Nano-ZnO modified geopolymer composite coatings for flame-retarding plywood

Nano-ZnO modified geopolymer composite coatings for flame-retarding plywood

[Display omitted] •Nano-ZnO (0.47 wt%)/MPP doping imparts geopolymer coatings enhanced flame retardancy.•The ceramic-like ZnP4O11 makes pyrolysis Eα rise from 204.30 to 255.61 kJ·mol−1 at 800 ∼ 1000 °C.•The interpenetrating Si/C/P residues exert 56% formaldehyde-adsorption capacity. Herein the nano-...

Full description

Saved in:
Bibliographic Details
Published in:Construction & building materials Vol. 338; p. 127649
Main Authors: Wang, YaChao, Xu, Mingrui, Zhao, JiangPing, Xin, A.
Format: Journal Article
Language:English
Published: Elsevier Ltd 04-07-2022
Subjects:
Flame retardants
Formaldehyde
Nano-ZnO
Pyrolysis kinetics
Silica fume
Flame retardants
Pyrolysis kinetics
Nano-ZnO
Formaldehyde
Silica fume
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:[Display omitted] •Nano-ZnO (0.47 wt%)/MPP doping imparts geopolymer coatings enhanced flame retardancy.•The ceramic-like ZnP4O11 makes pyrolysis Eα rise from 204.30 to 255.61 kJ·mol−1 at 800 ∼ 1000 °C.•The interpenetrating Si/C/P residues exert 56% formaldehyde-adsorption capacity. Herein the nano-ZnO/melamine polyphosphate (MPP) co-doped silica fume-based geopolymer composite coatings is fabricated for flame-retarding plywood. Its flame-retarding mechanism is investigated by microstructural characterizations and pyrolysis kinetics. The results show that an appropriate dosage of nano-ZnO (0.47 wt%) enhances flame retardancy, evidenced by the fire performance index increased to 2.98 s·m2·kW−1 from 1.10, the fire growth index (FGI) decreased from 0.48 to 0.23 kW·m−2·s−1, the flame retardant index (FRI) climbs from 1 to 2.79. Because the doped ZnO initiates the formation of ceramic-like Si/C/P residues, the as-formed ZnP4O11 is determined through the reactions between MPP and nano-ZnO. The ceramic-like reactions make the pyrolysis Eα rise from 204.30 to 255.61 kJ·mol−1 at 800 ∼ 1000 °C, according to the as-identified three-stage deceleration function (F3) of pyrolysis kinetics, resulting in the resilient and interpenetrating residues with a formaldehyde adsorption rate of 56%. It seeks effective recycling of metallurgical solid waste for preparing ecological flame-retarding coatings, proposing an efficient approach for quantitatively probing the Si/C/P residues.
ISSN:0950-0618
1879-0526
DOI:10.1016/j.conbuildmat.2022.127649