1. INTRODUCTION
If one looks
back at the undergraduate course on Strength of Materials, it may be recalled,
that, from the beginning of the coarse through its end, the material (of which
the structure is made up of) was idealized as being homogeneous (i.e. of
uniform composition) and a continuum (i.e. made up of a continuous mass than of
discrete particles). Thus, the subject of strength of materials never recognised
or considered the inherent flaws in
the structure.
It is
interesting to note that many of the structural failures that have occurred
since past few decades [some, not being very long ago] have been because of the
flaws/ defects present in the structure since its inception and the growth of
these flaws during the life time of the structure, thus, resulting in the
collapse of the structure. In fact, if one goes back to the history of the
subject of Fracture Mechanics, it
may be appreciated that the subject has gradually evolved through the lessons
learned through such structural failures which have been because of the
inherent flaws in the present in the structure and their growth through
different mechanisms during the life time of the structure.
Through this
article, I have attempted to focus on the following structural failures and the
lessons learned through these failures which have contributed to the evolvement
of the subject of Fracture Mechanics over the past few decades. These failures
being:
- Boston Molasses Tank Failure
- Liberty Ship Failure
- Comet Disaster
- Aloha Airlines Fuselage Failure
I have
discussed the above failures through the following sections in chronological
order and have finally (in the last section of this article) attempted to bring
out the lessons learned through these failures.
2. BOSTON MOLASSES TANK FAILURE
The Collapse:
On January 15, 1919,
Boston suffered one of history’s strangest
disasters: a devastating flood of molasses…! A large molasses tank in Boston,
Massachusetts in the United States exploded with a great force. The tank
contained 2.3 million gallons (i.e. more than 8 million litres) of molasses at
the time of collapse. The steel tank was enormous: 50 feet (15 metres) in height and 90 feet (27
metres) in diameter.
Figure: The Boston Post
Headlines January, 16, 1919
The wave of
molasses rushed through the streets of Boston at an estimated 35 miles per hour (i.e. 56 kilometres per hour) killing 21
people and injuring around 150. The power of the wave was sufficient to rip
buildings off their foundations. A piece of the tank was blown into the
elevated railway tracks, breaking girders (see picture below) and almost
forcing a northbound train off its tracks. The property
damage was estimated to a total of $100 million in today’s dollars.
Figure: A large piece of tank
pushed against an elevated railway
Some structural aspects of the steel tank:
The tank was itself just 3 years old at the time of the
disaster. The tank was constructed of large curved steel plates, seven vertical
rows overlapping and held together with rows of rivets, the whole set into a
reinforced concrete base.
The steel thickness varied from 0.67 inch for the first
ring at the base to 0.31 inch for the seventh ring at the top. The figure below
shows the vertical joint in the first ring at the base.
Figure: The geometry of the
vertical riveted joint in the first ring at the base of the tank
Causes of failure:
Several factors that
occurred on the day of the collapse and the previous day are believed to have
contributed to the disaster:
- Thermal shock: The tank was poorly constructed and insufficiently tested. Due to fermentation occurring within the tank, carbon dioxide production may have raised the internal pressure inside. The rise in the local temperatures that occurred over the previous day might have also assisted in the building up of the pressure.Records show that air temperature rose from -17°C to 5°C over that period thus resulting in a thermal shock.
- Fatigue crack propagating from near the base of the tank: The failure occurred from a manhole cover near the base of the tank (the hoop stress being greatest near the base of a filled cylindrical tank), and it was believed that a fatigue crack grew around to criticality. The tank had been filled to its capacity eight times since it was constructed thus putting the walls under an intermittent cyclic load.
