurality of lines to show the passing trajectory. Plasma more than 1 million degrees Celsius is compressed between the target and high speed bullet to increase the temperature to more than 100 million degrees Celsius, causing fusion. A high-speed bullet that fires across a high-speed bullet can be a target.

Plasma guns of more than 1 million degrees centigrade are fired from multiple plasma guns at the point where the target and bullet hit each other, and plasma is compressed between the target and the bullet to make fusion more than 100 million degrees centigrade.

The plasma launched at the point where the target collides with the bullet fires a laser in various directions to raise the temperature to over 1 million degrees Celsius and collide the target with the bullet to cause the plasma temperature to exceed 100 million degrees centigrade .

Fuel capsules with deuterium and tritium are fired and fuel capsules are heated to more than 1 million degrees Celsius by laser in various directions just before compression between the target and high speed bullets to produce more than 100 million degrees Celsius, Cause. The fuel capsule may be attached to one or both of the target or high speed bullets.

Using high-speed bullets at speeds of 7 km / sec or more, it compresses deuterium and tritium plasma more than 1 million degrees centigrade more than 100 times and obtains a high temperature of more than 100 million degrees Celsius, so a definite fusion reaction occurs. Fuel fusion reactions can be repeated as much as necessary for commercial development. Further improvements in the shape and speed of high speed bullets, size, material, composition of liquid metal, size and composition of deuterium tritium fuel capsules, plasma gun, laser gun, high speed gun performance, collision accuracy, Many of these improvements are relatively easy compared to the problems that need to be addressed before conventional fusion devices can be made.

The high-speed gun uses a conventional two-stage pistol that makes it possible to automatically replace bursting discs and high-density polyethylene (HDPE) pistons, but does not need HDPE pistons. Several light gas guns are installed on the rotating or conveyor-like device, so that they can be automatically turned and fired continuously. Even when the rail gun is used as a high-speed gun, the performance of the existing rail gun can be improved to be used as a gun for fusion power generation.

Tokamak or stellarator maintains a plasma of about 1 million degrees centigrade while compressing the plasma between two bullets and raising it to more than 100 million degrees centigrade to generate nuclear fusion by using plasma as a conventional fusion device such as Tokamak or Stellarator, It is relatively easy to maintain.

Plasma guns can propel more than 400 million degrees Celsius of plasma to more than 400 million degrees Celsius between a target and a high speed bullet above 11 km per second, or between two high-speed bullets, more than 400 million degrees Celsius, and more than 200 million degrees Celsius more than 800 million degrees Celsius The fuel causes a fusion reaction, which increases the efficiency.

According to the present invention, it is possible to realize an economical fusion power generation in a short time.

When fusion power is realized, the energy problem of mankind is solved. It can solve the energy problem of Mars by being built on Mars. It can be used as a propulsion device for ships, submarines and long-range spacecraft.

