17 August 1951: In order to demonstrate the capabilities of the United States Air Force’s new day fighter, Colonel Fred J. Ascani, Vice Commander, Air Force Flight Test Center, Edwards Air Force Base, California, had been assigned to take two new North American Aviation F-86E Sabres from the production line at El Segundo, California, to the National Air Races at Detroit, Michigan. He was to attempt a new world speed record.
Colonel Ascani selected F-86E-10-NA 51-2721 and 51-2724. They received bright orange paint to the forward fuselage and the top of the vertical fin. Bold numbers 2 and 4 were painted on their sides.
North American Aviation F-86E-10-NA Sabre 51-2721. (FAI)Colonel Fred J. Ascani with the Thompson Trophy, 1951. (AP)
Flying Number 2, F-86E 51-2721, Fred Ascani flew a 100-kilometer closed circuit at an average speed of 1,023.04 kilometers per hour (635.69 miles per hour), and set a new Fédération Aéronautique Internationale (FAI) World Record for Speed Over a Closed Circuit of 100 Kilometers.¹
For his accomplishment, Colonel Ascani was awarded both the Thompson Trophy and the Mackay Trophy.
The North American Aviation F-86 was a single-seat, single-engine day fighter designed by Edgar Schmued and the same team at North American that designed the World War II P-51 Mustang fighter. The Sabre was the first fighter to incorporate swept wings, which improved flight at high subsonic speed by reducing aerodynamic drag and delaying the onset of compressibility effects. The leading edges of the wings and tail surfaces were swept 35° based on captured German technical data and extensive wind tunnel testing.
North American Aviation F-86E-10-NA Sabre 51-2721. (U.S. Air Force)
The F-86E Sabre was an improved F-86A. The most significant change was the incorporation of an “all flying tailplane” in which the entire horizontal tail moved to control the airplane’s pitch. The tailplane pivoted around its rear spar, allowing the leading edge to move up or down 8°. The elevators were mechanically linked to the tailplane and their movement was proportional to the tailplane’s movement. Control was hydraulic, and this provided improved handling at high speeds where compressibility could “freeze” control surfaces. There were systems improvements as well, with “artificial feel” to the hydraulic controls to improve feedback to the pilot and prevent over-controlling. Beginning with Block 10 aircraft, the “V”-shaped windscreen of the earlier models was replaced with an optically flat laminated glass windshield.
Fred Ascani in the cockpit of North American Aviation F-86E-10-NA Sabre 51-2724. (U.S. Air Force)
The F-86E was 37 feet, 6.5 inches (11.443 meters) long with a wingspan of 37 feet, 1.4 inches (11.313 meters) and overall height of 14 feet, 1 inch (4.293 meters). Its empty weight was 10,555 pounds (4,787.7 kilograms) and the maximum takeoff weight was 16,436 pounds (7,455.2 kilograms).
The F-86E was powered by a General Electric J47-GE-13 turbojet engine. The J47 was an axial-flow turbojet with a 12-stage compressor and single stage turbine. The J47-GE-13 was rated at 5,200 pounds of thrust and 6,000 pounds (“wet”). The engine was 12 feet, 0.0 inches (3.658 meters) long, 3 feet, 3.0 inches (0.991 meters) in diameter and weighed 2,525 pounds ( kilograms).
The F-86E Sabre had a maximum speed of 679 miles per hour (1,092.7 kilometers per hour) at Sea Level and 601 miles per hour (967.2 kilometers per hour) at 35,000 feet (10,668 meters). Its service ceiling was 47,200 feet (14,386.7 meters).
The F-86E carried 437 gallons (1,654.2 liters) of fuel internally and could carry two 200-gallon (757.1 liter) drop tanks under the wings. Maximum range was 1,022 miles (1,645 kilometers).
The F-86A, E and F Sabres were armed with six Browning AN-M3 .50-caliber aircraft machine guns with 1,602 rounds of ammunition.
