Theoretical Analysis of Light-Weight Truss Construction in Fire Conditions, Including the Use of Fire-Retardant-Treatment Wood

Ziemba, Gilead Reed

05 May 2006

Fire statistics suggest that there is an urgent need for improved performance of light-weight truss construction in fire scenarios. This thesis proposes the use of Fire Retardant Treated Wood (FRTW). Several floor truss systems were designed for a residential living room using sawn lumber and FRTW. A finite difference, heat transfer model was used to determine time to collapse and to identify modes of failure during a simulated exposure to the standard ASTM E-119 test fire curve. As part of ongoing research at WPI, this is an initial effort to use analytical methods in the study of heat transfer and structural performance of wood construction during fire conditions. Results were examined for important relationships to further advance the understanding of collapse mechanisms in wood trusses. Experimental procedures for further testing have also been developed. Acknowledgment that in-service conditions may alter structural fire performance is made and the implications are discussed. An alternate fire scenario, more representative of residential fire loading, was also developed and compared to the ASTM E-119 fire curve.

light-weight truss construction

fire scenario

fire-retardant-treated wood

Fireproofing of wood

Testing

Building

Fireproof

Trusses

Fire testing

Fire resistant materials

YTBEHANDLADE TRÄELEMENT : En studie av brandskydd, bärförmåga, pris och miljöpåverkan av ytbehandlade träelement.

Issa, Angelo, Machhadi, Maher, Barbu, Mircea

January 2021

The current Swedish building code (Boverkets Byggregler, BBR) is very strict regarding fire-safety in high-rise timber structures because of the heightened risk of fast flame spread or structural failure in case of fire. Fire safety solutions, that are used in timber structures must therefore be optimal to contain flames from spreading in the event of fire. The current building code requires that load-bearing elements must withhold their load-bearing capacity for 60 minutes under fire. The purpose of this study was to research the effect that different fire-retardant surface treatments, have on fire protection of a load bearing, laminated timber element. Thereafter, a short analysis was made on the environmental impact of the fire-retardant surface-treatments in question and finally, a cost analysis and comparison were conducted with regard to different fire-safety solutions such as fire-resistant gypsum board and a combination of fire-resistant gypsum board and stone-wool. The methods used in this study are a combination of theoretical reviews and theoretical calculations. A theoretical review was conducted in order to collect the information needed to understand the behavior of timber under fire, the impact of fire-resistant surface treatments on fire protection, and the environmental impact of the actual surface treatments. Therefore, a series of theoretical calculations were made in accordance with European standards (Eurocodes) in order to present the impact in numbers. The calculations made were concerning a laminated timber beam with the dimensions of 145 x 450 x 6000 [mm] and took into account the remaining cross-section of the timber element under various timestamps during fire with regard to fire-stage, charring-rate, and fire coating. The results of this study indicate that the moment-capacity and shear-capacity of an untreated beam decrease constantly under fire and does not fulfill the requirements of the Swedish building code. Thereafter, in case that the same timber beam is fire-treated with a fire-retardant surface treatment. The moment-capacity is observed to increase in the first stage of fire, were the fire-protection of the surface-retardant treatment is still in action. Therefore, after fire-protection ceases, the moment-capacity of the timber beam is calculated to decrease in different rates with regard to fire-stage. The shear capacity of the treated beam is calculated to decrease under fire with a time-displacement of 30 & 60 minutes in comparison to the untreated element. The conclusions are that the studied surface treated timber beam and the actual fire treatments fulfill the requirements of the Swedish building code. Have insignificant environmental impact and are in comparison to other solutions cheaper.

Timber

surface-treatment

fire-safety

load-bearing capacity

charring-rate

fire-retardant paint

fire-resistance

high-rise building.

Building Technologies

Husbyggnad

Étude de la stabilité dimensionnelle d'un revêtement polymère sur placage de bois pour structures intérieures d'avions

Duport, Nicolas

08 1900

No description available.

Vernis ultra-brillants

Panneaux composites

Cabinetterie des avions

Essence de bois

Traitement ignifuge

Traitement thermo-hygrométrique

High-gloss varnishes

Composites panels

Aircraft cabinetry

Wood species

Fire retardant treatment

Thermo-hygrometric treatments

Development of greener benzoxazines with intrinsic flame retardancy and their properties

Machado, Irlaine

January 2021

No description available.

Polymers

Engineering

Materials Science

Aerospace Materials

Chemistry

Organic Chemistry

Polymer Chemistry

Benzoxazine

polybenzoxazine

green flame retardant

polyurethane foam

sesamol

furfurylamine

benzaldehyde

truly bio-based polybenzoxazine

fire retardant

green flame retardant additive

self-extinguishing

noncombustible polymer

non-halogenated flame retardant

adhesion

flexibility

thermoset.