PAH emission from
the incineration of three plastic wastes
Environment
International v.27, i.1, Jul01
Chun-Teh Li, Huan-Kai Zhuang, Lien-Te Hsieh, Wen-Jhy Lee and Meng-Chun
Tsao
Department of Environment Engineering, National Cheng Kung University,
Tainan 70101, Taiwan, ROC
Received 8 May 2000; accepted 10 April 2001 Available online 27 June 2001.
Abstract
A batch-type, controlled-air incinerator was used for the treatment of
polyvinyl chloride (PVC), high-density polyethylene (HDPE), and
polypropylene (PP) plastic wastes. The concentration and composition of 21
individual polycyclic aromatic hydrocarbons (PAHs) in the raw wastes, flue
gas (gas and particle phases), and ash were determined. Stack flue-gas
samples were collected by a PAH stack-sampling system. Twenty-one
individual PAHs were analyzed primarily by a gas chromatograph/mass
spectrometer (GC/MS). The CO concentration correlated well with the total
PAH (R2>.89), and thus can be used as a surrogate indicator for PAH
emission. Excess amounts of air supply in the incineration of plastic
wastes could decrease not only the concentration of the PAHs in the bottom
ash but also the emission factor (EF) of the total PAH in the stack flue
gas. Of the three plastic wastes, HDPE was found to have the highest mean
EF of the total PAHs (462.3 mg/kg waste) from the stack flue gas.
Incinerating PVC would result in a higher EF of PAHs (195.4 mg/kg waste) in
the bottom ash. When PVC plastic wastes were incinerated, higher-ringed
PAHs constituted a larger percentage in the bottom ash as compared to those
from PP and HDPE plastics. By judging the output and input (O/I) ratio of
the PAHs from the incineration trials of plastic wastes, the PAHs involved
in incineration of three plastic wastes were almost entirely destroyed; and
a low residual amount between 0.00018 and 0.00032 remained in the emission.
Author Keywords: PAHs; Emission factor; Plastic wastes; Incineration;
Flue gas
1. Introduction
In recent decades, due to the worldwide use of plastic products, plastic
wastes have come to be a major component of both industrial and municipal
wastes. According to the estimation of investigations, the generation rate of
plastic wastes is over 1,700,000 ton/year in Taiwan (U.S. EPA, 1991). In many
countries, incineration is a traditional and available method in reducing the
different plastic wastes. In view of both reduction and destruction,
incineration is a valuable means of waste disposal with the advantage of being
highly effective in reducing the volume of waste. Thus, the method or technology
regarding incineration is becoming a more widespread concern. During the
incineration process, air pollutants such as CO, NOx, SOx, particles, and
polycyclic aromatic hydrocarbons (PAHs) are exhausted. Understanding the
characteristics of both formation and emission of PAHs is necessary because it
is proved that some PAHs are carcinogenic (Doll and Speizer). PAHs and their
derivatives are widespread harmful compounds generated by incomplete combustion
of organic material arising, in part, from natural combustion such as forest
fires and volcanic eruptions, but for the most important part, from human
activities (Bjorseth; Benner and Baek), such as industrial production,
transportation, waste incineration, and so on.
Tuominen et al. (1988) found that the major factor of effecting PAH
concentration in the city atmosphere was transportation exhaust. Masclet et al.
(1986) showed that higher molecular weight PAHs (such as, fluoranthene, pyrene,
coronene, and so on) were contributed mainly by mobile sources. Incineration of
wastes is also a major source of PAHs exhausted. Kamiya and Ose (1987)
investigated the mutagenic activity of fly ash and emission gases from municipal
waste incinerators and found that mutagens, equivalent to 1700-3000 cars, were
discharged from the incinerator into the environment. Chiang et al. (1992)
investigated the incineration of typical urban solid wastes containing plastic
components. Their results showed that the incineration temperature controlled in
the combustion zone and gasification zone exerted marked effects on the species
of PAHs in the particulate samples. Wheatley et al. (1993) studied that PAHs
were exhausted from the combustion of selected municipal plastic wastes. They
found that the changes in PAH emission were mainly attributable to the
postcombustion gas temperature and residence time. In addition, their results
indicated that the minimum emission of hydrocarbons was achieved at the highest
gas temperature (1150íC) and residence time (2 s).
The main objective of this study was to investigate the correlation between
air supply and PAH emission, the comparison of emission factor (EF) of three
plastic wastes, and the output/input (O/I) mass ratios of these 21 individual
PAHs from incineration trials of three kinds of plastic wastes. This information
is not only required for PAH control, but is also useful for the impact
assessment on both ambient air quality and health.