6,233 F-86 Sabres were built by North American at Inglewood, California and Columbus Ohio. Another 521 were assembled by Fiat and Mitsubishi. 1,815 CL-13 Sabres were built by Canadair, and 115 CA-26 and CA-27 Sabres by Commonwealth Aircraft Corporation in Australia. Total production for all types and manufacturers was 8,684. North American Aviation built 336 F-86Es and 60 more were built by Canadair (F-86E-6-CAN).
In order to emphasize that Colonel Ascani’s record-setting Sabre was a standard production airplane, it was immediately sent into combat with the 25th Fighter Interceptor Squadron, 51st Fighter Interceptor Wing, at Suwon Air Base, Korea. There, it was christened THIS’LL KILL YA. On 3 May 1953, 51-2721 was damaged during a landing accident at Kimpo Air Base, but it was repaired and returned to service.
A group of Allied pilots stand with the FAI World Speed Record holder, North American Aviation F-86E-10-NA Sabre 51-2721, at Suwon Air Base, Korea, circa 1952. Its pilot, Lieutenant Jack L. Price, has named it THIS’LL KILL YA.
William Barton Bridgeman (Boris Artzybasheff/TIME Magazine)
15 August 1951: Just 8 days after he set an unofficial world speed record of Mach 1.88 (1,245 miles per hour; 2,033.63 kilometers per hour), Douglas Aircraft Company test pilot William Barton (“Bill”) Bridgeman flew the rocket-powered United States Navy/National Advisory Committee on Aeronautics (NACA) Douglas D-558-II Skyrocket, Bu. No. 37974, to a world record altitude at Edwards Air Force Base in the high desert of Southern California.
The Skyrocket was airdropped at 34,000 feet (10,363 meters) from a highly-modified U.S. Navy P2B-1S Superfortress, Bu. No. 84029. The mother ship was a U.S. Air Force Boeing B-29-95-BW Superfortress, 45-21787, transferred to the Navy and flown by another Douglas test pilot, George R. Jansen.
Douglas D-558-II Skyrocket, Bu. No., 37974, NACA 144, is dropped from the Boeing P2B-1S Superfortress, Bu. No. 84029, NACA 137. (NASA)
The flight plan was for Bridgeman to fire the rocket engine and allow the Skyrocket to accelerate to 0.85 Mach while climbing. The Skyrocket was powered by a Reaction Motors LR8-RM-6 engine, which produced 6,000 pounds of thrust. As the rocketplane continued to accelerate to Mach 1.12, the test pilot was to pull up, increasing the angle of climb while holding an acceleration rate of 1.2 Gs. This would result in a constantly increasing angle of climb. When it reached 50°, Bridgeman was to maintain that, climbing and accelerating, until the rocket engine ran out of fuel.
Initially, the plan was to continue climbing after engine shutdown until the D-558-II was approaching stall at the highest altitude it could reach while on a ballistic trajectory. There were differing expert opinions as to how it would behave in the ever thinner atmosphere. On the morning of the flight, Douglas’ Chief Engineer, Ed Heinemann, ordered that Bridgeman push over immediately when the engine stopped.
Bill Bridgeman stuck to the engineers’ flight plan. As the Skyrocket accelerated through 63,000 feet (19,200 meters), it started to roll to the left. He countered with aileron input, but control was diminishing in the thin air. The next time it began there was no response to the ailerons. Bridgeman found that he had to lower the Skyrocket’s nose until it responded, then he was able to increase the pitch angle again. At 70,000 feet (21,336 meters), travelling Mach 1.4, he decided he had to decrease the pitch angle or lose control. Finally at 76,000 feet (23,165 meters), the engine stopped. Following Heinemann’s order, Bridgeman pushed the nose down and the D-558-II went over the top of its arc at just 0.5 G.
