Silverstein Committee
Encyclopedia
The Saturn Vehicle Evaluation Committee, better known as the Silverstein Committee, was a US government commission assembled in 1959 to recommend specific directions that NASA
could take with the Saturn program
. The committee was chaired by Abe Silverstein
, a long-time NASA engineer, with the express intent of selecting upper stages for the Saturn after a disagreement broke out between the Air Force and Army over its development. During the meetings the Committee members outlined a number of different potential designs, including the low-risk solution von Braun was developing with existing ICBM airframes, as well as versions using entirely new upper stages developed to take full advantage of the booster stage. The advantages of using new uppers were so great that the committee won over an initially skeptical von Braun, and the future of the Saturn program changed forever.
The Air Force was in the midst of their Dyna-Soar project, and were designing a new booster to launch it under their "SLV-4" requirement. Their primary answer to this requirement was a Titan II missile equipped with a new hydrogen-burning upper stage, the Titan C. The resulting design had a somewhat bulbous appearance; as the hydrogen fuel required large tanks, the upper stage was 160 inches (4,064 mm) in diameter, compared to the 120 inches (3,048 mm) of the Titan II. Other teams within the Air Force were also developing the Space Launch System
concept, which combined the same Titan II with a number of solid fuel rockets as a "zeroth stage". By combining different numbers and sizes of these rockets, the launch stack could be tuned to different payloads. The SLS team also outlined a development path for a manned lunar mission under their Lunex Project
proposal, using the Titan with four solids to test the re-entry vehicle from Earth orbit, and entirely new solids and liquid stages for flights to the moon.
To meet the same DoD requirement for a heavy space launcher, the Army team at the Army Ballistic Missile Agency
(ABMA) under the direction of a team led by Wernher von Braun
studied a number of designs that clustered existing missile airframes and optionally added new engines. The design series included the "Super-Titan", "Super-Atlas" and "Super-Jupiter". The later quickly became their focus, as it consisted of technology developed at ABMA, while the Atlas and Titan were Air Force designs suffering from extended development problems. The Super-Jupiter design was based almost entirely on existing equipment, using a cluster of Redstone and Jupiter missiles to form a lower stage powered by a new engine, with an upper stage adapted from the Titan. Their proposal was much simpler and lower-risk than the Air Force proposal, which required the development of a new hydrogen-burning upper stage. Like the Air Force team, ABMA also outlined their vision of a manned lunar mission as Project Horizon
, using fifteen of these rockets to build a large vehicle in Earth orbit.
The newly formed ARPA
, who was put in charge of development of the launcher, sided with the ABMA design. Their only concern was that the new engines might be a risk, suggesting that more moderate upgrades of existing engines be used instead. ABMA quickly adapted the design to use eight engines developed from the Jupiter's S-3D as the H-1
, as opposed to four of the proposed E-1
of the original design. ARPA was satisfied, and started funding development of both the booster at ABMA and the new H-1
engines at Rocketdyne
. Contracts were tendered in October 1958 and work proceeded quickly; the first test-firing of the H-1 occurred in December and a mock-up of the booster had already been completed. Originally known as Super-Jupiter, the design became the Juno V during development, and on February 3 an ARPA memorandum officially renamed the project Saturn.
Soon after, the newly-formed NASA also expressed their interest in the Saturn design as part of their long-term strategy. Launches in the early 1960s would focus on low-Earth orbit using existing ICBM's as launchers, technology development for the lunar program would be based on Saturn, and the actual direct assent lunar mission would use the massive Nova rocket
, then under design at NASA. Shortly thereafter, on 9 June 1959, Herbert York, Director of Department of Defense Research and Engineering, announced that he had decided to terminate the Saturn program. York felt that the DoD should not be funding a booster whose only concrete role was to support a civilian space program. A meeting was arrange to "save" the program, which resulted in the Saturn program, and all of ABMA with it, being transferred to NASA.