FIG. 1 shows a method of firing a high-speed bullet having a deodorant and tritium fuel-containing capsule in a liquid metal curtain target at the center of the fusion reaction furnace and irradiating the fuel capsule in various directions immediately before the high- FIG. 2 is a schematic view of a nuclear fusion reactor in which a high-temperature plasma is generated by heating to confine it between a target and a high-speed bullet to cause a fusion reaction.
FIG. 2 is a schematic view showing a liquid metal curtain target in the inner center of the fusion reaction apparatus of FIG. 1, a liquid metal curtain protecting the fusion reactor wall and a high speed gun firing a high velocity bullet and a laser gun firing the laser.
Figure 3 shows a five-ply liquid metal curtain target in the center of the fusion reactor in Figure 2, a five-ply liquid metal curtain protecting the walls of the reactor, and a two-ply liquid metal Fig.
Figure 4 is a top view of Figure 3
FIG. 5 is a graph showing the results obtained by shooting a capsule containing deuterium and tritium fuel in a liquid metal curtain target in the center of the fusion reaction furnace from top to bottom and firing a high-speed bullet to fire the laser in various directions immediately before the high- A schematic of a fusion reactor in which a heated fuel capsule is heated to produce a high-temperature plasma, which is then confined between a target and a high-speed bullet to cause a fusion reaction.
FIG. 6 is a graphical representation of the results of a method of firing a high velocity bullet at a liquid metal curtain target at the center of the fusion reaction furnace and firing deuterium and tritium plasma from the various directions into the plasma gun, Is a schematic view of a fusion reaction apparatus that generates a high-temperature plasma by heating a plasma by irradiating a laser and compressing the plasma between a target and a high-speed bullet to generate a fusion reaction.
If a plasma gun blows a plasma with a temperature of more than one million degrees centigrade, it is not necessary to heat the plasma with a laser, but even if the plasma gun fires a plasma with a temperature of more than 4,000,000 degrees centigrade, further heating with a laser is effective.
FIG. 7 is a schematic diagram of a fuel cell in which when the fuel capsule is heated by a laser immediately before a target and a high-speed bullet hit the liquid metal curtain target with a high-speed bullet having a deuterium and tritium fuel capsule in front, And a laser is heated just before the high-speed bullet collides with the laser, and the laser is heated immediately before the target collides with the high-speed bullet after the plasma is fired.
Figure 8 is a schematic view showing a liquid metal curtain target in the center of the fusion reaction furnace and a liquid metal curtain protecting the reactor wall and a liquid metal curtain dividing the reactor interior into four parts.
Figure 9 is a schematic view showing a liquid metal curtain target in the center of the fusion reaction furnace and a liquid metal curtain protecting the reactor wall and a liquid metal curtain dividing the reactor interior into eight parts.
10 is a schematic view showing an example in which a liquid metal curtain target is located in the middle of the fusion reaction furnace, and a liquid metal curtain is divided into 3, 4, 5, 6, and 8 parts of the reactor interior.
11 is a schematic view showing a muzzle emitting a high-speed bullet inside a fusion reaction furnace, a window emitting a laser, a muzzle emitting a plasma, and a hole through which a liquid metal protecting the wall flows.
12 is a schematic view showing an example of a wall having a hole for flowing liquid metal to protect the wall of the fusion reaction furnace;
13 shows that a high-speed gun fires a high-speed bullet like a cup at a speed of 7 km per second or more, and a plasma gun fires a deuterium tritium plasma at a temperature of more than 4,000,000 Celsius at a rate of 250 km / A schematic diagram of a nuclear fusion reactor in which two high-speed bullets are trapped, compressed and compressed to raise the plasma temperature to over 400 million degrees Celsius, resulting in a fusion reaction.
FIG. 14 shows that when a high-speed gun fires a high-speed bullet like a cup in front, and when a plasma gun fires a deuterium tritium plasma and plasma collides with each other, the plasma is heated by a laser to produce plasma with a temperature of more than 1 million degrees centigrade. A schematic representation of a fusion reactor in which two high-velocity bullets are trapped and collided to produce a fusion reaction by increasing the plasma temperature by more than 100 million degrees Celsius.
FIG. 15 illustrates a case where a high-speed bullet fired from a high-speed gun is blown through a center tube of a plasma gun in the case where a high-speed bullet flying at a speed of 7 km / sec or more flows in the center of a plasma gun that fires plasma of 4,000,000 degrees Celsius or more. The current flows from the outer copper cone to the inner copper cone. The emitted plasma compresses as the space between the outer and inner cones narrows and the temperature rises. Plasma leaving the cone plasma gun collides with the plasma that flies from the opposite side of the high-speed bullet that first left, and when two high-speed bullets gather the plasma like a cup and collide to compress the plasma, the temperature rises to over 400 million degrees Celsius, Of the fusion reaction apparatus.
FIG. 16 shows that a high speed bullet fired from a high speed gun flies through a center tube of a plasma gun when a high speed bullet flying at a speed of 7 km / sec or more flows in the center of a plasma gun that emits plasma of 4,000,000 degrees Celsius or more. The plasma leaving the cone plasma gun collides with the plasma that flies from the opposite side of the high-speed bullet that has passed first, and the laser is shot at several places at this time to raise the plasma temperature so that two high-speed bullets collide while collecting the high- A schematic representation of a fusion reactor in which the temperature rises above 400 million degrees Celsius to cause a fusion reaction.
FIG. 17 is a schematic view showing a high-speed gun for launching a high-speed bullet in a conical plasma gun and a plasma gun center tube used in FIGS. 15 and 16. FIG.
18 is a schematic cross-sectional view showing the inside of a conical plasma gun; The current flows from the outer copper cone to the inner copper cone, and the emitted plasma compresses as the space between the outer and inner cones narrows and the temperature rises. The high-speed bullet through the center tube passes through the high-speed bullet.
FIG. 19 is a schematic view showing a high-speed bullet, a high-temperature plasma generated by a conical plasma gun when a high-speed bullet collides with a target, so that a plasma fired from the back can be passed over and collected in front; The target may be a high-speed bullet fired from the opposite side, a solid target firing from the opposite side or firing from top to bottom, or a liquid metal curtain target. In FIG. 19, a plurality of plasma masses are shown, but this is intended to show the trajectory, and in practice, only one mass is fired at a time. The temperature can be further increased with the laser.
FIG. 20 is a schematic view of a nuclear fusion reactor in which a high-velocity bullet is fired from opposite sides and a plasma is fired in various directions and the plasma is heated in various directions by a laser just before the two concave high-speed bullets collide with each other to compress the plasma.
FIG. 21 is a schematic view of a high-speed bullet capable of holding a high-temperature plasma by being recessed in front and accommodating deuterium and tritium fuel in an internal space by adjusting a weight by placing a proper space therein.
FIG. 22 is a schematic view of a high-speed bullet having a round or round capsule containing deuterium and tritium fuel at the front or a little away from the front. FIG.
The high-speed bullet itself can also make deuterium and tritium bear with lithium hydride.
Figure 23 is a graphical representation of a high-speed bullet with deuterium and tritium fuel capsules in the entire front recess and a capsule containing deuterium and tritium fuel to participate in the fusion reaction of the fuel capsule, schematic.
FIG. 24 is a schematic view showing various shapes of high-speed bullets that have high concaved high-speed bullets and various shapes of high-speed bullets that have deuterium and tritium fuel in front or inside, so as to collect and compress hot plasma when colliding with a target.
Figure 25 shows a high speed bullet target having a fuel capsule in front of it and a high speed bullet without a fuel capsule. When heating a fuel capsule with a laser just before it collides, a high speed bullet target with a fuel capsule and a fuel capsule A schematic diagram showing the case where a fuel capsule is heated by a laser just before a preceding high-speed bullet collides with each other, and the fuel capsule is fired separately and heated by a laser to compress between a high-speed bullet target and a high-speed bullet which collide with each other.
26 is a schematic diagram showing various shapes of a solid metal target firing from a high-speed gun toward a high-speed gun or from above and below with a fusion reaction;
The solid metal target has a space inside it with multiple layers to control weight and not penetrate high-speed bullets.
A wide solid metal target fires at low speed to help collect plasma from multiple directions.
Figure 27 is a schematic diagram showing various forms of solid metal targets firing from a high-speed gun across a high-speed gun having a round or round and long deuterium and tritium fuel capsules in front, or firing down from a fusion reaction.
28 is a schematic view showing a state in which a fuel capsule of various shapes is pressed and compressed by a target and a high-speed bullet;
FIG. 29 illustrates a method of heating a fuel capsule immediately before a solid metal target collides with a high-speed bullet when the fuel capsule is heated by a laser just before a high-speed bullet collides with a solid metal target having a fuel capsule in front thereof , The plasma is fired between the solid metal target and the high-speed bullet, and when the plasma is heated by the laser, the plasma is fired immediately before colliding with the high-speed bullet after the wide solid metal target is fired and the plasma is heated by the laser Schematic showing case.
FIG. 30 is a schematic view showing a case in which a plasma at a temperature higher than 1 million degrees centigrade is fired immediately before a high-speed bullet and a high-speed bullet collide with each other,
FIG. 31 is a schematic view showing a case where a high-temperature plasma having a temperature of more than 1 million degrees centigrade in a plurality of directions is fired into a cylinder fired from top to bottom and a high-temperature plasma colliding with each other in a cylinder is compressed into two concave forward high-speed bullets to cause a fusion reaction.
FIG. 32 is a cross-sectional view of a fusion reactor in which a tube such as a tennis barrel is installed in the center of a fusion reaction chamber and a liquid metal is fired from several nozzles to form a conical target made of a liquid metal, A schematic diagram showing a case where a plasma is fired and a laser is heated from various directions by a laser, or a hot plasma is fired from the beginning into a cone to compress a hot plasma between a conical target and a high-speed bullet to cause a fusion reaction.
FIG. 33 is a schematic view showing that a forward concave high-speed bullet is separated from a new bow after being fired from a high-speed gun; FIG.
FIG. 34 is a schematic view showing a state where a high-speed bullet, a new bow, and a bursting disk are pre-assembled into a chamber of a high-speed gun.
The case of the bullet contains a busting disc as an integral part like easy open can. The shots are automatically loaded into high speed guns.
35 is a schematic view of a high-speed gun that compresses hydrogen gas into several pistons instead of compressing hydrogen gas into HDPE pistons when rupturing the busting disk to launch a high-speed bullet;
FIG. 36 is a schematic view of a fusion reaction furnace in which a liquid metal flows from top to bottom, such as a stepped rice paddle, to protect a reactor wall from a high-speed neutron generated in a fusion reaction.
FIG. 37 is a graph showing the relationship between the high-speed bullets and the high-speed bullets when the two high-speed bullets collide with each other by emitting a concave high-speed bullet in a tokamak or a stellarator, A schematic diagram of a fusion reactor in which a plasma is collected and compressed to increase the plasma temperature to 100 million degrees Celsius or more to cause a fusion reaction.

