Friday, June 3, 2011

Rapid Response, Part Four, Section Two: The Lockheed RS-71 Blackbird

Since the [SR]-71 was originally the RS-71, as in Reconnaissance/Strike, it follows that it would have had a weapons-carrying capability from the outset.  Reconnaissance/Strike involves scouting targets and interdicting those targets not already destroyed.







From Wikipedia, the free encyclopedia
"SR-71" redirects here. For other uses, see SR-71 (disambiguation).







SR-71 "Blackbird"




Dryden's SR-71B Blackbird, NASA 831, slices across the snow-covered southern Sierra Nevada Mountains of California after being refueled by an Air Force tanker during a 1994 flight. SR-71B was the trainer version of the SR-71. Notice the dual cockpit to allow the instructor to fly.
An SR-71B Trainer over the Sierra Nevada Mountains of California in 1994. Note the raised second cockpit for the instructor.



Role:  Strategic reconnaissance aircraft

Manufacturer:  Lockheed Skunk Works

Designed by:  Clarence "Kelly" Johnson

First flight:  22 December 1964

Introduced:  1966

Retired:  1998

Status:  Phased out of service

Primary users:  United States Air Force and NASA
Number built:  32

Developed from:  Lockheed A-12





The Lockheed SR-71 "Blackbird" was an advanced, long-range, Mach 3+ strategic reconnaissance aircraft.[1] It was developed as a black project from the Lockheed A-12 reconnaissance aircraft in the 1960s by the Lockheed Skunk Works. Clarence "Kelly" Johnson was responsible for many of the design's innovative concepts. During reconnaissance missions the SR-71 operated at high speeds and altitudes to allow it to outrace threats. If a surface-to-air missile launch was detected, the standard evasive action was simply to accelerate and outrun the missile.[2]



The SR-71 served with the U.S. Air Force from 1964 to 1998. Although twelve of the 32 aircraft built were destroyed in accidents, none were lost to enemy action.[3][4] The SR-71 was unofficially named the Blackbird, and called the Habu by its crews, referring to an Okinawan species of pit viper.[5] Since 1976, it has held the world record for the fastest air-breathing manned aircraft, a record previously held by the YF-12.[6][7][8]

Development


Background


The Lockheed A-12, designed for the Central Intelligence Agency (CIA) by Clarence Johnson at the Lockheed Skunk Works,[9] was the precursor of the SR-71. The A-12's first flight took place at Groom Lake (Area 51), Nevada, on 25 April 1962. It was equipped with the less powerful Pratt & Whitney J75 engines due to protracted development of the intended Pratt & Whitney J58. The J58s were retrofitted as they became available, and became the standard power plant for all subsequent aircraft in the series (A-12, YF-12, M-21) as well as the follow-on SR-71 aircraft.
Thirteen A-12s were built. Two A-12 variants were also developed, including three YF-12A interceptor prototypes, and two M-21 drone carrier variants. The cancellation of A-12 program was announced on 28 December 1966,[10] due to budget concerns,[11] and because of the forthcoming SR-71. The A-12 flew missions over Vietnam and North Korea before its retirement in 1968.

SR-71




File:SR71 factoryfloor SkunkWorks.jpg

SR-71 assembly line at Skunk Works

The SR-71 designator is a continuation of the pre-1962 bomber series, which ended with the XB-70 Valkyrie. During the later period of its testing, the B-70 was proposed for a reconnaissance/strike role, with an RS-70 designation. When it was clear that the A-12 performance potential was much greater, the Air Force ordered a variant of the A-12 in December 1962.[12] Originally named R-12[N 1] by Lockheed, the Air Force version was longer and heavier than the A-12, with a longer fuselage to hold more fuel, two seats in the cockpit, and reshaped chines. Reconnaissance equipment included signals intelligence sensors, a side-looking radar and a photo camera.[12] The CIA's A-12 remained a better photo reconnaissance platform than the Air Force's R-12, however, especially since the A-12 flew higher and faster,[11] and with only one pilot it had room to carry a superior camera[11] and more instruments.[13]
During the 1964 campaign, Republican presidential nominee Barry Goldwater repeatedly criticized President Lyndon B. Johnson and his administration for falling behind the Soviet Union in developing new weapons. Johnson decided to counter this criticism by revealing the existence of the YF-12A Air Force interceptor (which also served as cover for the still-secret A-12)[14] and, on 25 July 1964, the Air Force reconnaissance model. Air Force Chief of Staff General Curtis LeMay preferred the SR (Strategic Reconnaissance) designation and wanted the RS-71 to be named SR-71. Before the July speech, LeMay lobbied to modify Johnson's speech to read SR-71 instead of RS-71. The media transcript given to the press at the time still had the earlier RS-71 designation in places, creating the story that the president had misread the aircraft's designation.[15][16]
This public disclosure of the program and its renaming came as a shock to everyone at the Skunk Works and to Air Force personnel involved in the program. All of the printed maintenance manuals, flight crew handbooks,[N 2] training slides and materials were labeled "R-12" and 18 June 1965 Certificates of Completion issued by the Skunk Works to the first Air Force Flight Crews and their Wing Commander were labeled "R-12 Flight Crew Systems Indoctrination, Course VIII". The name change was taken as an order from the Commander-in-Chief, and immediate reprinting began of materials, including 29,000 blueprints, with the new name.
Design and operational details



File:SR-71 flight instruments.triddle.jpg

The flight instrumentation of SR-71 Blackbird

A particularly difficult issue with flight at over Mach 3 is the high temperatures generated. As an aircraft moves through the air at supersonic speed, the air in front of the aircraft is compressed into a supersonic shock wave, and the energy generated by this heats the airframe. To address this problem, high-temperature materials were needed, and the airframe of the SR-71 was substantially made of titanium, obtained from the USSR at the height of the Cold War. Lockheed used many guises to prevent the Soviet government from knowing what the titanium was to be used for. In order to control costs, Lockheed used a more easily worked alloy of titanium which softened at a lower temperature. Finished aircraft were painted a dark blue (almost black) to increase the emission of internal heat (since fuel was used as a heat sink for avionics cooling) and to act as camouflage against the night sky. The aircraft was designed to minimize its radar cross-section, an early attempt at stealth design.[17] The call sign of the aircraft, "Blackbird", signifies the resistance of its airframe to visible light and radar detection.

