Original designs Lockheed's proposed craft was a small space shuttle-shaped
lifting body design big enough for six astronauts and their equipment. Its airplane-shaped design made it easier to navigate during high-speed returns to Earth than the capsule-shaped vehicles of the past, according to Lockheed Martin. According to the French daily
Le Figaro and the publication
Aviation Week and Space Technology, EADS SPACE Transportation would be in charge of the design and construction of the associated
Mission Module (MM). The head of the Lockheed team was
Cleon Lacefield. The Lockheed Martin CEV design included several modules in the LEO (
low Earth orbit) and crewed lunar versions of the spacecraft, as well as an abort system. The abort system was an escape tower like that used in the
Mercury,
Apollo,
Soyuz, and
Shenzhou craft (Gemini, along with the Space Shuttles
Enterprise and
Columbia [until
STS-4] used
ejection seats). It would be capable of an abort during any part of the ascent phase of the mission. The crew would sit in the Rescue Module (RM) during launch. According to the publication
Aviation Week and Space Technology, the RM would have an outer heat shield of
reinforced carbon-carbon and a redundant layer of felt reusable surface insulation underneath in case of RCC failure. The RM comprised the top half of the Crew Module (CM), which comprised the RM and the rest of the lifting-body structure. The CM included living space for four crew members. In an emergency the RM separates from the rest of the CM. The RM would seat up to six crew members, with two to a row, and the CM has living space and provisions for four
astronauts for 5–7 days.
Extra-Vehicular Activities (EVAs) could be conducted from the CM, which could land on land or water and could be reused 5–10 times. The mission module would be added to the bottom of the CEV for a lunar mission, and would be able to hold extra consumables and provide extra space for a mission of lunar duration. It would also provide extra power and communications capabilities, and include a docking port for the
Lunar Surface Access Module (LSAM). On the bottom of the lunar CEV stack would be the Propulsion or Trans-Earth Injection Module (TEIM) which would provide for return to the Earth from the Moon. It would probably incorporate (according to Aviation Week) 2 Pratt & Whitney RL-10 engines. Together, the RM/CM, MM, and TEIM made up the Lockheed Martin lunar stack. The original idea was to launch the CM, MM, and TEIM on three separate
Evolved Expendable Launch Vehicles (EELVs), with one component in each launch. This vehicle would need additional modules to reach lunar orbit and to land on the Moon. However, this plan was to be altered according to the CFI (Call for Improvements), described below. Unlike the well-publicized Lockheed Martin CEV design, virtually no information was publicly available on the Boeing/Northrop Grumman CEV design. However, it is instructive to note that most publicly released Boeing designs for the canceled
Orbital Space Plane (OSP) resembled the Apollo capsule. It was possible that the Boeing CEV is a capsule rather than a lifting body or plane design.
Changes to original bids Sean O'Keefe's strategy would have seen the CEV development in two distinct phases. Phase I would have involved the design of the CEV and a demonstration by the potential contractors that they could safely and affordably develop the vehicle. Phase I would have run from bid submissions in 2005 to FAST (by Sept 2008) and down-select to one contractor. Phase II would have begun after FAST and would have involved the final design and construction of the CEV. However, this schedule was unacceptably slow to Mike Griffin, and the plan was changed such that NASA will issue a "Call for Improvements" (CFI) after the release of the ESAS for Lockheed Martin and Boeing to submit Phase II proposals. NASA chose Lockheed Martin's consortium as the winning consortium on 31 August 2006. == Post Constellation ==