- Poor structural health monitoring: It has been reported that the storage facility was never properly tested - by filling it with water - because a shipload of molasses was due only days after the completion of the tank in December 1915. From the beginning leaks had appeared and it is believed that the distillery company had painted the tank brown deliberately to hide the leaks (since molasses is brown in colour).It should be noted that the failure occurred due to a fatigue crack growing near the manhole cover to its critical length, thus, throwing light on the crack growth mechanism due to fatigue.Metallurgical aspects of the tank that led to a brittle collapse:Two metallurgical aspects of the molasses tank steel are of note: the likely brittle behaviour during the failure temperature (4°C) and the observation of a microstructural feature called Neumann bands.Low carbon and manganese in steel leading to explosive / brittle behaviour:
Most of the
structural steel production in 1915 was by open hearth process (https://en.wikipedia.org/wiki/Open_hearth_furnace). The material exhibited very good
strength with high ductility. At that time, fracture toughness was not
specified in material procurements. The
chemistry for steel in the plates containing the manhole (where the fatigue
crack grew to its critical length) is shown the table below and compared with 2
modern steels:
Table:
A typical chemistry for the molasses tank steel shell plate and current steels
Note the
particularly low value of manganese in the steel used to construct the molasses
tank. Chemistry, thermal processing and quality of production all affect the
fracture properties of steel.
For the class
of steels corresponding to the molasses tank, carbon has the greatest effect on
the propensity (tendency) for brittle behaviour. The higher the carbon, the
higher the temperature at which there is a transition from brittle to ductile
behaviour. Some research data (of 1951 i.e. 32 years after the collapse!)
suggests that the transition temperature for the molasses tank steel could have
been as high as 15°C which is significantly above the operating temperature at
the time of failure (which was 4°C).
Neumann bands (the
contribution of the failure to Fracture Mechanics)
Neumann bands
are narrow bands, a few micrometres wide, usually within a grain. Substantial
research even before the molasses tank failure indicated that this feature was
only produced in low carbon steel by explosive loading or at extremely low
temperatures. Expert reports showed micrographs of Neumann bands were found near
the primary fracture. It is now known that a rapidly propagating crack in
brittle low carbon steel can produce Neumann bands without explosive loading.
Crack velocities in brittle steels can reach as high as 3,000 feet per second.
1 4. LIBERTY SHIP FAILURE: BRITTLE FRACTURES AND THE BIRTH OF FRACTURE MECHANICS
Figure: One of the ‘survived’
Liberty ship
History behind the construction of Liberty ships:
As part of
the war effort during the World War II, the materials, munitions and supplies
were vital to the United States in order to sustain the battle against the
Germans. A very successful bombing operation by Germany on the ships had
inflicted significant damage to the munitions of the United States.
As a result,
in 1941, President Roosevelt announced that $350 million would be spent to
provide a ship building programme, the objective being to build ships faster than
the enemy could sink them!
In pursuit of
this objective, the Americans decided to use the method of “welding” than the
conventionally followed method of “riveting” for ship building. The ships were
called as “Liberty ships”. In addition to increasing the speed of construction,
the use of welding also decreases construction costs. The number of skilled
labourers required carrying out welding on the ship’s hull and the deck were
thought to be significantly lesser than the numbers required to carry out using
riveting.
The
sinking, cracking and the damage:
2708 Liberty
ships were constructed between 1939 to 1945. 1038 damages or accidents were
reported by April, 1st 1946!
More than 200
Liberty ships sank or were damaged beyond repair. “Schenectady” (as named) was one of those ships which broke into 2
pieces with a loud sound (see picture below). The accidents were caused due to
the lack of fracture toughness of the welded joint. The accident highlighted
the importance the importance of fracture toughness and marked the “birth of fracture mechanics”.
Figure:
“Schenectady”-
the ship that broke into
two
Causes
of collapse:
It was clear
from the nature of the failures of the ships that the collapse occurred through
a brittle fracture. It was observed that nearly all the failures occurred in
the cold waters of the North Atlantic whereas the ships stationed in the South
Pacific remained intact! The mystery was later resolved by Constance Tipper of
Cambridge University.
She
demonstrated that there is a critical temperature that there is a critical
temperature below which the fracture mode in steels shifts from ductile to
brittle. That is: the fracture toughness of steel changes drastically over a
small temperature range. The low temperature steel is brittle and fractures by
cleavage. At high temperature, it is ductile and fails by plastic collapse. In
transition between ductile and brittle, both mechanisms of fracture can occur.