Air inlets


File:SR71 J58 Engine Airflow Patterns.svg

Operation of the air inlets and air flow patterns through the J58

The air inlets allowed the plane to cruise at over Mach 3.2, yet kept air flowing into the turbojet engines at a subsonic, Mach 0.5 speed. At the front of each inlet was a sharply pointed movable cone called a "spike" that was locked in its full forward position on the ground and when in subsonic flight. As the aircraft accelerated past Mach 1.6, an internal jackscrew moved the spike as much as 26 inches (66 cm) to the rear.[18]
The original air inlet computer was an analog design which, based on pitot-static, pitch, roll, yaw, and angle-of-attack inputs, would determine how much movement was required. By moving, the spike tip would withdraw the shock wave, riding on it closer to the inlet cowling until it just touched slightly inside the cowling lip. In this position shock-wave spillage, causing turbulence over the outer nacelle and wing, was minimized while the spike shock-wave then repeatedly reflected between the spike centerbody and the inlet inner cowl sides. In doing so, shock pressures were maintained while slowing the air until a Mach 1 shock wave formed in front of the engine compressor.[19]
The backside of this "normal" shock wave was subsonic air for ingestion into the engine compressor. This capture of the Mach 1 shock wave within the inlet was called "Starting the Inlet". Tremendous pressures would be built up inside the inlet and in front of the compressor face. Bleed tubes and bypass doors were designed into the inlet and engine nacelles to handle some of this pressure and to position the final shock to allow the inlet to remain "started". Air that is compressed by the inlet/shockwave interaction is diverted around the turbo machinery of the engine and directly into the afterburner where it is mixed and burned. This configuration is essentially a ramjet and provides up to 70% of the aircraft's thrust at higher mach numbers.
Ben Rich, the Lockheed Skunkworks designer of the inlets, often referred to the engine compressors as "pumps to keep the inlets alive" and sized the inlets for Mach 3.2 cruise (where the aircraft was at its most efficient design point).[20] The additional "thrust" refers to the reduction of engine energy required to compress the airflow. One unique characteristic of the SR-71 is that the faster it went, the more fuel-efficient it was in terms of pounds burned per nautical mile traveled. An incident related by Brian Shul, author of Sled Driver: Flying the World's Fastest Jet, was that on one reconnaissance run he was fired upon several times. In accordance with procedure they accelerated and maintained the higher than normal velocity for some time; afterwards they discovered that this had reduced their fuel consumption.[21]
In the early years of the Blackbird programs the analog air inlet computers would not always keep up with rapidly changing flight environmental inputs. If internal pressures became too great and the spike was incorrectly positioned the shock wave would suddenly blow out the front of the inlet, called an "Inlet Unstart." The flow of air through the engine compressor would immediately stop, thrust would drop, and exhaust gas temperatures would begin to rise. Due to the tremendous thrust of the remaining engine pushing the aircraft asymmetrically an unstart would cause the aircraft to yaw violently to one side. SAS, autopilot, and manual control inputs would fight the yawing, but often the extreme off-angle would reduce airflow in the opposite engine and cause it to begin "sympathetic stalls". The result would be rapid counter-yawing, often loud "banging" noises and a rough ride. The crews' pressure-suit helmets would sometimes bang on the cockpit canopies until the initial unstart motions subsided.[22]
One of the standard counters to an inlet unstart was for the pilot to unstart both inlets. This stopped the aircraft's yawing and pitching, and allowed the pilot to restart the inlets.[23] Lockheed implemented an electronic control to detect unstart conditions and perform this action without pilot intervention.[24] The initial analog inlet control system was replaced by a digital system beginning in 1980. The new system prevented many of unstarts encountered during flights.[25]

Titanium structures and airframe



File:SR71BLACKBIRD.jpg

A Lockheed M-21 with D-21 drone on top

Before the Blackbird, titanium was only used in high-temperature exhaust fairings and other small parts directly related to supporting, cooling, or shaping high-temperature areas on aircraft. Building the Blackbird's structure using 85% titanium and 15% composite materials was a first in the aircraft industry. The advances made by Lockheed in fabricating this material have been used in subsequent high-speed aircraft, including most modern fighters.

Titanium was difficult to work with, expensive, and scarce. Initially, 80% of the titanium delivered to Lockheed was rejected due to metallurgical contamination.[26][27] One example of the difficulties of working with titanium is that welds made at certain times of the year were more durable than welds made at other times. It was found that the manufacturing plant's water came from one reservoir in the summer and another in the winter; the slight differences in the impurities in the water from these sources led to differences in the durability of the welds, since water was used to cool the titanium welds.[28]

Studies of the aircraft's titanium skin revealed that the metal was actually growing stronger over time, because of intense heating due to compression of the air, caused by the rapid flight of the vehicle (heat treatment).

Major portions of the upper and lower inboard wing skin of the SR-71 were corrugated, not smooth. The thermal expansion stresses of a smooth skin would have caused splitting or curling. By making the surface corrugated, the skin was allowed to expand vertically and horizontally without overstressing, which also increased longitudinal strength. Despite its success, aerodynamicists initially opposed the concept and accused the design engineers of trying to make a 1920s era Ford Trimotor — known for its corrugated aluminum skin — go Mach 3.[20] The red stripes on some SR-71s are to prevent maintenance workers from damaging the skin. The curved skin near the center of the fuselage is thin and delicate. There is no support underneath with exception of the structural ribs, which are spaced several feet apart.

To allow for thermal expansion at the high operational temperatures, the fuselage panels were manufactured to fit only loosely on the ground. Proper alignment was only achieved when the airframe heated due to air resistance at high speeds, causing the airframe to expand several inches. Because of this, and the lack of a fuel sealing system that could handle the thermal expansion of the airframe at extreme temperatures, the aircraft would leak JP-7 jet fuel onto the runway before it took off. The aircraft would quickly make a short sprint, meant to warm up the airframe, and was then refueled in the air before departing on its mission. Cooling was carried out by cycling fuel behind the titanium surfaces at the front of the wings (chines). On landing after a mission the canopy temperature was over 300 °C (572 °F), too hot to approach. Non-fibrous asbestos with high heat tolerance was used in high-temperature areas.[20]

Stealth and threat avoidance

The SR-71 was the first operational aircraft designed around a stealthy shape and materials. There were a number of features in the SR-71 that were designed to reduce its radar signature. The first studies in radar stealth technology seemed to indicate that a shape with flattened, tapering sides would avoid reflecting most radar energy toward the radar beams' place of origin. To this end, the radar engineers suggested adding chines to the design and canting the vertical control surfaces inward. The aircraft also used special radar-absorbing materials which were incorporated into sawtooth shaped sections of the skin of the aircraft, as well as cesium-based fuel additives to reduce the exhaust plumes' visibility on radar. Despite these efforts, the SR-71 was still easily detected on radar while traveling at speed due to its large exhaust stream and air heated by the body (large thermal gradients in the atmosphere are detectable with radar). The SR-71's radar cross section (RCS) of almost 10 square meters [29] was much greater than the later F-117's RCS, which is similar to that of a small ball bearing.[30]

The overall effectiveness of these designs is still debated; Ben Rich's team could show that the radar return was, in fact, reduced, but Kelly Johnson later conceded that Russian radar technology was advancing faster than the "anti-radar" technology Lockheed was using to counter it.[31] The SR-71 made its debut years before Pyotr Ya. Ufimtsev's ground-breaking research made possible today's stealth technologies, and, despite Lockheed's best efforts, the SR-71 was still easy to track by radar and had a huge infrared signature when cruising at Mach 3.2 or more. It was visible on radar since air traffic control tracked it when not using its transponder,[32] and missiles were often fired at the aircraft.

Although equipped with defensive electronic countermeasures, the SR-71's greatest protection was its high top speed, which made it almost invulnerable to the attack technologies of the time. Over the course of its service life, no SR-71 was shot down, despite more than 4,000 attempts to do so. It flew too fast and too high for surface-to-air missile systems to track and shoot down, and was much faster than the Soviet Union's fastest aircraft of the time, the MiG-25, which had a top speed of Mach 3.2 at high altitude, however the engines would burn up at that speed.[33] All the SR-71 pilot had to do was to accelerate.[2]

Chines



File:A-12 Nose View.jpg

Head-on view of an A-12 (precursor to the SR-71) on the deck of the Intrepid Sea-Air-Space Museum, illustrating the chines.

One of the Blackbird's interesting features was its chines, sharp edges leading aft on either side of the nose and along the sides of the fuselage.

The Blackbird was originally not going to have chines. At its A-3 design stage, the fuselage had a circular or vertical oval cross section. Dr. Frank Rodgers, of the Scientific Engineering Institute (a CIA front company), had discovered that a section of a sphere—round on the bottom and flat on top—had a greatly reduced radar reflection. He adapted this to a cylindrical fuselage by 'stretching' the sides out and leaving the bottom round.[34] After the advisory panel provisionally selected Convair's FISH design over the A-3 on the basis of RCS, Lockheed adopted chines for its A-4 through A-6 designs,[35] and used them in redesigning the A-11 into the A-12.