Bill Bridgeman. (Unattributed)
“In the arc she picks up a couple of thousand feet. The altimeter stops its steady reeling and swings sickly around 80,000 feet. The altitude is too extreme for the instrument to function.
“Eighty thousand feet. It is intensely bright outside; the contrast of the dark shadows in the cockpit is extreme and strange. It is so dark lower in the cockpit that I cannot read the instruments sunk low on the panel. The dials on top, in the light, are vividly apparent. There seems to be no reflection. It is all black or white, apparent or non-apparent. No half-tones. It is a pure, immaculate world here.
“She levels off silently. I roll right and there it is. Out of the tiny windows slits there is the earth, wiped clean of civilization, a vast relief map with papier-mâché mountains and mirrored lakes and seas. . . .
“It is as if I am the only living thing connected to this totally strange, uninhabited planet 15 miles below me. The plane that carries me and I are one and alone.”
—The Lonely Sky,William Bridgeman with Jacqueline Hazard, Castle and Company LTD, London, 1956, Chapter XXII at Page 268.
After the data was analyzed, it was determined that William Bridgeman and the Douglas Skyrocket had climbed to 79,494 feet (24,230 meters), higher than any man had gone before. This was the last flight that would be made with a Douglas test pilot. The rocketplane was turned over to NACA, which would assign it the number NACA 144.
A Douglas D-558-II Skyrocket, Bu. No. 37974, glides back toward Rogers Dry Lake at Edwards Air Force Base. A North American Aviation F-86E-1-NA Sabre, 50-606, flies chase. Lieutenant Colonel Frank K. “Pete” Everest and Major Charles E. “Chuck” Yeager frequently flew as chase pilots for both Bill Bridgeman and Scott Crossfield. (NASA)
Bill Bridgeman had been a Naval Aviator during World War II, flying the Consolidated PBY Catalina and PB4Y (B-24) Liberator long range bombers with Bombing Squadron 109 (VB-109), “The Reluctant Raiders.” Bridgeman stayed in the Navy for two years after the war, then he flew for Trans-Pacific Air Lines in the Hawaiian Islands and Pacific Southwest Airlines in San Francisco, before joining Douglas Aircraft Co. as a production test pilot, testing new AD Skyraiders as they came off the assembly line at El Segundo, California. He soon was asked to take over test flying the D-558-2 Skyrocket test program at Muroc Air Force Base.
The D-558-II Skyrocket was Phase II of a planned three phase experimental flight program. It was designed to investigate flight in the transonic and supersonic range. It was 46 feet, 9 inches (14.249 meters) long with a 25 foot (7.62 meter) wing span. The wings were swept back to a 35° angle. The Skyrocket was powered by a Westinghouse J34-WE-40 11-stage axial-flow turbojet engine, producing 3,000 pounds of thrust, and a Reaction Motors LR8-RM-6 four-chamber rocket engine, which produced 6,000 pounds of thrust. The rocket engine burned alcohol and liquid oxygen.
There were three D-558-2 Skyrockets. Between 4 February 1948 and 28 August 1956, they made a total of 313 flights. Bill Bridgeman’s speed and altitude record-setting Skyrocket, Bu. No. 37974, NACA 144, is in the collection of the Smithsonian Institution National Air and Space Museum.
Douglas D-558-2 Skyrocket, Bu. No. 37974, NACA 144. (NASA)
Commonwealth Aircraft Corporation CA-26 Sabre A94-101 (Royal Australian Air Force)
14 August 1953: Near Avalon Field, Geelong, Victoria, Australia, Flight Lieutenant William H. Scott, Royal Australian Air Force, the 28-year-old Chief Test Pilot of the Government Aircraft Factories, put the new Commonwealth Aircraft Corporation, Pty. Ltd., prototype into shallow dive from 25,000 feet (7,620 meters) over Port Phillip Bay. This was the new airplane’s sixth test flight. Scott passed 670 miles per hour (1,078 kilometers per hour) and broke the “sound barrier.” A triple sonic boom was heard throughout the Melbourne area.
