Preliminary Results of Wood Plastics Composite: An Innovative
Eco-friendly Product
Arif Nuryawan
1
, Iwan Risnasari
1
, Rahmawaty
2
, Esra Y. S. Purba
1
and Nova O. Hutauruk
1
1
Department of Forest Products Technology, Faculty of Forestry, Universitas Sumatera Utara, Medan, Indonesia
2
Department of Forest Management, Faculty of Forestry, Universitas Sumatera Utara, Medan, Indonesia
Keywords: Wood Plastics Composite, Grave Yard Test, Weight Loss.
Abstract: The eco-friendly wood plastics composite (WPC) made of low density polyethylene (LDPE) as the matrices
and 80-mesh wood powder as the filler have been produced in various percentage composition, namely 85/15;
90/10; and 95/5 (w/w) using compounding process with xylene as the solvent of the plastics. Physical and
mechanical properties have been investigated according to Japanese Industrial Standard (JIS) A 5908 for
particleboard. In this contribution, emphasizing on the WPC as the eco-friendly product has been discussed
through their capability to degrade after grave yard test. Even though the result of weight loss for the WPC’s
samples after buried in the soil for 50 days were very light, these results indicated that WPC has capability to
decompose. In other words, products of WPC were environmentally friendly because they will deteriote after
certain time buried in the soil although the composition of the plastics was majority.
1 INTRODUCTION
Wood plastics composite (WPC) is made by
thoroughly mixing hydrophobic plastics as the matrix
and hydrophilic wood as the filler (Suzuki, 2014).
The types of wood filler are consisted of wood
particle, wood flour, and wood pulp having different
dimensions (size and shape) and aspect ratio (Kim,
2014). Initially, application of WPC can be found in
automotive industry for interior parts such as door
inner panels and seatbacks (Ozdemir & Mengeloglu,
2008) but to date, the use of WPC are more expand
including in housing components such as decking,
fencing, flooring, railings, moldings, and roofing
(Caufield et al., 2005); and also infrastructure such as
marine and boardwalks (Homkhiew et al. 2015).
Numerous investigators have been studied the
manufacturing process of WPC (Ozdemir &
Mengeloglu, 2008; Rahman et al., 2013);
compatibility of hydrophobic plastics as the matrix
and hydrophilic wood as the filler (Bledzki et al.,
1998; Catto et al. 2014); properties of resulted WPC
(Rahman et al., 2013; Catto et al. 2014); but only
limited reports were found in durability of WPC
(Schrip et al., 2008). Therefore in this contribution,
investigation on degradation of WPC was reported.
The WPC was intended to be manufactured with
predominant plastics in their composition in order to
encapsulate the wood filler with the plastics. In this
circumstance, if an organism like termite attacks the
wood filler for feed, the matrices plastics should be
broken first either physically or biologically. Termite
will bite the surface of WPC to get the wood filler for
feed. Physically the WPC will be broken down and
biologically presumably the termite eats some part of
plastics accidentally.
In this report, weight loss of the WPC after buried
in the soil will be revealed. Others results such as
micro-morphology of the WPC after grave yard test,
spectroscopy test of termite’s guts after WPC’s
feeding, and physical and mechanical properties of
WPC will be declared elsewhere in upcoming
publications. Therefore, the aim of this study was to
observe step by step WPC alteration after
decomposing in the soil particularly from weight loss
point of view.
98
Nuryawan, A., Risnasari, I., Rahmawaty, ., Purba, E. and Hutauruk, N.
Preliminary Results of Wood Plastics Composite: An Innovative Eco-friendly Product.
DOI: 10.5220/0010097600980101
In Proceedings of the International Conference of Science, Technology, Engineering, Environmental and Ramification Researches (ICOSTEERR 2018) - Research in Industry 4.0, pages
98-101
ISBN: 978-989-758-449-7
Copyright
c
2020 by SCITEPRESS – Science and Technology Publications, Lda. All rights reserved
2 MATERIALS AND METHODS
2.1 Preparation of Raw Materials
Commercial granule thermoplastics of LDPE (low
density polyethylene) with specific gravity of 0.93
g/cm
3
and the melting point of 110C, was used as the
matrix. Wood filler was obtained by sieving industrial
sawdust of durian-wood (Durio sp.) collected from
local mills to 80-mesh particle size. The wood particle
was then dried in an convection oven for 24 h at
(105+2)C. Xylene as the solvent of the plastics was
reagent grade and purchased in local chemical store
in Medan city.
2.2 Manufacturing Process
Here, compounding process was applied in this work.
The process can be described as blending process
which consists of mixing, kneading, and shearing,
respectively prior to manufacturing products (Kim,
2014). Hence, in WPC, the compounding process is
normally done to blend WPC compositions. Blended
and compounded ingredients are formed into pellets
for future processing. The compositions of the raw
materials were shown in Table 1.
