Category Archives: Aviation

13 September 1931

Aviation, , , , , , , , , , , , , , , , ,
Supermarine S.6B S.1595 at the London Science Museum. (sciencemuseum.org.uk)

13 September 1931: Having won the previous two Coupe d’Aviation Maritime Jacques Schneider international seaplane races, the United Kingdom was in the position of permanently winning the famous Schneider Trophy if it were to win a third consecutive race.

The 1931 race was the twelfth in a series of annual or semiannual races which were first held in 1913, specifically for seaplanes. Teams from several nations, France, Great Britain, Italy and the United States, competed with float-equipped airplanes built specifically for the races. The national team which won three consecutive races would win the series and take home the Trophy. Italy had won three times (1920, 1921, and 1926); the United States, twice (1923, 1925); and France, one time (1913). The United Kingdom had previously won in 1922, 1927 and 1929.

Royal Air Force High-Speed Flight, 1931. (Unattributed)

Having won the race in 1929, Great Britain was the host nation for 1931. Like the 1929 race, the 1931 race was held over The Solent, a body of water between the harbor city of Portsmouth, England, and the Isle of Wight. Instead of the four-sided polygon used previously, the 1931 race course was a triangle of 50 kilometers (31.07 statute miles). Competitors would make seven circuits of the course, with all left-hand turns, for a total distance of 350 kilometers (217.48 statute miles).

Competitors would fly seven counter-clockwise laps of the 50-kilometer triangular race course (FLIGHT)

Italy had been developing the Macchi-Castoldi M.C. 72 with its 3,100-horsepower, 24-cylinder Fiat AS.6 engine, but the airplane was not ready by the required date. The United States was unwilling to invest the required money and had not entered since the 1927 race. France also was not prepared to compete. Both France and Italy formally announced their intention not to compete on 4 September 1931.

This meant that only a single British airplane was required to complete the race course to win the race and permanent possession of the trophy. Three airplanes were ready, one Supermarine S.6 and two new S.6Bs.

Three racing aircraft of the Royal Air Force High-Speed Flight at RAF Calshot for the 1931 Schneider Trophy Race. Left to right, #7, Supermarine S.6B S.1596; #4, Supermarine S.6 N.248; and #1, Supermarine S.6B S.1595. (FLIGHT)

Postponed because of rain and fog on the previous day, the 1931 race started at 1:02:10 p.m., Sunday, 13 September, with the firing of the starting gun from HMS Medea. Flight-Lieutenant John Nelson Boothman, Royal Air Force, in a blue and silver Supermarine S.6B, number S.1565, taxied across the start line at 1:10:19 p.m.

Race rules required that competitors take off, circle and land on the water. They were then required to taxi on the water for two minutes, before taking off a second time to begin the officially timed race laps. Observers reported that Flight-Lieutenant Boothman’s performance of the preliminary test was flawless. He taxied into position for his second takeoff and was airborne with a 40 second run.

Flight-Lieutenant John N. Boothman (FLIGHT)

Boothman’s lap times were:

Lap 1: 552.15 kilometers per hour (343.1 miles per hour)

Lap 2: 551.5 kilometers per hour (342.7 miles per hour)

Lap 3: 547.1 kilometers per hour (340.0 miles per hour)

Lap 4: 544.5 kilometers per hour (338.3 miles per hour)

Lap 5: 546.5 kilometers per hour (339.6 miles per hour)

Lap 6: 546.1 kilometers per hour (339.4 miles per hour)

Lap 7: 543.5 kilometers per hour (337.7 miles per hour)

Overall average speed: 547.3 kilometers per hour (340.08 miles per hour)

Air Ministry,

9th October, 1931.

ROYAL AIR FORCE.

     The KING has been graciously pleased to approve of the award of the Air Force Cross to the undermentioned officers of the Royal Air Force:—

Flight Lieutenant John Nelson Boothman.

In recognition of his achievement in winning the Schneider Trophy Contest, 1931.