The aircraft was the CA-26 Sabre, A94-101. The Australian-built Sabre had made its first flight 1 August, also with Flt. Lt. Scott in the cockpit. After about a week there were reports of sonic booms in the area around Melbourne.
Commonwealth Aircraft Corporation CA-26 Sabre A94-101 (Royal Australian Air Force)
Based on the highly successful North American Aviation F-86F Sabre, the C.A.C. variant used a license-built Rolls-Royce Avon RA.7 turbojet with 7,350 pounds of thrust. The Sabre’s fuselage had to be extensively redesigned to allow installation of the new engine. Although it was about the same size as the J47 it replaced, the Avon needed a much larger intake duct. And because it weighed less than the J47, it had to be moved aft to maintain the Sabre’s center of gravity. Only about 40% of the original structure remained.
Other changes were replacing the fighter’s basic armament of six .50-caliber Browning machine guns with two 30 mm ADEN revolver cannon. In testing, it was found that the muzzle blast of the ADEN cannons could cause the engine to flame out. “Maxim” shock wave baffles were installed to eliminate the problem.
Commonwealth Aircraft Corporation CA-26 Sabre A94-901. (Royal Australian Air Force)
The aircraft, often called the “Avon Sabre,” was put into production as the CA-27 Sabre Mk 30. Twenty-two aircraft were built in the version. With the introduction of the Mark 31, the original Sabres were upgraded to the new standard. Sixty-nine Sabre Mk 32 fighters were built with the Avon 25 engine and increased fuel capacity.
The CA-27 was in service with the Royal Australian Service from 1954 until 1971. Several were transferred to Malaysia and Indonesia and operated for those countries until 1982.
The prototype CA-26 Sabre, A94-901, flew with several RAAF squadrons, including the 76 Squadron “Black Panthers” Aerobatic Team, 1961–1965. It was withdrawn from service in 1966. The Sabre was restored by Hawker de Havilland at Bankstown Airport, before being sent to the Historical Aircraft Restoration Society Museum (“HARS”) at Illawarra Regional Airport, south of Sydney, New South Wales, Australia. The airplane is again in the livery of the “Black Panthers.”
A94-901 as it appeared when assigned to 76 Squadron “Black Panthers,” 1961–1965. (HARS Museum)
14 August 1931: The Tupolev ANT-14 made its first flight, piloted by famed Russian aviator Mikhail Mikhaylovich Gromov (Михаил Михайлович Громов). It was the largest aircraft of its time, and was capable of carrying up to 32 passengers on long-distance flights.
The ANT-14 was designed by a team led by Andrei Nikolayevich Tupolev. It was an all-metal high-wing monoplane with fixed landing gear. The wings and fuselage were covered in corrugated duralumin. The design of the aircraft took three months. This was possible as components of earlier Tupolev aircraft were included in the new aircraft. Tupolev paid special attention to the safety and comfort of the passengers, using features from railroad passenger cars.
The flight crew consisted of two pilots and a navigator. Two flight attendants were in the passenger cabin. Seating was arranged in nine rows of four seats, with a central aisle.
The ANT-14 was 26.49 meters (86.91 feet) long with a wingspan of 40.40 meters (132.55 feet and height of 5.02 meters (16.47 feet). The total wing area was 240.00 square meters (2,583.34 square feet). The transport’s empty weight was 10,828 kilograms (23,872 pounds) and its gross weight was 17,530 kilograms (38,647 pounds). The wings contained four fuel tanks with a capacity of 2,000 kilograms of gasoline (about 2,650 liters, or 700 gallons).
