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Essay Unit 16 Astronomy and Space Science - C&D 'The final frontier' $27.30   Add to cart

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Essay Unit 16 Astronomy and Space Science - C&D 'The final frontier'

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DISTINCTION - both C &D I met all the criteria, including step-by-step calculations for both assignments, evaluation, and conclusion; for a discount, message me x. Assignment C: Investigate the essential factors involved in space flight C.P5: Explain the main factors associated with achieving...

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  • February 18, 2024
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  • 2022/2023
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‘The Final Frontier’
Assignment C: Investigate the essential factors involved in space flight

C.P5: Explain the main factors associated with achieving space flight for manned and unmanned
exploration.

Unmanned Missions:

1. Payload: Determine the purpose of the mission and the payload requirements. This includes
scientific instruments, communication equipment, cameras, or any other necessary
equipment.
2. Launch Vehicle: Select an appropriate launch vehicle capable of carrying the payload to the
desired destination. Consider factors such as payload capacity, performance, and
compatibility with the mission requirements.
3. Orbital Mechanics: Calculate the trajectory and orbital parameters required to reach the
intended destination. This involves understanding the gravitational forces, transfer orbits,
and timing to ensure accurate positioning.
4. Materials and Design: Construct the spacecraft using materials that can withstand the harsh
conditions of space, such as extreme temperatures, radiation, and vacuum. Consider the
structural integrity, thermal protection, and shielding requirements.
5. Propulsion System: Choose the appropriate propulsion system for the mission, considering
factors such as efficiency, thrust, and fuel requirements. Common options include chemical
propulsion (liquid or solid rockets) or electric propulsion (ion engines).
6. Power Systems: Determine the power requirements for the mission, considering the energy
needs of the payload and spacecraft systems. This could involve solar panels, fuel cells, or
radioisotope thermoelectric generators (RTGs) for long-duration missions.
7. Communication: Establish a reliable communication system to transmit data between the
spacecraft and Earth. This typically involves antennas, transmitters, receivers, and ground
stations. Consider bandwidth limitations, signal strength, and latency.
8. Hazards and Risk Mitigation: Identify potential hazards like micrometeoroids, space debris,
and solar radiation, and develop strategies to mitigate their impact on the spacecraft and
mission success.
9. Cost: Consider the financial implications of the mission, including launch costs, spacecraft
development, operations, and data analysis.

Manned Missions:

In addition to the aspects mentioned above, manned missions require further considerations:

1. Life Support Systems: Develop life support systems to sustain astronauts with oxygen, water,
food, and waste management. This includes environmental control (temperature, pressure),
air revitalization, and radiation protection.
2. Crew Safety: Implement measures to ensure astronaut safety during launch, in space, and
during re-entry. This involves emergency escape systems, spacesuit design, and training for
potential contingencies.
3. Human Factors: Account for human physiological and psychological effects in space, such as
microgravity-induced bone loss, muscle atrophy, and psychological stress. Design spacecraft
interiors and mission timelines to support crew health and well-being.

,Factors such as escape velocity, hazards, and costs are relevant to both manned and unmanned
missions:

 Escape Velocity: Consider the minimum velocity needed to overcome Earth's gravitational
pull and reach space. Escape velocity varies depending on the body being launched from
(e.g., Earth, Moon, or other planets) and the desired destination.
 Hazards: Assess risks associated with launch failures, re-entry, micrometeoroids, space
debris, solar flares, and other potential threats. Develop strategies to minimize risks and
protect the spacecraft and crew.
 Costs: Understand the financial implications of the mission, including launch costs,
spacecraft development, mission operations, crew training, and long-term sustainability.

Achieving space flight requires a comprehensive understanding of these aspects, careful planning,
and technological advancements in materials, fuels, and communication systems. Continuous
innovation and research in these areas are crucial for the success of space missions, whether
manned or unmanned.




In detailed explained:

When considering the launch of an object or sending humans into space, several aspects need to be
taken into account. These aspects include:

1. Materials: The materials used in spacecraft construction must be lightweight, yet strong
enough to withstand the extreme conditions of space, including high temperatures, vacuum,
and radiation. Advanced composites, metals like aluminium and titanium, and heat-resistant
materials are commonly used. Other common materials include advanced composites (such
as carbon fibre-reinforced polymers), aluminium alloys, titanium alloys, and stainless steel.
These materials provide structural integrity while minimizing the overall weight of the
spacecraft.
2. Physical Properties: Spacecraft must be able to withstand the extreme conditions of space.
They need to have a high melting point, low thermal expansion coefficients, and good
mechanical properties. Additionally, they should have low outgassing properties to prevent
contamination of sensitive instruments and optics.
3. Ceramic and Carbon-Carbon Compound Properties for Protection: Spacecraft experience
extreme temperature variations, ranging from intense heat during atmospheric reentry to
extremely cold temperatures in the vacuum of space. Ceramic materials with high thermal
resistance, such as reinforced carbon-carbon (RCC) or ablative heat shields, are used to
protect spacecraft during re-entry. These materials can withstand high temperatures and
prevent heat transfer to the spacecraft's sensitive components.
4. Power Supplies: Spacecraft require power for various systems, including communication,
propulsion, and scientific instruments. Power is typically generated through solar panels,
which convert sunlight into electricity. On some missions, such as those in deep space,
radioisotope thermoelectric generators (RTGs) may be used to convert the heat generated
by decaying radioactive material into electricity.
5. Fuels: Rockets require propellants to generate the necessary thrust to overcome Earth's
gravity and reach space. Liquid fuels like liquid oxygen and liquid hydrogen, solid propellants,
and hybrid combinations are used based on the mission requirements. Fuel cells can be used

