Spacecraft maneuver in space primarily by using thrusters that expel propellant in the opposite direction, following Newton's third law of motion. These thrusters can be small and used for precise adjustments or larger for significant changes in velocity and trajectory. Additionally, spacecraft can utilize gravitational assists from planets to alter their course without using much fuel. Attitude control systems, such as reaction wheels or gyroscopes, help maintain or change the spacecraft's orientation during maneuvers.
The shuttle never has and never will orbit the moon.
The manual burn in Apollo 13 lasted for about 14 seconds. It was a critical maneuver to adjust the spacecraft's trajectory and safely return the astronauts back to Earth after an oxygen tank explosion in space.
In Apollo 13, oxygen served three key functions: it was essential for breathing, providing the astronauts with the necessary air to survive; it was a component of the fuel cells that generated electricity for the spacecraft; and it played a role in the chemical reactions used for propulsion, helping to maneuver the spacecraft during its critical journey back to Earth after the explosion.
In the exosphere, a space shuttle uses thrusters to maneuver by controlling its attitude and orientation. These thrusters help adjust the spacecraft's position without relying on air or other external forces. The shuttle can change its trajectory by firing specific thrusters to push against the vacuum of space.
A spaceplane is a vehicle that can fly and glide like an aircraft in Earth's atmosphere and maneuver like a spacecraft in outer space. To do so, spaceplanes must incorporate features of both aircraft and spacecraft.
The slingshot maneuver, also known as a gravitational assist, is a spaceflight technique used to accelerate a spacecraft by using the gravity of a planet or moon. As the spacecraft approaches the celestial body, it is pulled in by its gravitational field, gaining speed as it swings around. After the flyby, the spacecraft is propelled away at a higher velocity, effectively "slingshotting" it towards its next destination. This technique can save fuel and time during long space missions.
Spacecraft maneuver in space primarily by using thrusters that expel propellant in the opposite direction, following Newton's third law of motion. These thrusters can be small and used for precise adjustments or larger for significant changes in velocity and trajectory. Additionally, spacecraft can utilize gravitational assists from planets to alter their course without using much fuel. Attitude control systems, such as reaction wheels or gyroscopes, help maintain or change the spacecraft's orientation during maneuvers.
Yes. The NASA space shuttles use hypergolic chemicals to produce thrust vectoring to steer the orbiters in space.
Gravity shield technology works by creating a field around the spacecraft that counteracts the gravitational forces in outer space. This field helps to stabilize the spacecraft and protect it from the harmful effects of gravity, allowing it to maneuver more effectively and safely in space.
RCS direction refers to the orientation in which a Reaction Control System (RCS) is used to maneuver a spacecraft. The RCS can provide thrust in various directions to control the attitude and position of the spacecraft in space. The direction of RCS thrust can be adjusted to achieve specific maneuvers such as rotation, translation, or stabilization.
Apollo 13 did make it back to planet Earth, although it had to maneuver around the moon it still made it back to Earth.
Using a carefully planned and controlled descent. By planning when to commence the descent they can predict approximately where they will be and then where they will land. Then by controlling the descent they can maneuver the spacecraft their desired destination.
The slingshot effect, also known as gravitational assist, is a maneuver used by spacecraft to gain speed by using the gravity of planets. The effects on humans would be minimal, as humans are not typically exposed to this maneuver in spaceflight. However, it can help reduce mission duration and fuel consumption for robotic missions.
the heimlich maneuver
Gravity is not a form of energy. When a spacecraft manuevers near a planet in a certain trajectory, relative to the motion of the planet, the spacecraft will be accelerated at the expense of the planet; the planet slows down ever so slightly.
That was a strange maneuver when he moved over there.