A.N. Tupolev ANT-14, Pravda. (LiveInternet)
The ANT-14 was powered by five engines, with one mounted at the nose, and two on each wing. They were air-cooled, supercharged 28.628 liter (1,746.991 cubic inch displacement) Établissements Gnome et Rhône Jupiter 9 Akx nine-cylinder radial engines with a compression ratio of 5.15:1, a licensed version of the British Bristol Aeroplane Company’s Jupiter VI engine. The Gnome-Rhône 9 Akx produced 476 chaval vapeur (470 horsepower) at 1,870 r.p.m., and drove two-bladed fixed-pitch propellers through gear reduction. The direct-drive Gnome-Rhône 9 Ak variant weighed 301 kilograms (664 pounds).
(Gnome-Rhône had a production facility in St. Petersburg. In 1928, Wladimir Klimov purchased 200 Jupiter 9 engines, and a license to produce them. The Soviet version of the Jupiter 9 was designated Shvetsov M-22. It is not known whether the ANT-14’s engines were built by Gnome-Rhône or Shvetsov.)
The ANT-14 had a maximum speed of 195 kilometers per hour (121 miles per hour) at low altitude, and 236 kilometers per hour (147 miles per hour) at high altitude. Its cruising speed was 204 kilometers per hour (127 miles per hour). The airplane’s service ceiling was 4,220 meters (13.845 feet), and its range was 400 kilometers (249 miles).
Andrei Tupolev, 1937
Designer Tupolev was pleased with the new airplane, saying, “Look, he is handsome, and in the plane the external form is the most important part.”
Aeroflot (Аэрофлот), the Soviet airline, tested the aircraft in 1932 but as they had no need for an airplane so big, none were ordered. The single ANT-14 was then named Pravda (Правда—”Truth”) and used as a propaganda tool for the Communist government. It was flown for ten years and during that time, carried more than 40,000 passengers.
Tupolev ANT-14, CCCP-N1001. (Авиация)
Mikhail Mikhaylovich Gromov was born 24 February 1899, at Tver, about 110 miles (180 kilometers) northwest of Moscow. He was the son of Mikhail Konstantinovich Gromov, an “intellectual” who had studied medicine at Moscow University, and Lyubov Ignayevna Gromov, a midwife. The family were of the nobility, but poor.
Mikhail M. Gromov, circa 1917.
The younger Gromov attended the Resurrection Real School, and then the Moscow Higher Technical School for Aviation. He graduated in 1917. Gromov was taught to fly by Boris Konstantinovich Welling, a pioneer in Russian long-distance flights. After working as a flight instructor, Gromov began test flying. He became the chief test pilot for the Tupolev Design Bureau. By the outbreak of World War II, he had test flown twenty-five different airplanes.
In 1926, Gromov made a non-stop long-distance flight in a Tupolev ANT-3, from Moscow via Berlin, Paris, Rome, Vienna, Prague, Warsaw and back to Moscow. The flight took 34 hours. In 1934, he flew a Tupolev ANT-25 12,411 kilometers (7,712 miles) in a closed circuit over 75 hours. For this accomplishment, he was named a Hero of the Soviet Union.
From 12–14 July 1937, Gromov set a world record for distance in a straight line, flying an ANT-25 from Moscow to San Jacinto, California, a distance of 10,148 kilometers (6,306 miles).¹ The duration of this flight was 62 hours, 17 minutes.
Lieutenant Colonel Mikhail Mikhaylovich Gromov, c. 1939.
In March 1941, Gromov became the first director of the Flight Research Institute at Zhukovsky, southeast of Moscow. The Institute was later named the M.M. Gromov Flight Research Institute, in his honor.
In 1942, during The Great Patriotic War, Gromov commanded the Soviet long range air forces on the Kalinin Front. He next commanded the 3rd Air Army, 1942–1943, and the 1st Air Army, 1943–1944. In 1945, he returned to test flying.
Following the War, Gromov continued to work in the aviation industry, but following a disagreement with the Minister of Aviation, Pyotr Vasilyevich Dementiev, over the issue of quality vs. quantity and the safety of the test pilots, he retired. Later, he entered politics and was twice elected to the Supreme Soviet.