When the target and the front collide with a high-speed bullet at a speed of 7 km / sec or less like a cup, they collide with the high-temperature deuterium and tritium plasma to cause fusion. A slow-moving target is a reaction shot from the opposite side that fires a high-speed bullet in a fusion reactor. It is a reaction from the top of the ceiling or wall to the bottom of the ceiling or downward, or a fired lead or lithium or lead cup or cone, It could be a bullet-like solid, or it could be a liquid metal in which lead or lithium and lead-dissolved metal flowed from top to bottom like a curtain or waterfall. It can also be a cone made by spraying liquid or molten lead or lithium and lead by arranging several nozzles in a circle. A fast-moving target may be the same as a high-speed bullet, or it may be larger than a high-speed bullet but the same weight. High-temperature plasma can be more than one million degrees centigrade when shooting with a plasma gun, and plasma can be created by laser guns at just over 1 million degrees Celsius before the target and high-speed bullet collide. A capsule containing deuterium and tritium fuel can be attached to a slow-moving solid target, and the capsule can be shot with a laser gun to raise it to over 1 million degrees Celsius. After dropping or launching the capsule between the target and the high-speed bullet, the capsule can be shot with a laser gun and raised to over 1 million degrees Celsius. The capsule can be placed in front of the target and the high-speed bullet and heated with a laser just before the target and high-speed bullet collide. Capsules can be left in front of high-speed bullets. Capsules can be placed in front of a target or a high-speed bullet, placed in front of a target or a high-speed bullet, or integrated into a capsule in front of a high-speed bullet.

In order to increase the energy efficiency of fusion power generation, the temperature of deuterium and tritium plasma before compression with target and high-speed bullet, the collision speed of target and high-speed bullet, the temperature at the time of fusion reaction by target and high- . More than 4,000,000 degrees Celsius deuterium and tritium plasma can be made each time to create a fusion reaction, or it can be kept in the fusion reactor. The target and high-speed bullet can be shot at more than 11 km per second to collide with each other for more than 22 km per second. In the event of a collision, a plasma of more than 4,000,000 degrees Celsius may be compressed 200 times or more to increase the plasma temperature to more than 800 million degrees Celsius, thereby causing a fusion reaction.

In this way, more than 1 million degrees Celsius deuterium and tritium plasma are compressed 100 times or more between the targets and high-speed bullets above 7 km per second to raise the temperature to more than 100 million degrees Celsius, causing fusion.

Just before the target collides with a high-speed bullet, you can shoot a deuterium tritium plasma that is over 1 million degrees Celsius, heat the plasma with a laser, heat it to more than 1 million degrees Celsius, or heat the capsule with laser to make more than 1 million degrees Celsius It can maintain a plasma of more than 1 million degrees centigrade in a conventional tokamak or stellarator and compress the plasma between a fast moving target and a high-speed bullet, raising the temperature to more than 100 million degrees Celsius and causing fusion.

Whenever deuterium and tritium plasma are compressed between a target and a high-speed bullet, a fuel capsule containing deuterium and tritium is placed in front of the bullet in front of the bullet, To heat the deuterium and tritium of the fuel capsule to 1 million degrees Celsius. If the target is a solid object larger than a high velocity bullet made of lead or lithium and lead, the fusion reaction will cause it to fall down from the ceiling or from the upper part of the wall downwards, or to fire at the opposite side of the high speed gun toward the high speed gun. The target may contain deuterium and tritium in the interior of the target, or the target metal itself may include deuterium and tritium as metal hydrides. The surface where the target collides with the bullet may be concave or hemispherical, convex or flat. Just before the target collides with the high-speed bullet, it can be heated to more than one million degrees centigrade with a laser after firing a plasma at 1 million degrees Celsius or a lower temperature plasma. Deuterium and tritium in fuel capsules placed in front of high-speed bullets can be heated by laser to make more than 1 million degrees Celsius. Using this method, more than 1 million degrees Celsius deuterium and tritium plasma are compressed between the target and the high-speed bullet, raising the temperature to more than 100 million degrees Celsius, causing fusion.

If the target is lead or a molten metal made of lithium and lead, the liquid metal flows down through the various nozzles from the ceiling of the fusion reactor to the floor like a curtain. The curtains let down several layers. If the curtains are in the center of the fusion reaction, the curtains form three to eight pillars that allow the high-speed gun to fire bullets at three to eight walls of the fusion reaction. The cross section of the central column may be circular instead of a polygon. A blanket can be placed in the middle of the column to absorb neutron energy that can not be absorbed by multiple sheets of liquid metal curtains. The column may have one or two of the fusion reactions. When there are multiple pillars, a molten metal curtain wall is created between the pillars to prevent the debris from colliding with the target and the high-speed bullet from protruding toward the other column. If the target is lead or a molten metal made of lithium and lead, it can flow from the ceiling to the floor like a curtain in front of a wall of a fusion reactor. A high speed gun can fire a bullet from the other side. If the Fusion Reaction Furnace is square and there are no pillars in the middle, a high-speed gun should be placed in two locations, shoot a bullet on a liquid metal curtain target in front of the opposite wall, or place a high-speed gun at four locations, Shoot a bullet at the liquid metal curtain target, slightly below the entrance. The fusion reaction causes the curtains in front of the wall to be folded so that the bullet does not damage the walls of the reactor. A blanket may be installed in the reactor furnace wall to absorb neutron energy that is not absorbed by the liquid metal curtain. Reactor walls and columns can also be protected with molten lithium and lead liquid metal from multiple holes. Molten metal curtains fired from the ceiling or flowing down can protect pillars and walls from neutrons. A high-speed gun shoots a bullet at the opposite side of the flat surface of molten lithium and lead liquid metal curtains falling from the ceiling to the floor. The walls of the reactor can be made like terraced paddies, allowing molten metal to flow down like liquid, protecting the reactor walls from neutrons. The molten lithium and lead are drawn from several nozzles not only in the top layer of the staircase but also in the middle layers. There are several nozzles that spray liquid metal into the reactor walls, so that molten lithium and lead can flow down the walls to protect the reactor walls from neutrons. If there is a column in the reactor, the wall of the column likewise allows the molten lithium and lead from several nozzles to flow out to protect the column. Liquid metal curtains and liquid metal flowing from walls and columns protect nuclear fusion reactors from neutrons, absorb neutron energy from fusion reactions and transfer them to water vapor or carbon dioxide from a heat exchanger. Lithium is converted into tritium, Of fuel.