The aerodynamicists discovered that the chines generated powerful vortices around themselves, generating much additional lift near the front of the aircraft, leading to surprising improvements in aerodynamic performance.[36] The angle of incidence of the delta wings could then be reduced, allowing for greater stability and less high-speed drag, and more weight (fuel) could be carried, allowing for greater range. Landing speeds were also reduced, since the chines' vortices created turbulent flow over the wings at high angles of attack, making it harder for the wings to stall. The Blackbird can, consequently, make high-alpha turns to the point where the Blackbird's unique engine air inlets stop ingesting enough air, which can cause the engines to flame out.[37] Blackbird pilots were thus warned not to pull more than 3 g, so that angles of attack stay low enough for the engines to get enough air. The chines act like the leading edge extensions that increase the agility of modern fighters such as the F-5, F-16, F/A-18, MiG-29 and Su-27. The addition of chines also allowed designers to drop the planned canard foreplanes. Early design models of what became the Blackbird featured canards.[N 3][38][39]
When the Blackbird was being designed, no other airplane had featured chines, so Lockheed's engineers had to solve problems related to the differences in stability and balance caused by these unusual surfaces. Their solutions have since been extensively used. Chines remain an important design feature of many of the newest stealth UAVs, such as the Dark Star, Bird of Prey, X-45 and X-47, since they allow for tail-less stability as well as for stealth.

Fuel



File:Sr71 1.jpg
An air-to-air overhead front view of an SR-71A. Note the water vapor, condensed by the low-pressure vortices generated by the chines outboard of each engine inlet.

Development began with using a coal slurry powerplant,[20] but Johnson determined that the coal particles damaged engine components. He then began researching a liquid hydrogen powerplant, but the tanks required to store cryogenic hydrogen did not suit the Blackbird's size and shape.[20]
The focus then became somewhat more conventional, though still specialized in many ways. The result was JP-7 jet fuel, which had a relatively high flash point (140 °F, 60 °C) to cope with the heat. The fuel was used as a coolant and hydraulic fluid in the aircraft before being burned. The fuel contained fluorocarbons to increase its lubricity, an oxidizing agent to enable it to burn in the engines, and even a cesium compound, A-50, which disguised the exhaust's radar signature.
JP-7 is very slippery, a disadvantage on the ground, because the aircraft leaked small amounts of fuel when not flying. However, JP-7 was not a fire hazard.
The fuel is also extremely difficult to light in any conventional way. When the engines were started, puffs of triethylborane (TEB), which ignites on contact with air, were injected into the engines to produce temperatures high enough to ignite the JP-7. The TEB produced a characteristic puff of greenish flame that could often be seen as the engines were ignited.[21] TEB was also used to ignite the afterburners. The aircraft carried 20 fluid ounces (600 ml) of TEB per engine, enough for at least 16 injections (a counter told the pilot how many TEB injections remained), more than enough for any missions it was likely to carry out.

Life support



File:SR-71 full pressure flight suit.JPG

SR-71 full pressure flight suit, Hill Aerospace Museum

Crews flying the SR-71 at 80,000 ft (24,000 m) faced two main survival problems: maintaining consciousness at high altitude, and surviving ejection. With a standard pressure demand oxygen mask, human lungs cannot absorb oxygen quickly enough above 43,000 ft (13,000 m). The pressure difference inside the mask versus the cockpit pressure on the chest also makes exhalation extremely difficult. In addition, emergency ejection at Mach 3.2 would expose the pilot to an instant heat rise pulse of approximately 450 °F (230 °C) as a result of the air flow. To solve these problems, the David Clark Company was hired to produce protective full pressure suits for the A-12, YF-12, MD-21 and SR-71 aircraft. These suits were later adapted for use on the Space Shuttle.

In addition, cruising at Mach 3.2 would heat the aircraft's external surface well above 500 °F (260 °C)[40] and the inside of the windshield to 250 °F (120 °C), so a robust coolant system was vital. This was achieved with an air conditioner, which used a heat exchanger to dump heat from the cockpit into the fuel prior to combustion.

After a high altitude bailout, an onboard oxygen supply would keep the suit pressurized. The crew member would then free-fall to 15,000 ft (4,600 m) before the main parachute was opened, allowing heat to bleed off. To demonstrate this full pressure suit capability, crew members would wear one of these suits and undergo an altitude chamber explosive decompression at 78,000 ft (24,000 m) or higher while chamber heaters would be turned on to 450 °F (230 °C), gradually decreasing at the expected rate in real life free-fall.

The cabin could be pressurized to an altitude of 10,000 ft (3,000 m) or 26,000 ft (7,900 m) during flight.[41] So, crews flying a low-subsonic flight (such as a ferry mission) would wear either standard USAF hard hat helmets, pressure demand oxygen masks and nomex flying suits, or a full pressure suit.

Engines



File:SR-71 Blackbird engine.jpg

SR-71 Blackbird engine on display at the Battleship Memorial Park.



File:SR-71 engines.JPG

Pratt & Whitney J58 engines beneath the SR-71 Blackbird on display at Imperial War Museum Duxford.

The Pratt & Whitney J58-P4 engines used in the Blackbird were the only American engines designed to operate continuously on afterburner, and became more efficient as speed increased. Each J58 engine could produce 32,500 lbf (145 kN) of static thrust.

The J58 was unique in that it was a hybrid jet engine. It could operate as a regular turbojet at low speeds, but at high speeds it became a ramjet. The engine can be thought of as a turbojet engine inside a ramjet engine. At lower speeds, the turbojet provided most of the compression and most of the energy from fuel combustion. At higher speeds, the turbojet throttled back and sat in the middle of the engine as air passed around it, having been compressed by the shock cones and only burning fuel in the afterburner.

In detail, air was initially compressed (and thus also heated) by the shock cones, which generated shock waves that slowed the air down to subsonic speeds relative to the engine. The air then passed through four compressor stages and was split by movable vanes: some of the air entered the compressor fans ("core-flow" air), while the rest of the air went straight to the afterburner (via six bypass tubes). The air traveling through the turbojet was further compressed (and further heated), and then fuel was added to it in the combustion chamber: it then reached the maximum temperature anywhere in the Blackbird, just under the temperature where the turbine blades would start to soften. After passing through the turbine (and thus being cooled somewhat), the core-flow air went through the afterburner and met with any bypass air.

At around Mach 3, the increased heating from the shock cone compression, plus the heating from the compressor fans, was already enough to get the core air to high temperatures, and little fuel could be added in the combustion chamber without the turbine blades melting. This meant the whole compressor-combustor-turbine set-up in the core of the engine provided less power, and the Blackbird flew predominantly on air bypassed straight to the afterburners, forming a large ramjet effect.[20] The maximum speed was limited by the specific maximum temperature for the compressor inlet of 800 °F (427 °C).[42][43]

The J58 engines were most efficient around Mach 3.2,[44] and this was the Blackbird's typical cruising speed.

Early 1990s studies of inlets of this type indicated that newer technology could allow for inlet speeds with a lower limit of Mach 6.[45]

Startup



File:AG330 start cart.JPG

AG330 start cart, Hill Aerospace Museum

Originally, the Blackbird's engines started up with the assistance of an external engine referred to as a "start cart". The cart included two Buick Wildcat V8 engines positioned underneath the aircraft. The two engines powered a single, vertical driveshaft connecting to a single J58 engine. Once one engine was started, the cart was wheeled to the other side of the aircraft to start the other engine. The operation was deafening. Later big block Chevrolet engines were used. Eventually, a quieter, pneumatic start system was developed for use at Blackbird main operating bases, but the start carts remained in the inventory to support recovery team Blackbird starts at diversion landing sites not equipped to start J-58 engines.[46]

Astro-Inertial Navigation System (ANS)

Blackbird precision navigation requirements for route accuracy, sensor pointing and target tracking preceded the development and fielding of the Global Positioning System (GPS). U-2 and A-12 Inertial Navigation Systems existed, but US Air Force planners wanted a system that would limit inertial position error growth for longer missions envisioned for the R-12 / SR-71.

Nortronics, the electronics development organization of Northrop, had extensive astro-inertial experience, having provided an earlier generation system for the USAF Snark missile. With this background, Nortronics developed the Astro-Inertial Navigation System for the AGM-48 Skybolt missile, which was to be launched from B-52H bombers. When the Skybolt Program was cancelled in December 1962, the assets Nortronics developed for the Skybolt Program were ordered to be adapted for the Blackbird program. A Nortronics "Skunkworks" type organization in Hawthorne, California completed the development of this system, sometimes referred to as the NAS-14 and/or the NAS-21.