During his military career, in addition to the Gold Star Medal of Hero of the Soviet Union, Colonel General Mikhail Mikhaylovich Gromov was awarded the Order of Lenin four times, the Order of the Red Banner (four), and the Order of the Red Star (three). He died 22 January 1985.
Colonel-General Mikhail Mikhaylovich Gromov, Hero of the Soviet Union.
The prototype Bell 222 hovering in ground effect during its first flight, 13 August 1976. (Bell Helicopter TEXTRON)
13 August 1976: At the Bell Helicopter facility at Arlington, Texas, the prototype Model 222 twin-engine helicopter, registration N9988K, made its first flight. During the 42-minute flight, test pilots Donald Lee Bloom and Louis William Hartwig flew the aircraft through a series of hovering maneuvers and transitions to forward flight. A Bell spokesperson described it as, “One of the most successful prototype flights we’ve ever had.”
The prototype Bell 222 in flight with landing gear retracted, 13 August 1976. (Bell Helicopter TEXTRON)
The Model 222 (“Two Twenty-Two”) was Bell Helicopter’s first completely new helicopter since the Model 206 JetRanger series. Classified as a light twin, the aircraft was originally powered by two Lycoming LTS101-650C-3 turboshaft engines. The two-blade main rotor was similar in design to that used on the AH-1 Cobra attack helicopters. The first four prototypes were built with a T-tail configuration, but problems discovered early in the test program resulted in a change to the arrangement used in the production version.
Bell Model 222 prototype, N9988K, in flight. Note T-tail configuration. (Bell Helicopter TEXTRON)
The Bell 222 is used as an executive transport, a utility transport and an aeromedical helicopter. It can carry a maximum of ten persons, and is operated with either one or two pilots. The 222 is certified for Instrument Flight Rules. The standard aircraft has retractable tricycle landing gear but the Model 222UT replaces that with a lighter weight skid gear.
The Bell Model 222 is 47 feet, 6.16 inches (14.482 meters) long with rotors turning. The helicopter has a maximum height of 14 feet, 7.25 inches (4.451 meters) with the forward main rotor blade against its droop stop. The height from ground level to the top of the vertical fin is 11 feet, 0.56 inches (3.367 meters). The helicopter’s maximum width is 11 feet, 4.0 inches (3.454 meters). The empty weight is 4,555 pounds (2,066 kilograms), and the maximum gross weight is 7,848 pounds (3,560 kilograms).
The fifth prototype Bell 222, N222BX (c/n 47005), in the 40′ × 80′ (12.2 × 24.4 meters) wind tunnel at the NASA Ames Research Center, Moffett Field, California. The man at the lower left corner of the image shows scale. (NASA)
The 222’s main rotor mast is tilted 5° forward and 1° 15′ to the left. This contributes to a higher forward air speed and counteracts the helicopter’s translating tendency in a hover.
The two-bladed, underslung, semi-rigid main rotor system rotates counter-clockwise as seen from above (the advancing blade is on the right.)and turns 324 r.p.m at 100% NR. The main rotor has a diameter of 39 feet, 9.0 inches (12.116 meters). The blades have a chord of 2 feet, 4.6 inches (7.264 meters) and are pre-coned 3° 30′. The two-bladed tail rotor is positioned on the left side of the tail boom and turns clockwise as seen from the helicopter’s left (the advancing blade is below the axis of rotation). The tail rotor’s diameter is 6 feet, 6.0 inches (1.981 meters). The blades’ chord is 10.0 inches (0.254 meters).