The fusion reaction may be performed in various ways as shown in FIGS. 1, 5, 6, 8, 9, 10, 13, 14, 15, 16, 20, Multiple layers of liquid metal curtains can be placed in front of the pillars or walls of the fusion reactor to target high-speed bullets. Spray liquid metal that has dissolved lithium and lead from the nozzle of the column and the wall to flow down the column surface or the wall surface. A liquid metal curtain is made between the high-speed bullet and the target to prevent the debris from splashing when the target collides. If necessary, eliminate some liquid metal curtains when launching plasma guns or laser guns to ensure a launch angle.

In this way, more than 1 million degrees Celsius deuterium and tritium plasma are compressed between target and high-speed bullet, raising the temperature to more than 100 million degrees Celsius, generating fusion and generating electricity.

A solid target made of lead or lithium and lead into a cup or cone is shot or dropped from the ceiling to the floor by a fusion reaction, or fired from a high speed gun muzzle toward a high speed gun muzzle. The inner tip of the cone is the target, which can cause plasma and high speed bullets to collide. Plasma more than 1 million degrees centigrade is fired, compressed between a target and a high speed bullet, or shot by a plasma, heated with a laser to raise the temperature to over 1 million degrees Celsius, and compressed between the target and the high speed bullet. Deuterium and tritium fuel capsules placed in front of the bullet can be heated with a laser to cause the target and bullet to collide with each other. Plasma inside the cone can be collected and heated by a laser to raise the temperature to more than 1 million degrees centigrade, or plasma guns can fire 1 million degrees Celsius plasma and compress between target and high speed bullet to cause fusion. A solid cone can be made of lead or lithium and lead to drop it, fire a high-speed gun inside the cone, and launch a plasma to compress the plasma inside the cone to cause fusion. Using this method, more than 1 million degrees Celsius deuterium and tritium plasma are compressed between the target and the high-speed bullet, raising the temperature to more than 100 million degrees Celsius, causing fusion.

Plasma can be fired directly behind the bullet just before the two bullets hit the plasma gun, or vertically on the bullet hit line, or obliquely from various directions behind. The plasma that fires behind the bullet is much faster than the bullet, so it overtakes the bullet and collides with the plasma between the two bullets. When firing a plasma at a temperature of 1 million degrees Celsius or lower, the laser is fired at various directions just before it is compressed between the target and the bullet, making it 1 million degrees Celsius. When firing from a conical plasma gun right behind, you can put a wing around a high-speed bullet so that the plasma can overtake the bullet and collect it in front of the bullet. In FIG. 19, a plurality of plasma rings are drawn on one line, but in reality, it is a ring and is drawn like a plurality of lines to show the passing trajectory. There is also an effect of increasing the bullet speed when the plasma overtakes the bullet. You can also increase the speed by adding a magnetic field accelerator to the plasma gun. You can add a deflecting coil to adjust the angle at which you shoot the plasma. When a conical plasma gun fires a donut-shaped plasma mass and impacts a target with a bullet, several high-speed guns may fire a number of high-velocity guns in various directions to allow multiple high-speed bullets to simultaneously compress the donut. If you fire a plasma at less than one million degrees Celsius, you can fire a laser in multiple directions to make more than a million degrees centigrade and compress between the target and the bullets.

Plasma is shot between two or more high-speed bullets, plasma collides with each other, laser is heated up to 1 million degrees Celsius, and two bullets collide with each other to cause compression, resulting in nuclear fusion.

Using this method, more than 1 million degrees Celsius deuterium and tritium plasma are compressed between the target and the high-speed bullet, raising the temperature to more than 100 million degrees Celsius, causing fusion.

Fuel capsules with deuterium tritium can be placed on both bullets or only on one side of the bullet when high-speed bullets hit each other. Fuel capsules are laser fired in multiple directions and heat to more than 1 million degrees Celsius. Fuel capsules can be placed on bulky, heavy, and slow bullets to make fuel capsules easier to align with the laser. Reactors can be fueled with capsules that can be easily injected into the fuel by shooting down from the ceiling, free-falling, or a large solid target made of lead or lithium and lead that fires from the high-speed gun to the high-speed gun.

A concave bullet in the front is concave, hemispherical, or elliptical, allowing the plasma to be gathered between the target and the bullet or between two bullets to be compressed.

The bullet may contain deuterium and tritium in the space inside the bullet, or the bullet metal itself may be in a state of metal hydride (deuterium and tritium). There may be a fuel capsule with deuterium and tritium in the front of the bullet.

The cross section from the top of the target curtain can be concave, convex, or planar. The plasma is fired at 1 million degrees Celsius or less, and plasma is fired. The bullet is heated to 1 million degrees Celsius The appropriate shape should be selected according to the conditions.

Using this method, more than 1 million degrees Celsius deuterium and tritium plasma are compressed between the target and the high-speed bullet, raising the temperature to more than 100 million degrees Celsius, causing fusion.