Thus, there is a region where the material is 100% ductile and a region where
the material is 100 % brittle and a transition zone as shown in the figure
below.
Figure: The ductile-brittle
transition (note: the low fracture toughness in the zone corresponding to low
temperatures)
The ships
stationed in the North Atlantic were susceptible to brittle fracture as the
temperature was in the corresponding zone as marked above.
Quality of the welds:
The welding
techniques used in ship production caused a controversy. There were issues with
inexperienced labourers who had been drafted in to increase ship production for
the World War II efforts. It was believed that the unskilled welding caused
micro-cracks in the weld itself, thus, resulting stress concentrations which
contributed to the brittle fracture of the Liberty ships.
Crack growth, fracture: Locations
It should be
noted that the most common type of cracks (for most of the ships) was one which
began at the square corner of the hatch (opening) which coincided with a weld.
Thus, both the weld and stress concentrations acted as localised areas of high
stresses.
One remedial measure
adopted was to use rivet steel arrestor plates in areas of higher stress
concentration thus arresting crack growth. In fact, Victory ship was an upgrade
in ship
design had
arrestor plates to maintain a less stiff and stronger ship design that
was better able to deal with fatigue.
Thus, the reasons of the failure of the Liberty ships
could be summarized as;
- The material used did not have sufficient fracture toughness especially at lower temperatures.
- The standard of the welded joints was in general poor due to inexperienced welders; which meant there were micro cracks in the welds.
- The all-welded construction eliminated crack arresting plate boundaries which are present in riveted joints.
1 4. THE COMET DISASTER
de Havilland
Comet was the world’s first production commercial jet liner. Developed and
manufactured by de Havilland (https://en.wikipedia.org/wiki/De_Havilland), the Comet’s first prototype first
flew on 27 July 1949. It featured an aerodynamically clean design with 4
turbojet engines buried in the wings, a pressurised fuselage and “large square windows”. For
that era, it offered a relatively quiet, comfortable passenger cabin and showed
signs of being a commercial success at its 1952 debut.
Initial
success and the sensation:
During its
first year of operation, the Comet carried a total of 28,000 passengers
covering a total of 104 million miles. By 1953, de Havilland Comet had firm
orders of 50 Comets from the world’s several airlines and was negotiating for
100 more. The Comet was looked upon as a great success throughout the world.
And, then,
after a year of service, the accidents began (1953)….!
Accidents
in 1953:
The first 2
accidents in 1953 occurred during take-off.
In the first,
the plane failed to become airborne. The accident was blamed as a pilot error
and no one was killed.
The second
accident left no survivors and appeared to be a design flaw and modifications
were done to the wings that allowed a greater lift at low speed.
The third
accident occurred as the Comet crashed on take-off from Calcutta in India. In
spite of these 3 accidents, the public confidence was in place until January,
10 1954…!
What
happened on January 10, 1954?
On the 10th
of January, 1954 a Comet after departing from Ciampino Airport in Rome to London,
had climbed 26,000 feet en-route to its assigned altitude of 36,000 feet when
it plunged into the sea. Witnesses in the island of Elba in Italy saw the aircraft
fall into the sea in flames. All 29 passengers and 6 crew members were killed.
The Elba investigation and the Comet
water tank test:
While a crash
investigation is normally conducted by the government or aviation authority, it
was decided that the British authorities would head the Elba investigation. Around
70% of the Elba wreckage was recovered following thorough investigation which
for the first time included using under water television cameras.
The
authorities salvaged the wreckage from the ocean and reconstructed the
aircraft. Once the debris was put together, it was found that the cabin itself
had failed and the conclusion was the disaster was due to extreme decompression
of the cabin.
The Ministry
of Civil Aviation decided upon a unique test to figure out the exact cause of
the accidents. They built a large tank, large enough to hold one of the
grounded comets. The wings protruded from the water tight slots from the sides
of the tank (see picture below):
Figure:
The Comet in the water tank for pressure tests
The wings
protruded from the water tight slots from the sides of the tank. Then the tank
and the cabin were flooded with water.