2. Materials and methods
2.1. Incineration system
The incineration of plastic wastes was investigated by using a solid grate
incinerator. This incinerator was produced and installed by Taiwan Lonesun,
Taipei, Taiwan. It was equipped with a primary and a secondary combustion
chamber, a stack, a control panel, an air-supply device, and an auxiliary fuel
feeding system. The wastes were burned batchwise (5 kg/run) by being fed
manually into the combustion chamber. The volumes of the primary and secondary
combustion chambers were 0.34 and 0.68 m3, respectively. In general, the
residence time of air flow going through the secondary combustion chamber was
between 0.8 and 1.5 s and is averaged at 1.1 s. In this study, seven runs of the
incineration experiment were investigated. During the incineration of
high-density polyethylene (HDPE) and polypropylene (PP), the operational
temperature was controlled at 450íC and 850íC for the first and second
combustion chambers, respectively. During the incineration of polyvinyl chloride
(PVC), the operational temperature was controlled at 400íC and 850íC for the
first and second combustion chambers, respectively. The excess air ratios of
these experimental runs were between 1.0 and 1.8.
2.2. PAH sampling system (PSS) for stack flue gas
After draft design, the PSS for flue gas was produced and installed by
Bay-Ming, Taipei, Taiwan. This PSS is based on the modification of the U.S.
EPA's sampling method 5 (MM5) (40CFR60) by Graseby (U.S. EPA, 1996). This PSS
was equipped with a sampling probe, a cooling device, a glass cartridge, a pump,
a flow meter, and a control computer. The flue gas was sampled isokinetically
from the stack. In this study, the operational flow rates of the PSS were
between 4.5 and 5.5 l/min and were averaged at 5.0 l/min.
A PSS with a tube-type glass fiber filter (cleaned by distilled deionized
water and heated to 450íC) was used to collect particulate and particle-phase
PAHs. A glass cartridge packed with XAD-16 resin and supported by a polyurethane
foam (PUF) plug was used to collect the phase PAHs. After each sampling cycle,
the sampling train was rinsed with n-hexane (Yang, 1998).
The glass fiber filters were weighed before and after sampling to determine
the amount of particles collected. PUF plugs and resin were always stored and
transported in clean screw-capped jars with Teflon cap liners. Glass fiber
filters were transported to and from the field in a prebaked glass bottle and
were wrapped with aluminum foil.
Breakthrough tests were investigated by three stages of XAD-16/PUF cartridge.
Each stage of XAD-16 resin was analyzed individually and compared for the PAH
mass collected in each stage. Three breakthrough tests were investigated in this
study and no significant PAH mass was found to be collected in the third stage
of XAD-16 resin. All the experiments were repeated to make sure that the results
were reproducible (Yang, 1998).
2.3. Sampling from ambient air
In order to calculate the O/I mass ratios of PAHs, both the particle and gas
phases of PAHs in the ambient air were collected on the day of incinerator
operation by using a standard semivolatile sampling train (General Metal Works
PS-1). Two sets of PS-1 samplers were operated simultaneously for 24 h during
the sampling periods to collect the PAHs. Besides, sets of 24-h samples have
been determined in this study. Before sampling, the PS-1 sampler with a glass
filter and puff cartridge was pretreated according to the same procedure used
for the PSS.
2.4. Plastic waste and ash samples
The plastic waste samples bought from a plastic shop in Tainan City were used
for this study. Information about plastic waste is shown in Table 1 and Table 2.
After weighing, 20 g of plastic waste and ash samples were placed in an oven
(104-105íC, respectively) for the measurement of moisture content and another
group of 20-g samples were extracted directly for the PAH analysis. Therefore,
the measured PAH composition in the plastic waste and ash samples, respectively,
is reported on the basis of dry weight.
Table 1. Components of three plastic wastes and liquid diesel (not
included here)
Table 2. Element composition and heat content of three plastic wastes
and liquid diesel (not included here)
2.5. Liquid diesel sample
The auxiliary fuel used for the incineration was liquid diesel (specific
GRAVITY=0.80; heating VALUE=10,948 kcal/kg), which was bought from a gas station
in Tainan City, Taiwan. Information about the diesel is shown in Table 2. A
10-ml sample of liquid diesel was cleaned up and reconcentrated for the PAH
analysis.