Supermarine S.6B, S.1596. (BAE Systems)

S.1595 was Vickers-Supermarine S.6B Monoplane, designed by Reginald Joseph Mitchell, who would later design the legendary Supermarine Spitfire fighter of World War II. The racer was developed from Mitchell’s earlier S.4, S.5 and S.6 Schneider Cup racers, and was built at the Supermarine Aviation Works (Vickers), Ltd., Southampton, on the south coast of England. There were two S.6Bs, with the second identified as S.1596.

Cutaway illustration of the Supermarine S.6B. (George Horace Davis)

The Supermarine S.6B was a single-place, single-engine, low-wing monoplane with two fixed pontoons as an undercarriage. It was of all-metal construction and used a high percentage of duralumin, a very hard alloy of aluminum and copper, as well as other elements. The float plane was 28 feet, 10 inches (8.788 meters) long, with a wingspan of 30 feet, 0 inches (9.144 meters) and height of 12 feet, 3 inches (3.734 meters). The wing area was 145 square feet (13,5 square meters). The S.6B had an empty weight of 4,560 pounds (2,068 kilograms) and gross weight of 5,995 pounds (2,719 kilograms).

Supermarine S.6B S.1596 (BAE Systems)

In an effort to achieve the maximum possible speed, aerodynamic drag was eliminated wherever possible. There were no radiator or oil cooler intakes. The wing surfaces were constructed of two thin layers of duralumin with a very small space between them. The engine coolant, a mixture of water and ethylene glycol, was circulated between these layers, which are known as surface radiators. The engine had a high oil consumption rate and the vertical fin was the oil supply tank. The skin panels also served as surface radiators. The fuselage panels were corrugated for strength, and several small parallel passages transferred lubricating oil from the fin tank to the engine, and further cooled the oil.

Supermarine S.6B S.1596 (BAE Systems)

S.1595 was powered by a liquid-cooled, supercharged, 2,239.327-cubic-inch-displacement (36.696 liter) Rolls-Royce Type R single-overhead-camshaft (SOHC) 60° V-12 engine, number R29. The Type R was a racing engine with 4 valves per cylinder and a compression ration of 6:1. In the 1931 configuration, it produced 2,350 horsepower at 3,200 r.p.m. It used a 0.605:1 reduction gear and turned a Fairey Aviation fixed-pitch airscrew with a diameter of 8 feet, 6 inches (2.591 meters). A special fuel, a mixture of benzol, methanol and acetone with TCP anti-detonation additive, was used.

Lucy, Lady Houston, with the Royal Air Force High-Speed Flight, 1931. R.J. Mitchell, designer of the S-series racers, is standing at right. (Royal Air Force Museum)

There would have been no 1931 British Schneider Trophy Race team without the generous contribution of Lucy, Lady Houston, D.B.E., who donated £100,000 to Supermarine to finance the new aircraft. Lady Houston would later sponsor the 1933 Houston Mount Everest Flying Expedition.

The winning aircraft, S.1595, is in the collection of the Science Museum, London.

Supermarine S.6B S.1596 (BAE Systems)

John Nelson Boothman was born at Harrow, northwest London, England, 19 February 1901. He was the son of Thomas John Boothman, a railway clerk, and Mary Burgess Boothman. He  became interested in aviation while very young, and took his first flight at the age of 10, as a passenger of Samuel Franklin Cody, the first pilot to fly a powered airplane in England.

Boothman was educated at Harrow High School. In 1918, when he was 16 years old, Boothman volunteered as a driver with the Croix-Rouge française (French Red Cross), serving in the Balkans until World War I came to an end. He was awarded the Croix de Guerre.

On his return to England, he took flying lessons and joined the Royal Air Force. He received a short-service commission as a Pilot Officer (probationary), 29 March 1921. He trained at No. 1 Flight Training School. He then joined No. 4 Squadron at Constantinople. On 22 March 1922, Boothman was confirmed in the rank of Pilot Officer. He was promoted to Flying Officer 29 September 1922.

Also in 1922, Pilot Officer Boothman married Miss Gertrude Andrews. They would have one son.

Flying Officer Boothman returned to England in 1924 and was assigned as a flight instructor at the Central Flying School. He was also a member of an aerial demonstration team.

