Abstract
The present study presents the application of artificial neural network (ANN) to predict the modulus of rupture (MOR) and mass loss (ML) of the fire retarded fiberboard. Hence, the effect of adding the fire retardants including boric acid, borax and ammonium sulfate was evaluated on MOR and ML of fiberboard manufactured at different press temperatures. At first, the experimental design was created based on the Response Surface Methodology, and then the significance of each independent variable with respect to its effect on the responses was evaluated through ANOVA test. It was determined that the positive effects of increasing press temperatures on MOR compensated the negative effects of fire retardant content on it. However, ML decreases more at the same time. ANN results exhibited a good agreement with experimental results. It was shown that the prediction error was in an acceptable range. The results indicated that the developed ANN model can predict the MOR and ML of the fiberboard with an acceptable accuracy. Therefore, applying the proposed model can lead to obtain the desirable outputs of MOR and ML by performing fewer experiments, and spending less time and cost.
Highlights
It is for a long time that the application of medium density fiberboard (MDF) is popular for internal uses of buildings
This study focused on the artificial neural network (ANN) modeling of the effect of adding fire retarding chemicals and press temperature on the modulus of rupture (MOR) and mass loss (ML) during the firing of the medium density fiberboard (MDF) connected with UF resin
The developed artificial neural network is suitable for modeling the MOR together with the fire retarding properties of the fiberboard using the press temperature and chemical fire retarding agents at different levels
Summary
It is for a long time that the application of MDF is popular for internal uses of buildings. Acidic fire retarding agents such as boric acid or phosphoric acid can affect mechanical properties via increasing the panel’s brittleness through depolymerization of long molecular polymers of cellulose, especially hemicellulose (Ayrilmis, 2007) This decrement is probably due to the brittleness of wood fibers created by the formation of crystals inside the cell walls of the wood or cross connections between cellulose or hemicellulose molecules (Bayani et al, 2019). In the present research, it is tried to show capability of ANN approach in order to predict the bending strength and fire retarding property of MDF fire-retarded with adding different fire retarding agents including boric acid, borax and ammonium sulfate as the press temperature is changed
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