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- Story Listed as: Fiction For Teens
- Theme: Science Fiction
- Subject: Science / Science Fiction
- Published: 06/10/2024
my space shuttle space gun 76
Born 2007, M, from New york, United StatesVirgin Galactic's suborbital flight begins with the takeoff of the WK2 carrier aircraft. At an altitude of about 14 kilometers, SS2 separates from it. For a few seconds it falls freely, simultaneously raising its nose upward, and then turns on its own engine and begins an almost vertical climb. The launch of the rocket plane can be observed by passengers of the carrier aircraft, for example, friends or relatives of space tourists.
The fuel runs out in about 90 seconds. At this point, the ship is gaining an altitude of about 50 kilometers and a speed of 4200 km/h. Then the rise continues by inertia. A couple of minutes later, having reached an altitude of 110 kilometers, the ship begins to fall, gradually accelerating. During this ballistic flight, a state of weightlessness sets in, which lasts approximately 4 minutes (advertising materials say 6 minutes, but for this you would have to rise to at least 200 kilometers). Passengers can unbuckle from their seats, float around the ship's spacious cabin and admire views of the Earth from numerous windows scattered throughout the fuselage. The pilots will then ask them to return to their seats in the anti-g seats. 40 seconds are allotted for this. But in case someone doesn't have time to sit down, the floor of the cabin is made of soft material. This allows, albeit not too comfortably, to survive the descent, during which the overloads for a short time can reach a very significant value - 6-7g. To evaluate them, imagine that six people of equal weight to you were put on top of you.
At the top point of the trajectory, special pneumatic actuators raise the tail booms of the rocket plane along with the wing at an angle of approximately 65°. With this configuration, reentry is carried out in an aerodynamically stable position that does not require pilot intervention. At an altitude of 20-25 kilometers, when the speed of the rocket plane drops, its wings and tail return to their original position, and SS2 carries out a gliding descent to the landing site at the airfield.
A spacecraft with a plasma detonation engine and a space sail has the following structure:
1. The spacecraft body is made of lightweight but durable materials to ensure minimal weight and maximum protection from external influences.
2. The plasma detonation engine is located at the rear of the ship and provides thrust by accelerating the release of high-energy plasma.
3. The space sail is attached to special masts or structures located around the ship. The sail uses solar wind or a laser beam to accelerate the ship through space.
4. The ship also has a life support system, as well as navigation and communication systems for communication with the Earth and other space objects.
5. The ship can be equipped with weapons for self-defense from hostile spacecraft or asteroids.
6. The ship's crew is in special cabins with protection from radiation and other dangers of space.
Thus, the plasma detonation engine and space sail spacecraft combines advanced technologies to achieve maximum speed and efficiency in space travel.
Using a space sail of engines that help go into hyperspace requires a complex maneuvering scheme on the spacecraft.
First, the spacecraft must be equipped with special engines capable of generating enough energy to create the necessary thrust to maneuver the space sail.
The ship must then adjust its engines to a specific angle relative to the plane of the sail to provide the desired rotation around the sail. Motors must be installed to ensure smooth and stable rotation.
In addition, the ship must have a stabilization system to prevent loss of control during rotation. Stabilization systems may include gyroscopes, computer automatic control systems and other devices.
Finally, to go into hyperspace, the ship must accurately calculate and time its trajectory and use its engines to generate enough speed to enter hyperspace.
Overall, rotating around a space sail using thrusters to help it enter hyperspace requires precise coordination and control by the ship's crew, as well as complex technical solutions to ensure safety and successful completion of the mission.
A plasma detonation propulsion (PDA) spacecraft is a specially designed spacecraft equipped with a thruster that uses a combination of plasma and detonation processes to generate thrust and propulsion in outer space.
The structure of such a ship includes the following main components:
1. Ship hull: Typically made of lightweight and strong materials such as carbon composites or titanium alloys to provide the necessary strength and resistance to space conditions.
2. Plasmadynamic Accelerator: This is a device that creates and heats plasma to high temperatures and pressures using electrical discharge or other methods. The resulting plasma is used to create thrust and accelerate the ship.
3. Detonation Engine: This is a device that uses a combination of plasma and detonation processes to generate thrust and propel the ship. The detonation process makes it possible to increase engine efficiency and provide higher speeds.
4. Fuel tanks: contain a flammable substance that is used to generate plasma and create thrust in the engine. Typically, special fuel mixtures or gases are used, such as hydrogen, helium or deuterium.
5. Control system: includes various sensors, computers and software that monitor engine operation, regulate fuel and plasma flows, and provide navigation and safe control of the ship.
These are the main components and structure of a plasma detonation propulsion spacecraft that enables efficient and rapid propulsion in outer space.
Hypersonic space jump using plasma detonation propulsion is a process in which a spacecraft achieves supersonic speeds by using high-temperature plasma as fuel.
The operation diagram of a plasma detonation engine is as follows:
1. The initial stage is the activation of the plasma reactor. To do this, it is necessary to create conditions for the formation of plasma, for example, by applying a high-frequency electric current.
2. Acceleration phase - as a result of the reaction in the plasma reactor, high-temperature plasma is formed, which is accelerated in a special engine nozzle system.
3. Detonation phase - upon reaching a certain speed, the plasma undergoes detonation, which leads to additional acceleration of the spacecraft.
4. Hypersonic jump - as a result of plasma detonation, the spacecraft reaches supersonic speeds, breaking the sound barrier.