The ANS primary alignment was done on the ground and was time consuming, but brought the inertial components to a high degree of accuracy for the start of a mission. A "blue light" source star tracker, which could detect and find stars during day or night, would then continuously track stars selected from the system's digital computer ephemeris as the changing aircraft position would bring them into view. Originally equipped with data on 56 selected stars, the system would correct inertial orientation errors with celestial observations. The resulting leveling accuracies limited accelerometer errors and position growth.

Rapid ground alignments and air-start abilities were later developed and added to the ANS. Attitude and position inputs to on-board systems and flight controls included the Mission Data Recorder, Auto-Nav steering between loaded destination points, automatic pointing and control of cameras at control points and optical or SLR sighting of fix points (this mission data being tape loaded into the ANS prior to takeoff).

The ANS was located behind the Reconnaissance Systems Officer (RSO) station and tracked stars through a round quartz window in the upper fuselage.[21] Cooling in the Blackbird Mach 3.2+ cruising environment was a serious challenge, resolved by Lockheed and Nortronics engineers during the early test phases. The ANS was a reliable and accurate self-contained navigation system.

Note: The original B-1A Offensive Avionics Request For Proposal (RFP) required the installation and integration of an NAS-14 system, but cost-cutting changes later deleted it from the B-1. Some U-2Rs did receive the NAS-21 system, but newer Inertial and GPS systems replaced them.

Sensors and payloads



File:SR-71 Defensive System B.jpg

The SR-71 Defensive System B

Original capabilities for the SR-71 included optical/infrared imagery systems, side-looking airborne radar (SLAR), electronic intelligence (ELINT) gathering systems, defensive systems (for countering missile and airborne fighter threats) and recorders for SLAR, ELINT and maintenance data.

Imagery systems used on the Blackbird were diverse. At the simple end of the spectrum, SR-71s were equipped with a Fairchild tracking camera of modest resolution and an HRB Singer infrared-tracking IR camera, both of which ran during the entire mission to document where the aircraft flew and answer any post-flight political charges of overflight.

While the A-12's principal sensor was a single large focal length optical camera located in the "Q-Bay", behind the pilot, that location was taken by the cockpit for the observer in the SR-71, forcing the use of different camera systems, which could be located in the wing chines or in the interchangeable nose of the aircraft. Wide area imaging was provided by two of Itek's Operational Objective Cameras (OOC) that provided stereo imagery left and right of the flight track, or an Itek Optical Bar Camera (OBC) that replaced the OOCs and was carried in the nose in place of the SLR, which gave continuous horizon-to horizon coverage. A closer view of the target area was given by the HYCON Technical Objective Camera (TEOC), that could look straight down or up to 45 degrees left or right of centerline.[47] SR-71s were equipped with two of them, each with a six-inch (152 mm) resolution and the ability to show such details as the painted lines in parking lots from an altitude of 83,000 feet (25,000 m).[citation needed] During the early years of service, the resolution produced by the smaller TEOCs was less than that of the larger camera carried by the A-12, although improvements in the camera and the film used later greatly improved the cameras performance.[47][48] In the later years of the SR-71 operation, usage of the infrared camera was discontinued.

Side-looking radar, built by Goodyear Aerospace in Arizona, was carried in the removable nose section (which could be loaded with the SLR antenna in the maintenance shop before installation on the Blackbird). It was eventually replaced by Loral's Advanced Synthetic Aperture Radar System (ASARS-1) and built and supported by Goodyear. Both the first SLR and ASARS-1 were ground mapping imaging systems and could collect data in fixed swaths left or right of centerline or from a spot location where higher resolution was desired.[47] As an example, in passing abeam of an open door aircraft hangar, ASARS-1 could provide meaningful data on the hangar's contents.

ELINT gathering systems, called the Electro Magnetic Reconnaissance System (EMR) built by AIL could be carried in both the left and right chine bays to provide a wide view of the electronic signal fields the Blackbird was flying through.[47][49] Computer-loaded instructions looked for items of special intelligence interest.

Defensive systems built by several leading electronic countermeasures (ECM) companies included (and evolved over the years of the Blackbird's operational life) Systems A, A2, A2C, B, C, C2, E, G, H and M. Several of these different frequency/purpose payloads would be loaded for a particular mission to match the threat environment expected for that mission. They, their warning and active electronic capabilities, and the Blackbird's ability to accelerate and climb when under attack, resulted in the SR-71's long and proven survival track-record.

Recording systems captured SLR phase shift history data (for ground correlation after landing), ELINT-gathered data, and Maintenance Data Recorder (MDR) information for post-flight ground analysis of the aircraft and its systems' overall health. From an altitude of 80,000 feet (24,000 m), it could survey 100,000 square miles (260,000 km2) per hour of the Earth's surface.[50][unreliable source?]

In the later years of its operational life, a data-link system was added that would allow ASARS-1 and ELINT data from about 2,000 nmi (3,700 km) of track coverage to be downlinked if the SR-71 was within "contact" with a mutually equipped ground station.

Operational history



File:Boeing KC-135Q refueling SR-71.JPEG

A SR-71 refueling from a KC-135Q Stratotanker during a flight in 1983

The first flight of an SR-71 took place on 22 December 1964, at Air Force Plant 42 in Palmdale, California.[51] The first SR-71 to enter service was delivered to the 4200th (later, 9th) Strategic Reconnaissance Wing at Beale Air Force Base, California, in January 1966.[52] The United States Air Force Strategic Air Command had SR-71 Blackbirds in service from 1966 through 1991.

SR-71s first arrived at the 9th SRW's Operating Location (OL-8) at Kadena Airbase, Okinawa on 8 March 1968.[53] These deployments were code named "Glowing Heat", while the program as a whole was code named "Senior Crown". Reconnaissance missions over North Vietnam were code named "Giant Scale".

On 21 March 1968, Major (later General) Jerome F. O'Malley and Major Edward D. Payne flew the first operational SR-71 sortie in SR-71 serial number 61-7976 from Kadena AB, Okinawa.[53] During its career, this aircraft (976) accumulated 2,981 flying hours and flew 942 total sorties (more than any other SR-71), including 257 operational missions, from Beale AFB; Palmdale, California; Kadena Air Base, Okinawa, Japan; and RAF Mildenhall, England. The aircraft was flown to the National Museum of the United States Air Force near Dayton, Ohio in March 1990.

From the beginning of the Blackbird's reconnaissance missions over enemy territory (North Vietnam, Laos, etc.) in 1968, the SR-71s averaged approximately one sortie a week for nearly two years. By 1970, the SR-71s were averaging two sorties per week, and by 1972, they were flying nearly one sortie every day.

While deployed in Okinawa, the SR-71s and their aircrew members gained the nickname Habu (as did the A-12s preceding them) after a pit viper indigenous to Japan, which the Okinawans thought the plane resembled.[5]

Swedish JA 37 Viggen fighter pilots, using the predictable patterns of SR-71 routine flights over the Baltic Sea, managed to lock their radar on the SR-71 on numerous occasions. Despite heavy jamming from the SR-71, target illumination was maintained by feeding target location from ground-based radars to the fire-control computer in the Viggen.[54] The most common site for the lock-on to occur was the thin stretch of international airspace between Ă–land and Gotland that the SR-71 used on the return flight.[55][56][57]

Operational highlights for the entire Blackbird family (YF-12, A-12, and SR-71) as of about 1990 included:[58]

3,551 Mission Sorties Flown

17,300 Total Sorties Flown

11,008 Mission Flight Hours

53,490 Total Flight Hours

2,752 hours Mach 3 Time (Missions)

11,675 hours Mach 3 Time (Total)

Only one crew member, Jim Zwayer, a Lockheed flight-test reconnaissance and navigation systems specialist, was killed in a flight accident. The rest of the crew members ejected safely or evacuated their aircraft on the ground.

