The Delta-class 1st Stage Booster was the Imperial Space Administration's first design at a reusable booster system to deploy satellites and other equipment into Low Earth Orbit. The big test was to build the Orbital Science Space Station. After a total number of 13 launches utilizing 7 of the Delta-class Boosters, it took 1 Month and 8 Days for the Station to be completed. After then, the system was also used to launch a multitude of Satellites for Shazbotdom News Corporation and to launch a large grouping of CubeSats for a Univesrity from an Allied nation. As of now, the booster's main process is to launch Resupply and Crewed Missions to the Orbital Science Space Station and the occasional launching of sections to the new Orbital Transfer Station.

The Second Stage Gamma-class Booster is the secondary boosting mechanism for the Low to Mid-Orbit Launch System. It's purpose is to give the push of launches to get equipment up to an orbital height of ~110km.

The Epsilon-class Orbit was designed as the primary booster system for the 3rd Generation Space Capsule. Its purpose is to push the capsule into its final orbital trajectory to complete docking procedures with the Orbital Research Space Station. It is also the primary mode of transporation to return the Space Capsule back to Earth. Utilizing the engines to decelerate from orbit, it has landing legs, RCS Thrusters, and a parachute to assist in landing operations to bring anywhere from 3 to 6 Astronauts to the space staiton and back to Earth.

The updated Epsilon-class v2 Orbiter is completed and is now paired with the 4th Generation Capsule, where the docking ring is moved from sides of the orbiter to the top of the cone and the parachute is integrated into the body of the capsule and moved off of the nose cone. There is also the addition of a Launch Abort System (LAS) onto the top of the capsule, which will be utilized in case there is a catastrophic system failure. This system will eject and catapult the Capsule away from the rest of the Full Stack, where it will be able to successfully land to keep the astronauts safe.

The high tech Capsules of the Imperial Space Administration are nearly 100% automated in terms of it's orbital capabilities. With most information shown on touch-screen displays within arms reach of the seats. There is a manual joystick behind a door underneith the center display. This joystick is just in case that there is an issue with the onboard computer and it is needed to manually dock or undock with the Space Station. While it does not have any RCS thrusters of it's own, it does have smaller cold-gas thrusters that give it the ability to roll and pitches so that the heat shield is always pointed towards the right direction so that it doesn't burn up upon re-entry.

The Capsule's heat shield is designed so that the Capsule and Heat Shield have a hatch at the bottom that is automated and can create a airtight seal to ensure that no damage occurs to the underside of the Capsule. This design is to ensure that if something occurs with whatever vehicle is transporting the Capsule to orbit (i.e. the Epsilon-class Orbiter that is used to transport to the Research Space Station) can be detached so that the Capsule can return to earth with minimal to no issues, losing only the Service Module that makes up the Orbiter. The Capsule has the ability to deliver 1 Pilot, 2 Service Crew, and 4 Passengers to orbit with each launch.

The Updated 4th Generation Space Capsule has been slated with enhanced biometrics. This system encodes the Capsule's system to the crew that is assigned to the mission. The capsule also has an enhanced air filtration system and cooling system to ensure the comfort of the astronauts onboard. Each suit is integrated into the filtration and cooling system via three tubes that attach to the right side of each chair. Each suit is perfectly tailored to the specific astronaut to ensure comfort. There is a mobile computer panel that attaches to either wrist of the suit that is utilized as a control panel to adjust the airflow and temperature for the individual's suit.

The main workhorse of the Cargo Transportation Fleet for the Orbital Science Space Station, the Omega-class specialty cargo transporters are designed to connect with the lowest docking segments of the Space Station so that Scientists can unload any and all equipment and new Research Projects onto the station as quickly as possible, utilizing the large docking ports at the top end of the transport ship. The vehicle is also designed to the point that it can bring up new equipment to replace old, outdated, and/or broken computer equipment.

These Cargo Transporters are designed to have a total lifespan of 25 years before they need to be replaced. As of right now, the Imperial Space Administration has plans for at least two replacements for the Omega-class, with production of the prototypes of these two replacements. There is no official word of when these prototypes will be finished, they are being designed by two different private corporation teams. Imperial Space Expeditions Incorporated has the contract for one of the Prototypes while The Imperial Scientific University at Fairbanks is holds the contract for the second of the Prototypes.