2.6. PAH analysis
After final weighing (if needed), the PAH sample was placed in a solvent
solution (the mixture of n-hexane and dichloromethane, vol:vol=500:500 ml,
respectively), and extracted in a Soxhlet extractor for 24 h. The extract was
then concentrated, cleaned up, and reconcentrated to exactly 1.0 or 0.5 ml.
(Manchester and Yang).
A gas chromatograph (GC) (Hewlett-Packard 5890A) with a mass selective
detector (MSD) (Hewlett-Packard 5972), and a computer workstation was used for
the PAH analysis. This GC/MS (mass spectrometer) was equipped with a
Hewlett-Packard capillary column (HP Ultra 2 -- 50 m*0.32 mm*0.17 m), an
HP-7673A automatic sampler, with injection volume at 1 l, splitless injection at
310íC, ion source temperature at 310íC, and an oven with ranges of 50-100íC
at 20íC/min and 100-290íC at 3íC/min, held at 290íC for 40 min. The masses
of primary and secondary ions of PAHs were determined using the scan mode for
pure PAH standards. Qualification of PAHs was performed using the selected
ion-monitoring (SIM) mode.
The concentrations of the following PAHs were determined: naphthalene (Nap),
acenaphthylene (AcPy), acenaphthene (Acp), fluorene (Flu), phenanthrene (PA),
anthracene (Ant), fluoranthene (FL), pyrene (Pyr), cyclopenta[c,d]pyrene (CYC),
benz[a]anthracene (BaA), chrysene (CHR), benzo[b]fluoranthene (BbF),
benzo[k]fluoranthene (BkF), benzo[e]pyrene (BeP), benzo[a]pyrene (BaP), perylene
(PER), indeno[1,2,3,-c,d]pyrene (IND), dibenzo[a,h]anthracene (DBA),
benzo[b]chrycene (BbC), benzo[ghi]perylene (BghiP) and coronene (COR).
PAH recovery efficiencies varied between 0.75 and 1.12 and were averaged at
0.845. The blank tests for PAHs were accomplished by using the same procedure as
the recovery-efficiency tests without adding the known standard solution before
extraction. Analyses of field blanks, including the glass fiber filter and
PUF/XAD-16 cartridge found no significant contamination (GC/MS integrated
area<detection limit).
2.7. Trial sampling
Prior to formal sampling, several trial burns were investigated to obtain
optimum waste-feed amounts (kilograms), air-supply rates, duration time of
incineration, and the sampling flow rate of PSS.
3. Results and discussion
3.1. Correlation between CO and total PAH concentration in the stack flue
gas
In general, the CO and CO2 concentration can be used as a surrogate indicator
for combustion efficiency. The formation of PAH is associated with incomplete
combustion. Hence, the correlation between CO and total PAH concentration in the
stack flue gas is worth discussing. Several previous investigations have
indicated that the CO concentration does not correlate well with the total PAH
concentration in the stack flue gas (Frenklach, 1990). However, the results in
this study present a positive correlation. As shown in Fig. 1, three R2 values
of the correlation between CO and the total PAH concentration were .93, .96, and
.89 for the case of incinerating PVC, PP, and HDPE wastes, respectively.
Although the incineration results from three different plastic wastes were not
the same, three relative trends of the total PAH concentration (g/nm3) vs. CO
concentration (ppm) were similar (Fig. 1A-C). With increasing CO concentration,
the total PAH concentration increases linearly in the case of incinerating PVC,
PP, and HDPE wastes. The trend in this study is consistent with the results
reported by Li et al. (1995). Since the increase of CO concentration occurs with
incomplete combustion, the total PAH concentration rises increasingly in the
stack flue gas, especially from incineration of PVC during the experiment
process.
Fig. 1. The correlation between CO and the total PAH concentration in
the stack flue gas by incinerating PVC, PP, and HDPE wastes, respectively.
(not included here)
3.2. Correlation between excess air ratio and PAH composition in the
bottom ash
The good correlation between excess air ratio and PAH composition in the
bottom ash by incinerating PVC, PP, and HDPE wastes, respectively, are shown in
Fig. 2A-C. The relative trends of three plastic wastes were similar, especially
the comparison between PP and PVC with the approximate PAH content level (1.92-2.16
g/g bottom ash). The R2 values of the three plastic wastes were .98, .93, and
.91 for PVC, PP, and HDPE, respectively. Compared with PP and PVC, the trend of
HDPE plastics was milder. This result indicated that increased air supply would
reduce the PAHs in the bottom ash; however, this drop was not as evident as the
effect found in the emission exhaust.