Table 1. Compositions of the raw materials for making
WPC
Composition
LDPE:wood filler
Amount of
LDPE (g)
Amount of
wood filler (g)
85:15 186 33
90:10 197 22
95:5 208 11
In this regards, traditional method of dissolution
of the plastics was applied (Achilias et al., 2007). The
solvent was placed in the reactor and then the mantle
heater was heated up to 110C. Subsequently, a
certain amount of plastics were added and the mixture
was heated under reflux for 25-30 minutes until the
plastics had reached their melting temperature. After
all of the plastics dissolved, wood filler was added
and stirred gently approximately 10 minutes. The
mixture in the form of pellets then was conditioned in
fume hood for 24 h in order to evaporate the solvent.
The resulted pellets then was flat-pressed in
105C using laboratory hydraulic hot press for 6
minutes for converting into board with size dimension
of 25 cm x 25 cm and 0.5 cm in thickness with target
density of 0.7 g/cm
3
.
2.3 Durability Test
Prior to undergo test of durability, the WPC was cut
into samples with size dimension of 5 cm x 5 cm as
shown in Figure 1.
Figure 1. Specimen of respective WPC for durability testing
in various proportions of plastics and wood filler (85:15,
90:10, and 95:5)
The specimens were buried in the soil for 50 days
and they were weight every 10 days for measuring the
weight loss. The resulted data were tabulated and the
discussion regarding this data was presented. In order
to avoid the influence of moisture content, the
specimens were dried in convection oven for 24 h at
(105+2)C prior to balance. Observation of their
alteration in micro-morphology before and after
grave yard test will be reported in upcoming
publications.
3 RESULTS AND DISCUSSIONS
Typical WPC in this research was shown in Figure 2.
The WPC showed distinguish parts between LDPE
matrices and wood filler under bright field
microscope. Further advance micro-morphological
characterization is needed to ensure clearly identify
wood particle was encapsulated with the matrix in
the WPC system, for instance previous work of one
the author (Singh et al., 2013) in using FE-SEM (field
emission scanning electron microscope) for resolving
particle-matrix interfaces in the WPC.
In addition, wood filler appeared covered with
LDPE plastics thus wood degrading organisms like
termite will attack the plastics first before reach the
edible wood. This condition is very important for
investigating further such as behavior of termite in
reaching edible wood; spectroscopy of termite’s guts
whether it contains plastics or not, and description of
the micro-morphology of the WPC prior and after
durability test whether the changes occurs only on the
surface or into inner part of WPC.
Preliminary Results of Wood Plastics Composite: An Innovative Eco-friendly Product
99
Figure 2. Typical wood filler which was covering LDPE
matrices in specimen WPC with proportion of plastic and
wood of 85:15. (A) under bright field microscope with 4x
magnification and (B) with higher 10x magnification view
of the red box in Fig.A
The weight of the WPC samples prior and after
grave yard test in certain periods was shown in Table
2.
Table 2. Data of weight of the WPC samples before and
after buried in the soil in certain days
Type
of
WPC
WPC
85:15
WPC
90:10
WPC
95:5
Weight
(
g
)
Initial
8.67
(0.32)
8.36
(0.77)
8.48
(0.77)
10
th
da
y
8.62
(0.31)
8.31
(0.78)
8.46
(0.76)
20
th
da
y
8.56
(0.32)
8.25
(0.78)
8.42
(0.76)
30
th
da
y
8.52
(0.32)
8.21
(0.80)
8.39
(0.75)
40
th
da
y
8.47
(0.31)
8.16
(0.80)
8.35
(0.76)
50
th
da
y
8.42
(0.31)
8.11
(0.81)
8.30
(0.76)
Remarks: the parentheses is the standard deviation
From the data presented in Table 2, there was a
consistent tendency of the weight loss. The longer
buried in the soil, the weight of the WPCsample
decreased. Although plastics can hinder wood filler
from organisms attacks, the weight loss of the sample
were occurs and inevitable. According to the best
knowledge of the authors, wood can easily degrade
vice versa with the plastics; they are very difficult to
be decomposed. Therefore, they were factors made of
the WPC deteriorate and they need investigate
further, such as wood decaying fungi or symbioses
between mold and termite as the agent of degrading
wood.
4 CONCLUSIONS
Products of WPC were environmentally friendly
because they will deteriote after certain time buried in
the soil although the composition of the plastics was
majority
.
ACKNOWLEDGEMENTS
The authors thank to University of Sumatera Utara for
funding this research under scheme of Penelitian
Terapan TALENTA-USU year of 2018, contract
number 2590/UN5.1.R/PPM/2018 date March 16,
2018
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