The Upsilon-class 1st stage of a Medium Lift Rocket is an essential component of any space mission. It is responsible for propelling the rocket off the ground and achieving the necessary velocity for orbit insertion. The rocket design presented here, developed by the Shazbotdom Imperial Space Administration (SISA), incorporates state-of-the-art technologies and innovative designs to maximize performance and reliability.

The 1st stage of the Shazbotdom Imperial Space Administration's Medium Lift Rocket consists of a liquid-fueled propulsion system. The rocket uses a combination of Liquid Oxygen (LOX) and Liquid Methane (CH4) as a propellant, giving the vehicle a high specific impulse and superior thrust-to-weight ratio. The propellant is stored in high-pressure tanks, which are housed in the rocket's lower section. The propulsion system of the 1st stage consists of a single engine, which is powered by a combination of Liquid Oxygen (LOX) and Liquid Methane (CH4). The combustion chamber of the engine is fed by propellant through injectors, which produce the thrust required for liftoff. The engine is equipped with an advanced turbopump system that efficiently transfers propellant from the storage tanks to the combustion chamber.

The 1st stage engine of the Shazbotdom Imperial Space Administration's Medium Lift rocket is designed to provide a maximum thrust of 200,000 Newtons (N). This level of thrust is necessary to overcome the gravitational pull of the Earth and achieve the required velocity for orbit insertion. The engine's performance is characterized by its specific impulse, which measures the efficiency with which propellant is converted into thrust. The Shazbotdom Imperial Space Administration's engine has a specific impulse of 450 seconds, which is well above the industry average.

Specifications

Class: Spacecraft, Reusable

Craft Diameter: 21.75’

Core:

Main Core Height: 134.85’

Full Load Weight: 850 Tons

Engines: 5 x Bird of Prey-class v1 Engine

Engine Weight: 7 Tons

Engine Thrust: 230 Tons

Fueling Systems

Fuel: Liquid Methane (CH4)

Oxidizer: Liquid Oxygen (LOx)

The Phi-class second stage of a Medium Lift Rocket, designed in the Shazbotdom Imperial Space Administration, is a crucial component that ensures the efficient and reliable transport of payloads into orbit around the Earth. This stage is responsible for boosting the rocket's velocity to a high enough level to overcome Earth's gravitational pull and break free from its atmosphere. This section of the document will provide an overview of the design considerations, technical specifications, and capabilities of the second stage of the Shazbotdom Imperial Space Administration's Medium Lift Rocket.

The second stage propulsion system of the Medium Lift Rocket is designed to propel the rocket and its payload beyond the Earth's atmosphere. This stage utilizes a liquid-fueled propulsion system, consisting of Liquid Oxygen (LOX) and Liquid Methane (CH4). The choice of these propellants allows for high specific impulse (Isp), which is crucial for achieving efficient propulsion during the ascent phase. Additionally, the use of liquid propellants allows for precise control of the rocket's trajectory and allows for multiple burns during the flight.

The second stage structure of the Medium Lift Rocket is designed to withstand the extreme forces and vibrations experienced during the launch and flight. The structure consists of a lightweight yet robust framework, which houses the propulsion system and other critical components. The structure is designed to optimize weight distribution and minimize the mass fraction, ensuring optimal performance and cost-effectiveness.

Maintaining the appropriate operating temperature of the second stage propulsion system is essential for its proper functioning. The Shazbotdom Imperial Space Administration has incorporated advanced thermal management systems into the second stage design. These systems include insulation materials, cooling channels, and temperature control systems to maintain the appropriate operating temperatures throughout the flight. By effectively managing the heat generated during the rocket's ascent, the Shazbotdom Imperial Space Administration ensures reliable performance and reduces the risk of thermal-related failures.

To ensure accurate guidance and navigation during the second stage flight, the Shazbotdom Imperial Space Administration has implemented advanced guidance and navigation technologies. These systems utilize a combination of inertial measurement units (IMUs), Global Positioning System (GPS) receivers, and star trackers to provide precise information about the rocket's position, velocity, and attitude. This enables the rocket to be maneuvered accurately along its predefined trajectory and enables communication with the ground control station.