The Bell 222 was originally powered by two Lycoming LTS101-650C-3 engines. The LTS101 is a compact, light weight, turboshaft engine. The 2-stage compressor section has 1 axial-flow stage and 1 centrifugal-flow stage. The turbine section has 1 high-pressure gas generator stage and 1 low-pressure free power stage. The LTS101-650C-3 was has a maximum continuous power rating of 598 shaft horsepower (446 kilowatts at 49,159 r.p.m. (N1) at Sea Level, and 630 shaft horsepower (470 kilowatts) at 49,638 r.p.m. for takeoff (5-minute limit). The output shaft (N2) turns 9,545 r.p.m. With one engine inoperative (OEI), the -650C-3 is rated at 650 shaft horsepower (485 kilowatts) at 50,169 r.p.m. (30-minute limit), and a maximum 675 shaft horsepower at 50,548 r.p.m. N1/9,784 r.p.m. N2 (2½-minute limit). The LTS101-650C-3 is 1 foot, 10.6 inches (0.574 meters) in diameter, 2 feet,7.3 inches (0.795 meters) long, and has a dry weight of 241 pounds (109 kilograms).
The Bell 222 has a maximum speed of 130 knots. Its hover ceiling is approximately 9,000 feet (2,743 meters). The service ceiling is 12,800 feet (3,901 meters). The maximum range is 324 nautical miles (373 statute miles/600 kilometers).
During early production, problems were experienced with the LTS101 engines, which were also used on the Sikorsky S-76 and the Aérospatiale AS-350D A-Star. This seriously hurt the reputation and sales of all three helicopters. Bell Helicopter’s parent corporation, Textron, bought the Lycoming factory and modernized it in order to improve the engine. (The engine is now owned by Honeywell Aerospace.) Operators began to replace the two Lycoming engines with a pair of Allison 250-C30 turboshafts, and eventually Bell Helicopter modified the aircraft, marketing it as the Model 230. A four-bladed variant with a longer cabin is called the Model 430.
After the test program was completed, the first prototype, N9988K, was used as a static prop on the popular television series, “Airwolf.”
Bell 222 N34NR, an aeromedical helicopter operated by Air Angels, Inc., Bolingbrooke, Illinois. (Photograph courtesy of Chris Hargreaves)Donald Lee Bloom
Donald Lee Bloom was born in Tulsa, Oklahoma, 23 April 1932. He was the son of Fred Miles Bloom, a telegraph operator for the Standard Oil Company, and Georgia Randolph Bloom.
Don Bloom attended the University of Houston as a Naval Reserve Officers Training Corps (NROTC) midshipman. He graduated in 1955. Bloom was commissioned as a second lieutenant, United States Marine Corps, 15 September 1955. He was assigned to pilot training at NAS Pensacola, Florida.
Lieutenant Bloom was promoted to the rank of first lieutenant, 15 March 1957. He married Miss Anne Marie Carruthers in Los Angeles, California, 5 September 1958. They would have four children, Susan, Stacy, Robert and Todd.
Lieutenant Bloom was released from active duty in 1960, and joined the Kaman Aircraft Corporation as a test pilot. In 1961, began his 29-year career as an experimental test pilot with the Bell Helicopter Company.
The first production Bell OH-58A-BF Kiowa, 68-16687. Don Bloom flight-tested this type in his investigation of Loss of Tail Rotor Effectiveness. (U.S. Army)
In 1984 the Society of Experimental Test Pilots gave its Iven C. Kincheloe Award to Don Bloom for his experimental research into the Loss of Tail Rotor Effectiveness (LTE).
After flying as a test pilot on 187 projects, Don Bloom retired from the Bell Helicopter Corporation in 1990 as Senior Experimental Test Pilot. He then worked for the Federal Aviation Administration Southwest Region as its Designated Engineering Representative Flight Test Pilot, testing aircraft for government certification. During his aviation career, Bloom flew over 14,000 hours in 102 different aircraft.
In 2011, the Federal Aviation Administration presented its Wright Brothers Master Pilot Award to Don Bloom.
Donald Lee Bloom died 18 July 2017 at Grapevine, Texas. He was buried at the Dallas-Fort Worth National Cemetery, Dallas, Texas.
