Daily Archives: December 1, 2024

1 December 1984

NASA 833, a remotely-piloted Boeing 720 airliner, pulls up after a practice approach to the impact point on Rogers Dry Lake. The "X" is the planned touchdown point. The "rhino" barriers are at the runway threshold. (NASA)
NASA 833, a remotely-piloted Boeing 720 airliner, pulls up after a practice approach to the impact point on Rogers Dry Lake. The “X” is the planned touchdown point. The “rhino” barriers are at the runway threshold. (NASA)

After four years of planning and preparation, the National Aeronautics and Space Administration (NASA) and the Federal Aviation Administration (FAA) intentionally crashed a Boeing 720 airliner to test an experimental fuel additive intended to reduce post-crash fires, and to assess passenger survivability. An anti-misting agent was added to standard commercial JP-5 jet fuel to create AMK, or “Anti-Misting Kerosene.” The airliner’s fuel tanks were filled with the AMK mixture, totaling 16,060 gallons (10,794 liters). Instrumented crash test dummies were placed in the passengers seats.

Passengers relaxing before a flight aboard NASA’s Boeing 720, N833NA. (NASA ECN-28307)

NASA 833, the Boeing 720-027 airliner, FAA registration N833NA, was a remotely-piloted aircraft. NASA test pilot Fitzhugh Lee (“Fitz”) Fulton, Jr., flew NASA 833 from a ground station, the NASA Dryden Remotely Controlled Vehicle Facility. More than 60 flights had been made prior to the actual test.

Fitz Fulton in the CID.
Fitz Fulton in the NASA Dryden Remotely Controlled Vehicle Facility

The test was planned so that the airliner would make a shallow 3.8° approach to a prepared runway on the east side of Rogers Dry Lake at Edwards Air Force Base. It was to land on its belly in a wings-level attitude, then slide into a group of barriers, called “rhinos,” which would slice open the wing tanks. The fuselage and passenger cabin would remain intact. NASA and the FAA estimated that this would be “survivable” for all occupants.

Just before touchdown, the Boeing 720 entered a "Dutch roll." The airliner's nose yawed to the left and the left wing dipped, striking the ground sooner than was planned. All four engines are still at full throttle. NASA 833 is to the right of the runway center line. (NASA)
Just before touchdown, the Boeing 720 entered a “Dutch roll.” The airliner’s nose yawed to the left and the left wing dipped, striking the ground sooner than was planned. All four engines are still at full throttle. NASA 833 is to the right of the runway center line. (NASA)

As the Boeing 720 descended on its Final Approach, its nose yawed to the right and the airplane went to the right of the runway center line. It then yawed back to the left and entered an out-of-phase oscillation called a “Dutch roll.” The decision height to initiate a “go-around” was 150 feet (45.7 meters) above the surface of the lake bed. Fitz Fulton thought he had enough time to get NASA 833 back on the center line and committed to the test landing. However, the Dutch roll resulted in the airliner’s left wing impacting the ground with the inboard engine on the left wing (Number Two) just to the right of the center line.

NASA 833 slews left as it approaches the test apparatus. The Boeing 720 has reached the intended touchdown point but is out of position, still to the right of center line and misaligned. (NASA)
NASA 833 slews left as it approaches the test apparatus. The Boeing 720 has reached the intended touchdown point but is out of position, still to the right of center line and misaligned. (NASA)

According to the test plan, all four of the airliner’s engines should have been brought to idle, but they remained at full throttle. The left wing’s impact yawed the airliner to the left and, rather than the fuselage passing through the rhino barriers undamaged, the passenger compartment was torn open. Another rhino sliced into the Number Three engine (inboard, right wing), opening its combustion chamber. With the fuel tanks in the wings ruptured, raw fuel was sprayed into the engine’s open combustion chamber which was still at full throttle.

As the airliner slides through the "rhino" barriers, they rip open the fuel tanks, the Number Three engine and the passenger compartment. The raw fuel immediately ignited. (NASA)
As the airliner slides through the “rhino” barriers, they rip open the fuel tanks, the Number Three engine and the passenger compartment. The raw fuel immediately ignited. (NASA)

The raw fuel ignited and exploded into a fireball. Flames immediately entered the passenger compartment. As the 720 slid on the runway it continued to rotate left and the right wing broke off though the fuselage remained upright.

NASA 833's right wing breaks off, rupturing the fuel tanks. Nearly 8,000 gallons (30,000 liters) of jet fuel pours out into the fireball. (NASA)
NASA 833’s right wing breaks off, rupturing the fuel tanks. Nearly 8,000 gallons (30,000 liters) of jet fuel pours out into the fireball. (NASA)

As the right wing came off the ruptured fuel tanks emptied most of the raw fuel directly into the fireball.

The flaming wreckage of NASA 833 slides to a stop on Rogers Dry Lake. Fire fighters needed more than one hour to extinguish the fire. (NASA)
The flaming wreckage of NASA 833 slides to a stop on Rogers Dry Lake. Fire fighters needed more than one hour to extinguish the fire. (NASA)

Over an hour was required to extinguish the flames. The test of the flame-reducing fuel additive was a complete failure. Test engineers estimated that 25% of the occupants might have survived the crash, however, it was “highly speculative” that any could have escaped from the burning, smoke-filled passenger compartment.