A conventional light gas gun ignited a combustible gas or smokeless powder to push a high density polyethylene (HDPE) piston, which compressed the hydrogen gas to high temperature and high pressure, bursting the busting disk and pushing the new bullet with the bullet at high speed The present invention automatically shoots and launches a shot using a pre-assembled shot of a high-speed bullet, a new bow, and a bursting disk so that it can be fired continuously. Instead of pushing out and replacing the high density polyethylene piston every time, replace the cap with a high-density polyethylene cap in front of a lightweight pistol made of CFRP and titanium. Make the cylinder and piston so that excessive deformation of the cap does not occur. The piston is driven by supercritical steam or supercritical carbon dioxide, which is used to drive the turbine. Instead of rupturing the busting disk by compressing the hydrogen gas with a single piston, several pistons may be arranged in a circular shape so that multiple pistons compress the hydrogen gas to rupture the busting disk. A high-speed shutter is used so that the high-speed bullet propelling hydrogen gas does not enter the reactor. High-speed bullets, new bows and bursting discs can automatically load pre-assembled bullets and continue to fire as high-speed guns are ready to fire. When high-speed bullets collide with each other, high-speed guns can be mounted facing each other in various directions, and multiple units can be installed and shot to shoot. If you are shooting a high-speed gun on a target, you can shoot one or more high-speed guns in multiple directions around the reaction chamber, fire one at a time, or several units in multiple directions and fire one at a time have. The frequency of firing is controlled according to the energy of the fusion reaction that takes place per foot. Using this high-speed gun system, more than 1 million degrees Celsius deuterium and tritium plasma are compressed between the target and high-speed bullets, raising the temperature to more than 100 million degrees Celsius, causing fusion.

Fusion Reaction A liquid metal curtain falling from the ceiling to the floor of a nuclear fusion reactor in front of a wall or a pole. Fission reaction or a fusion reaction. Ceiling or fusion reaction. Drops from the top of the wall downward or from the high velocity gun toward the high velocity gun. When a high-speed bullet is fired on a solid target, if there is deuterium and tritium fuel capsules in front of the bullet, it will be laser-launched at just over 1 million degrees Celsius immediately before impact.

When a high-speed bullet is fired on a liquid metal curtain target or on a solid metal target fired from the opposite side, just before the bullet hits the target, several plasma guns from various directions are fired and the laser is heated to heat the bullet The plasma temperature should be above 1 million degrees Celsius.

When a high-speed bullet is fired on a liquid metal curtain target or on a solid metal target that is fired from the opposite side, a cone-shaped plasma gun behind the bullet just before the bullet hits the target will shoot and overtake a plasma at 1 degree Celsius, A laser can be used to make the plasma temperature higher and compress it with a bullet.

Deuterium and tritium fuel capsules can be fired independently between the target and high-speed bullets, or the capsules can be attached to one or more legs in front of a bullet or solid target, assembled to the front of a bullet or solid target, or integrated . Fuel capsules can be spherical, cylindrical, elliptical, conical, etc.

It is possible to increase the efficiency when the laser is heated by putting a frame around the fuel capsule attached to the target. Just prior to the collision of the bullets from both sides with the fuel capsules on both sides, the fuel capsule in the middle can be heated with laser to bring the temperature above 1 million degrees Celsius. It can be compressed more than 100 times and cause fusion at more than 100 million degrees. In the ICF, a round capsule is laser-launched from the four sides of the sphere to raise it to more than 100 million degrees Celsius. In the present invention, however, it is possible to make the laser more than one million degrees centigrade by firing the laser around the periphery of the sphere. By heating the plasma at 1 degree Celsius and speeding up to 7 kilometers per second, the plasma volume is compressed by 100 to 200 times, increasing the temperature by 100 to 200 millions of degrees Celsius, so that more deuterium and tritium react to the fusion reaction.

Using this method, more than 1 million degrees Celsius deuterium and tritium plasma are compressed between the target and the high-speed bullet, raising the temperature to more than 100 million degrees Celsius, causing fusion.

Fusion reactions can compress the plasma between the targets fired at both ends and the high-speed bullet by shooting down or dropping lead or lithium and lead in the ceiling from the ceiling. The inside of the conduit can serve as a mirror to enhance the effect of heating the plasma with the laser. It also has the effect of blocking the plasma even when colliding high-velocity bullets with lead or lithium and lead solid targets firing toward high-speed guns. Plasma more than 1 million degrees Celsius can be shot to compress between the target and the bullet in the conduit. Plasma more than 1 million degrees Celsius fired from behind a bullet can be compressed between two high-speed bullets. Two bullets of 7 km per second collide with each other for 14 km per second, compressing more than 1 million degrees centigrade plasma to make more than 100 million degrees centigrade, causing fusion.

When a deuterium and tritium plasma of 1 million degrees Celsius is maintained in a tokamak or stellar reactor fusion reactor, the plasma is compressed into the bullet when the front bullet, such as cup or cup, is fired at 7 km / sec. When two bullets collide at a speed of 14 km per second, the plasma between the two is compressed more than 100 times and the fusion reaction of deuterium and tritium occurs when it exceeds 100 million. The neutron energy is then absorbed by the lead and lithium metals in the blanket surrounding the tokamak or stellarator reactor. The hot liquid metal goes to the heat exchanger to heat the water vapor and the water vapor turns the steam turbine generator to produce electricity. A high-speed gun that fires two bullets is placed facing up or down on the tokamak or stellar reactor, or placed side-by-side. If the two bullets are less likely to collide at higher plasma densities in the reactor due to subtle differences in the launch point and velocity of the two bullets, one of the two bullets will shoot first, making them heavier and slower than the others. The shape of the tokamak or stellarator and the arrangement of the high-speed gun are shown in Fig.

Supercritical and ultra-supercritical steam turbines or supercritical carbon dioxide turbines are used to propel the turbine generators and propel the pistons of high-speed guns.

In this way, more than 1 million degrees Celsius deuterium and tritium plasma are compressed between target and high-speed bullet, raising the temperature to more than 100 million degrees Celsius, generating fusion and generating electricity.

