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The Comet's story began in 1929, when an officer of the Royal Air Force
named Frank Whittle proposed powering an airplane with a gas turbine
engine. Rather than applying power to a propeller, this engine would
force exhaust gases out the rear of the engine, generating enough force
to drive the aircraft forward. Whittle himself described his idea as
"something like a giant vacuum cleaner; it sucks air at the front and
blows it out at the back." Eleven years of research and experimentation
produced Britain's first jet fighter, the Gloster Meteor. By the end of
World War II, only one manufacturer had experience building both jet
engines and aircraft. The plane was the Vampire, a fighter built by de
Havilland. By 1952, the de Havilland Comet, the world's first
commercial jetliner went into service and, by all appearances, Great
Britain was destined to dominate the changing world of commercial
aviation.
The Comet was an immediate sensation, for obvious reasons. Trains and
ships were still the dominant means of travel in 1952. Air travel was
still a novelty for most travellers. Since World War II meant the
temporary suspension of work into newer and faster commercial aircraft,
the airliners of the early 1950's were little changed from those of the
late 1930's. Even the Douglas DC-7C, the first plane to offer regular
non-stop transatlantic service, was little more than a 15 year-old
design that had been stretched to carry more passengers and fuel. It's
3,400 horsepower engines, each with 72 cylinders, were noisy and
produced unpleasant vibrations inside the passenger compartment.
Imagine the surprise then, when the de Havilland Comet made its
appearance in 1952. It had no obvious means of propulsion; it's four
jet engines were built inside the wings. Rather than the usual sound of
piston engines, people heard an unfamiliar howling sound as the Comet
rolled down the runway. Instead of a 40 hour flight to Johannesburg,
South Africa, the Comet could fly from London to Johannesburg , via
Rome, Beirut and Khartoum, in 23 hours, at speeds up to 500 MPH. Rather
than lumbering through storms, the Comet flew above the weather, eight
miles up in the stratosphere. Its air-conditioned, fully pressurized
cabin provided passengers with a quiet, smooth ride previously unheard
of in commercial aviation.
During its first year
of operation, the Comet carried 28,000 passengers a total of 104
million miles. By May 1953, de Havilland had firm orders for 50 Comets
from the world's airlines and was negotiating for 100 more. The Comet
was such a sensation the Queen Mother and Princess Margaret flew one
from London to Rhodesia. The Comet was an unqualified success and, by
all appearances, Great Britain was poised to dominate commercial
aviation for the next forty years. As the editor of American Aviation
Magazine said, "Whether we like it or not, the British are giving the
U.S. a drubbing in jet transport." And then the accidents began.
The first two accidents, in 1953, occurred on takeoff. In the first,
the plane failed to become airborne. The accident was blamed on pilot
error and no one was killed. The second accident, however, left no
survivors and appeared to be caused by a design flaw in the airplane. A
modification would be made to the wings that allowed for greater lift
at low speeds. A third accident occurred as a Comet crashed on takeoff
from Calcutta. This accident was blamed on turbulence and no fault was
found with the plane. The public's confidence in the Comet was
undiminished - until January 10, 1954.
A BOAC Comet departing from Rome climbed to 26,000 feet, en route to
its assigned altitude of 36,000 feet. Captain Alan Gibson began to
radio a message to another BOAC plane behind him. "Did you get my . .
." Silence. Seconds later, fishermen near the island of Elba saw the
remains of the Comet plunge into the sea.
The Comets were
grounded while de Havilland and the British government searched for the
cause of the disaster. Unfortunately, with the plane in thousands of
pieces beneath 500 feet of water, the investigators had little to go
on. Speculation ranged from sabotage to clear-sky turbulence to an
explosion of vapour in an empty fuel tank. While the Royal Navy
utilized sonar, divers and underwater television cameras to salvage as
many parts of the plane as possible, the investigators utilized what
limited information they had and recommended 50 modifications to the
remaining Comets that would, they hoped, correct whatever problem had
destroyed the BOAC flight. Basically, they were guessing. The
modifications included the installation of shields between the engines
and fuel tanks, reinforced fuel lines and new smoke detectors. Less
than two months later, with the modifications in place, the Comets
again took to the skies. The engineers crossed their fingers, hoping
their shotgun approach had found the real culprit. It hadn't. Sadly,
only two weeks after resuming service, another BOAC Comet disappeared.
The plane had departed Rome on its way to Cairo and was climbing to its
assigned altitude of 35,000 feet when, suddenly, radio contact ceased.
There were no eye-witnesses. Once again, the Comets were grounded.