A meeting of all involved parties was arranged under the direction of Abe Silverstein, whose earlier efforts were instrumental in Saturn being selected for NASA missions. The committee established two criteria for a successful Saturn program: fast development time of an initial system, and growth potential for future launches. The group listed three missions for the initial Saturn vehicle: unmanned lunar and deep space missions with an escape payload of about 4,500 kg; 2,250 kg payloads to geostationary orbit; and manned spacecraft missions in low orbits, such as Dyna-Soar.
To make such "high altitude" missions practical, the performance of the upper stages would be key. Every pound used in the stage or its fuel would mean that much less cargo, given any particular booster (first stage). Since it was the power-to-weight ratio
that they needed, upper stages based on liquid hydrogen
seemed to be the only way forward – the light weight of the fuel makes up for any difficulty handling it. The Saturn proposal had always included such a stage for orbital insertion, the Centaur
, a hydrogen-burning stage derived from the Atlas ICBM.
For the intermediate stages the designers has somewhat more flexibility. The Committee members outlined a number of possible solutions grouped into different classes. The class "A" designs were the low-risk solutions; von Braun's current design became the A-1, consisting of the Jupiter/Redstone clustered lower stage, the Titan I as the intermediate, and the Centaur upper. The A-2 replaced the intermediate with another cluster made up from Thor
missiles. The single B-1 design replaced the intermediate with an all-new 220" LOX/RP-1 design using four of the H-1 engines that the lower stage also used, along with a new four-engine third stage derived from Centaur but in a 220" diameter. The C designs used hydrogen-burning uppers only; C-1 would consist of the existing Saturn booster, a new Douglas Aircraft 220" S-IV stage powered by four upgraded versions of the Centaur engines with 15000 lbf (66.7 kN) to 20000 lbf (89 kN) thrust per engine, and a modified Centaur using the same engines as a third stage. The C-1 would become the C-2 upon insertion of a new S-III stage with two new 150000 lbf (667.2 kN) to 200000 lbf (889.6 kN) thrust engines, keeping the S-IV and Centaur on top. The C-3 was a similar adaptation, inserting the S-II stage with four of the same 150-200,000 lbf thrust engines, keeping the S-III and S-IV stages of the C-2, but eliminating the Centaur.
Examining the results strongly suggested that the C models were the only ones worth proceeding with, as they offered much higher performance than any other combination and offered great flexibility by allowing the stages to be mixed-and-matched for any particular launch need. Additionally, the Titan-derived intermediate had little growth potential, its weight already being near the maximum the Saturn booster could lift. If more performance was called for in the future, a new middle stage would be needed anyway. The same analysis eliminated the 160" stage; designed for the smaller Titan, the Saturn booster would be wasting much of its potential performance lifting this lighter load.
Thus the decision came down not to performance, which was clearly settled, but development risk. The Saturn had always been designed to be as low-risk as possible, the only really new components being a minor upgrade to the engine for the lower stage and the Centaur as the upper. Developing entirely new hydrogen-burning stages for the entire "stack" would increase the risk that a failure of any one of the components could disrupt the entire program. But as the Committee members noted: "If these propellants are to be accepted for the difficult top-stage applications, there seems to be no valid engineering reasons for not accepting the use of high-energy propellants for the less difficult application to intermediate stages." von Braun was won over; development of the current design would continue as a back-up, but the future of the Saturn was based on hydrogen and was tailored solely to NASA's requirements.
On the last day of 1959, Keith Glennan, Administrator of NASA, approved the Silverstein recommendations. Chances of meeting the schedule improved with two Eisenhower administration decisions in January 1960. The Saturn project received a DX rating, which designated a program of highest national priority, which gave program managers privileged status in securing scarce materials. More important, the administration agreed to NASA's request for additional funds. The Saturn FY 1961 budget was increased from $140 million to $230 million. On 15 March 1960 President Eisenhower officially announced the transfer of the Army's Development Operations Division to NASA.
