Studying the effects of fire on steel structures, nuclear plants

previous work has been done in fire laboratories, which don’t have the same experimental resources of a structures lab. We can subject the structures to failure and make more fundamental observations of behavior and failure to build models. Almost no tests or data like we have can be found in the public domain.”

Doctoral student Anil Agrawal led work to create a model that shows precisely what happens to a steel member subjected to fire while forces are applied by the hydraulic cylinders. The model has been found to be accurate when compared to the experimental results from work led by Choe.

“These are very difficult experiments to perform,” Varma said. “Having a dependable model to predict behavior means you don’t have to do as many experiments when testing new designs.”

Wellman led a portion of the work focusing on the effects of fire on a building’s steel-and-concrete floor and its connections to the building. The composite design is the most common type of floor system used in steel structures.

“Conventional wisdom says the presence of concrete floors improves the fire resistance of a building,” Varma said. “We found that this isn’t necessarily true for the worst-case scenario, unless you set out to design the floor specifically to perform well in fire.”

The release notes that the aim of the research is to learn precisely what happens to the connections between a floor’s steel beams and the building columns. Extreme heat causes the beams to sag.

“When it starts sagging, the question is, how do the connections perform? This has been a big question for the industry,” Varma said.

The researchers analyzed critical joints after a floor system was subjected to extreme heat in a special oven at Michigan State University. Results will be used to help researchers create a model of the steel-concrete floor system.

“It is far more difficult to model a floor system than it is to model columns,” Varma said. “But we will eventually be able to do that.”

Another paper to be published in December in the American Institute of Steel Construction’s Engineering Journal shows how to use the models to create design specifications for columns. The paper was written by Agrawal, who also is involved in modeling the steel columns and the collapse of entire building systems. The work is ongoing.

Varma also has led research to test a new type of design for nuclear power plants. The work focuses on testing structures like those to be used in the Westinghouse Electric Co. AP1000 standard nuclear power plant design.

Engineers tested components of an “enhanced shield building” that will contain the plant’s main system components.

The building consists of an inner steel-wall containment vessel and an outer radiation shield made using a technology called steel-concrete-composite construction. Instead of using more conventional reinforced concrete, which is strengthened with steel bars, the steel-concrete approach uses a sandwich of steel plates filled with concrete.