The highly specialized tooling used in manufacturing the SR-71 was ordered to be destroyed in 1968 by then-Secretary of Defense Robert McNamara, per contractual obligations at the end of production.[citation needed] Destroying the tooling killed any chance of there being an F-12B, but also limited the SR-71 force to the 32 completed, the final SR-71 order having to be cancelled when the tooling was destroyed.

First retirement

In the 1970s, the SR-71 was placed under closer congressional scrutiny and, with budget concerns, the program was soon under attack. Both Congress and the USAF sought to focus on newer projects like the B-1 Lancer and upgrades to the B-52 Stratofortress, whose replacement was being developed. While the development and construction of reconnaissance satellites was costly, their upkeep was less than that of the nine SR-71s then in service.[citation needed]

The SR-71 had never gathered significant supporters within the Air Force, making it an easy target for cost-conscious politicians. Also, parts were no longer being manufactured for the aircraft, so other airframes had to be cannibalized to keep the fleet airworthy. The aircraft's lack of a datalink (unlike the Lockheed U-2) meant that imagery and radar data could not be used in real time, but had to wait until the aircraft returned to base. The Air Force saw the SR-71 as a bargaining chip which could be sacrificed to ensure the survival of other priorities. A general misunderstanding of the nature of aerial reconnaissance and a lack of knowledge about the SR-71 in particular (due to its secretive development and usage) was used by detractors to discredit the aircraft, with the assurance given that a replacement was under development. In 1988, Congress was convinced to allocate $160,000 to keep six SR-71s (along with a trainer model) in flyable storage that would allow the fleet to become airborne within 60 days. The USAF refused to spend the money. While the SR-71 survived attempts to be retired in 1988, partly due to the unmatched ability to provide high quality coverage of the Kola Peninsula for the US Navy,[59] the decision to retire the SR-71 from active duty came in 1989, with the SR-71 flying its last missions in October that year.[60]

Funds were redirected to the financially troubled B-1 Lancer and B-2 Spirit programs. Four months after the plane's retirement, General Norman Schwarzkopf, Jr., was told that the expedited reconnaissance which the SR-71 could have provided was unavailable during Operation Desert Storm.[61] However, it was noted by SR-71 supporters that the SR-71B trainer was just coming out of overhaul and that one SR-71 could have been made available in a few weeks, and a second one within two months. Since the aircraft was recently retired, the support infrastructure was in place and qualified crews available. The decision was made by Washington not to bring the aircraft back.

Reactivation

Due to increasing unease about political conditions in the Middle East and North Korea, the U.S. Congress re-examined the SR-71 beginning in 1993.[61] At a hearing of the Senate Committee on Armed Services, Senator J. James Exon (noting Senator John Glenn's disapproval of reactivating the SR-71) asked Admiral Richard C. Macke: "If we have the satellite intelligence that you collectively would like us to have, would that type of system eliminate the need for an SR-71… Or even if we had this blanket up there that you would like in satellites, do we still need an SR-71?  Macke replied, "From the operator's perspective, what I need is something that will not give me just a spot in time but will give me a track of what is happening. When we are trying to find out if the Serbs are taking arms, moving tanks or artillery into Bosnia, we can get a picture of them stacked up on the Serbian side of the bridge. We do not know whether they then went on to move across that bridge. We need the [data] that a tactical, an SR-71, a U-2, or an unmanned vehicle of some sort, will give us, in addition to, not in replacement of, the ability of the satellites to go around and check not only that spot but a lot of other spots around the world for us. It is the integration of strategic and tactical."[62]

Rear Admiral Thomas F. Hall addressed the question of why the SR-71 was retired, saying it was under "the belief that, given the time delay associated with mounting a mission, conducting a reconnaissance, retrieving the data, processing it, and getting it out to a field commander, that you had a problem in timeliness that was not going to meet the tactical requirements on the modern battlefield. And the determination was that if one could take advantage of technology and develop a system that could get that data back real time… that would be able to meet the unique requirements of the tactical commander." Hall stated that "the Advanced Airborne Reconnaissance System, which was going to be an unmanned UAV” would meet the requirements but was not affordable at the time. He said that they were “looking at alternative means of doing [the job of the SR-71]."[62]

Macke told the committee that they were “flying U-2s, RC-135s, [and] other strategic and tactical assets” to collect information in some areas.[62]

Senator Robert Byrd and other Senators complained that the “better than” successor to the SR-71 had yet to be developed at the cost of the "good enough" serviceable aircraft. They maintained that, in a time of constrained military budgets, designing, building, and testing an aircraft with the same capabilities as the SR-71 would be impossible.[58]

Congress' disappointment with the lack of a suitable replacement for the Blackbird was cited concerning whether to continue funding imaging sensors on the U-2. Congressional conferees stated the "experience with the SR-71 serves as a reminder of the pitfalls of failing to keep existing systems up-to-date and capable in the hope of acquiring other capabilities."[58]

It was agreed to add $100 million to the budget to return three SR-71s to service, but it was emphasized that this "would not prejudice support for long-endurance UAVs [such as the Global Hawk]." The funding was later cut to $72.5 million.[58] The Skunk Works was able to return the aircraft to service under budget, coming in at $72 million.[63]

Colonel Jay Murphy (USAF Retired) was made the Program Manager for Lockheed’s reactivation plans. Retired Air Force Colonels Don Emmons and Barry MacKean were put under government contract to remake the plane’s logistic and support structure. Still-active Air Force pilots and Reconnaissance Systems Officers (RSOs) who had worked with the aircraft were asked to volunteer to fly the reactivated planes. The aircraft was under the command and control of the 9th Reconnaissance Wing at Beale Air Force Base and flew out of a renovated hangar at Edwards Air Force Base. Modifications were made to provide a data-link with "near real-time" transmission of the Advanced Synthetic Aperture Radar's imagery to sites on the ground.[58]

Second retirement

The reactivation met much resistance: the Air Force had not budgeted for the aircraft, and UAV developers worried that their programs would suffer if money was shifted to support the SR-71s. Also, with the allocation requiring yearly reaffirmation by Congress, long-term planning for the SR-71 was difficult.[58] In 1996, the Air Force claimed that specific funding had not been authorized, and moved to ground the program. Congress reauthorized the funds, but, in October 1997, President Bill Clinton used the line-item veto to cancel the $39 million allocated for the SR-71. In June 1998, the Supreme Court of the United States ruled that the line-item veto was unconstitutional. All this left the SR-71's status uncertain until September 1998, when the Air Force called for the funds to be redistributed. The plane was permanently retired in 1998. The Air Force quickly disposed of their SR-71s, leaving NASA with the two last flyable Blackbirds until 1999.[64] All other Blackbirds have been moved to museums except for the two SR-71s and a few D-21 drones retained by the NASA Dryden Flight Research Center.[63]

SR-71 timeline

Important dates pulled from many sources.[65]

24 December 1957: First J58 engine run.

1 May 1960: Francis Gary Powers is shot down in a Lockheed U-2 over the Soviet Union.

13 June 1962: SR-71 mock-up reviewed by Air Force.

30 July 1962: J58 completes pre-flight testing.

28 December 1962: Lockheed signs contract to build six SR-71 aircraft.

25 July 1964: President Johnson makes public announcement of SR-71.

29 October 1964: SR-71 prototype (#61-7950) delivered to Palmdale.

7 December 1964: Beale AFB, CA announced as base for SR-71.

22 December 1964: First flight of the SR-71 with Lockheed test pilot Bob Gilliland at AF Plant #42.

21 July 1967: Jim Watkins and Dave Dempster fly first international sortie in SR-71A #61-7972 when the Astro-Inertial Navigation System ( ANS ) fails on a training mission and they accidentally fly into Mexican airspace.

