Air Force Space Command   Right Corner Banner
Join the Air Force

Library > Fact Sheets > Evolved Expendable Launch Vehicle

EVOLVED EXPENDABLE LAUNCH VEHICLE

Posted 11/2/2010 Printable Fact Sheet
 
Photos 
Atlas V
Expendable Launch Vehicle, known as EELV, is designed to improve our nation¡¦s access to space by making space launch vehicles more affordable and reliable. The program is replacing the existing fleet of launch systems with two families of launch vehicles, each using common components and common infrastructure. The vehicles are the Boeing Delta IV and Lockheed Martin Atlas V. EELV¡¦s operability improvements over current systems include a standard payload interface, standardized launch pads and increased off-pad processing.
Download HiRes

Mission 

Evolved Expendable Launch Vehicle, known as EELV, is designed to improve the United States' access to space by making space launch vehicles more affordable and reliable. The program replaced launch systems with two families of launch vehicles, each using common components and common infrastructure. The vehicles are the Boeing Delta IV and Lockheed Martin
Atlas V. EELV's operability improvements over current systems include a standard payload interface, standardized launch pads and increased off-pad processing.

As the Air Force's space-lift modernization program, EELV was designed to reduce launch costs by at least 25 percent over heritage Atlas, Delta and Titan space launch systems.

The U.S. Air Force Evolved Expendable Launch Vehicle will serve America's lift-to-orbit requirements with two launch vehicle families, assuring access to space for both government and military payloads.

Features 

Rocket booster system with variants

Background 

The initial phase of the EELV program, Low Cost Concept Validation (LCCV), was successfully completed in November 1996. LCCV emphasized competition in preliminary designs and risk reduction demonstrations. Four $30-million contracts were awarded during this phase to Alliant Techsystems, The Boeing Company, Lockheed Martin Corporation and McDonnell Douglas Aerospace. (Note: Boeing acquired McDonnell Douglas at about the time this competition ended.)

During the second phase, pre-engineering and manufacturing development, two $60-million, 17-month contracts were awarded to The Boeing Company and Lockheed Martin Corporation to continue refining their system concepts and complete a detailed system design.

EELV phase three began in October 1998 with the award of two development agreements and two initial launch services contracts (known as Buy 1) totaling more than $3 billion. The development agreements ran through fiscal year 2007 and the initial launch services contracts will run through FY 2012. Additional launch service awards were made in Buy 2 and proposed in Buy 3 contracts. 

Boeing Delta IV

The Delta IV family of launch vehicles is designed for optimum performance for a wide range of flight profiles, and is capable of carrying payloads ranging from 4,231 kg (9,327 lb) to 12,757 kg (28,124 lb) to geosynchronous transfer orbit (GTO). The Delta IV Medium, Medium-Plus and Heavy configurations are evolved, combining highly reliable, flight proven systems from Delta II and III, while incorporating the latest technology into a family of vehicles maximizing the use of common hardware.

Commonality between all of the systems is central to the Delta IV. Each Medium & Medium-Plus vehicle uses a single common booster core (CBC), while the Heavy uses three CBCs. The Pratt and Boeing Rocketdyne-built RS-68, a liquid hydrogen/liquid oxygen engine that produces 663,000 lbs of liftoff thrust, powers the first stage. This engine is mounted to the CBC first-stage structure and was designed for ease of manufacture by significantly reducing part count and thereby increasing reliability. Thirty percent more efficient than conventional liquid oxygen/kerosene engines, the RS-68 is environmentally friendly, producing steam as a combustion by-product. The three Delta IV Medium-Plus vehicles use a single CBC and are augmented by either two or four 1.5-meter (60-inch) diameter solid rocket strap-on graphite epoxy motors (GEMs).

The cryogenic second stage is an evolutionary design incorporating the Redundant Inertial Flight Control Assembly (RIFCA) from Delta II and the Pratt & Whitney RL10B-2 engine. The Delta IV Medium & Medium-Plus (4,2) vehicles use the same 4-meter diameter second stage, while the Delta IV Medium-Plus (5,2), Medium-Plus (5,4) and Heavy vehicles use the same RL10B-2 engine, but have larger 5-meter diameter fuel tanks and stretched oxidizer tanks.

On the Delta IV Medium & Medium-Plus (4,2), the payload is encapsulated in a 4-meter (13.1-feet) diameter payload fairing (PLF) for protection. On the Delta IV Medium-Plus (5,2), Medium-Plus (5,4) and Heavy, the payload is encapsulated with a similar 5-meter (16.7-feet) diameter payload fairing. Both the 4 and 5-meter diameter PLFs are composite bisector structures that were evolved from the Delta II 2.9 meter diameter and the Delta III 4-meter diameter PLFs. The Heavy vehicle can also employ a 5-meter diameter aluminum trisector fairing with Titan IV heritage.

United Launch has successfully launched eight Delta IV launch vehicles. Delta IV's inaugural flight was marked by the successful launch of a commercial satellite on a Medium-Plus (4,2) in November 2002. Two Air Force communication satellites were successfully launched on Delta IV Medium vehicles in 2003, and the first Heavy vehicle was launched in December 2004. 

Lockheed Martin Atlas V

The Lockheed Martin Atlas V resulted from Lockheed Martin's combination of the best practices from both the Atlas and Titan programs into an evolved commercial and government launch system for the 21st century. Atlas V builds on the design innovations demonstrated on Atlas III and incorporates a structurally stable booster propellant tank, enhanced payload fairing options and optional strap-on solid rocket boosters.

Further, all Atlas V to date were successfully launched. The Atlas V family uses a single-stage Atlas main engine, the Russian RD-180 and the newly developed Common Core Booster (CCB)TM with up to five strap-on solid rocket boosters. The CCBTM is 12.5 ft. (3.8 m) in diameter by 106.6 ft. (32.5m) long and uses 627,105 lbs. (284,453 kg) of liquid oxygen and RP-1 rocket fuel propellants.

Additionally, on Atlas V, United Launch Alliance introduced a 4.57-meter usable diameter Contraves payload fairing in addition to retaining the option to use the heritage Atlas payload fairings. The Contraves fairing is a composite design and is based on flight proven hardware. Three configurations will be manufactured to support Atlas V. The short and medium length configurations will be used on the Atlas V 500 series.

The Centaur upper stage uses a pressure stabilized propellant tank design and cryogenic propellants. The Centaur stage for Atlas V is stretched 5.5 ft (1.68 m) and is powered by either one or two Pratt & Whitney RL10A-4-2 engines, each engine developing a thrust of 22,300 lbs. (99.2 kN). Operational and reliability upgrades are enabled with the RL10A-4-2 engine configuration. The inertial navigation unit (INU) located on the Centaur provides guidance and navigation for both Atlas and Centaur, and controls both Atlas and Centaur tank pressures and propellant use. The Centaur engines are capable of multiple in-space starts, making possible insertion into low-earth parking orbit, followed by a coast period and then insertion into GTO.

General Characteristics

Primary Function: Spacelift vehicle
Primary contractor: United Launch Alliance (Boeing and Lockheed Martin)
Dimensions: vehicle dependant
Payload: satellites and space vehicles

(Current as of November 2010)




Point of Contact: Air Force Space Command, Public Affairs Office; 150 Vandenberg St., Suite 1105; Peterson AFB, CO 80914-4500; DSN 692-3731, or (719) 554-3731.





 Inside AFSPC

ima cornerSearch

 




Site Map      Contact Us     Questions     USA.gov     Security and Privacy notice     E-publishing  
Suicide Prevention    SAPR   IG   EEO   Accessibility/Section 508   No FEAR Act