Specifications

Class: Spacecraft, Reusable

Craft Diameter: 17.5’

Core:

Main Core Height: 90.15’

Full Load Weight: 330 Tons

Engines: 3 x Wizzard-class Engine

Engine Weight: 3 Tons

Engine Thrust: 45 Tons

Fueling Systems

Fuel: Liquid Methane (CH4)

Oxidizer: Liquid Oxygen (LOX)

The Shazbotdom Imperial Space Administration, after a large contract that was to launch multiple sattelites into Heliocentric Orbit, began the design of what was to become the HLS. This Launch System is designed so that the Empire can launch satellites and other payloads into High Earth Orbit and out of Earth's Orbit. As of right now, there are 2 Stages, with the Second Stage currently having 4 different types in operation while a 5th and 6th are in planning/testing phases.

The First Stage Zeta-class Booster is the main Heavy Lift vehicle for the new Heavy Launch System. The Version 1 (v1.1) configuration is the version utilized for Active Missions while the Version 2 (v2.1) is the version that has been built by the Engine Propulsion Laboratory and is designed to be hot swappable and will only be utilized for SubOrbital Testing of new engine deigns.

The Operational/Active Mission (v1.0) Boosters have undergone retrofitting and modification as of late February to Early March, 2024 in preparation for the Retirement of the Lambda-class Stage 1 Side Boosters. They have been re-christened as v1.1 Boosters. The Test Mission (v2.0) have undergone the same modifications and have ben re-christened as the v2.1 Boosters.

The Second Stage Block 1 Alpha-class Booster is specifically designed to deliver deliver multiple smaller Satellites into Low Earth or High Earth Orbit and return to Earth with little to no effort. The system has been setup to either deliver 4 or 6 Satellites, but can, with alterations, deliver up to 8 Satellites. This system has, to the point, only been utilized to deploy Satellites for Shazbotdom News Corporation.

Future plans for this booster include the creation of a communication system for any future Lunar missions and for the inevitable creation of the Lunar Colonial Posession. To ensure that no matter what direction the moon is pointing, the Lunar Colony will continue to have communications capabilities with the Imperial Space Administration. Plans for this communication system between Earth and Luna are still in the preliminary phase, but these plans are progressing quickly.

The Second Stage Block 2 Omicron-class Booster is specifically designed to deliver deliver Large satellites or other large payloads into High Earth Orbit and return to Earth with little to no effort. The boosters nose cone fairing system has changed over the course of the last 6 months since the system went operational, this is to ensure less drag on ascent into orbit, ensuring that any cargo inside of the Fairing does not overheat and get damaged beyond repair. This new fairing is being utilized on the Stage 2 Block 3 Booster as well.

This Booster's main purpose, for the time being, is to continue to support the creation of the Large Orbital Space Station. It is set to deliver larger parts to the space station as the contruction of the station continues into the future. Other missions that it would be applicable for will be for the deployment of larger scientific satellites for foreign entities as well as larger communication satellites for private enterprises.

The Second Stage Block 3 Theta-class Booster is specifically designed to deliver deliver Large Satellites or other Large Payloads into Heliocentric Orbit and return to Earth with little to no effort. The SSB Block 3 was specifically designed after the signing of the contract with the PATHOS Foundation for the launch of their 81 Sattelites.

The 2nd Stage Block 4 Kappa-class Booster is the Human Transport System variant of the HLS 2nd Stage Boosters. It's design is for the transportation of up to 100 civilians for the colonization of the solar system. This stage will be utilized in conjuction with the High Altitude Transfer Station, which will have a section dedicated to the manufacture of fuel for the missions. It's first successful mission was completed on the 8th of November, 2023 when it successfully landed after delivering the first set of Colonists to the Lunar Orbit Transfer Station, where they transitioned to the Lunar Lander to be brought to their final destination at the Sea of Tranquility Colony.

The 2nd Stage Block 5 Iota-class Booster is planned to be the intra-planetary Refueling system for the Second Stage Block 4 Booster. This booster system is to be placed at strategic points that are to be determined to ensure that the Second Stage Block 4 Booster will be able to make the full trip from Earth to all points in the solar system, ensuring that Humanity can reach the distant worlds of our solar system for human colonization.