3 November 1967: A-12 and SR-71 conduct a reconnaissance fly-off. Results were questionable.

5 February 1968: Lockheed ordered to destroy A-12, YF-12, and SR-71 tooling.

8 March 1968: First SR-71A (#61-7978) arrives at Kadena AB to replace A-12s.

21 March 1968: First SR-71 (#61-7976) operational mission flown from Kadena AB over Vietnam.

29 May 1968: CMSgt Bill Gornik begins the tie-cutting tradition of Habu crews neck-ties.

3 December 1975: First flight of SR-71A #61-7959 in "Big Tail" configuration.

20 April 1976: TDY operations started at RAF Mildenhall in SR-71A #17972.

27 July 1976 – 28 July 1976: SR-71A sets speed and altitude records (Altitude in Horizontal Flight: 85,068.997 ft (25,929.030 m) and Speed Over a Straight Course: 2,193.167 mph).

August 1980: Honeywell starts conversion of AFICS to DAFICS.

15 January 1982: SR-71B #61-7956 flies its 1,000th sortie.

21 April 1989: #974 was lost due to an engine explosion after taking off from Kadena AB. This was the last Blackbird to be lost, and was the first SR-71 accident in 17 years.[3][4]

22 November 1989: Air Force SR-71 program officially terminated.

21 January 1990: Last SR-71 (#61-7962) left Kadena AB.

26 January 1990: SR-71 is decommissioned at Beale AFB, CA.

6 March 1990: Last SR-71 flight under SENIOR CROWN program, setting four speed records enroute to Smithsonian Institution.

25 July 1991: SR-71B #61-7956/NASA #831 officially delivered to NASA Dryden.

October 1991: Marta Bohn-Meyer becomes first female SR-71 crew member.

28 September 1994: Congress votes to allocate $100 million for reactivation of three SR-71s.

26 April 1995: First reactivated SR-71A (#61-7971) makes its first flight after restoration by Lockheed.

28 June 1995: First reactivated SR-71 returns to Air Force as Detachment 2.

28 August 1995: Second reactivated SR-71A (#61-7967) makes first flight after restoration.

2 August 1997: A NASA SR-71 made multiple flybys at the EAA AirVenture Oshkosh air show. It was then supposed to perform a sonic boom at 53,000 feet (16,000 m) after a midair refueling, but a fuel flow problem caused it to divert to Milwaukee. Two weeks later, the pilot's flight path brought him over Oshkosh again, and there was, in fact, a sonic boom.

19 October 1997: The last flight of SR-71B #61-7956 at Edwards AFB Open House.

9 October 1999: The last flight of the SR-71 (#61-7980/NASA 844).

September 2002: Final resting places of #956, #971, and #980 are made known.

15 December 2003: SR-71 #972 goes on display at the Steven F. Udvar-Hazy Center in Chantilly, Virginia.


Records



File:SR71Robins2.JPG

#61-7958 on display in Kalamazoo Aviation History Museum, Portage, Michigan

The SR-71 was the world's fastest and highest-flying operational manned aircraft throughout its career. On 28 July 1976, SR-71 serial number 61-7962 broke the world record for its class: an "absolute altitude record" of 85,069 feet (25,929 m).[8][66][67][68] Several aircraft exceeded this altitude in zoom climbs but not in sustained flight.[69] That same day SR-71, serial number 61-7958 set an absolute speed record of 1,905.81 knots (2,193.2 mph; 3,529.6 km/h).[8][68]

The SR-71 also holds the "Speed Over a Recognized Course" record for flying from New York to London distance 5,645 kilometres (3,508 mi), 1,435.587 miles per hour (2,310.353 km/h), and an elapsed time of 1 hour 54 minutes and 56.4 seconds, set on 1 September 1974 while flown by U.S. Air Force Pilot Maj. James V. Sullivan and Maj. Noel F. Widdifield, reconnaissance systems officer (RSO).[70] This equates to an average velocity of about Mach 2.68, including deceleration for in-flight refueling. Peak speeds during this flight were probably closer to the declassified top speed of Mach 3.2+. For comparison, the best commercial Concorde flight time was 2 hours 52 minutes, and the Boeing 747 averages 6 hours 15 minutes.

In April 26, 1971 61-7968 flown by Majors Thomas B. Estes and Dewain C. Vick flew over 15,000 miles in 10 hrs. 30 min. This flight was awarded the 1971 Mackay Trophy for the "most meritorious flight of the year" and the 1972 Harmon Trophy for "most outstanding international achievement in the art/science of aeronautics".[71]


Pilot and RSO,

6 March 1990

Last SR-71 Senior Crown flight


File:Pilot-RSO last flight SR-71.jpg
When the SR-71 was retired in 1990, one Blackbird was flown from its birthplace at United States Air Force Plant 42 in Palmdale, California, to go on exhibit at what is now the Smithsonian Institution's Steven F. Udvar-Hazy Center in Chantilly, Virginia. On 6 March 1990, Lt. Col. Raymond "Ed" E. Yielding and Lt. Col. Joseph "Jt" T. Vida piloted SR-71 S/N 61-7972 on its final Senior Crown flight and set four new speed records in the process.

1.Los Angeles, CA to Washington, D.C., distance 2,299.7 miles (3,701.0 km), average speed 2,144.8 miles per hour (3,451.7 km/h), and an elapsed time of 64 minutes 20 seconds.[70]

2.West Coast to East Coast, distance 2,404 miles (3,869 km), average speed 2,124.5 miles per hour (3,419.1 km/h), and an elapsed time of 67 minutes 54 seconds.

3.Kansas City, Missouri to Washington D.C., distance 942 miles (1,516 km), average speed 2,176 miles per hour (3,502 km/h), and an elapsed time of 25 minutes 59 seconds.

4.St. Louis, Missouri to Cincinnati, Ohio, distance 311.4 miles (501.1 km), average speed 2,189.9 miles per hour (3,524.3 km/h), and an elapsed time of 8 minutes 32 seconds.



These four speed records were accepted by the National Aeronautic Association (NAA), the recognized body for aviation records in the United States.[72] After the Los Angeles–Washington flight, Senator John Glenn addressed the United States Senate, chastening the Department of Defense for not using the SR-71 to its full potential:  "Mr. President, the termination of the SR-71 was a grave mistake and could place our nation at a serious disadvantage in the event of a future crisis. Yesterday's historic transcontinental flight was a sad memorial to our short-sighted policy in strategic aerial reconnaissance."—Senator John Glenn, 7 March 1990[73]

Succession

Much speculation exists regarding a replacement for the SR-71, most notably aircraft identified as the Aurora. This is due to limitations of spy satellites, which are governed by the laws of orbital mechanics. It may take 24 hours before a satellite is in proper orbit to photograph a particular target, far longer than a reconnaissance plane. Spy planes can provide the most current intelligence information and collect it when lighting conditions are optimum. The fly-over orbit of spy satellites may also be predicted and can allow the enemy to hide assets when they know the satellite is above, a drawback spy planes lack. These factors have led many to doubt that the US has abandoned the concept of spy planes to complement reconnaissance satellites.[74] Unmanned aerial vehicles (UAVs) are also used for much aerial reconnaissance in the 2000s. They have the advantage of being able to overfly hostile territory without putting human pilots at risk.

Variants

The SR-71A was the main production variant. The SR-71B was a trainer variant.[75] Production of the SR-71 totaled 32 aircraft with 29 SR-71As, 2 SR-71Bs, and 1 SR-71C.[76]

The SR-71C was a hybrid aircraft composed of the rear fuselage of the first YF-12A (S/N 60-6934) and the forward fuselage from a SR-71 static test unit. This Blackbird was seemingly not quite straight and had a yaw at supersonic speeds.[77] It was nicknamed "The Bastard".[78] The YF-12 had been wrecked in a 1966 landing accident.