After five years of service, on 1 January 1926 Boothman’s commission as a Flying Officer, Royal Air Force, was made permanent. He returned to the Middle East, joining No. 55 Squadron in Iraq, 21 September 1926. This was a bombing squadron, equipped with the de havilland DH-9A. Boothman was promoted to Flight-Lieutenant 1 July 1927. He served with the Air Staff before going on to No. 30 Squadron, which also flew DH-9As, as a flight commander, 24 February 1928.

Flight-Lieutenant John Nelson Boothman, Royal Air Force.

Flight-Lieutenant Boothman was assigned as a test pilot at the Marine Aircraft Experimental Establishment, Felixstowe, Suffolk, 10 February 1930. On 11 May 1931, he became a member of the High-Speed Flight at RAF Calshot.

After winning the Schneider Trophy Race, on 3 October 1931, Flight-Lieutenant Boothman was assigned as a flight commander with No. 22 Squadron, a test squadron supporting the Aeroplane Experimental Establishment at RAF Martlesham Heath. During 1932, he became seriously ill and was removed from duty for several months. He returned to duty 13 August 1932 as a test pilot in the Experimental Section at RAE Farnborough. He then served as Chief Flying Instructor, Central Flying School.

Flight-Lieutenant Boothman attended the Royal Air Force Staff College in 1935. He was promoted to the rank of Squadron Leader, 1 December 1935. From 4 January 1936, he was assigned to Air Staff, Headquarters, Coastal Command. On 26 March 1937, Squadron Leader Boothman was assigned to Air Staff, Headquarters, Royal Air Force, Far East.

Boothman was promoted to Wing Commander, 1 January 1939. In September he was placed in command of No. 44 Squadron at RAF Waddington in Lincolnshire. This was a light bomber squadron which flew Bristol Blenheims and Handley Page Hampdens.

During the early stages of World War II, Wing Commander Boothman was assigned to Air Staff—Directorate of Operations (Home), and Air Staff, Headquarters, Bomber Command. He returned to RAF Waddington in March 1940 as the station’s commanding officer. He was promoted to Group Captain (temporary), 1 March 1941, then sent to the United States as an adviser to the U.S. Army Air Forces. Boothman returned to England as commanding officer of RAF Finningley, South Yorkshire.

On 6 June 1943, Group Captain Boothman was promoted to the rank of Acting Air Commodore, and assigned as Air Officer Commanding, No. 106 Wing. The wing controlled all photographic reconnaissance units in the United Kingdom. In 1 December 1943, Air Commodore Boothman’s rank was changed from Acting to Temporary.

In July 1944 Air Commodore Boothman was assigned as Commandant, Aeroplane and Armament Experimental Establishment (A. & A.E.E.) at RAF Boscombe Down, Wiltshire. In the King’s Birthday Honours, 1944, Air Commodore Boothman was invested Companion of the Most Honourable Order of the Bath, Military Division (C.B.).

On 2 July 1945, was promoted to Acting Air Vice Marshal and appointed Assistant Chief of Air Staff (Technical Requirements). On 9 October 1945, The U.S. Army Air Forces awarded him the the medal of Commander, Legion of Merit.

Air Vice Marshal John Nelson Boothman D.F.C., A.F.C., Royal Air Force, is presented the Legion of Merit by General Carl A. Spaatz, United States Army Air Forces. (Smithsonian Institution)

Air Vice Marshal Boothman once again returned to Iraq in 1948 as Air Officer Commanding, Air Headquarters, Iraq.

On 4 September 1950, he was promoted to Acting Air Marshal, and Controller of Supply (Air), Ministry of Supply. On 15 November 1953, Air Marshal Boothman became Commander in Chief, Coastal Command and Commander in Chief (Air) Eastern Atlantic Area.

In the King’s Birthday Honours list, 7 June 1951, Air Marshal Boothman, C.B., D.F.C., A.F.C., was promoted to Knight Commander of the Military Division of the Most Excellent Order of the British Empire (K.B.E.).

In the Queen’s Birthday Honours, June 1954, Air Marshal Sir John Boothman, K.B.E., D.F.C., A.F.C., was invested Knight Commander of the Most Honourable Order of the Bath (K.C.B.).

