2010
DOI: 10.1016/j.biortech.2010.05.040
|View full text |Cite
|
Sign up to set email alerts
|

Physiochemical properties of bio-oil produced at various temperatures from pine wood using an auger reactor

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...
1
1
1
1

Citation Types

14
75
0
3

Year Published

2011
2011
2023
2023

Publication Types

Select...
7
1
1

Relationship

1
8

Authors

Journals

citations
Cited by 216 publications
(94 citation statements)
references
References 31 publications
14
75
0
3
Order By: Relevance
“…In general, the viscosity of bio-oils produced from different feedstocks decreased with an increase in temperature. Similar trends were reported for biooils produced from different feedstocks such as softwood bark (Boucher et al, 2000a, b), sugarcane bagasse (Garcia-Perez et al, 2002), rice husk (Zhang et al, 2006), switchgrass (Boateng et al, 2007), corn stover (Yu et al, 2007), hardwood (Tzanetakis et al, 2008), pine and oak wood and bark (Ingram et al, 2008), pine wood chips (Thangalazhy-Gopakumar et al, 2010), and rice husk (Ji-Lu & Yong-Pong, 2010). When temperature was increased from 20 to 40ºC, viscosity of bio-oil from canola showed a minimum decrease of 9% and bio-oil from corn cob 1 showed a maximum decrease of 25%.…”
Section: Effect Oftemperature On Viscosity Of Bio-oils From Differentsupporting
confidence: 73%
See 1 more Smart Citation
“…In general, the viscosity of bio-oils produced from different feedstocks decreased with an increase in temperature. Similar trends were reported for biooils produced from different feedstocks such as softwood bark (Boucher et al, 2000a, b), sugarcane bagasse (Garcia-Perez et al, 2002), rice husk (Zhang et al, 2006), switchgrass (Boateng et al, 2007), corn stover (Yu et al, 2007), hardwood (Tzanetakis et al, 2008), pine and oak wood and bark (Ingram et al, 2008), pine wood chips (Thangalazhy-Gopakumar et al, 2010), and rice husk (Ji-Lu & Yong-Pong, 2010). When temperature was increased from 20 to 40ºC, viscosity of bio-oil from canola showed a minimum decrease of 9% and bio-oil from corn cob 1 showed a maximum decrease of 25%.…”
Section: Effect Oftemperature On Viscosity Of Bio-oils From Differentsupporting
confidence: 73%
“…In order to transport the bio-oil in pipeline, the temperature of the pipeline should be maintained in the range of 35-45ºC to keep the viscosity similar to that of crude oil (Pootakham & Kumar, 2010a, b). According to Thangalazhy-Gopakumar et al (2010), viscosity of bio-oil is relatively higher than that of diesel (0.011 Pa.s) and gasoline (0.006 Pa.s). In general, high viscosity fuel results in poor atomization and incomplete combustion, formation of excessive carbon deposits on the injection nozzles and the combustion chamber, and contamination of the lubricating oil with unburnt residues.…”
Section: Significance Of Bio-oil Viscositymentioning
confidence: 99%
“…Lepkość kształtowała się w typowym zakresie dla biooleju z biomasy lignocelulozowej [2,16]. Obecność w biooleju z mikroalg związków azotowych (indole, pirydyna, aminy czy amoniak) przekłada się na odczyn alkaliczny (pH = 9,2÷9,5), co jest różne od wartości pH bioolejów uzyskanych z biomasy lignocelulozowej (na ogół pH = 2÷3) [16]. Podobne rezultaty w odniesieniu do pH bioolejów uzyskanych z mikroalg opisywali również inni badacze [5,8].…”
Section: Analiza Składu Oraz Właściwości Fizykochemicznych Bioolejuunclassified
“…Generally, the primary thermal degradation of biomass occurs at a lower pyrolysis temperature. The pyrolytic volatiles were further cracked into low molecular weight organics and gases rather than biochar as the pyrolysis temperature increased [17]. Losses in hydrogen and oxygen content at high pyrolysis temperature were attributed to the cleavage and cracking of weak bonds within the biochar structure [18].…”
Section: Characteristics Of the Samplesmentioning
confidence: 99%