Post on 27-May-2015
Thermal, Mechanical, and Physical
Properties of Wood-Plastic
Composites with Added Biochar
David DeVallance,
Gloria Oporto,
George Cheng, and
Patrick Quigley
The long-term goal of this research:
• Integrate bio-energy related by-products,
particularly biochar, with plastics and wood by-
products to create sustainable composite products
The objective in this project:
• To combine biochar with wood flour and polymeric
materials (i.e., plastics) to fabricate a novel
composite material
GOALS & OBJECTIVES
• Wood and most polymers (i.e., plastics) are not
compatible
• Polymers – hydrophobic (i.e., non-polar)
• Wood – hydrophilic (i.e., polar)
• Traditional WPC’s use coupling agents
• Most WPCs undergo some UV degradation and
lighten over time (Falk et al. 2001)
• Carbon black – additive to reduce UV degradation
• There is a need to identify alternative,
environmentally friendly materials that can replace
the currently used additives in WPCs
• Biochar - Viable replacement for WPC
additives?
BACKGROUND
Biochar • By-product of slow pyrolysis
processes used to produce
gas and bio-oil (Sohi et al., 2009)
• Exhibits a hydrophobic
nature (Maciejewska, et al. 2006)
• Should reduce UV
degradation in WPCs
BACKGROUND
• Has a higher ignition temperature, as opposed to
wood fiber (Antal and Gronli, 2003)
• Should be more thermal resistant than wood
EXPERIMENTAL Wood (yellow-poplar), Biochar (mixed hardwoods), and
Polypropylene (with lubricant) were combined to form
composites
EXPERIMENTAL Component were mixed using a Haake PolyDrive blender
Composite specimens for physical and mechanical
analysis prepared using a Carver Hot press (Temp.
200°C, Pressure 8.9 kN)
EXPERIMENTAL Mechanical properties evaluated using an Instron
Universal Test Machine
Water absorption and swelling were measured after
24 and 48 hours
Thermogravimetric analysis (TGA, DTGA) was
performed
TEST RESULTS: Bending
Composites with biochar
included resulted in a
statistically significant
higher flexure strength
(MOR), as compared to
the composites without
biochar
Box-and-Whisker Plot
Fle
xu
ral S
tre
ng
th (
MP
a)
Group
Exp. 1 Exp. 2 Exp. 3 Exp. 4 Exp. 5
8
12
16
20
24
Modulus of Rupture, MOR (MPa)
Summary Statistic 40/0/60 35/5/60 25/15/60 15/25/60 0/40/60
Average 16.1 19.4 20.4 21.3 19.5
St. Dev. 4.3 1.4 1.6 1.5 2.3
COV % 26.7 7.1 7.7 7.2 11.8
Minimum 8.7 17.0 17.6 18.4 15.8
Maximum 23.6 21.6 23.0 23.6 22.4
TEST RESULTS: Tension Box-and-Whisker Plot
Te
ns
ile
Str
en
gth
(M
Pa
)
Group
Exp. 1 Exp. 2 Exp. 3 Exp. 4 Exp. 5
7.9
9.9
11.9
13.9
15.9
While two composites
that included biochar
(5% and 15%) resulted in
higher average tensile
strengths, the
differences were not
statistically significant
Tensile Strength, Ft (MPa)
Summary Statistic 40/0/60 35/5/60 25/15/60 15/25/60 0/40/60
Average 11.2 12.5 12.0 10.8 11.0
St. Dev. 1.4 1.3 1.3 1.3 0.9
COV % 12.6 10.1 11.1 12.3 8.1
Minimum 9.4 10.2 9.6 7.9 9.0
Maximum 14.3 14.4 14.9 12.5 12.4
TEST RESULTS: Water Absorption
Water absorption is reduced by 25%, 51% and 73%
after the incorporation of 5%, 15% and 25% biochar
TEST RESULTS: Swelling
Although reduction in swelling is observed after the
addition of biochar, no statistically significant
difference was found
TEST RESULTS: Thermogravimetric
Analysis (TGA & DTGA)
Considering a 10% of weight loss, biochar increase
the composite decomposition temperature from
315°C to 360°C when 15% is added to the mixture
On-going research
Research is underway to evaluate:
1. Potential improvements in UV degradation,
2. Flame resistance,
3. Conductivity,
4. Mechanical properties with the incorporation of
coupling agent, and
5. Microbial degradation after the incorporation of
biochar in wood-plastic composites (WPCs)
Major Conclusions
Addition of biochar appears to have:
1. Improved strength properties,
2. Improved thermal degradation properties, and
3. Reduced water absorption
Acknowledgments:
Dr. Rakesh Gupta, Chair of the Chemical Engineer
Department at West Virginia University, for giving us
access to some laboratory equipment
Questions? Further Information: david.devallance@mail.wvu.edu
References:
Antal, M.J. and Gronli, M. 2003. The art, science, and technology of charcoal
production. Ind. Eng. Chem. Res. 2003(42):1619-1640.
Falk, R.H., T. Lundin, and C. Felton, 2001. Accelerated weathering of natural
fiber-thermoplastic composites: Effects of ultraviolet exposure on bending
strength and stiffness. In: Proc. Sixth International Conference on Woodfiber-
Plastic Composites. Forest Prod. Soc., Madison, WI. pp. 87-93.
Maciejewska, A., H. Veringa, J. Sanders, and S.D. Peteves. 2006. Co-firing of
biomass with coal: Constraints and role of biomass pre-treatment. DG JRC
Institute for Energy. Retrieved October 21, 2010, from
<http://www.techtp.com/Cofiring/Cofiring%20biomass%20with%20Coal.pdf>
Sohi, S., E. Lopex-capel, E. Krull, and R. Bol. 2009. Biochar, climate change
and soil: A review to guide future research. CSIRO Land and Water Science
Report. Retrieved April 28, 2010, from, <http://www.csiro.au/files/files/poei.pdf>.