On 1 October 1954, Sir John was promoted to the rank of Air Chief Marshal. He retired from the Royal Air Force in 1956.

Air Chief Marshal Sir John Nelson Boothman, K.C.B., K.B.E., D.F.C., A.F.C., Royal Air Force, died 29 December 1957 at the age of 57 years.

Air Vice Marshal Sir John Nelson Boothman, 1946. (Photographed by Walter Stoneman)

© 2018, Bryan R. Swopes

12 September 1966, 14:42:26.546 UTC

Aviation, , ,
Gemini XI lifts off from Launch Complex 19 at the Cape Canaveral Air Force Station, (Great Images of NASA, GPN-2000-001020)

12 September 1966: At 14:42:26.546 UTC (9:42:26 a.m., Eastern Standard Time), Gemini XI was launched by a Titan II GLV from Launch Complex 19, Cape Canaveral Air Force Station. On board were NASA astronauts Charles (“Pete”) Conrad, Jr., Command pilot, on his second space flight; and Richard Francis Gordon, Jr., Pilot.

Richard Francis Gordon, Jr., Pilot, and Charles (“Pete”) Conrad Jr., Command Pilot, Gemini XI. (NASA S65-58504)

Earlier that morning, at 13:05:01.725 UTC (8:05:01 EST), a Gemini Agena Target Vehicle, GATV 5006, had been launched by an Atlas Agena D rocket from Launch Complex 14 and placed in a near circular orbit. Its perigee was 156.43 nautical miles (289.70 kilometers) and apogee, 165.82 nautical miles (307.10 kilometers). It completed an orbit in 1 hour, 30 minutes, 33.6 seconds.

Agena Target Vehicle 11 is launched by an Atlas Agena D from Launch Complex 14, Cape Canaveral Air Force Station. (NASA S66-50784)

Gemini XI made a direct first orbit rendezvous with the Agena Target Vehicle. Five maneuvers were required to match orbits, and rendezvous occurred at 11:07 a.m., and docking at 11:16 a.m. Each astronaut practiced two docking exercises. At 2:14:14 p.m., a maneuver placed the combined spacecraft into a 178.02 mile (154.70 nautical mile/286.50 kilometer) × 189.08 mile (164.31 nautical mile/304.30 kilometer)  orbit with a period of 1 hour, 30 minutes, 25.2 seconds.

At 9:51 a.m.,13 September, Gordon exited the Gemini capsule to begin a Extra Vehicluar Activity (“EVA”). He recovered a micrometeorite detector and was to detach one end of a 30 meter (98.43 feet) tether from the Agena and attach it to the Gemini. The effort proved exhausting and Gordon’s space suit life support system was unable to control the heat. Perspiration fogged Gordon’s faceplate and obscured his vision. He stopped to rest. Conrad ordered him to return to the Gemini, which he did at 10:12 a.m.

On 14 September at 2:12:41 EST, the Agena engine was fired to raise the combined vehicles into a 853.8 mile (741.9 nautical mile/1,374.10 kilometer) × 180.01 mile (156.43 nautical mile/289.70 kilometer) elliptical orbit. The orbital period increased to 101.52 minutes. After two orbits, the Agena engine was fired again to lower the spacecraft back down to a 178.02 mile × 178.02 mile (154.70 nautical mile/286.50 kilometer) × 189.08 (164.31 nautical mile/304.30 kilometer) orbit.

Dick Gordon standing in the open hatch of Gemini XI. (NASA S66-54653)

Gordon opened his hatch to begin a “standup” EVA at 7:49 a.m., 14 September. He took photographs and conducted various experiments. This EVA period lasted 2 hours, 8 minutes.

The Gemini Agena Target Vehicle photographed by Dick Gordon from Gemini XI. The tether connecting the two spacecraft is visible. (NASA)

The two spacecraft separated and Gemini XI moved to the end of the tether. Conrad began a slow rotation around the Agena, keeping the tether taut. The circular motion created “artificial gravity.” After about three hours, the tether was released. The spacecraft moved apart, and another rendezvous was performed.