1. Fusion Reactor with Medium Liquid Metal Curtain Targets
2. High-speed gun using high-speed bullet paw
3. Laser gun
4. High speed bullet and new bow separation and recovery device (considered as part of high speed gun)
5. Liquid metal curtains that protect walls with fusion reactions and absorb the fusion reaction energy
6. A liquid metal curtain that is a target of high-speed bullet impact and absorbs fusion reaction energy
7. Liquid metal curtain dividing the fusion reactor into several parts
8. Capsule gun firing a deuterium tritium fuel capsule from top to bottom in front of a liquid metal curtain target
9. Plasma Gun to Launch Plasma Jet
10. Liquid metal curtain targets in the center or wall of the fusion reaction
11. High-speed bullets
12. Deuterium and tritium fuel capsules attached to solid metal targets (including high-speed bullets) or high-speed bullets
13. Proprietary deuterium and tritium fuel capsules
14. High speed bullet exit
15. Exit from plasma
16. Exit from laser
17. The outlet through which liquid metal flows down the wall surface
18. A solid metal target fired from both sides (a high-speed bullet is also considered as a kind of solid metal target) and a fusion reaction in which a high-speed bullet collides with the center
19. Plasma gun to fire high temperature plasma
20. Plasma guns that launch high-temperature plasma with a tube through which a high-speed bullet passes in the middle
21. The tube through which the high-speed bullet passes
22. External electrode
23. Internal electrode
24. The space between the inner and outer electrodes where the plasma is compressed and the temperature rises
25. Insulator
26. The exit where the high-speed bullet and the high-temperature plasma are fired
27. Solid metal targets
28. Space for controlling weight or space containing deuterium and tritium fuel for secondary fusion reaction
29. High-speed bullets with wings that allow plasma to overtake and collect high-speed bullets
30. When the laser is heated, deuterium and tritium fuel capsules with tubes attached to both sides of the plasma so that the plasma bursts on both sides and high-
31. Individually launched tubes that fire high temperature plasma before high-speed bullets collide
32. Tubes for supplying liquid metal in which lead or lithium and lead are dissolved
33. Cone formed by liquid metal sprayed from several nozzles on the rim
34. A new bow that protects high-speed bullets as they accelerate by pushing high-speed bullets from high-speed guns to hydrogen gas
35. A gun made in one piece with a busting disk containing high-speed bullets and a new bow.
36. Bursting disks burst by compressed high temperature, high pressure,
37. Chambers of high-speed guns loaded with high-speed bullets and new bow
38. Pistons operating with supercritical steam or supercritical carbon dioxide
39. Piston connected with 38, compressing hydrogen to high temperature and high pressure to burst bursting disk
40. Cascade wall of fusion reactor flowing liquid metal protecting wall
41. A blanket of liquid metal that absorbs the neutron energy of the fusion reaction and produces tritium from lithium
42. Liquid metal circulation pump
43. Heat exchanger exchanging heat energy between liquid metal and supercritical water or supercritical carbon dioxide
44. Tokamak
45. Stellarator

Claims (11)