Flight simulator

The Link Simulator Company's SR-71 Flight Simulator was developed during 1963–1965 under a deep "black" security blanket because it and the team Link assigned to it were given access to CIA OXCART and USAF R-12 / SR-71 clearances, the complete list of names of classified vendors supplying parts and software that had to be simulated, the total aircraft performance envelope data and a government-produced satellite photo montage of almost the entire continental United States to provide optical imagery for the RSO's portion of the Flight Simulator. This later capability was mounted on a separate, large, rectangular glass plate (approximately 6 feet (1.8 m) by 12 feet (3.7 m) in size) over which moved an optical sighting head that traveled at the scaled speed and direction of the Blackbird during its simulated flight. Realistic and accurate images were then displayed in the Optical View Sight and SLR RCD (Radar Correlator Display) in the RSO cockpit. Imagery was not provided to the pilot's simulator, which like the RSO simulator, had translucent window panels with varying degrees of lighting to change a simulated flight from daylight to night flying conditions.[citation needed]

Instructor positions were behind both the pilot's and the RSO's cockpits, with monitoring, malfunction and emergency problem controls provided. The simulator halves could be flown as separate cockpits with different training agendas or in a team mode, where intercom, instrument readings and air vehicle/sub-systems performance were integrated. Although most simulator flights were in a flight suit "shirt sleeve" environment, selected flights during a crew's checkout training were made with the crew wearing the complete David Clark Company's Full Pressure Suit.[citation needed]

In 1965, when the first Beale AFB Instructor Pilot/RSO crew (in civilian attire) visited the Flight Simulator during USAF checkout and acceptance trials at Link's upstate New York facilities, they were surprised to park in front of a busy, active grocery store and then be escorted to a side door that led to a hidden, rear portion of the building that was Link's classified "Skunkworks" type facility for the Blackbird program. Secrecy was so complete that no one in the township was aware of what was happening behind the busy checkout stands selling groceries.[citation needed] Later in 1965, the Flight Simulator was transferred to Beale AFB, California and the 9th Strategic Reconnaissance Wing's SAGE building, which provided vault level security for it plus the Wing Headquarters, Flight Mission Planning, and Intelligence Analysis / Exploitation of Blackbird mission products.[citation needed]

Besides SR-71 flight crew training and currency usage, the Flight Simulator was used several times by Lockheed and CIA operatives to analyze Groom Lake A-12 problems and accidents, with similar assistance provided for SR-71 flights at Edwards AFB. Another unique feature was that an actual flight mission tape for the SR-71 ANS could be loaded into the Flight Simulator's digital computers, which had been designed and programmed by Link engineers to emulate the Nortronics ANS. During Category II testing at Edwards AFB, some types of ANS navigation errors could be duplicated in the Flight Simulator at Beale AFB, with Link engineers then often assisting in software fixes to the main ANS flight software programs.[citation needed]

At the conclusion of SR-71 flying at Beale AFB, the Flight Simulator (minus the RSO optical imagery system) was transferred to the NASA Dryden facility at Edwards AFB in support of NASA SR-71 flight operations. Upon completion of all USAF and NASA SR-71 operations at Edwards, the Flight Simulator was moved in July 2006 to the Frontiers of Flight Museum on Love Field Airport in Dallas, Texas[79] and, with support from the Museum and Link (now, L-3 Communications, Link Simulation and Training), it is intended for viewing by Museum visitors.

Specifications (SR-71A)

Data from SR-71.org,[80] Pace[81]

File:Lockheed SR-71A 3view.svg

General characteristics

Crew: 2

Payload: 3,500 lb (1,600 kg) of sensors

Length: 107 ft 5 in (32.74 m)

Wingspan: 55 ft 7 in (16.94 m)

Height: 18 ft 6 in (5.64 m)

Wing area: 1,800 ft2 (170 m2)

Empty weight: 67,500 lb (30,600 kg)

Loaded weight: 152,000 lb (69,000 kg)

Max takeoff weight: 172,000 lb (78,000 kg)

Powerplant: 2 × Pratt & Whitney J58-1 continuous-bleed afterburning turbojets, 34,000 lbf (151 kN) each

Wheel track: 16 ft 8 in (5.08 m)

Wheelbase: 37 ft 10 in (11.53 m)

Aspect ratio: 1.7



Performance

Maximum speed: Mach 3.3[81][82][83] (2,200+ mph, 3,530+ km/h, 1,900+ knots) at 80,000 ft (24,000 m)

Range: 2,900 nmi (5,400 km)

Ferry range: 3,200 nmi (5,925 km)

Service ceiling: 85,000 ft (25,900 m)

Rate of climb: 11,810 ft/min (60 m/s)

Wing loading: 84 lb/ft² (410 kg/m²)

Thrust/weight: 0.44


Accidents and aircraft disposition

In total, 32 SR-71s were built. Twelve SR-71s were lost and one pilot died in accidents during the aircraft's service career.[3][4]



File:Lockheed Sr-71.jpg

SR-71 at Pima Air & Space Museum, Tucson, Arizona



File:SR71 closeup.jpg

Close-up of the SR-71B operated by NASA’s Dryden Flight Research Center, Edwards, California

List of SR-71 Blackbirds


Serial number
Model
Location or fate


61-7950

SR-71A

Lost, 10 January 1967



61-7951

SR-71A

Pima Air & Space Museum, Tucson, Arizona



61-7952

SR-71A

Lost, 25 January 1966



61-7953

SR-71A

Lost, 18 December 1969[84]



61-7954

SR-71A

Lost, 11 April 1969



61-7955

SR-71A

Air Force Flight Test Center Museum, Edwards Air Force Base, California[85]



61-7956

SR-71B

Air Zoo, Kalamazoo, Michigan



61-7957

SR-71B

Lost, 11 January 1968




61-7958

SR-71A

Museum of Aviation, Warner Robins, Georgia




61-7959

SR-71A

Air Force Armament Museum, Eglin Air Force Base, Florida[86]



61-7960

SR-71A

Castle Air Museum, Atwater, California



61-7961

SR-71A

Kansas Cosmosphere and Space Center, Hutchinson, Kansas



61-7962

SR-71A

American Air Museum in Britain, Imperial War Museum Duxford, Cambridgeshire, England[87]



61-7963

SR-71A

Beale Air Force Base, Marysville, California



61-7964

SR-71A

Strategic Air and Space Museum, Ashland, Nebraska



61-7965

SR-71A

Lost, 25 October 1967



61-7966

SR-71A

Lost, 13 April 1967



61-7967

SR-71A

Barksdale Air Force Base, Bossier City, Louisiana



61-7968

SR-71A

Virginia Aviation Museum, Richmond, Virginia



61-7969

SR-71A

Lost, 10 May 1970



61-7970

SR-71A

Lost, 17 June 1970



61-7971

SR-71A

Evergreen Aviation Museum, McMinnville, Oregon



61-7972

SR-71A

Steven F. Udvar-Hazy Center, Washington Dulles International Airport, Chantilly, Virginia



61-7973

SR-71A

Blackbird Airpark, Palmdale, California



61-7974

SR-71A

Lost, 21 April 1989



61-7975

SR-71A

March Field Air Museum, Riverside, California[88]



61-7976

SR-71A

National Museum of the United States Air Force, Wright-Patterson Air Force Base, Dayton, Ohio



61-7977

SR-71A

Lost, 10 October 1968



61-7978

SR-71A

Lost, 20 July 1972[3]



61-7979

SR-71A

Lackland Air Force Base, San Antonio, Texas



61-7980

SR-71A

Dryden Flight Research Center, Edwards Air Force Base, California



61-7981
SR-71C
Hill Aerospace Museum, Hill Air Force Base, Ogden, Utah (formerly YF-12A 60-6934



References




Notes



1.^ See the opening fly page in Paul Crickmore's book SR-71, Secret Missions Exposed, which contains a copy of the original R-12 labeled plan view drawing of the vehicle.

2.^ Crickmore SR-71, Secret Missions Exposed, original R-12 labeled plan view drawing

3.^ See Blackbird with Canards image for visual.


Citations



1.^ "SR-71 Blackbird." lockheedmartin.com. Retrieved: 14 March 2010.

2.^ a b "SR71 Blackbird." PBS documentary, Aired: 15 November 2006.

3.^ a b c d Landis and Jenkins 2005, pp. 98, 100–101.