Gemini XI’s retrorockets were fired at 8:24:03 a.m. EST, 15 September, and reentry began. It splashed down in the western Atlantic Ocean at N. 24.25, W. 70.00, at 8:59:35 EST, just 3.04 miles (4.9 kilometers) from the target point. Gemini XI had completed 44 orbits. Total duration of the mission was 2 days, 23 hours, 17 minutes, 9 seconds. The recovery vessel was the Iwo Jima-class amphibious assault ship USS Guam (LPH-9).

USS Guam (LPH-9), February 1965. (U.S. Navy)

GATV 11 decayed 30 September 1966.

Artist’s concept of Gemini spacecraft, 3 January 1962. (NASA-S-65-893)

The two-man Gemini spacecraft was built by the McDonnell Aircraft Corporation of St. Louis, Missouri, the same company that built the earlier Mercury space capsule. The spacecraft consisted of a reentry module and an adapter section. It had an overall length of 19 feet (5.791 meters) and a diameter of 10 feet (3.048 meters) at the base of the adapter section. The reentry module was 11 feet (3.353 meters) long with a diameter of 7.5 feet (2.347 meters). The weight of the Gemini varied from ship to ship.

Titan II GLV, (NASA Gemini V Mission Report, Figure 3.1-1, at Page 3–11)

The Titan II GLV was a “man-rated” variant of the Martin SM-68B intercontinental ballistic missile. It was assembled at Martin’s Middle River, Maryland plant so as not to interfere with the production of the ICBM at Denver, Colorado. Twelve GLVs were ordered by the Air Force for the Gemini Program.

The Titan II GLV was a two-stage, liquid-fueled rocket. The first stage was 63 feet (19.202 meters) long with a diameter of 10 feet (3.048 meters). The second stage was 27 feet (8.230 meters) long, with the same diameter. The 1st stage was powered by an Aerojet Engineering Corporation LR-87-7 engine which combined two combustion chambers and exhaust nozzles with a single turbopump unit. The engine was fueled by a hypergolic combination of hydrazine and nitrogen tetroxide. Ignition occurred spontaneously as the two components were combined in the combustion chambers. The LR-87-7 produced 430,000 pounds of thrust. It was not throttled and could not be shut down and restarted. The 2nd stage used an Aerojet LR-91 engine which produced 100,000 pounds of thrust.

© 2024, Bryan R. Swopes

12 September 1934

Aviation, , , , , , , , , , ,
Gloster SS.37 G7, prototype Gloster Gladiator
The Gloster G.37, prototype of the Gloster Gladiator Mk.I (Gloster Aircraft Co., Ltd.)

12 September 1934: Hawker Aircraft Company test pilot Flying Officer Phillip Edward Gerald Sayer made the first flight of the Gloster G.37, a prototype fighter for the Royal Air Force, designed to reach a speed of 250 miles per hour (402 kilometers per hour) while armed with four machine guns. The flight took place at Gloster’s private airfield at Brockworth, Gloucestershire.

The Gladiator was designed by Gloster’s chief designer, Henry Philip Folland.

The Gladiator was a single-place, single-engine, single-bay biplane, with fixed landing gear. The airplane was primarily of metal construction, though the aft fuselage, wings and control surfaces were fabric covered.

The production Gladiator Mk.I was 27 feet, 5 inches (8.357 meters) long with a wingspan of 32 feet, 3 inches (9.830 meters) and overall height of 11 feet, 9 inches (3.581 meters). It had an empty weight of 3,217 pounds (1,459 kilograms) and gross weight of 4,594 pounds (2,084 kilograms).

Gloster SS.37 prototype, right profile
Gloster G.37 prototype, right profile

The G.37 was equipped with a left-hand tractor, air-cooled, supercharged, 1,519.083 cubic-inch-displacement (24.893 liters) Bristol Mercury IV-S2 nine cylinder radial engine. With a compression ratio of 5.3:1, the IV-S2 was rated at  505 horsepower at 2,250 r.p.m., and 540 h.p. at 2,600 r.p.m., both at 13,000 feet (3,962 meters). It developed a maximum 560 horsepower at 2,600 r.p.m. at 16,000 feet (4,877 meters). The engine had a take-off power rating of 530 horsepower at 2,250 r.p.m., at Sea Level (3-minute limit). The IV-S2 drove a two-bladed fixed-pitch propeller through a 0.655:1 gear reduction. This engine weighed 920 pounds (417 kilograms).