Meanwhile, the Royal Navy had succeeded in salvaging about two-thirds
of the Comet from the first disappearance. The wreckage suggested that
the cabin itself had failed. There were traces of blue on the vertical
stabilizer or tail of the plane. Chemical analysis showed them to have
come from the seats, suggesting that some force had hurled the contents
of the cabin against the tail. Paint from the fuselage was found on the
left wing. The conclusion was inescapable - explosive decompression of
the cabin. But why? How had the designers failed? The Comet was the
most thoroughly tested passenger plane ever built. The engineers at de
Havilland knew the Comet would have to withstand changes in
pressurization that no piston-powered airliner had ever encountered.
They had built a decompression chamber to test the cabin of the new
airliner. They manipulated pressures inside and outside the cabin to
simulate conditions the Comet would experience in the thin, cold air at
38,000 feet. One test cabin was subjected to this test 2,000 times and
passed with flying colors. After all this testing, why were the planes
blowing apart in actual flight?
The Ministry of Civil Aviation decided upon a unique test to find out.
They built a tank large enough to hold one of the grounded Comets. The
wings protruded from water-tight slots in the sides of the tank. Then
the tank and cabin were flooded with water. The water pressure inside
the cabin would be raised to eight and a quarter pounds per square inch
to simulate the pressure encountered by a Comet at 35,000 feet. It
would be held there for three minutes and then lowered while the wings
were moved up and down by hydraulic jacks. The hydraulic jacks would
simulate the flexing that naturally occurs in aircraft wings during
flight. This process continued non-stop, 24 hours a day. This torture
test continued until the cabin in the tank had been subjected to the
stresses equivalent to 9,000 hours of actual flying. Suddenly, the
pressure dropped. The water was drained and the fuselage examined. The
investigators were horrified to find a split in the fuselage. It began
with a small fracture in the corner of an escape hatch window and
extended for eight feet. Metal fatigue! Had the Comet not been under
water, the cabin would have exploded like a bomb. Several months later
the results of this test were corroborated when an Italian trawler
recovered a large section of cabin roof from the sea. A crack had
started in the corner of a navigation window on top of the fuselage.
Like the escape hatch window of the test Comet, it had square corners.
The square design of the windows was the major flaw that doomed the
Comet. Strangely, the U.S. Civil Aeronautics Administration,
predecessor to the FAA, had misgivings about the square windows of the
Comet several years earlier and refused to grant it an air-worthiness
certificate so it could fly in the United States.
The bottom line? Aside from the square windows, de Havilland's testing
of the new plane while still in its design phase was inadequate. They
had limited the new cabin to static testing alone, meaning they had
subjected the cabin to pressurization, but neglected to add in the
effects of motion, such as flexing of the airframe and wings. No one at
de Havilland had anticipated the effects on the airframe of an airliner
that would climb to altitude as quickly as the jet-powered Comet. Like
the Titanic forty years earlier, the Comet suffered design flaws that
sealed its fate before its first flight. It would be four full years
before the Comet would be re-engineered sufficiently to once again take
to the skies. But by then it was too late. The Boeing 707 had already
gone into service. The newer 707 could carry twice as many passengers
as the Comet and had a greater range. The word's airlines began
ordering 707s and the Comet, along with its maker, were doomed to
oblivion. The 707 went on to become one of the safest, most successful
airliners of all time but - that's a tale for another day!
Dimensions (Comet 1)
Length 93 ft 10 in 28.61 m
Wingspan 114 ft 9 in 34.98 m
Height 29 ft 6 in 9 m
Wing area 2,023 ft² 188.3 m²
Weights
Empty lb kg
Loaded 105,000 lb 47,600 kg
Maximum takeoff lb kg
Capacity 36-44 passengers
Powerplant
Engines 4 × de Havilland Ghost 50 turbojets
Thrust (each) 5,000 lbf 22.2 kN
Performance
Maximum speed 450 mph 725 km/h
Range 1,500 mi 2,400 km
Ferry range km miles
Service ceiling 42,000 ft 12,800 m
Rate of climb ft/min m/min
Dimensions
Dimensions (Comet 4)
Length 111 ft 6 in 34.0 m
Wingspan 114 ft 10 in 35.0 m
Height 29 ft 6 in 9.0 m
Wing Area 2,121 ft² 197 m²
Weights
Empty 75,400 lb 34,200 kg
Loaded 162,000 lb 73,470 kg
Maximum takeoff lb kg
Capacity 56-109 passengers
Powerplant
Engine 4 × Rolls-Royce Avon Mk 524 turbojets
Thrust (each) 10,500 lbf 46.8 kN
Performance
Maximum speed 500 mph 805 km/h
Range 3,225 miles 5,190 km
Ferry range km miles
Service ceiling 40,000 ft 12,200 m
Rate of climb ft/min m/min |
