Abstract:Resorcinol-formaldehyde (RF) resin is a kind of excellent exterior-grade wood structural adhesive, which can be conveniently cold-set for various applications. In order to decrease the production cost, pyrolysis bio-oil from renewable bioresources was used to replace resorcinol to synthesize the bio-oil-resorcinol-aldehyde (BRF) resin. The effect of replacing resorcinol with bio-oil on the properties, bonding performance, and characterization of resorcinol-aldehyde resin was comparatively investigated. A highe… Show more
“…The spectrum of olivetol showed the characteristic peaks of this drug according to the literature at 690 cm − 1 , 830 cm − 1 , 1145 cm − 1 , 1210 cm − 1 , 1310 cm − 1 , 1376 cm − 1 , 1477 cm − 1 , 1600 cm − 1 , 1628 cm − 1 , 2858 cm − 1 , 2929 cm − 1 and 3240 cm − 1 (Fig. 4A) [42][43][44]. At 690 cm − 1 and 830 cm − 1 wavenumbers, two peaks from CH out of plane deformations were observed because of the triple substitution in one, three and five carbon positions in the benzene ring of the OLV.…”
“…The spectrum of olivetol showed the characteristic peaks of this drug according to the literature at 690 cm − 1 , 830 cm − 1 , 1145 cm − 1 , 1210 cm − 1 , 1310 cm − 1 , 1376 cm − 1 , 1477 cm − 1 , 1600 cm − 1 , 1628 cm − 1 , 2858 cm − 1 , 2929 cm − 1 and 3240 cm − 1 (Fig. 4A) [42][43][44]. At 690 cm − 1 and 830 cm − 1 wavenumbers, two peaks from CH out of plane deformations were observed because of the triple substitution in one, three and five carbon positions in the benzene ring of the OLV.…”
“…The peak at 1112 cm −1 indicates C–H stretching vibrations in different groups of lignin [ 34 ]. C–H aliphatic bonds are detected at 880 cm −1 and the C–H aromatic bonds of phenol can be observed at 828 cm −1 , 758 cm −1 , and 694 cm −1 [ 27 , 33 , 35 ]. Figure 3 FTIR spectra of PR, LR-5–15 (HAO), and LR-5–15 (VRE) resoles.…”
We investigate two different dehydration methods to determine their suitability for preparing resoles for foam synthesis. A simplified process for synthesizing lignin foam (LF) from lignin resole (LR) dehydrated in a hot air oven (HAO) is compared with that dehydrated using a vacuum rotary evaporator (VRE). First, the LR formulation is prepared by mixing phenol with untreated lignin (0%–15% by weight), and subsequently, the prepared LRs are dehydrated using an HAO and a VRE. We find that for the same dehydration time, both techniques yield LRs with the same chemical compositions; however, the HAO technique affords a moisture removal of 13–17% by weight, whereas the VRE technique removes 9–12% moisture by weight. The LR obtained by the HAO is more viscous and maintains a circular shape after being dropped on a plate. In our experimental synthesis of LF containing VRE resole, biofoam is not formed owing to insufficient viscosity, whereas biofoam is obtained with the HAO resole. The synthesized LF exhibits a density range of 44.96–85.68 kg/m
3
and a compressive strength of 103.28–152.27 kPa. Scanning electron microscopy investigations show that the morphology of the foam is a closed-cell structure. The simplified synthesis of LF from the HAO-treated resole offers significant advantages over the complexity of the conventional VRE approach in terms of equipment cost and energy consumption. The resulting foam exhibits a thermal stability and thermal performance comparable with the counterpart properties of phenolic foam.
“…3 TGA FTIR analysis of (a) 3D plot of MBO and (b) hot volatile released during pyrolysis of MBO Fig. 4 FTIR spectrum of MBO recognized as the stretching of C-O that indicates an attendance of alcohol and aliphatic ethers [41]. The peaks originating within 500-900 cm −1 represented an aromatic C-H stretching vibration that exhibited attendance of poly and mono aromatic in the bio-oil [21].…”
In this work, mixed bio-oil (MBO) is transformed into valuable biocarbon through slow pyrolysis technique. MBO was accomplished in a semi-batch reactor at 600 and 900 °C temperature, 10 °C min−1 heating rate, and 30 min holding time under a non-oxidizing environment. The produced mixed bio-oil-derived biocarbon (MBOB) was characterized by its surface properties, thermal stability, elemental composition, thermal conductivity, BET surface area, surface morphology, and electrical conductivity. The pyrolysis outcomes established that the temperature has a predominant impact on the variation in yield and properties of MBOB. Characterization results of MBOB exposed increased properties (thermal stability, electrical and thermal conductivity, graphitic content, carbon content, and HHV) at 900 compared to 600 °C. Also, the elemental and EDS investigation of MBOB established a broad diminution in O2 and H2 at 900 than 600 °C. The purest form of carbon with enhanced thermal stability, higher carbon content, smoothness, and bigger particles of biocarbon (verified by SEM) is accomplished at 900 °C. The electrical and thermal conductivity (EC and TC) of MBOB increased with increasing the temperature from 600 to 900 °C due to the close contact of biocarbon particles. Finally, an investigation of the particle size of MBOB established that the majority of particles are within 1.5 to 1.7 µm.
Graphical abstract
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