The G.37 was repowered with a Bristol Mercury VI-S engine, which had a 6:0:1 compression ratio and a 0.5:1 gear reduction ratio. This engine produced a maximum of 636 horsepower at 2,750 r.p.m. at 15,500 feet.

The prototype was armed with two synchronized, air-cooled Vickers .303-caliber machine guns, firing forward through the propeller arc, and two .303-caliber Lewis guns mounted under the bottom wing.

With the upgraded engine and armament, the G.37 reached 242 miles per hour (389 kilometers per hour).

The Gloster Gladiator Mk.I with an enclosed cockpit and a Bristol Mercury IX engine had a maximum speed of 257 miles per hour (414 kilometers) per hour) at 14,600 feet (4,450 meters).

This production Gloster Gladiator Mk.I, K6131, shows the cockpit enclosure. (This airplane, the second production Gladiator Mk.I, was damaged beyond repair when it ran out of fuel near RAF Church Fenton, 26 March 1938.) (Royal Air Force)
Gloster Gladiator Mk.I L8032. (SDASM)

The Gladiator Mk.I entered service with the Royal Air Force in February 1937. It was the last biplane fighter to do so, and was the first fighter with an enclosed cockpit. Beginning with No. 72 Squadron, eight fighter squadrons were equipped with the type, though by the beginning of World War II, these were being phased out by more modern airplanes like the Hawker Hurricane and Supermarine Spitfire.

A total of 737 Gloster Gladiators, Mk.I and Mk.II, were built. In addition to the Royal Air Force, there were operated by several other countries in Europe, the Mediterranean and the Middle East.

Prototype Gloster Gladiator in flight, now marked K5200.
Prototype Gloster Gladiator G.37 in flight, now marked K5200. A .303-caliber Lewis machine gun is visible under the right wing. (Royal Air Force)
Phillip E.G. Sayer, O.B.E. (Flight)

Phillip Edward Gerald Sayer was born at Colchester, England, 2 February 1905. He was the second of three children of Edward James Sayer, a retired British Army officer and Ethel Jane Hellyar Sayer.

Sayer was granted a short service commission in the Royal Air Force as a Pilot Officer on probation, 30 June 1924. His rank was confirmed 23 May 1925. He was promoted to Flying Officer 30 March 1926. Flying Officer Sayer was transferred to the R.A.F. Reserve, 2 March 1929.

In 1930, Gerry Sayer joined Hawker Aircraft Company as a test pilot. When Hawker took over Gloster Aircraft Co., Ltd. in November 1934, he was appointed Chief Test Pilot of Gloster.

Flight Lieutenant Sayer completed his service and relinquished his commission, 2 March 1937. He was permitted to retain his rank.

On 15 May 1941, Sayer made the first flight of the Gloster-Whittle E.28/39, a prototype jet fighter.

Chief Test Pilot Phillip Edward Gerald Sayer, Esq., was appointed an Officer of the Most Excellent Order of the British Empire (OBE) in the New Years Honours list, 30 December 1941.

Gerry Sayer was flying a Hawker Typhoon from RAF Acklington, 22 October 1942, to the Druridge Bay gunnery range. He never returned.

© 2018, Bryan R. Swopes

11 September 1974: TDiA No. 1,500 ¹

Aviation, , ,
Bell Helicopter Company prototype Model 206L LongRanger, N206L. (Vertical Flight Society)

11 September 1974: The first prototype Model 206L made its first flight at the Bell Helicopter Company plant at Hurst, Texas.

Based on the Bell 206B-3 JetRanger III, the LongRanger featured a 30-inch (76.2 centimeters) stretch to the passenger cabin, a lengthened tail boom and longer main rotor blades. It retained the JetRanger’s Allison 250-C20B turboshaft engine.

¹ As of 11 September 2024, This Day in Aviation has published 1,667 articles.

© 2019, Bryan R. Swopes