Don Bloom was a project development test pilot for the Bell AH-1G Cobra. (U.S. Army)
Louis William Hartwig was born at Sherman, Iowa, 26 July 1922. He was the son of Lawrence C. Harwig and Alta May Gaughey Hartwig. He attended Bowie High Schoo in Bowie, Texas.
Lou Hartwig enlisted in the United States Army 8 September 1942. (s/n 17119277) He was assigned to the 304th and 902nd Field Artillery Battalions, 77th Infantry Division.
Lou Hartwig married Miss Katherine Elizabeth Healzer, a school teacher, at Rustburg, Virginia, 19 February 1944. They would have a son, Ronald.
Piper L-4 Grasshopper. (Harry S. Truman Library & Museum)
Hartwig was deployed to the Pacific theater of operations, 24 March 1944. He flew a Piper L-4 Grasshopper as an artillery spotter at Guam and Okinawa. He was discharged from his enlistment 18 June 1944, and commissioned a second lieutenant, 19 June 1944 (s/n O-1821011). Lieutenant Hartwig returned to the United States on 21 November 1945. He was released from active duty 24 January 1946.
Lou Hartwig was one of the early students of the Bell Aircraft Corporation’s helicopter flight school at Niagara Falls Airport, New York. The school was for experienced pilots only, and required 10–15 days to complete. Each student received a minimum 22½ flight hours in a Bell Model 47. The cost of the course was $600. Hartwig was then employed as an agriculture “crop dusting” pilot in California.
While spraying insecticide in a field near Sacramento, California, Hartwig was overcome by the poisonous chemicals and lost consciousness. The helicopter struck power lines and crashed. Hartwig was thrown from the cockpit. Crash investigators described the accident as “unsurvivable.” He spent the next 11 months in hospital.
Lou Hartwig was a test pilot for the U.S. Navy’s Bell HSL-1 ASW helicopter. (Bell Aircraft Corporation)
The Bell Helicopter Company hired Hartwig as a test pilot on 15 February 1955. One of his first projects was flight testing the Model 61, the only tandem rotor helicopter ever produced by Bell. It was used as an anti-submarine warfare helicopter by the U.S. Navy, designated HSL-1.
On 31 January 1961, Hartwig set a Fédération Aéronautique Internationale (FAI) World Record for Speed Over a Closed Circuit of 100 Kilometers Without Payload, when he flew a Bell Model 47J Ranger at an average speed of 168.36 kilometer per hour (104.61 miles per hour).¹
On 2 February 1961, Lou Hartwig flew a Bell Model 47G, N967B, to set three more FAI world records: Distance in a Closed Circuit Without Landing, 1,016.20 kilometers (631.44 miles); ² Speed Over a Closed Circuit of 500 Kilometers Without Payload, averaging 119.07 kilometers per hour (73.99 miles per hour); ³ and Speed Over a Closed Circuit of 1,000 Kilometers, 118.06 kilometers per hour (73.36 miles per hour.⁴ The Model 47G had been modified with an additional fuel tank from the earlier Model 47D-1, and curved landing skids from the Model 47J.
The Bell 533, 56-6723, in one of its many configurations. It was flown with two- and four-bladed main rotors, with and without wings, and with and without turbojet engines. (Bell Helicopter Corporation)
Lou Hartwig worked on the U.S. Army’s High Performance Helicopter project. A pre-production YH-40 Iroquois, serial number 56-6723, was modified into a winged and compound helicopter configuration, designated Model 533. Hartwig flew the helicopter to a speed of 274.6 knots (316.00 statute miles per hour/508.56 kilometers per hour). In 1971, the Vertical Flight Society gave its Frederick L. Feinberg Award to Hartwig.
Mrs. Hartwig died 10 February 1989, in San Diego, California. Lou Hartwig married his second wife, Joanne Dunning, in 1990.
Louis William Hartwig died 12 April 2016, at the age of 93 years. He was buried at the Dearborn Memorial Park, Poway, California.