Fithugh L. "Fitz" Fulton, Jr. (NASA)
Fitzhugh Lee “Fitz” Fulton, Jr., with NASA 905, a Shuttle Carrier Aircraft, and Enterprise (OV-101). (NASA)
Fitz Fulton, 1942 (The Cohiscan)

Fitzhugh Lee Fulton, Jr., was born at Blakely, Georgia, 6 June 1925, the first of two sons of Fitzhugh Lee Fulton, a merchant seaman, and Manila Fulton. He attended Columbus High School, Columbus Georgia, graduating in 1942. He entered College at Alabama Polytechnic Institute (now known as Auburn University) and the University of Oklahoma. He was awarded a bachelor of arts degree from Golden Gate University, San Francisco, California.

Fulton entered the U.S. Army Air Corps in 1943, and was trained as a pilot. He married Miss Erma I. Beck at Tucson, Arizona, 16 December 1945. They would have three children.

Following World War II, participated in Operation Crossroads, the atomic bomb tests at Bikini Atoll, July 1946. Lieutenant Fulton flew the Douglas C-54 Skymaster four-engine transport during the Berlin Airlift, making 225 sorties, and then the Douglas B-26 Invader light attack bomber during the Korean War.

Captain Fitz Fulton, U.S. Air Force, in teh cockpit of a Douglas B-26 Invader, circa 1952. (Air & Space Magazine)
Captain Fitz Fulton, U.S. Air Force, in the cockpit of a Douglas B-26 Invader, circa 1952. (Air & Space Magazine)

Fulton graduated from the Air Force Test Pilot School in 1952. He served as project test pilot for the Convair B-58 Hustler supersonic bomber and flew the B-58 to a World Record Altitude of 26,017.93 meters (85,360.66 feet) on 14 September 1962.¹

Major Fitz Fulton in the cockpit of a Convair B-58. (Jet Pilot Overseas)
Major Fitz Fulton in the cockpit of a Convair B-58. (Jet Pilot Overseas)

At Edwards Air Force Base, he flew the B-52 “mother ships” for the X-15 Program. He flew the North American XB-70A Valkyrie faster than Mach 3. When Fulton retired from the Air Force in 1966, he was a lieutenant colonel assigned as Chief of Bomber and Transport Test Operations.

Fitz Fulton continued as a research test pilot for NASA, flying as project pilot for the YF-12A and YF-12C research program. He flew all the early test flights of the NASA/Boeing 747 Shuttle Carrier Aircraft and carried the space shuttle prototype, Enterprise. By the time he had retired from NASA, Fulton had flown more than 16,000 hours in 235 aircraft types.

Fitzhugh L. Fulton, Jr., died at Thousand Oaks, California, 4 February 2015, at the age of 89 years..

Lieutenant Colonel Fitzhugh Lee Fulton, Jr., with a North American Aviation XB-70A Valkyrie.
Colonel Joseph Frederick Cotton and Lieutenant Colonel Fitzhugh Lee Fulton, Jr., with a North American Aviation XB-70A Valkyrie.

NASA 833 (c/n 18066) was ordered by Braniff Airways, Inc., as N7078, but the sale was not completed. The airplane first flew 5 May 1961 and it was delivered to the Federal Aviation Administration as a test aircraft one week later, 12 May 1961, registered N113. A few years later the identification was changed to N23, then back to N113, and then once again to N23. In 1982, the Boeing 720 was transferred to NASA to be used in the Controlled Impact Demonstration. At this time it was registered as N2697V. A final registration change was made to N833NA.

NASA 833 at Edwards Air Force Base, prior to the Controlled Impact Demonstration. (Paul)

The Boeing 720 was a variant of the Model 707, intended for short to medium range flights. It had 100 inches (2.54 meters) removed from the fuselage length and improvements were made to the wing, decreasing aerodynamic drag, though it retained the span of the 707.

The Boeing 720 was powered by four Pratt & Whitney Turbo Wasp JT3C-7 turbojet engines, a civil variant of the military J57 series. The 720B was equipped with the more efficient P&W JT3D-1 turbofan engines. The JT3C-7 was a “two-spool” axial-flow engine with a 16-stage compressor (9 low- and 7 high-pressure stages), 8 combustion tubes, and a 3-stage turbine (1 high- and 2 low-pressure stages). It was rated at 12,030 pounds of thrust (53.512 kilonewtons) for takeoff. The JT3D-1 was a dual axial-flow turbofan engine, with a 2-stage fan section 13-stage compressor (6 low- and 7 high pressure stages), 8 combustion chambers and a 4-stage turbine (1 high- and 3 low-pressure stages). This engine was rated at 14,500 pounds of static thrust (64.499 kilonewtons) at Sea Level, and 17,000 pounds (75.620 kilonewtons), with water injection, for takeoff (2½ minute limit). Almost half of the engine’s thrust was produced by the fans. Maximum engine speed was 6,800 r.p.m. (N1) and 10,200 r.p.m. (N2). It was 11 feet, 4.64 inches (3.471 meters) long, 4 feet, 5.00 inches (1.346 meters) wide and 4 feet, 10.00 inches (1.422 meters) high. It weighed 4,165 pounds (1,889 kilograms). The JT3C could be converted to the JT3D configuration during overhaul.

