The material strategy of fire-resistant tree barks | Health & Environmental Research Online (HERO)

HERO ID

6656791

Reference Type

Journal Article

Title

The material strategy of fire-resistant tree barks

Author(s)

Tributsch, H; Fiechter, S; ,

Year

2008

Is Peer Reviewed?

1

Journal

WIT Transactions on the Built Environment
ISSN: 1743-3509

Publisher

WIT PRESS/COMPUTATIONAL MECHANICS PUBLICATIONS

Location

SOUTHAMPTON

Book Title

WIT Transactions on the Built Environment

Volume

97

Page Numbers

43-52

Language

English

DOI

10.2495/HPSM080051

Web of Science Id

WOS:000256986600005

URL

https://www.scopus.com/inward/record.uri?eid=2-s2.0-58849144629&doi=10.2495%2fHPSM080051&partnerID=40&md5=e10f2f6da46ecb82fe8dd2154883c898
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Abstract

The fire protection of organic building and thermal insulation materials is a technical challenge, for which new approaches are desirable. Exceptionally fire resistant tree barks from trees such as Sequoiadendron giganteurn, Pinus canariensis and from Eucalyptus species, which evolved in fire adapted eco-systems, were studied by thermo-gravimetric techniques in combination with mass spectroscopy and complementary analysis in a temperature range up to 600'C. It turned out that while a technical reference poymer (ABS = acryinitrilebutadien-styrole) burned by leaving only 2.6% solid, the most fire resistant tree barks only carbonized leaving up to 60% solid. It is mostly graphite and carbon, which are highly heat insulating and fire protecting as is also known from technical "foaming" graphite layers. A key chemical component that has evolved in tree barks to support fire resistance, besides other properties, is tannin, a polyphenol, which complexes macromolecules and efficiently reduces oxidants and radicals. The oxidation, in a fire, of these large planar molecules is thus suppressed to be transformed into a similarly structured graphitic component with fire retarding properties. Additional adaptations of fire resistant tree barks appear to be a fibrous micro- and nano-structure and optimised infrared optical properties. They may retard heat transfer within the bark via suppression of microscopic conduction and radiation processes.

Keywords

Eucalyptus; Fire retardation; Sequoia; Tannins; Tree barks

Editor(s)

DeWilde, WP; Brebbia, CA;

ISBN

978-1-84564-106-1

Conference Name

4th International Conference on High Performance Structures and Materials

Conference Location

Algarve, PORTUGAL