When the target and the front collide with a high-speed bullet at a speed of 7 km / sec or less like a cup, they collide with the high-temperature deuterium and tritium plasma to cause fusion. A slow-moving target is a reaction shot from the opposite side that fires a high-speed bullet in a fusion reactor. It is a reaction from the top of the ceiling or wall to the bottom of the ceiling or downward, or a fired lead or lithium or lead cup or cone, It could be a bullet-like solid, or it could be a liquid metal in which lead or lithium and lead-dissolved metal flowed from top to bottom like a curtain or waterfall. It can also be a cone made by spraying liquid or molten lead or lithium and lead by arranging several nozzles in a circle. A fast-moving target may be the same as a high-speed bullet, or it may be larger than a high-speed bullet but the same weight. High-temperature plasma can be more than one million degrees centigrade when shooting with a plasma gun, and plasma can be created by laser guns at just over 1 million degrees Celsius before the target and high-speed bullet collide. A capsule containing deuterium and tritium fuel can be attached to a slow-moving solid target, and the capsule can be shot with a laser gun to raise it to over 1 million degrees Celsius. After dropping or launching the capsule between the target and the high-speed bullet, the capsule can be shot with a laser gun and raised to over 1 million degrees Celsius. The capsule can be placed in front of the target and the high-speed bullet and heated with a laser just before the target and high-speed bullet collide. Capsules can be left in front of high-speed bullets. Capsules can be placed in front of a target or a high-speed bullet, placed in front of a target or a high-speed bullet, or integrated into a capsule in front of a high-speed bullet.
In order to increase the energy efficiency of fusion power generation, the temperature of deuterium and tritium plasma before compression with target and high-speed bullet, the collision speed of target and high-speed bullet, the temperature at the time of fusion reaction by target and high- . More than 4,000,000 degrees Celsius deuterium and tritium plasma can be made each time to create a fusion reaction, or it can be kept in the fusion reactor. The target and high-speed bullet can be shot at more than 11 km per second to collide with each other for more than 22 km per second. In the event of a collision, a plasma of more than 4,000,000 degrees Celsius may be compressed 200 times or more to increase the plasma temperature to more than 800 million degrees Celsius, thereby causing a fusion reaction.
In this way, a high-temperature deuterium and tritium plasma with a temperature of more than 1 million degrees centigrade are compressed at a rate of more than 100 times between the target and the high-speed bullet that collide with each other at a speed of more than 7 km per second to increase the temperature to more than 100 million degrees Celsius, Just before the target collides with a high-speed bullet, you can shoot a deuterium tritium plasma that is over 1 million degrees Celsius, heat the plasma with a laser, heat it to more than 1 million degrees Celsius, or heat the capsule with laser to make more than 1 million degrees Celsius A fusion device that keeps a plasma of more than 1 million degrees centigrade in a conventional tokamak or stellarator and compresses the plasma between a fast moving target and a high-speed bullet, raising the temperature to more than 100 million degrees Celsius and causing fusion. The method of claim 1, wherein
Whenever deuterium and tritium plasma are compressed between a target and a high-speed bullet, a fuel capsule containing deuterium and tritium is placed in front of the bullet in front of the bullet, To heat the deuterium and tritium of the fuel capsule to 1 million degrees Celsius. If the target is a solid object larger than a high velocity bullet made of lead or lithium and lead, the fusion reaction will cause it to fall down from the ceiling or from the upper part of the wall downwards, or to fire at the opposite side of the high speed gun toward the high speed gun. The target may contain deuterium and tritium in the interior of the target, or the target metal itself may include deuterium and tritium as metal hydrides. The surface where the target collides with the bullet may be concave or hemispherical, convex or flat. Just before the target collides with the high-speed bullet, it can be heated to more than one million degrees centigrade with a laser after firing a plasma at 1 million degrees Celsius or a lower temperature plasma. Deuterium and tritium in fuel capsules placed in front of high-speed bullets can be heated by laser to make more than 1 million degrees Celsius. Using this method, a deuterium and tritium plasma of more than 1 million degrees Celsius is compressed between a target and a high-speed bullet to increase the temperature to more than 100 million degrees Celsius, The method of claim 1, wherein
If the target is lead or a molten metal made of lithium and lead, the liquid metal flows down through the various nozzles from the ceiling of the fusion reactor to the floor like a curtain. The curtains let down several layers. If the curtains are in the center of the fusion reaction, the curtains form three to eight pillars that allow the high-speed gun to fire bullets at three to eight walls of the fusion reaction. The cross section of the central column may be circular instead of a polygon. A blanket can be placed in the middle of the column to absorb neutron energy that can not be absorbed by multiple sheets of liquid metal curtains. The column may have one or two of the fusion reactions. When there are multiple pillars, a molten metal curtain wall is created between the pillars to prevent the debris from colliding with the target and the high-speed bullet from protruding toward the other column. If the target is lead or a molten metal made of lithium and lead, it can flow from the ceiling to the floor like a curtain in front of a wall of a fusion reactor. A high speed gun can fire a bullet from the other side. If the Fusion Reaction Furnace is square and there are no pillars in the middle, a high-speed gun should be placed in two locations, shoot a bullet on a liquid metal curtain target in front of the opposite wall, or place a high-speed gun at four locations, Shoot a bullet at the liquid metal curtain target, slightly below the entrance. The fusion reaction causes the curtains in front of the wall to be folded so that the bullet does not damage the walls of the reactor. A blanket may be installed in the reactor furnace wall to absorb neutron energy that is not absorbed by the liquid metal curtain. Reactor walls and columns can also be protected with molten lithium and lead liquid metal from multiple holes. Molten metal curtains fired from the ceiling or flowing down can protect pillars and walls from neutrons. A high-speed gun shoots a bullet at the opposite side of the flat surface of molten lithium and lead liquid metal curtains falling from the ceiling to the floor. The walls of the reactor can be made like terraced paddies, allowing molten metal to flow down like liquid, protecting the reactor walls from neutrons. The molten lithium and lead are drawn from several nozzles not only in the top layer of the staircase but also in the middle layers. There are several nozzles that spray liquid metal into the reactor walls, so that molten lithium and lead can flow down the walls to protect the reactor walls from neutrons. If there is a column in the reactor, the wall of the column likewise allows the molten lithium and lead from several nozzles to flow out to protect the column. Liquid metal curtains and liquid metal flowing from walls and columns protect nuclear fusion reactors from neutrons, absorb neutron energy from fusion reactions and transfer them to water vapor or carbon dioxide from a heat exchanger. Lithium is converted into tritium, Of fuel.
The fusion reaction may be performed in various ways as shown in FIGS. 1, 5, 6, 8, 9, 10, 13, 14, 15, 16, 20, Multiple layers of liquid metal curtains can be placed in front of the pillars or walls of the fusion reactor to target high-speed bullets. Spray liquid metal that has dissolved lithium and lead from the nozzle of the column and the wall to flow down the column surface or the wall surface. A liquid metal curtain is made between the high-speed bullet and the target to prevent the debris from splashing when the target collides. If necessary, eliminate some liquid metal curtains when launching plasma guns or laser guns to ensure a launch angle.
Using this method, a deuterium and tritium plasma of more than 1 million degrees Celsius is compressed between a target and a high-speed bullet to increase the temperature to more than 100 million degrees Celsius, The method of claim 1, wherein
A solid target made of lead or lithium and lead into a cup or cone is shot or dropped from the ceiling to the floor by a fusion reaction, or fired from a high speed gun muzzle toward a high speed gun muzzle. The inner tip of the cone is the target, which can cause plasma and high speed bullets to collide. Plasma more than 1 million degrees centigrade is fired, compressed between a target and a high speed bullet, or shot by a plasma, heated with a laser to raise the temperature to over 1 million degrees Celsius, and compressed between the target and the high speed bullet. Deuterium and tritium fuel capsules placed in front of the bullet can be heated with a laser to cause the target and bullet to collide with each other. Plasma inside the cone can be collected and heated by a laser to raise the temperature to more than 1 million degrees centigrade, or plasma guns can fire 1 million degrees Celsius plasma and compress between target and high speed bullet to cause fusion. A solid cone can be made of lead or lithium and lead to drop it, fire a high-speed gun inside the cone, and launch a plasma to compress the plasma inside the cone to cause fusion.
Using this method, a deuterium and tritium plasma of more than 1 million degrees Celsius is compressed between a target and a high-speed bullet to increase the temperature to more than 100 million degrees Celsius, The method of claim 1, wherein