The maximum cruise speed of the Boeing 720 was 611 miles per hour (983 kilometers per hour) and maximum speed was 620 miles per hour (1,009 kilometers per hour). The range at at maximum payload was 4,370 miles (7,033 kilometers).

Boeing built 154 720 and 720B airliners from 1959 to 1967.

The Federal Aviation Administration's Boeing 720-027 N113. (FAA)
The Federal Aviation Administration’s Boeing 720-027 N113. (FAA)

¹ FAI Record File Numbers 14652 and 14656

© 2018, Bryan R. Swopes

1909: De Havilland No. 1

De Havilland No. 1 at Seven Barrows, Hampshire, 1909. (BAE Systems)

History has forgotten the actual date—perhaps because he was no one of  any importance at the time—but one day in the Fall or Winter of 1909, Geoffrey de Havilland, an automotive engineer, took off from Seven Barrows, Hampshire, England, in an airplane of his own design. Today, that airplane is known as the de Havilland No. 1.

De Havilland had borrowed £1,000 from his grandfather, and together with fellow engineer Francis Trounson Hearle, built an airplane.

The de Havilland No. 1 was a single-engine, single-place, three-bay biplane in a pusher configuration. It had a forward elevator (canard), and an aft-mounted rudder and adjustable horizontal stabilizer. Ailerons were mounted on the upper wing.

The structure of the airplane was built of American white wood (which proved to be a poor choice) and was braced with steel wires. The fuselage was an open girder tapered at each end. It was built of 1½″ × 1½″ (3.81 × 3.81 centimeters) longitudinals with 1¼″ × ¼″ (3.175 × 0.635 centimeter) cross braces from the engine aft. It had a cross section at the widest point of 2′4″ x 2′0″ (0.711 × 0.610 meters). The lower longitudinals were reinforced with angled steel beneath the engine

The de Havilland was 29 feet, 0 inches (8.839 meters) long with a wingspan of 36 feet, 0 inches (10.973 meters). Both wings had a chord of 6 feet, 0 inches (1.829 meters) and the vertical gap was also 6 feet, 0 inches. The wings were not staggered. The airplane weighed 850 pounds ( kilograms).

Three-view illustration of the de Havilland No. 1. (FLIGHT, 9 April 1910, Page 267)

The DH.1 was powered by a single water-cooled, normally-aspirated, 302.18 cu in (4.95 liters) de Havilland-Iris four-cylinder horizontally-opposed overhead valve engine, designed by Geoffrey de Havilland and built by the Iris Motor Co., Willesden, London. The engine produced 40 horsepower at 1,050 r.p.m., and 52 horsepower at 1,500 r.p.m. In running condition, it weighed 230 pounds (104 kilograms) including a 30 pound (14 kilogram) flywheel. The de Havilland-Iris used cast iron cylinders with a copper water jacket. The two-throw crankshaft was prone to failures after a only few hours of operation.

The engine was mounted in the airframe with its crankshaft at a right angle to the direction of flight. It drove two 7 foot, 4 inch (2.235 meter) diameter counter-rotating propellers made of aluminum. The paddle-type blades could be adjusted for pitch before flight. Tubular shafts drove through 90° bevel gears and turned the propellers at 550–600 r.p.m.

De Havilland 302 cubic inch (4.95 liter) 45-horsepower four-cylinder horizontally-opposed aircraft engine. (FLIGHT)
Cross section of de Havilland-Iris four-cylinder engine. (FLIGHT)

And it should be added that the past tense has advisably been used in the foregoing paragraph, inasmuch as the first free flight of the machine terminated in almost complete wreckage. The first time that it left the ground it did so after travelling some 40 yards on a downward slope under its own power; it then rose at a rather steep angle, which was corrected by the pilot; and almost immediately afterwards—about 35 yards from the take-off—the left main plane doubled up, causing the machine to fall heavily forward and to the left. Luckily, Mr. de Havilland himself was not hurt, but it will be observed from some of the photographs which we reproduce that the machine as such, apart from the propelling mechanism, the rudder, and the tail, was, for all practical purposes, virtually annihilated by the fall.

FLIGHT, No. 67 (Vol. II, No. 15), 9 April 1910, Page 266, Column 1

(Flight No. 68, Vol. II, No. 16, 16 April 1910, Page 286)

The airplane’s engine was salvaged and reused in de Havilland No. 2.

Geoffrey de Havilland, O.B.E., A.F.C., photographed 2 January 1920 by Bassano Ltd. (© National Portrait Gallery, London)

© 2019, Bryan R. Swopes