This is the 2nd Stage Block 6 Rho-class Booster that is responsible for delivering the Rover system. The main purpose of the mission is to deliver unmanned rovers to the Lunar surface of both Luna as well as the varied Moons that make up our Solar System, so that we may begin to understand and learn more about these celestial bodies that surrounds us.

To date, there have been a total of 10 of these boosters completed so far, but there is a possibility of more being added in the near future. It should be noted that on 12th of January, 2023, Rho-1 had its first SubOrbital test flight, and it was successful in all segments of the SubOrbital test flight, earning high marks on all segments.

The Lunar Colonist Lander is a crucial component of space exploration and colonization efforts on the Moon. Designed by the Shazbotdom Imperial Space Administration to transport humans and supplies from the Lunar Orbit Transfer Station to the Moon's surface, this advanced spacecraft plays a critical role in establishing a sustainable human presence beyond Earth.

The Lunar Colonist Lander is equipped with state-of-the-art technology, ensuring a safe and reliable landing on the Moon's surface. Its primary objective is to provide a means for astronauts to safely descend to the lunar surface, while also ensuring a smooth ascent back to lunar orbit for return to Earth.

One of the key features of the Lunar Colonist Lander is its precision landing capability. By utilizing advanced navigation systems and sensors, it can autonomously identify a suitable landing site and make adjustments during the descent to ensure a soft touchdown. This precision landing capability minimizes the risk of damage to the spacecraft and ensures the safety of the crew and cargo.

The Lunar Colonist Lander is also equipped with a robust life support system, which ensures the crew's survival in the harsh lunar environment. It provides a controlled atmosphere, regulates temperature and humidity, and removes carbon dioxide and other contaminants from the air. These life support systems are vital to sustaining human life during extended stays on the Moon.

The Martian/Venusian Astronaut Lander, designed and built by the Imperial Space Administration of Shazbotdom, is a technological feat that represents the pinnacle of human engineering. Equipped with six vacuum engines and six sea-level engines, this cutting-edge spacecraft is specifically designed to overcome the challenges of landing on the Martian and Venusian surfaces to facilitate exploration, research, and colonization missions on these two celestial bodies.

The Martian/Venusian Astronaut Lander's design is a result of meticulous planning and innovation. The Imperial Space Administration of Shazbotdom developed this spacecraft with a primary focus on safety, efficiency, and adaptability. The integration of six vacuum engines and six sea-level engines ensures optimal performance in both the vacuum conditions of space and the dense atmospheres of Mars and Venus.

The six vacuum engines, designed to operate in the absence of air, are powered by a combination of liquid oxygen and liquid methane propellant. These engines allow precise control and maneuverability during the initial stages of the spacecraft's descent and ascent. The vacuum engines work in conjunction with the six sea-level engines, which employ a different propellant mixture to operate efficiently within Mars' atmospheric conditions.

The Martian/Venusian Astronaut Lander's functionality and capabilities are a testament to the Imperial Space Administration's technical prowess. The spacecraft's propulsion system, consisting of twelve engines, allows for a controlled descent onto the Martian surface, ensuring a soft touchdown with minimal disruption to the environment.

The Imperial Space Administration of the Shazbotdom Empire has developed a modified lunar lander that serves the crucial purpose of transporting crops on the Lunar, Martian, and Venusian Surfaces. This innovative design incorporates a docking port at the bottom, which provides protection against the vacuum of space and harsh environment of Mars and Venus by docking with a specialty docking port on each Lunar, Martian, and Venusian colony.

The primary objective of this modified lander is to ensure the safe and efficient transportation of crops from the Hydroponics Farm Colonies to the Populated Colonies. The docking port, strategically placed at the bottom of the lander, serves as a secure entry point for crops at the end of the journey.

By having the docking port at the bottom, the lunar lander can minimize the risk of exposure to the vacuum of space and Atmosphere of Venus and Mars, which could potentially damage or compromise the crops. The docking port is equipped with advanced sealing technology and reinforced materials, providing an airtight seal and shielding the crops from the harsh conditions of space.