4.^ a b c Pace 2004, pp. 126–127.

5.^ a b Crickmore 1997, p. 64.

6.^ Landis and Jenkins 2005, p. 78.

7.^ Pace 2004, pp. 159.

8.^ a b c "Record." records.fai.org. Retrieved: 14 March 2010.

9.^ Rich and Janos 1994, p. 85.

10.^ McIninch 1996, p. 31.

11.^ a b c Robarge, David. "A Futile Fight for Survival. Archangel: CIA's Supersonic A-12 Reconnaissance Aircraft." CSI Publications, 27 June 2007. Retrieved: 13 April 2009.

12.^ a b Landis and Jenkins 2005, pp. 56–57.

13.^ McIninch 1996, p. 29.

14.^ McIninch 1996, pp. 14–15.

15.^ Non-Standard DOD Aircraft Designations

16.^ Merlin 2005, pp. 4–5.

17.^ Crickmore 2009, pp. 30–31.

18.^ "SR-71 manual, Air Inlet System." sr-71.org. Retrieved: 14 March 2010.

19.^ "Penn State- turbo ramjet engines." personal.psu.edu. Retrieved: 14 March 2010.

20.^ a b c d e f Johnson 1985

21.^ a b c Shul and O'Grady 1994

22.^ Crickmore 1997, pp. 42–43.

23.^ Landis and Jenkins 2005, p. 97.

24.^ Rich and Janos 1994, p. 221.

25.^ Landis and Jenkins 2005, p. 83.

26.^ Rich and Janos 1994, p. 203.

27.^ McIninch 1996, p. 5.

28.^ Rich and Janos 1994, p. 222.

29.^ Graham, 1996, p. 75

30.^ Rich and Janos 1994, p. 36.

31.^ Hott, Bartholomew and George E. Pollock. "The Advent, Evolution, and New Horizons of United States Stealth Aircraft." web.ics.purdue.edu. Retrieved: 5 May 2007.

32.^ "SR-71." GlobalSecurity.org. Retrieved: 14 March 2010.

33.^ "MiG-25 Foxbat". Retrieved 31 May 2011.

34.^ Suhler 2009, p. 100.

35.^ Suhler 2009, ch. 10.

36.^ AirPower May 2002, p. 36.

37.^ SR-71 Gallery

38.^ Goodall 2003, p. 19.

39.^ AirPower, May 2002, p. 33.

40.^ Popular Mechanics, June 1991, p. 28.

41.^ Donald 2003, p. 172.

42.^ "Blackbird manual." sr-71.org. Retrieved: 14 March 2010.

43.^ "Aerostories." aerostories.free.fr. Retrieved: 14 March 2010.

44.^ "SR-71." yarchive.net. Retrieved: 14 March 2010.

45.^ Colville, Jesse R. Axisymmetric Inlet Design for Combined Cycle Engines. Digital Repository at the University of Maryland, 1993.

46.^ Landis and Jenkins 2005, pp. 95–96.

47.^ a b c d Crickmore 1997, p. 74.

48.^ Crickmore 1997, p. 563.

49.^ Crickmore 1997, p. 77.

50.^ "SR-71 History." pacificcoastairmuseum.org. Retrieved: 14 March 2010.

51.^ Crickmore 1997, pp. 56, 58.

52.^ Crickmore 1997, p. 59.

53.^ a b Crickmore 1997, pp. 62–64.

54.^ Flyghistorisk Revy – System 37 Viggen, Stockholm: Svensk Flyghistorisk Förening, 2009, ISSN 0345-3413

55.^ Mach 14, vol 4, no 3, 1983, p. 5. ISSN 0280-8498.

56.^ Mach 25, vol 7, no 2, 1986, pp. 28–29. ISSN 0280-8498.

57.^ Darwal 2004, pp. 151–156.

58.^ a b c d e f Graham 1996

59.^ Crickmore 1997, pp. 84–85.

60.^ Crickmore 1997, p. 81.

61.^ a b Remak 2001

62.^ a b c "Department of Defense Authorization for Appropriations for Fiscal Year 1994 and The Future Years." United States Senate, May–June 1993.

63.^ a b Jenkins 2001

64.^ "NASA/DFRC SR-71 Blackbird." NASA. Retrieved: 16 August 2007.

65.^ "SR-71." sr-71.org. Retrieved: 14 March 2010.

66.^ Landis and Jenkins 2005, pp. 77–78.

67.^ Altitude record

68.^ a b A-12, YF-12A, & SR-71 Timeline of Events

69.^ "Records." records.fai.org. Retrieved: 14 March 2010.

70.^ a b "Blackbird Records." sr-71.org. Retrieved: 18 October 2009.

71.^ "1966 Lockheed SR-71". Retrieved 14 Feb 2011.

72.^ National Aeronautic Association

73.^ SR-71 Revealed: The Inside Story

74.^ Siuru, William D. and John D. Busick. Future Flight: The Next Generation of Aircraft Technology. Blue Ridge Summit, Pennsylvania: TAB Books, 1994. ISBN 0-8306-7415-2.

75.^ Landis and Jenkins 2005, pp. 56–58.

76.^ Merlin 2005, p. 6.

77.^ Landis and Jenkins 2005, p. 62.

78.^ Merlin 2005, p. 4.

79.^ "Frontiers of Flight Museum." flightmuseum.com. Retrieved: 14 March 2010.

80.^ "Lockheed SR-71 Blackbird page." sr-71.org. Retrieved: 14 March 2010.

81.^ a b Pace 2004, p. 110.

82.^ Graham 1996, p. 48.

83.^ Maximum speed limit was Mach 3.2, but could be raised to Mach 3.3 if the engine compressor inlet temperature did not exceed 801 F (427 C). (Graham 2002, pp. 93, 223)

84.^ SR-71 #953 crash. check-six.com

85.^ SR-71A Blackbird Air Force Flight Center Museum. Retrieved: 10 February 2009.

86.^ Exhibits. Air Force Armament Museum. Retrieved: 10 February 2009.

87.^ "Aircraft On Display: Lockheed SR-71A Blackbird." The American Air Museum, Imperial War Museum. Retrieved: 10 February 2009.

88.^ "Aircraft: Lockheed SR-71A Blackbird." March Field Air Museum. Retrieved: 10 February 2009.

89.^ "U-2 / A-12 / YF-12A / SR-71 BLACKBIRD & RB-57D – WB-57F LOCATIONS". Retrieved 22 January 2010.



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Additional sources



Brandt, Steven A., Randall J. Stiles and John J. Bertin. Introduction to Aeronautics: A Design Perspective. Reston, VA: American Institute of Aeronautics & Astronautics, 2004, pp. 141–150. ISBN 1-56347-701-7.

Brown, Kevin V. "America's SuperSecret Spy Plane." Popular Mechanics, June 1968, pp. 59–62, 190.

Clarkson, Jeremy. I Know You Got Soul. Penguin Books Limited, 2006. ISBN 0-14-102292-2.

Crickmore, Paul F. Lockheed Blackbird: Beyond the Secret Missions. London: Osprey Publishing, 2004. ISBN 1-84176-694-1.

Crickmore, Paul and Jim Laurier. Lockheed SR-71 Operations in the Far East. London: Osprey Publishing, 2008. ISBN 1-84603-319-5.

Graham, Richard H. SR-71 Revealed: The Inside Story. Osceola, WI: Motorbooks International, 1996. ISBN 0-7603-0122-0.

Merlin, Peter. Mach 3+: NASA USAF YF-12 Flight Research 1969–1979. Washington, D.C.: Diane Publishing Co., NASA History Division Office, 2002. ISBN 1-4289-9458-0.

Periscope Film Com. Sr-71 Blackbird Pilot's Flight Manual. Lulu.com, 2006. ISBN 1-4116-9937-8.

Reithmaier, Lawrence W. Mach 1 and Beyond. New York: McGraw-Hill, 1994, pp. 220–237. ISBN 0-07-052021-6.

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