All that survived was the smallest of the new upper stages, the S-IV. It was originally intended that this would be equipped with four upgraded Centaur engines, but to further lower risk it was decided to used the existing engines and increase their number from four to six. A new engine, the famed J-2
, was already in the pipeline that could replace these anyway. Even the original S-IV design, the 220" with six engines, was used only for a short period until a larger diameter 260" version was created for the Saturn Block II models, and then finally replaced with the J-2 powered S-IVB of the Saturn IB
. Centaur was never used on Saturn.
Equally ironically, neither the Titan C nor SLS would ever be built. Instead, the solid-fuel boosters of the SLS were combined with the existing Titan II and Centaur to produce the Titan III
, which was the workhorse of the DoD's space launch needs for decades. Filling a role very similar to the original Titan C, the III was also used by NASA for a number of launches.
NASA
The National Aeronautics and Space Administration is the agency of the United States government that is responsible for the nation's civilian space program and for aeronautics and aerospace research...
could take with the Saturn program
Saturn (rocket family)
The Saturn family of American rocket boosters was developed by a team of mostly German rocket scientists led by Wernher von Braun to launch heavy payloads to Earth orbit and beyond. Originally proposed as a military satellite launcher, they were adopted as the launch vehicles for the Apollo moon...
. The committee was chaired by Abe Silverstein
Abe Silverstein
Abraham "Abe" Silverstein was an American engineer who played an important part in the United States space program. He was a longtime manager at the National Aeronautics and Space Administration and its predecessor, the National Advisory Committee for Aeronautics...
, a long-time NASA engineer, with the express intent of selecting upper stages for the Saturn after a disagreement broke out between the Air Force and Army over its development. During the meetings the Committee members outlined a number of different potential designs, including the low-risk solution von Braun was developing with existing ICBM airframes, as well as versions using entirely new upper stages developed to take full advantage of the booster stage. The advantages of using new uppers were so great that the committee won over an initially skeptical von Braun, and the future of the Saturn program changed forever.
Background
In 1957 the Department of Defense (DoD) released a set of requirements for a new heavy-lift booster for missions starting in the early 1960s. At the time, all three branches of the US military were in the process of developing their own rockets, which led to considerable in-fighting between them on the priority of future developments. In 1956 the US Air Force won the concession that long range rocketry was its domain, including all ground-to-ground missiles over 200 miles (321.9 km) range. The agreement did not cover "other roles" however, and existing projects at the Navy and Army continued as before.The Air Force was in the midst of their Dyna-Soar project, and were designing a new booster to launch it under their "SLV-4" requirement. Their primary answer to this requirement was a Titan II missile equipped with a new hydrogen-burning upper stage, the Titan C. The resulting design had a somewhat bulbous appearance; as the hydrogen fuel required large tanks, the upper stage was 160 inches (4,064 mm) in diameter, compared to the 120 inches (3,048 mm) of the Titan II. Other teams within the Air Force were also developing the Space Launch System
Space Launch System
The Space Launch System, or SLS, is a Space Shuttle-derived heavy launch vehicle being designed by NASA, following the cancellation of the Constellation Program, to replace the retired Space Shuttle. The NASA Authorization Act of 2010 envisions the transformation of the Ares I and Ares V vehicle...
concept, which combined the same Titan II with a number of solid fuel rockets as a "zeroth stage". By combining different numbers and sizes of these rockets, the launch stack could be tuned to different payloads. The SLS team also outlined a development path for a manned lunar mission under their Lunex Project
Lunex Project
The Lunex Project was a US Air Force 1958 plan for a manned lunar landing prior to the Apollo Program. The final lunar expedition plan in 1961 was for a 21-airman underground Air Force base on the Moon by 1968 at a total cost of $ 7.5 billion....
proposal, using the Titan with four solids to test the re-entry vehicle from Earth orbit, and entirely new solids and liquid stages for flights to the moon.
To meet the same DoD requirement for a heavy space launcher, the Army team at the Army Ballistic Missile Agency
Army Ballistic Missile Agency
The Army Ballistic Missile Agency was the agency formed to develop the US Army's first intermediate range ballistic missile. It was established at Redstone Arsenal on February 1, 1956 and commanded by Major General John B...
