The amount of fuel required to travel to the International Space Station varies depending on the spacecraft being used, distance to the station, and other factors. Typically, a spacecraft like the SpaceX Crew Dragon uses around 20,000 kilograms of fuel to reach the ISS.
The actual amount of fuel needed to travel to the moon and back depends on the specific spacecraft and propulsion system used. However, it typically requires a significant amount of fuel due to the distance and speed required to make the journey. For example, the Apollo missions used approximately 300,000 gallons of fuel to reach the moon and return to Earth.
The spacecraft used a combination of liquid oxygen and rocket-grade kerosene as fuel for propulsion. This fuel combination provides the energy needed to propel the spacecraft into space and carry out its mission efficiently.
The Apollo 11 spacecraft used approximately 7.6 million pounds of fuel for its entire mission, including the journey to the Moon, lunar landing, and return to Earth. The Saturn V rocket that launched the spacecraft had three stages, each burning a different type of fuel to propel the spacecraft into space.
The International Space Station (ISS) does not carry fuel for propulsion itself. Its fuel needs are met by the spacecraft that dock with it, like the Russian Soyuz or Progress spacecraft, which have their own fuel reserves for maneuvering and deorbiting.
The amount of fuel required to travel to the International Space Station varies depending on the spacecraft being used, distance to the station, and other factors. Typically, a spacecraft like the SpaceX Crew Dragon uses around 20,000 kilograms of fuel to reach the ISS.
The actual amount of fuel needed to travel to the moon and back depends on the specific spacecraft and propulsion system used. However, it typically requires a significant amount of fuel due to the distance and speed required to make the journey. For example, the Apollo missions used approximately 300,000 gallons of fuel to reach the moon and return to Earth.
Without fuel, the spacecraft cannot launch.
It stores fuel.
it lifts up the spacecraft
The spacecraft used a combination of liquid oxygen and rocket-grade kerosene as fuel for propulsion. This fuel combination provides the energy needed to propel the spacecraft into space and carry out its mission efficiently.
The Apollo 11 spacecraft used approximately 7.6 million pounds of fuel for its entire mission, including the journey to the Moon, lunar landing, and return to Earth. The Saturn V rocket that launched the spacecraft had three stages, each burning a different type of fuel to propel the spacecraft into space.
A spacecraft leaving Mars would need to carry enough fuel to achieve escape velocity from the planet's gravity well. This fuel would typically be carried on board the spacecraft in the form of liquid or solid propellant, either in the main propulsion system or in auxiliary thrusters. The amount of fuel required would depend on the spacecraft's mass, the desired trajectory, and the efficiency of the propulsion system.
The International Space Station (ISS) does not carry fuel for propulsion itself. Its fuel needs are met by the spacecraft that dock with it, like the Russian Soyuz or Progress spacecraft, which have their own fuel reserves for maneuvering and deorbiting.
Spacecraft can be refueled in space through a variety of methods, such as docking with a refueling module, transferring fuel through fuel lines, or utilizing in-space refueling technologies. Some spacecraft are designed with the ability to receive fuel from a separate tanker spacecraft, which can transfer propellant to the target spacecraft to extend its mission duration or reach distant destinations.
Fuel, food, and hopefully, people.
Engineers need to keep the mass of a spacecraft as low as possible to reduce the amount of fuel required for propulsion. This allows the spacecraft to achieve higher speeds, cover longer distances, and carry more payload. Additionally, lower mass helps with launch costs and overall mission efficiency.