, in spacecraft to generate electrical power. They use the chemical reaction between
hydrogen and oxygen (or other oxidizers) to produce electricity. Fuel cells offer a reliable and
efficient source of power for extended space missions
6. Escape Velocity: To reach space, objects need to achieve the escape velocity, which is the
minimum velocity required to escape Earth's gravitational pull. The escape velocity from
Earth's surface is approximately 11.2 km/s (about 25,020 mph).
7. Oxidizer: Rockets used for space travel require an oxidizer to facilitate the combustion of
propellants. Common oxidizers include liquid oxygen (LOX) and nitrogen tetroxide (N2O4).
The oxidizer combines with the fuel to provide the necessary chemical reaction for thrust
generation.
8. Hazards: Space is a hostile environment with several hazards. These include exposure to
microgravity, extreme temperatures, vacuum, radiation, and micrometeoroids. Designing
spacecraft and spacesuits to protect astronauts from these hazards is crucial.
 Heat and Cold: Spacecraft experience extreme temperature variations. They must be
designed to handle both the extreme heat of re-entry and the extreme cold of space.
 Micro-Meteorites: Spacecraft are at risk of being hit by micrometeoroids and orbital debris,
which can cause damage or puncture the spacecraft. Shielding materials and design
considerations are employed to protect against these hazards.
 Fuel Components: Proper handling and storage of fuels and oxidizers are critical to prevent
accidents and ensure safe operations. Strict protocols are followed to minimize the risk of
fuel leaks or explosions.
 Radiation: Spacecraft and astronauts are exposed to high levels of radiation in space due to
cosmic rays and solar radiation. Shielding materials and design techniques are used to
minimize the exposure and protect sensitive electronics and crew members.
9. Costs: Space missions involve substantial costs, encompassing research and development,
manufacturing, launch services, mission operations, and maintenance. The expenses are
influenced by factors like the complexity of the mission, payload mass, launch vehicle
selection, and duration of the mission.
10. Communication: Communication with spacecraft is facilitated through various systems,
including ground-based antennas, tracking networks, and satellites. Signals are transmitted
using radio waves, enabling real-time or near-real-time communication between the
spacecraft and mission control.



Case Study: Training Astronauts for Apollo Missions

During the Apollo missions, NASA faced several challenges when training astronauts for spaceflight.
Some of the key issues they encountered were:

,  Physical Conditioning: Astronauts needed to undergo extensive physical training to prepare
their bodies for the physical demands of spaceflight, including exposure to microgravity and
the high g-forces experienced during launch and re-entry.
 Lunar Landing Training: One of the primary goals of the Apollo missions was to land
astronauts on the Moon. NASA developed a Lunar Landing Training Program to simulate the
reduced gravity environment on the Moon. Astronauts practiced lunar surface activities,
such as walking, collecting samples, and driving the Lunar Roving Vehicle.
 Astronaut Health and Safety: Ensuring astronaut health and safety was crucial. NASA had to
develop rigorous medical screening procedures to select astronauts with excellent physical
and mental health. Additionally, they provided training in emergency procedures and
contingency plans to handle potential hazards during spaceflight.
 Simulators and Training Facilities: NASA developed various simulators and training facilities
to replicate the conditions astronauts would encounter during spaceflight. This included
spacecraft simulators, neutral buoyancy pools for simulating spacewalks, and centrifuges for
simulating the high g-forces during launch and re-entry.
 Teamwork and Mission Operations: Astronauts were trained extensively in teamwork,
communication, and mission operations to ensure efficient collaboration during space
missions. They learned to work effectively as a team, manage resources, and solve problems
in high-pressure situations.
 Lunar Geology and Science Training: Apollo astronauts received training in lunar geology to
effectively identify and collect samples during their missions. This training helped them
contribute to scientific research and understanding of the Moon's geological history.

By addressing these challenges and providing comprehensive training, NASA successfully prepared
astronauts for the Apollo missions, enabling them to safely and effectively accomplish their goals of
lunar exploration and scientific discovery.

C.M3: Assess the main factors and benefits associated with achieving space flight for manned and
unmanned exploration

Achieving and Sustaining Space Flight:

To achieve and sustain space flight, several factors need to be considered. Some factors include:

 Lift-off Principles: Lift-off is achieved through the principle of thrust generated by rocket
engines. Rockets expel a high-speed exhaust of gases in the opposite direction to generate
an equal and opposite force, known as Newton's third law of motion. This thrust overcomes
the force of gravity and propels the spacecraft upwards.
 Mass, Propulsion, Gimbals, and Staging: The mass of a spacecraft plays a crucial role in
determining the amount of thrust required for liftoff. Heavier spacecraft require more
powerful engines and more propellant. To control the direction of thrust, rocket engines
often employ gimbaling, which allows them to swivel and direct the exhaust. Staging
involves separating different sections of a rocket during flight to reduce mass and improve
efficiency.
 Spacesuit Design Features: Spacesuits are specially designed to protect astronauts in the
vacuum of space. They provide a life-sustaining environment with oxygen, temperature
control, pressure regulation, and radiation shielding. Spacesuits also incorporate mobility
features, such as joints and specialized gloves, to enable astronauts to work in the harsh
environment of space.

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