(ABMA) under the direction of a team led by Wernher von Braun
Wernher von Braun
Wernher Magnus Maximilian, Freiherr von Braun was a German rocket scientist, aerospace engineer, space architect, and one of the leading figures in the development of rocket technology in Nazi Germany during World War II and in the United States after that.A former member of the Nazi party,...
studied a number of designs that clustered existing missile airframes and optionally added new engines. The design series included the "Super-Titan", "Super-Atlas" and "Super-Jupiter". The later quickly became their focus, as it consisted of technology developed at ABMA, while the Atlas and Titan were Air Force designs suffering from extended development problems. The Super-Jupiter design was based almost entirely on existing equipment, using a cluster of Redstone and Jupiter missiles to form a lower stage powered by a new engine, with an upper stage adapted from the Titan. Their proposal was much simpler and lower-risk than the Air Force proposal, which required the development of a new hydrogen-burning upper stage. Like the Air Force team, ABMA also outlined their vision of a manned lunar mission as Project Horizon
Project Horizon
Project Horizon was a study to determine the feasibility of constructing a scientific / military base on the Moon. On June 8, 1959, a group at the Army Ballistic Missile Agency produced for the U.S. Department of the Army a report entitled Project Horizon, A U.S. Army Study for the Establishment...
, using fifteen of these rockets to build a large vehicle in Earth orbit.
The newly formed ARPA
ARPA
Arpa and ARPA may refer to:Arpa* Arpa River in Armenia* Areni, Armenia - formerly called Arpa* Arpi, Armenia, also called Arpa* Turkish for Akhurian River in Turkey and Armenia* Italian for harp, sometimes used in scoresARPA...
, who was put in charge of development of the launcher, sided with the ABMA design. Their only concern was that the new engines might be a risk, suggesting that more moderate upgrades of existing engines be used instead. ABMA quickly adapted the design to use eight engines developed from the Jupiter's S-3D as the H-1
H-1 (rocket engine)
Rocketdyne's H-1 is a thrust liquid-propellant rocket engine burning LOX and RP-1. The H-1 was developed for use in the S-IB first stage of the Saturn I and Saturn IB rockets, where it was used in clusters of eight engines...
, as opposed to four of the proposed E-1
E-1 (rocket engine)
Rocketdyne's E-1 was a liquid propellant rocket engine originally built as a backup design for the Titan I missile. While it was being developed, Heinz-Hermann Koelle at the Army Ballistic Missile Agency selected it as the primary engine for the rocket that would emerge as the Saturn I...
of the original design. ARPA was satisfied, and started funding development of both the booster at ABMA and the new H-1
H-1 (rocket engine)
Rocketdyne's H-1 is a thrust liquid-propellant rocket engine burning LOX and RP-1. The H-1 was developed for use in the S-IB first stage of the Saturn I and Saturn IB rockets, where it was used in clusters of eight engines...
engines at Rocketdyne
Rocketdyne
Rocketdyne was a Rocket engine design and production company headquartered in Canoga Park, California, United States. The company was related to North American Aviation for most of its history. NAA merged with Rockwell International, which was then bought by Boeing in December, 1996...
. Contracts were tendered in October 1958 and work proceeded quickly; the first test-firing of the H-1 occurred in December and a mock-up of the booster had already been completed. Originally known as Super-Jupiter, the design became the Juno V during development, and on February 3 an ARPA memorandum officially renamed the project Saturn.
Soon after, the newly-formed NASA also expressed their interest in the Saturn design as part of their long-term strategy. Launches in the early 1960s would focus on low-Earth orbit using existing ICBM's as launchers, technology development for the lunar program would be based on Saturn, and the actual direct assent lunar mission would use the massive Nova rocket
Nova rocket
Nova was a series of proposed rocket designs, originally as NASA's first large launchers for missions similar to the production-level Saturn V, and later as larger follow-ons to the Saturn V intended for missions to Mars. The two series of designs were essentially separate, but shared their name...