Plasma can be fired directly behind the bullet just before the two bullets hit the plasma gun, or vertically on the bullet hit line, or obliquely from various directions behind. The plasma that fires behind the bullet is much faster than the bullet, so it overtakes the bullet and collides with the plasma between the two bullets. When firing a plasma at a temperature of 1 million degrees Celsius or lower, the laser is fired at various directions just before it is compressed between the target and the bullet, making it 1 million degrees Celsius. When firing from a conical plasma gun right behind, you can put a wing around a high-speed bullet so that the plasma can overtake the bullet and collect it in front of the bullet. There is also an effect of increasing the bullet speed when the plasma overtakes the bullet. You can also increase the speed by adding a magnetic field accelerator to the plasma gun. In FIG. 19, a plurality of plasma rings are drawn on one line, but in reality, it is a ring and is drawn like a plurality of lines to show the passing trajectory. You can add a deflecting coil to adjust the angle at which you shoot the plasma. When a conical plasma gun fires a donut-shaped plasma mass and impacts a target with a bullet, several high-speed guns may fire a number of high-velocity guns in various directions to allow multiple high-speed bullets to simultaneously compress the donut. If you fire a plasma at less than one million degrees Celsius, you can fire a laser in multiple directions to make more than a million degrees centigrade and compress between the target and the bullets.
Plasma is shot between two or more high-speed bullets, plasma collides with each other, laser is heated up to 1 million degrees Celsius, and two bullets collide with each other to cause compression, resulting in nuclear fusion.
Using this method, a deuterium and tritium plasma of more than 1 million degrees Celsius is compressed between a target and a high-speed bullet to increase the temperature to more than 100 million degrees Celsius, The method of claim 1, wherein
Fuel capsules with deuterium tritium can be placed on both bullets or only on one side of the bullet when high-speed bullets hit each other. Fuel capsules are laser fired in multiple directions and heat to more than 1 million degrees Celsius. Fuel capsules can be placed on bulky, heavy, and slow bullets to make fuel capsules easier to align with the laser. Reactors can be fueled with capsules that can be easily injected into the fuel by shooting down from the ceiling, free-falling, or a large solid target made of lead or lithium and lead that fires from the high-speed gun to the high-speed gun.
A concave bullet in the front is concave, hemispherical, or elliptical, allowing the plasma to be gathered between the target and the bullet or between two bullets to be compressed.
The bullet may contain deuterium and tritium in the space inside the bullet, or the bullet metal itself may be in a state of metal hydride (deuterium and tritium). There may be a fuel capsule with deuterium and tritium in the front of the bullet.
The cross section from the top of the target curtain can be concave, convex, or planar. The plasma is fired at 1 million degrees Celsius or less, and plasma is fired. The bullet is heated to 1 million degrees Celsius The appropriate shape should be selected according to the conditions.
Using this method, a deuterium and tritium plasma of more than 1 million degrees Celsius is compressed between a target and a high-speed bullet to increase the temperature to more than 100 million degrees Celsius, The method of claim 1, wherein
A conventional light gas gun ignited a combustible gas or smokeless powder to push a high density polyethylene (HDPE) piston, which compressed the hydrogen gas to high temperature and high pressure, bursting the busting disk and pushing the new bullet with the bullet at high speed The present invention automatically shoots and fires a bullet, a new bow, and a bursting disk using a pre-assembled bullet so that the bullet can be easily fired continuously. Instead of pushing out and replacing the high density polyethylene piston every time, replace the cap with a high-density polyethylene cap in front of a lightweight pistol made of CFRP and titanium. Make the cylinder and piston so that excessive deformation of the cap does not occur. The piston is driven by supercritical steam or supercritical carbon dioxide, which is used to drive the turbine. Instead of rupturing the busting disk by compressing the hydrogen gas with a single piston, several pistons may be arranged in a circular shape so that multiple pistons compress the hydrogen gas to rupture the busting disk. A high-speed shutter is used so that the high-speed bullet propelling hydrogen gas does not enter the reactor. High-speed bullets, new bows and bursting discs can automatically load pre-assembled bullets and continue to fire as high-speed guns are ready to fire. When high-speed bullets collide with each other, high-speed guns can be mounted facing each other in various directions, and multiple units can be installed and shot to shoot. If you are shooting a high-speed gun on a target, you can shoot one or more high-speed guns in multiple directions around the reaction chamber, fire one at a time, or several units in multiple directions and fire one at a time have. The frequency of firing is controlled according to the energy of the fusion reaction that takes place per foot.
This high-speed gun system is used to compress deuterium and tritium plasma of more than 1 million degrees centigrade between target and high-speed bullet to increase the temperature to more than 100 million degrees Celsius, The method of claim 1, wherein
Fusion Reaction A liquid metal curtain falling from the ceiling to the floor of a nuclear fusion reactor in front of a wall or a pole. Fission reaction or a fusion reaction. Ceiling or fusion reaction. Drops from the top of the wall downward or from the high velocity gun toward the high velocity gun. When a high-speed bullet is fired on a solid target, if there is deuterium and tritium fuel capsules in front of the bullet, it will be laser-launched at just over 1 million degrees Celsius immediately before impact.
When a high-speed bullet is fired on a liquid metal curtain target or on a solid metal target fired from the opposite side, just before the bullet hits the target, several plasma guns from various directions are fired and the laser is heated to heat the bullet The plasma temperature should be above 1 million degrees Celsius.
When a high-speed bullet is fired on a liquid metal curtain target or on a solid metal target that is fired from the opposite side, a cone-shaped plasma gun behind the bullet just before the bullet hits the target will shoot and overtake a plasma at 1 degree Celsius, A laser can be used to make the plasma temperature higher and compress it with a bullet.
Deuterium and tritium fuel capsules can be fired independently between the target and high-speed bullets, or the capsules can be attached to one or more legs in front of a bullet or solid target, assembled to the front of a bullet or solid target, or integrated . Fuel capsules can be spherical, cylindrical, elliptical, conical, etc.
It is possible to increase the efficiency when the laser is heated by putting a frame around the fuel capsule attached to the target. Just prior to the collision of the bullets from both sides with the fuel capsules on both sides, the fuel capsule in the middle can be heated with laser to bring the temperature above 1 million degrees Celsius. It can be compressed more than 100 times and cause fusion at more than 100 million degrees. In the ICF, a round capsule is laser-launched from the four sides of the sphere to raise it to more than 100 million degrees Celsius. In the present invention, however, it is possible to make the laser more than one million degrees centigrade by firing the laser around the periphery of the sphere. By heating the plasma at 1 degree Celsius and speeding up to 7 kilometers per second, the plasma volume is compressed by 100 to 200 times, increasing the temperature by 100 to 200 millions of degrees Celsius, so that more deuterium and tritium react to the fusion reaction.
Using this method, a deuterium and tritium plasma of more than 1 million degrees Celsius is compressed between a target and a high-speed bullet to increase the temperature to more than 100 million degrees Celsius, The method of claim 1, wherein
Fusion reactions can compress the plasma between the targets fired at both ends and the high-speed bullet by shooting down or dropping lead or lithium and lead in the ceiling from the ceiling. The inside of the conduit can serve as a mirror to enhance the effect of heating the plasma with the laser. It also has the effect of blocking the plasma even when colliding high-velocity bullets with lead or lithium and lead solid targets firing toward high-speed guns. Plasma more than 1 million degrees Celsius can be shot to compress between the target and the bullet in the conduit. Plasma more than 1 million degrees Celsius fired from behind a bullet can be compressed between two high-speed bullets. Two bullets of 7 km per second collide with each other for 14 km per second, compressing more than 1 million degrees centigrade plasma to more than 100 million.
Using this method, a deuterium and tritium plasma of more than 1 million degrees Celsius is compressed between a target and a high-speed bullet to increase the temperature to more than 100 million degrees Celsius, The method according to claim 2, wherein
When a deuterium and tritium plasma of 1 million degrees Celsius is maintained in a tokamak or stellar reactor fusion reactor, the plasma is compressed into the bullet when the front bullet, such as cup or cup, is fired at 7 km / sec. When two bullets collide at a speed of 14 km per second, the plasma between the two is compressed more than 100 times and the fusion reaction of deuterium and tritium occurs when it exceeds 100 million. The neutron energy is then absorbed by the lead and lithium metals in the blanket surrounding the tokamak or stellarator reactor. The hot liquid metal goes to the heat exchanger to heat the water vapor and the water vapor turns the steam turbine generator to produce electricity. A high-speed gun that fires two bullets is placed facing up or down on the tokamak or stellar reactor, or placed side-by-side. If the two bullets are less likely to collide at higher plasma densities in the reactor due to subtle differences in the launch point and velocity of the two bullets, one of the two bullets will shoot first, making them heavier and slower than the others. The shape of the tokamak or stellarator and the arrangement of the high-speed gun are shown in Fig.
Supercritical and ultra-supercritical steam turbines or supercritical carbon dioxide turbines are used to propel the turbine generators and propel the pistons of high-speed guns.
Using this method, a deuterium and tritium plasma of more than 1 million degrees Celsius is compressed between a target and a high-speed bullet to increase the temperature to more than 100 million degrees Celsius,

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