THE COLLAPSE OF THE DOFASCO NO. 2 ORE BRIDGE, MARCH 28th 1995, HAMILTON, ONTARIO

Verhey, Timothy

09 1900

<p> Dofasco started producing steel on their Hamilton bayfront property around 1952. Much of the iron ore and coal required for their blast furnace operations was delivered by ship. Two Ore Bridges, probably fabricated in 1951 and in continuous service since, were used to unload the ships.</p> <p> On Tuesday March 28th, 1995 at approximately 8:40am, the No.2 Ore Bridge collapsed. </p> <p> At the time, the Ore Bridge appeared to be stationary. The operator was also not performing any specified operation. The collapse initiated with the failure of the tie-plate which keeps the Shear Leg from spreading at its base. The tie-plate is a critical member. As the structure contained no reasonable alternative load path for the tension in the tieplate, the failure of the tie-plate resulted in the collapse of the Ore Bridge. </p> <p> Initial calculations indicated there was no obvious structural overload that should have precipitated the catastrophic failure of the tie-plate. A metallurgical investigation of the tie-plate material was then initiated. </p> <p> The metallurgical investigation found the steel in the tie-plate was susceptible to brittle fracture at the approximate air temperature at the time of the collapse. Using a fracture mechanics approach it was concluded the failure of the tie-plate was the consequence of fatigue cracks initiating in corrosion pits on the underside of the plate, along the toe of the reinforcing fillet weld connecting the tie-plate to the rocker block. The fatigue cracks grew and combined until they created a flaw which reached a critical dimension, allowing a brittle fracture to initiate and run rapidly across the width of the plate. </p> <p> Over the years, the Ore Bridges have seen several alterations which increased the tension load in the tie-plate. In 1968 the apron was extended. In 1975 the trolley payload was increased. In 1990, increases in dead weight on the main span were recognised. </p> <p> In 1990 however, Dofasco also modified their method of handling iron ore pellets on the bayfront, which required the addition of a hopper into the Shear Leg of the Ore Bridges. The addition of the hopper was critical, as it created unbalanced lateral loadings on the sill truss which were cyclical in nature. The hopper forced the tie-plate to resist these lateral loads by bending horizontally, a loading condition for which it was not originally designed. The cyclic bending stresses resulting from the addition of the hopper led directly to the failure of the tie-plate and the resulting collapse of the No.2 Ore Bridge. </p> / Thesis / Master of Engineering (ME)

dofasco

ore bridge

Hamilton

Ontario

The Effects of Technology on the Labour Force of Dofasco Inc.

Kawalec, Christopher J.

04 1900

<p> The purpose of this research is to determine how the changing levels of technology at Dofasco Inc. have affected its labour force. This will be approached from the perspective of a production function. An overview of Dofasco's history quickly reveals that the level of technology in its factory is definitely growing. This fact is reflected in the large quantities of new equipment purchased in the company's past.</p> <p> The production function is utilized through a graphical interpretation of four ratios: the sales/labour; sales/output; output/labour; and capital/labour. These ratios provide an explanation of when, why, and how the technology level at Dofasco changes and the affect these will have on labour.</p> <p> The company successfully raises the value and quality of its output through value adding processing of the raw steel. This is attained by large capital expenditures on new equipment. The new equipment also has the effect of increasing labour productivity. Translating into a declining need for labour inputs. The exacting specifications needed in steel making are now satisfied through the use of computers and not through an experienced workers judgement.</p> / Thesis / Candidate in Philosophy

Theory and Experiments of Fiber Optic Temperature and Vibration Sensors

Stoute, Clyde

10 1900

Fiber optic temperature and vibration sensors were designed and built to take readings in the harsh environment of a steel mill. The sensors are insensitive to electromagnetic noise; making them well suited for the use in such an environment. The temperature sensor uses an optical filter technique. A piece of intrinsic silicon is inserted between two optical fibers and 1064nm wavelength light is transmitted through the silicon. As the temperature increases, the silicon becomes more highly absorbing. The vibration sensor uses an optomechanical technique. Light is transmitted across a short air gap between two optical fibers. One of the fibers acts as cantilever while the other is fixed. As the cantilever vibrates, the transmitted power fluctuates, which enables the detection of the frequency and amplitude of the vibration. Sensors were initially tested under laboratory conditions, and subsequently field tested at ArcelorMittal Dofasco. The temperature sensor has a sensitivity of 0.4°C over the temperature range from 22°C to 120°C. The vibration sensor has a sensitivity of 2.87mV /g peak over a frequency range from 0 to 1250 Hz. / Thesis / Master of Applied Science (MASc)

fiber optic

vibration sensors

steel mill

electromagnetic

Dofasco