WOOD RESEARCH Volume 67, Number 5, 2022
Renyuan Liu, Zhuliang Zeng, Quan Li, and Cenlong Hu

The effects of ACQ and water glass on the color change and decay resistance of carbonized bamboo

In this study, samples of bamboo and carbonized bamboo were impregnated with alkaline copper quaternary (ACQ) and water glass, the resulting differences in color and resistance to decay by Gloeophyllum trabeum were evaluated. The results showed that the impregnated bamboo and carbonized bamboo greatly reduced their lightness (L*). The red-green color index (a*) first decreased and then increased, while the yellow-blue color index (b*) first increased and then decreased. The total chromatic aberration (ΔE) was largest for bamboo and carbonized bamboo impregnated with ACQ and allowed to decay. Carbonized bamboo impregnated with ACQ and water glass and bamboo impregnated with ACQ reached level I (strong decay resistance). The decay resistance of bamboo and carbonized bamboo was as follows: ACQ impregnated > water glass impregnated > CK. Scanning electron microscopy further confirmed that the bamboo and carbonized bamboo were impregnated with ACQ had fewer hyphae, the maintained intact structure, and good decay resistance.

WOOD RESEARCH Volume 65, Number 6, 2020
Quan Li, Renyuan Liu, Xiaoqian Chen, and Hui Lin

Box-Behnken design for process parameters optimalization of bamboo-based composite panel manufacturing

High performance bamboo-based composite panel taking bamboo mats, bamboo curtains and poplar veneers are used as raw material, is manufactured from the each layers slab was crisscrossed, impregnated with phenolic resin, compressed and cured. The product was optimized by Box-Behnken model design and data analysis. The results show that the best parameter conditions were hot pressing temperature of 140°C, hot pressing time of 94 s.mm-1, and hot pressing pressure of 2.5 MPa. The model was validated according to the optimal process parameters and the static bending strength (MOR), elastic modulus (MOE), thickness expansion rate of water absorbing, adhesive strength and density are 98.95 MPa, 8.81 GPa, 4.7%, 1.25 MPa, 0.89 g.cm-3, respectively. The actual value is close to the predicted value, confirming that the obtained model can accurately predict the MOR of the product using the three factors of hot pressing as variables under different conditions.

WOOD RESEARCH Volume 65, Number 4, 2020
Huimin Zhang, Kai Tu, Qiandong Hou, Hui Lin, and Quan Li

The physiological and biochemical mechanisms of Cinnamomum camphora xylem extracts inhibit wood-decay fungi

The present study investigated the physiological and biochemical mechanism of extracts derived from Cinnamomum camphora (L.) Presl. The methanol and chloroform extracts of C. camphora xylem exhibited inhibitory activity against oxygen consumption in Coriolus versicolor and Gloeophyllum trabeum. The inhibitory effect of cellulose secreted by G. trabeum was concentration-dependent. The application of the ethyl acetate extracts of C. camphora xylem on the G. trabeum hyphae resulted in an improvement in electric conductivity, which followed a concentration-dependent fashion. Protein permeability increased with higher concentrations of the ethyl acetate extracts of C. camphora xylem. This research provided theoretical basis for understanding of the physiological and biochemical mechanisms of C. camphora extracts inhibit wood-decay fungi and the development of natural extracts as wood preservatives.

WOOD RESEARCH Volume 65, Number 4, 2020
Quan Li, Huimin Zhang, Hongguang Yan, Wenyu Qi, Jinguo Lin, and Jiqing Li

Emission of volatile camphor compounds from Cinnamomum camphora wood

Essential oil volatilization of Cinnamomum camphora (L.) Presl can positively affect indoor air quality through insect dispersal, antibacterial effects, and inhibiting decay, and thus is an important economic species in China. Camphor is the most abundant aromatic compound in C. camphora, although how time and temperature affect the release of the camphor is unknown. To address this question Cinnamomum camphora (C. camphora) wood was investigated using headspace gas chromatography (HS-GC). Camphor decreased with increasing detection times over temperatures of different temperature. During the detection, the release rate of camphor decreased rapidly with increased heating time in the first 2.5 h, and leveled-off after 2.5 h. The release of camphor at different temperatures was linear between 0 ~ 1.4 h.
By fitting this linear model with reaction temperature camphor release could be expressed as Y = -75.369 + 2.3786.T + (41.125 – 1.1972.T). Evaluating the release of camphor from C. camphora wood and creating a model may be useful for promoting its application in the medical and chemical industries.