By using
water instead of air, water being a much less compressible fluid the test would
be much safer and fuselage would be able to be repaired and re-tested as
necessary. Had air been used, the results would have resembled the catastrophic
inflight break up like the 2 flights. The wings of the aircraft were moved up
and down by hydraulic jacks to simulate the flexing of the wings that occurs
due to the air currents during flight.
The Comet that was being tested had
undergone 1230 pressurized flights before testing and 1830 “tank flights”
before the fuselage failed at the corner of a square forward escape hatch
window.
Figure: Fuselage failure at the corner of a “square” escape window
Several
months later the results of the tests were confirmed when a large section of
the cabin roof was recovered from the sea. A crack had started in the corner of
the navigation window at the top of the fuselage. Even through it was a small
crack of a few mm at the corner of a square window, structurally, total rack
length = length of the actual crack + length of window diagonal.
The stress
concentrations were high specifically because of the squarish shape of the
windows and window frames which is very different from the round/oval shapes of
modern airplane window.
And this was intuitive
reason for which the US Administration did not allow the Comet to fly because
the size of windows was larger than the normal windows. This was purely out of
engineering judgement, then…!
Causes of the disaster besides the
square windows:
Apart from
the square windows, de Havillands testing of the new plane was inadequate. They
had limited the new cabin to static testing alone meaning that during the
tests, they had subjected the cabin to pressurization alone but had neglected
the effects of motion such as flexing of the wings. Thus, the actual service
loads were not simulated properly and effect of flexing was neglected. This
provided an explanation that the structure was not fully design proof.
If one looks
at the history of fatigue development, this was the time that the concept of
S-N curve was being researched.
1 5. ALOHA AIRLINES FLIGHT 243 FUSELAGE FAILURE
Aloha
Airlines Flight 243 was a flight between Hilo and Honolulu in Hawaii. On April
28, 1988, a Boeing 737 serving flight suffered extensive damage after an
explosive decompression in flight, but was able to land safely in spite of
fuselage failure mid-air! There was one fatality (of one of the flight
attendant) and another 65 passengers and crew were injured.
Figure: Aloha Airlines flight 243 fuselage
failure
It
may be noted that the other three failures discussed in this article: Boston
Molasses tank failure, the Liberty Ships failure, Comet disaster, all occurred
after the structure had been in service for the first few years. But, in the
case of the Aloha airlines fuselage failure, the failure occurred after the
structure had been in service for 19 years whereas the intended design life was
20 years. Following the investigation, it was concluded that widespread
corrosion was the main cause.
The
disaster marked a turning point in the history of aircraft corrosion. At the
start of the jet age (1950 to 1960’s), little or no attention was paid to
corrosion and corrosion control. Only the more recent designs like Boeing 777
and later version of 737 have incorporated significant improvements in
corrosion prevention and control in design and manufacturing.
16. LESSONS LEARNED THROUGH THESE FAILURES
In summary,
it could be concluded that the following lessons have been learned through
these failures;
Boston
molasses tank failure:
- The failure brought out the importance of structural health monitoring. The tank was painted brown and hence no visual inspection was possible on any leak of molasses which is also brown.
- The failure reinforced the concept of ‘Neumann bands’ which are known to occur in in a rapidly propagating crack in brittle steels.
- The failure threw light on the composition of steel necessary for ductile behaviour.
Liberty
ship failure:
- The disaster brought out the importance of temperature effect on fracture toughness and marked the birth of fracture mechanics.
Comet
disaster:
- The failure highlighted that cracks could occur in stress concentration zones and grow in service due to fatigue loading causing failure
- The failure also highlighted the importance of proper simulation of service loads during testing. It may be noted that flexing of wings had been neglected during the testing.
Aloha
Airlines fuselage failure:
- The failure brought out the importance of stress corrosion cracking
- It gave impetus to improved design approaches for corrosion prevention and control