Additionally, the modified lunar lander utilizes state-of-the-art navigation systems and propulsion mechanisms to ensure precise landing and takeoff capabilities. These advancements, coupled with the docking port's protective features, guarantee a safe and reliable transportation process for the crops.

The Shazbotdom Imperial Space Administration's Celestial Body Research Division authorized the creation of a type of Rover that can be launched and landed on celestial bodies outside of Earth's Atmosphere. It was with this that the contract for the design was awarded to the Aerospace Department at New Hawthorne Technical University. Ph.D students as well as several Adjunct and Tenured Processors worked for 2 years to create the design for the rover and the original design was finalized in November of 2020.

Over the course of the next year and a half, a prototype was built from the ground up and delivered to the Celestial Body Research Division Offices at the Shazbotdom Imperial Space Administration Main Office Compound in the City of Joliet. It was put through intensive testing until the prototype rover was approved in December of 2022.

With the building of the rover, a delivery system was built for Terrestrial landings, such as Mars and Venus, via the launch of a Stage 2 Block 3 Theta-class Booster that can be quickly modified for such launches and the Stage 2 Block 6 Rho-class Booster to land on non-Terrestrial bodies such as Moons.

The 4534-class Launch System first originated within the Shazbotdom Empire during the mid 1980s, during the birth of its Space Exploration. Utilizing technology that would have been considered State of the Art at the time, the 4534-class Launch System was used to launch a multitude of Satellites into Earth Orbit and was instrumental in the deployment of both Imperial Lab 1 and Imperial Lab 2, the first two Orbital Laboratories from the Shazbotdom Empire.

During the early 1990s, it continued to be utilized for supplementing satellite deployments for the Empire until it was discontinued in 1993 after the controlled deorbit of Imperial Lab 2. In 2011, it was brought back into service for limited mission capabilities for several years, until 2018 when its operations ceased after the initiation of the Space Modernization Program, by Parliamentary Decree.

Since 2018, several attempts were made to revive the program for low earth orbit launches of small satellites for foreign corporations, but that idea was scrapped after the design of the Delta-class and Gamma-class Rockets.

Specifications

Class: Spacecraft, Single-Use

Vehicle Diameter: 10.5’

1st Stage Booster:

1st Stage Height: 145’

Full Load Weight: 80 Tons

1st Stage Engine: 2 x Wizard-class Engine

Engine Weight: 3 Tons each

Engine Thrust: 47 Tons each

2nd Stage Booster:

2nd Stage Height: 75’

Load Weight w/out Payload: 36 Tons

2nd Stage Engine: 2 x Kelabri-class Engines

Engine Weight: 0.5 Tons each

Engine Thrust: 16 Tons each

2nd Stage Payloads

Load Weight w/ Capsule: 41 Tons

Load Weight w/ Satellite: 50-60 Tons

Fueling Systems

Fuel: Refined Kerosene (RP-1)

Oxidizer: Liquid Oxygen (LOx)

Rickson-class Shuttle System

About

ISA Shuttle

Specifications

Fueling Systems

Fuel: Refined Kerosene (RP-1)

Oxidizer: Liquid Oxygen (LOx)

Low Lift 3rd Stage Booster

Low-Lift 3rd Stage Booster
Sigma-class v1

Specifications

Class: Spacecraft, Reusable

Each Segment Diameter: 10.5’

Core:

Main Core Height: 31.5’

Full Load Weight: 55 Tons

Engines: 2 x Wizard-class Engine

Engine Weight: 3 Tons each

Engine Thrust: 47 Tons each

Fueling Systems

Fuel: Refined Kerosene (RP-1)

Oxidizer: Liquid Oxygen (LOx)

Heavy Lift Stage 1 Side Boosters

Side Boosters
Lambda-class

Specifications

Class: Spacecraft, Reusable

Craft Diameter: 10.5’

Core:

Main Core Height: 94.5’

Full Load Weight: 45 Tons

Engines: 2 x Wizzard-class Engine

Engine Weight: 3 Tons each

Engine Thrust: 47 Tons each

Fueling Systems

Fuel: Liquid Methane (CH4)

Oxidizer: Liquid Oxygen (LOx)