Exploring the effect of fibers on texture, fire performance and sprayability of intumescent coating
Structural steel is a common material used in the building and construction industry and the marine industry due to its strength, durability, recyclability, ease of fabrication and its cost effectiveness. However, one major disadvantage of steel is that it loses strength and becomes ductile at 50...
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| Format: | Final Year Project |
| Language: | English |
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Nanyang Technological University
2024
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| Online Access: | https://hdl.handle.net/10356/176130 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | Structural steel is a common material used in the building and construction industry and the
marine industry due to its strength, durability, recyclability, ease of fabrication and its cost
effectiveness. However, one major disadvantage of steel is that it loses strength and becomes
ductile at 500°C. In a case where there is a fire breakout, temperatures can hit up to 815°C,
losing its strength significantly. As a result, fire protection is crucial for providing time to
evacuate. Intumescent coating provides a protective shield by forming a char layer but even
so, the char layer lacks structural integrity and may not protect steel from fire effectively.
Therefore, fibre reinforcement is required to provide the char strength. This project
investigates how different fiber material and aspect ratio will affect the spraying process in
terms of maximum wet thickness per spray due to fiber entanglement and viscosity of the
coating and the char expansion and rigidity of the residue char.
Coatings are sprayed on to a (100x100x10) mm steel substrate with thickness of 3.5mm for
furnace test and maximum wet thickness for each formulation were also tested with different
fiber materials, fiber length and weight percentage. 3 dissimilar materials are investigated:
Carbon fiber, glass fiber and basalt fiber with fiber length from 0.15mm to 3mm. Maximum
wet thickness is also investigated using the maximum fiber concentration for each type of
fiber. It was observed that fiber length and concentration determine the viscosity as well as
the maximum wet thickness per spray pass.
All fire performance test is conducted under the ISO 834 fire curve simulation. Results have
shown that CF 1mm with 3.51% weight content has the best fire performance in terms of the
longest time taken to delay heat transfer from furnace to the back plates of structural steel.
Analysis of the char residue suggest that char expansion and rigidity is a principal factor to
determine its fire-retardant properties. |
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