... Use of electric propulsion for interplanetary transit powered by a 7 MW nuclear reactor; (a Crew of 6) . 640У371 . ... That design was based on the decision to use electrical propulsion engines for the interplanetary transit. ...
... interplanetary trajectory, and over the next few months the vehicle transits to Mars ... powered electrical propulsion unit to support transit from Earth to Mars and back ...
... LP departure from the Home Port for transit to the launch site. May 29, 2003 . ... ACS departure from the Home Port for transit to the launch site. May 26, 2003 - . ... May 26, 2003 - . June 6, 2003 . LP and ACS transit to the launch site. ...
... At present, RSC Energia has developed a conceptual configuration for the interplanetary orbiter where the crew will work during the entire interplanetary transit. ...
... Sea transit of the launch platform and the assembly and command ship to the launch ... Activities during the transit phase: . Integrated rehearsal #2; . ... and the Platform itself from making the sea transit back to the Home Port on its own ...
... Start of Launch Platform transit to the launch site. March 13, 1999 . ... Start of Assembly-Command Ship transit to the launch site. March 25, 1999 . ... Completion of ship transit. First launch day at the launch site at the Equator. ...
... ACS and LP sea transit to the launch site. Activities during sea transit: . ... ACS and LP sea transit to the launch site. Activities during sea transit: . ... Post-launch operations, the start of the sea transit to the Home Port. ...
... The hangar has an air conditioning system which operates throughout the entire transit period. ... Basic perfomances . Displacement, ton: . In transit . Semi-submerged . 27400 . 46000 . ...
... interplanetary trajectory, and over the next few months the vehicle transits to Mars ... powered electrical propulsion unit to support transit from Earth to Mars and back ...