On July 16, 2020, at approximately 6:30 a.m., an explosion and fire occurred in a blast furnace in a steel mill USA. In iron manufacturing, a blast furnace operates at high temperatures to convert iron ore into molten iron. Hot, pressurized air enhances the blast furnace’s efficiency and capacity. This hot air is heated in a pressure vessel known as a stove, and the top hemispherical part of the stove is referred to as the dome.
On July 16, 2020, a blast furnace was operating normally when the dome on one of its stoves suddenly and catastrophically separated at approximately 6:30 a.m., resulting in a large explosion. Plant operators shut the unit down within minutes. The incident severely damaged portions of the mill.
The company's investigation revealed that the rupture originated at a large repair patch on the stove’s dome. The failure initiated where the dome’s shell was thinnest due to internal corrosion, measuring approximately one-tenth of an inch. This thickness was only ten percent of the dome’s original wall thickness of one inch. The investigation also found that the repair patch in this area was improperly welded and that the repair plate was only 0.25 inches thick, significantly less than the calculated minimum required thickness of 0.56 inches for the dome. The stove’s normal operating pressure of 36 pounds per square inch caused the fracture to spread along the welds of the shell.
High-temperature oxidation corrosion had significantly reduced the thickness of the dome’s shell over the years it was in operation. Several repair patches were applied throughout the dome’s service life to address thinning and weld cracking. The company's investigation concluded that some of these repairs did not conform to the American Society of Mechanical Engineers (ASME) Pressure Vessel Code requirements. In fact, several repair patches were improperly welded, used dissimilar steel grades that did not match the original structural steel, and failed to meet the minimum thickness requirements for this type of pressure vessel. These deficiencies likely compromised the strength of the repaired areas, allowing the crack to propagate along the welds after the initial failure.
Probable Cause
Based on the company's investigation, the CSB determined that the probable cause of the explosion was the catastrophic failure of the stove’s dome. The dome failed at a repair patch that had been improperly welded and did not provide the minimum thickness needed to contain the dome’s operating pressure. The steel mill’s mechanical integrity program lacked effective inspection and weld repair practices, contributing to the incident.
Source: CSB.gov