Early studies looked at alternate booster and external tank configurations such as: • SRM options that placed the SRBs inline but aft of the external tank (ET) • Liquid rocket boosters, both hydrogen and propane to replace the SRBs • Twin and catamaran flyback boosters to replace the SRBs • An engine pod aft of the ET fed from twin fuel tanks where the SRBs would normally be located • An in-line integrated booster/ET with a recoverable aft-engine pod • Tandem boosters and ETs in a variety of recoverable concepts • A single booster with multiple ETs (expendable and recoverable)
Advanced Solid Rocket Motor (ASRM) Project NASA had planned on replacing the post-
Challenger SRBs with a new Advanced Solid Rocket Motor (ASRM) to be built by
Aerojet. They would have been built at a new facility designed by a subcontractor, RUST International, on the location of a canceled
Tennessee Valley Authority nuclear power plant in Yellow Creek, Mississippi. The ASRM would have produced additional thrust in order to increase the shuttle payload to carry modules and construction components to the ISS. The ASRM program was canceled in 1993, after robotic assembly systems and computers were on-site and approximately 2 billion dollars spent, after NASA opted to instead issue minor corrections to the existing SRBs.
Recoverable Liquid Booster A large focus of the NASA/
MSFC Shuttle Growth Study contract was upgraded Recoverable Liquid Boosters. The boosters would have a similar flight path to the solid rocket motors, separating and deploying a parachute for recovery in the Atlantic Ocean. They were to be water-recoverable and used clamshell doors to protect the engines from saltwater immersion.
Liquid Fly-back Booster Liquid Flyback Booster concepts date back to the early 1970s. Original Shuttle boosters were massive piloted fly-back boosters. The concept was studied throughout the 1980s but shelved after the
Challenger disaster shut down most Shuttle upgrades. The Flyback booster concept reemerged in 1997 during the NASA Liquid Flyback Booster Study. The concept was abandoned due to the increased complexity and minor returns. The Shuttle Growth Study built on this background by developing design concepts in great detail for the liquid rocket boosters. launch vehicle would have used a Five-Segment SRB
Five-Segment Booster Prior to the destruction of the in 2003, NASA investigated the replacement of the current 4-segment SRBs with either a 5-segment SRB design or replacing them altogether with liquid "flyback" boosters using either
Atlas V or
Delta IV EELV technologies. The 5-segment SRB, which would have required little change to the current shuttle infrastructure, would have allowed the space shuttle to carry an additional of payload in a 51.6°-inclination orbit, eliminate the dangerous
"Return-to-Launch Site" (RTLS) and "Trans-Oceanic Abort" (TAL) modes, and, by using a so-called "dog-leg maneuver", fly south-to-north polar orbiting flights from Kennedy Space Center. After the destruction of
Columbia, NASA shelved the five-segment SRB for the Shuttle Program, and the three surviving Orbiters,
Discovery,
Atlantis, and
Endeavour were retired in 2011 after the completion of the
International Space Station. One five-segment engineering test motor, ETM-03, was fired on October 23, 2003. As part of the Constellation program, the first stage of the
Ares I rocket was planned to use five-segment SRBs – in September 2009 a five-segment Space Shuttle SRB was static fired on the ground in ATK's desert testing area in Utah. After the Constellation program was canceled in 2011, the new
Space Launch System (SLS) was designated to use five-segment boosters. The first test of an SRB for SLS was completed in early 2015, and a second test was performed in mid-2016 at Orbital ATK's Promontory, Utah facility. == External Tank Cargo Fairing ==