Thus, the plasma detonation engine makes it possible to provide powerful acceleration of the spacecraft and achieve hypersonic speeds in space.
my space shuttle space gun 76(Jay jordan)
Virgin Galactic's suborbital flight begins with the takeoff of the WK2 carrier aircraft. At an altitude of about 14 kilometers, SS2 separates from it. For a few seconds it falls freely, simultaneously raising its nose upward, and then turns on its own engine and begins an almost vertical climb. The launch of the rocket plane can be observed by passengers of the carrier aircraft, for example, friends or relatives of space tourists.
The fuel runs out in about 90 seconds. At this point, the ship is gaining an altitude of about 50 kilometers and a speed of 4200 km/h. Then the rise continues by inertia. A couple of minutes later, having reached an altitude of 110 kilometers, the ship begins to fall, gradually accelerating. During this ballistic flight, a state of weightlessness sets in, which lasts approximately 4 minutes (advertising materials say 6 minutes, but for this you would have to rise to at least 200 kilometers). Passengers can unbuckle from their seats, float around the ship's spacious cabin and admire views of the Earth from numerous windows scattered throughout the fuselage. The pilots will then ask them to return to their seats in the anti-g seats. 40 seconds are allotted for this. But in case someone doesn't have time to sit down, the floor of the cabin is made of soft material. This allows, albeit not too comfortably, to survive the descent, during which the overloads for a short time can reach a very significant value - 6-7g. To evaluate them, imagine that six people of equal weight to you were put on top of you.
At the top point of the trajectory, special pneumatic actuators raise the tail booms of the rocket plane along with the wing at an angle of approximately 65°. With this configuration, reentry is carried out in an aerodynamically stable position that does not require pilot intervention. At an altitude of 20-25 kilometers, when the speed of the rocket plane drops, its wings and tail return to their original position, and SS2 carries out a gliding descent to the landing site at the airfield.
A spacecraft with a plasma detonation engine and a space sail has the following structure:
1. The spacecraft body is made of lightweight but durable materials to ensure minimal weight and maximum protection from external influences.
2. The plasma detonation engine is located at the rear of the ship and provides thrust by accelerating the release of high-energy plasma.
3. The space sail is attached to special masts or structures located around the ship. The sail uses solar wind or a laser beam to accelerate the ship through space.
4. The ship also has a life support system, as well as navigation and communication systems for communication with the Earth and other space objects.
5. The ship can be equipped with weapons for self-defense from hostile spacecraft or asteroids.
6. The ship's crew is in special cabins with protection from radiation and other dangers of space.
Thus, the plasma detonation engine and space sail spacecraft combines advanced technologies to achieve maximum speed and efficiency in space travel.
Using a space sail of engines that help go into hyperspace requires a complex maneuvering scheme on the spacecraft.
First, the spacecraft must be equipped with special engines capable of generating enough energy to create the necessary thrust to maneuver the space sail.
The ship must then adjust its engines to a specific angle relative to the plane of the sail to provide the desired rotation around the sail. Motors must be installed to ensure smooth and stable rotation.
In addition, the ship must have a stabilization system to prevent loss of control during rotation. Stabilization systems may include gyroscopes, computer automatic control systems and other devices.
Finally, to go into hyperspace, the ship must accurately calculate and time its trajectory and use its engines to generate enough speed to enter hyperspace.
Overall, rotating around a space sail using thrusters to help it enter hyperspace requires precise coordination and control by the ship's crew, as well as complex technical solutions to ensure safety and successful completion of the mission.
A plasma detonation propulsion (PDA) spacecraft is a specially designed spacecraft equipped with a thruster that uses a combination of plasma and detonation processes to generate thrust and propulsion in outer space.
The structure of such a ship includes the following main components:
1. Ship hull: Typically made of lightweight and strong materials such as carbon composites or titanium alloys to provide the necessary strength and resistance to space conditions.
2. Plasmadynamic Accelerator: This is a device that creates and heats plasma to high temperatures and pressures using electrical discharge or other methods. The resulting plasma is used to create thrust and accelerate the ship.
3. Detonation Engine: This is a device that uses a combination of plasma and detonation processes to generate thrust and propel the ship. The detonation process makes it possible to increase engine efficiency and provide higher speeds.
4. Fuel tanks: contain a flammable substance that is used to generate plasma and create thrust in the engine. Typically, special fuel mixtures or gases are used, such as hydrogen, helium or deuterium.
5. Control system: includes various sensors, computers and software that monitor engine operation, regulate fuel and plasma flows, and provide navigation and safe control of the ship.
These are the main components and structure of a plasma detonation propulsion spacecraft that enables efficient and rapid propulsion in outer space.
Hypersonic space jump using plasma detonation propulsion is a process in which a spacecraft achieves supersonic speeds by using high-temperature plasma as fuel.
The operation diagram of a plasma detonation engine is as follows:
1. The initial stage is the activation of the plasma reactor. To do this, it is necessary to create conditions for the formation of plasma, for example, by applying a high-frequency electric current.
2. Acceleration phase - as a result of the reaction in the plasma reactor, high-temperature plasma is formed, which is accelerated in a special engine nozzle system.
3. Detonation phase - upon reaching a certain speed, the plasma undergoes detonation, which leads to additional acceleration of the spacecraft.
4. Hypersonic jump - as a result of plasma detonation, the spacecraft reaches supersonic speeds, breaking the sound barrier.
Thus, the plasma detonation engine makes it possible to provide powerful acceleration of the spacecraft and achieve hypersonic speeds in space.
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