, then under design at NASA. Shortly thereafter, on 9 June 1959, Herbert York, Director of Department of Defense Research and Engineering, announced that he had decided to terminate the Saturn program. York felt that the DoD should not be funding a booster whose only concrete role was to support a civilian space program. A meeting was arrange to "save" the program, which resulted in the Saturn program, and all of ABMA with it, being transferred to NASA.
Selecting an upper
Nevertheless, the Air Force continued to agitate the development process. In December, ABMA, still part of the Army at this point, received an order to change the upper stage of the Saturn from the Titan-derived vehicle with a 120" diameter, to a new one with 160" diameter that would require considerably more development. The 160" diameter was the same as the Titan C upper, and by making this change to the Saturn the DoD would have two competing upper-stage designs for the SLV-4 requirement, as well as allowing Saturn to launch Dyna-Soar if the need arose. ABMA was already testing the engines for their Titan-derived upper stage, and was upset with this new request.A meeting of all involved parties was arranged under the direction of Abe Silverstein, whose earlier efforts were instrumental in Saturn being selected for NASA missions. The committee established two criteria for a successful Saturn program: fast development time of an initial system, and growth potential for future launches. The group listed three missions for the initial Saturn vehicle: unmanned lunar and deep space missions with an escape payload of about 4,500 kg; 2,250 kg payloads to geostationary orbit; and manned spacecraft missions in low orbits, such as Dyna-Soar.
To make such "high altitude" missions practical, the performance of the upper stages would be key. Every pound used in the stage or its fuel would mean that much less cargo, given any particular booster (first stage). Since it was the power-to-weight ratio
Power-to-weight ratio
Power-to-weight ratio is a calculation commonly applied to engines and mobile power sources to enable the comparison of one unit or design to another. Power-to-weight ratio is a measurement of actual performance of any engine or power sources...
that they needed, upper stages based on liquid hydrogen
Liquid hydrogen
Liquid hydrogen is the liquid state of the element hydrogen. Hydrogen is found naturally in the molecular H2 form.To exist as a liquid, H2 must be pressurized above and cooled below hydrogen's Critical point. However, for hydrogen to be in a full liquid state without boiling off, it needs to be...
seemed to be the only way forward – the light weight of the fuel makes up for any difficulty handling it. The Saturn proposal had always included such a stage for orbital insertion, the Centaur
Centaur (rocket stage)
Centaur is a rocket stage designed for use as the upper stage of space launch vehicles. Centaur boosts its satellite payload to geosynchronous orbit or, in the case of an interplanetary space probe, to or near to escape velocity...
, a hydrogen-burning stage derived from the Atlas ICBM.
For the intermediate stages the designers has somewhat more flexibility. The Committee members outlined a number of possible solutions grouped into different classes. The class "A" designs were the low-risk solutions; von Braun's current design became the A-1, consisting of the Jupiter/Redstone clustered lower stage, the Titan I as the intermediate, and the Centaur upper. The A-2 replaced the intermediate with another cluster made up from Thor
PGM-17 Thor
Thor was the first operational ballistic missile of the U.S. Air Force . Named after the Norse god of thunder, it was deployed in the United Kingdom between 1959 and September 1963 as an intermediate range ballistic missile with thermonuclear warheads. Thor was in height and in diameter. It was...
missiles. The single B-1 design replaced the intermediate with an all-new 220" LOX/RP-1 design using four of the H-1 engines that the lower stage also used, along with a new four-engine third stage derived from Centaur but in a 220" diameter. The C designs used hydrogen-burning uppers only; C-1 would consist of the existing Saturn booster, a new Douglas Aircraft 220" S-IV stage powered by four upgraded versions of the Centaur engines with 15000 lbf (66.7 kN) to 20000 lbf (89 kN) thrust per engine, and a modified Centaur using the same engines as a third stage. The C-1 would become the C-2 upon insertion of a new S-III stage with two new 150000 lbf (667.2 kN) to 200000 lbf (889.6 kN) thrust engines, keeping the S-IV and Centaur on top. The C-3 was a similar adaptation, inserting the S-II stage with four of the same 150-200,000 lbf thrust engines, keeping the S-III and S-IV stages of the C-2, but eliminating the Centaur.
Examining the results strongly suggested that the C models were the only ones worth proceeding with, as they offered much higher performance than any other combination and offered great flexibility by allowing the stages to be mixed-and-matched for any particular launch need. Additionally, the Titan-derived intermediate had little growth potential, its weight already being near the maximum the Saturn booster could lift. If more performance was called for in the future, a new middle stage would be needed anyway. The same analysis eliminated the 160" stage; designed for the smaller Titan, the Saturn booster would be wasting much of its potential performance lifting this lighter load.
Thus the decision came down not to performance, which was clearly settled, but development risk. The Saturn had always been designed to be as low-risk as possible, the only really new components being a minor upgrade to the engine for the lower stage and the Centaur as the upper. Developing entirely new hydrogen-burning stages for the entire "stack" would increase the risk that a failure of any one of the components could disrupt the entire program. But as the Committee members noted: "If these propellants are to be accepted for the difficult top-stage applications, there seems to be no valid engineering reasons for not accepting the use of high-energy propellants for the less difficult application to intermediate stages." von Braun was won over; development of the current design would continue as a back-up, but the future of the Saturn was based on hydrogen and was tailored solely to NASA's requirements.
On the last day of 1959, Keith Glennan, Administrator of NASA, approved the Silverstein recommendations. Chances of meeting the schedule improved with two Eisenhower administration decisions in January 1960. The Saturn project received a DX rating, which designated a program of highest national priority, which gave program managers privileged status in securing scarce materials. More important, the administration agreed to NASA's request for additional funds. The Saturn FY 1961 budget was increased from $140 million to $230 million. On 15 March 1960 President Eisenhower officially announced the transfer of the Army's Development Operations Division to NASA.
Saturn emerges
Ironically, the Saturn C vehicles imagined in the Silverstein Committee report were never built. As soon as the Saturn became a NASA-tuned design of high performance, the DoD became less interested in it for their own needs. Development of the Titan continued for these roles, and as a result the flexibility offered by the variety of Saturn C-model intermediate stages simply wasn't needed, and were eventually abandoned.All that survived was the smallest of the new upper stages, the S-IV. It was originally intended that this would be equipped with four upgraded Centaur engines, but to further lower risk it was decided to used the existing engines and increase their number from four to six. A new engine, the famed J-2
J-2 (rocket engine)
Rocketdyne's J-2 rocket engine was a major component of the Saturn V rocket used in the Apollo program to send men to the Moon. Five J-2 engines were used on the S-II second stage, and one J-2 was used on the S-IVB third stage. The S-IVB was also used as the second stage of the smaller Saturn IB...
, was already in the pipeline that could replace these anyway. Even the original S-IV design, the 220" with six engines, was used only for a short period until a larger diameter 260" version was created for the Saturn Block II models, and then finally replaced with the J-2 powered S-IVB of the Saturn IB
Saturn IB
The Saturn IB was an American launch vehicle commissioned by the National Aeronautics and Space Administration for use in the Apollo program...
. Centaur was never used on Saturn.
Equally ironically, neither the Titan C nor SLS would ever be built. Instead, the solid-fuel boosters of the SLS were combined with the existing Titan II and Centaur to produce the Titan III
Titan III
The Titan IIIC was a space booster used by the United States Air Force. It was launched from Cape Canaveral Air Force Station, FL., and Vandenberg Air Force Base, CA. It was planned to be used as a launch vehicle in the cancelled Dyna-Soar and Manned Orbiting Laboratory programs...
, which was the workhorse of the DoD's space launch needs for decades. Filling a role very similar to the original Titan C, the III was also used by NASA for a number of launches.