Fig. 2. The correlation between the excess air ratio and the PAH content
in the bottom ash by incinerating PVC, PP, and HDPE wastes,
respectively. (not included here)
3.3. Correlation between excess air ratio and EF of the total PAH in the
stack flue gas
The correlation between excess air ratio and EF of the total PAH in the stack
flue gas is shown in Fig. 3. When the excess air ratio increased, the mean EF of
the total PAH decreased linearly. In a comparison of the linear regression in
the three different plastic wastes (Fig. 3A-C), PVC is the best. The R2 values
of PVC, HDPE, and PP were .97, .88, and .71, respectively. The results also
suggested that by providing more air supply, the EF of the total PAH in the
stack flue gas could be reduced.
Fig. 3. The correlation between the excess air ratio and the EF of the
total PAH in the stack flue gas by incinerating PVC, PP, and HDPE wastes,
respectively. (not included here)
3.4. Comparison of EF of the total PAH among three plastic wastes
Fig. 4A and B shows the mean EFs of the total PAH in the stack flue gas were
320.5, 315.3, and 462.3 mg/kg waste for PVC, PP, and HDPE, respectively. The
mean EF of the total PAH from the stack flue gas for HDPE was 1.5 times higher
than that for PP and PVC. In the bottom ash, the mean EF of the total PAH was
195.4, 45.2, and 71.4 mg/kg waste for PVC, PP, and HDPE, respectively. The mean
EF of the total PAH from the bottom ash for PVC is 4.33. and is 2.74 times
higher than that from the bottom ash for PP and HDPE, respectively. This is due
to the fact that incinerating PVC needed the lower combustion temperature.
Fig. 4. The comparison of total PAH EFs among incinerating three plastic
wastes. (not included here)
3.5. Distribution of PAH output mass
The PAH mass discharged from the incinerator includes the mass from stack
flue gas and that from ash residue. In this study, the mean output mass fraction
of the total PAH was 78.8% and 21.2%, discharged from the stack flue gas and ash
residue, respectively. The total PAH mass was emitted mainly by the stack flue
gas. Fig. 5 shows the distribution of individual PAH mean output mass fractions
by incinerating PVC, PP, and HDPE, respectively. Lower molecular weight PAHs --
Nap, AcPy, Acp, and Flu -- had dominant fractions of their mass discharged by
the stack flue gas. Furthermore, it is clear that the distribution of the
individual PAHs exhausted by incinerating PP and HDPE wastes was similar. It is
associated with the fact that PP and HDPE plastic wastes were similar in both
physical and chemical properties. When PVC plastic wastes were incinerated,
higher-ringed PAHs constituted a larger percentage in the bottom ash as compared
to those from PP and HDPE plastics. This is exactly the characteristic of PAHs
exhausted.
Fig. 5. The distribution of individual PAH output mass fractions by
incinerating PVC, PP, and HDPE wastes, respectively. (not included
here)
3.6. PAH O/I mass ratio
Table 3 shows the PAH O/I mass ratios from the incineration trials of three
kinds of plastic wastes. The total PAH O/I mass ratios were between 0.00018 and
0.00032 and were averaged at 0.00024. During incineration of PP plastics, the
BbF O/I mass ratio was the highest -- 0.05035. However, it was still quite low.
As a whole, most of the PAHs have been destroyed during the incineration of the
three plastic wastes, and the remains of PAHs that exist in the emission became
rarer (Table 3). This is associated with the fact that the three plastic wastes
are just suitable for incineration and the level of PAH content in those plastic
wastes is not high. In this study, the result was similar to that from previous
measurements (BjÏrseth and Ramdahl, 1985).
Table 3. The input and output ratio of the PAHs from the incineration of
three kinds of plastic wastes (not included here)
4. Conclusions
(1) The result indicated that the CO concentration correlated well with the
total PAH (R2>.89), and thus can be used a surrogate indicator for PAH
emission. Despite the difference in the incinerating results of the three
plastic wastes, the relative trend of the total emission concentration of PAH
vs. CO concentration was similar.
(2) Excess amounts of air supply in the incineration of plastic wastes could
decrease not only the concentration of the PAHs in the bottom ash but also the
EF of the total PAH in the stack flue gas. The relationship between the amounts
of PAH in the bottom ash of PP plastics and PVC plastics and the excess air
ratios was similar. In HDPE plastics, the trend was milder.
(3) Of the three plastic wastes, HDPE was found to have the highest EF (462.3
mg/kg waste) of the total PAH from the stack flue gas. Incinerating PVC would
result in a higher EF (195.4 mg/kg waste) of PAH in the bottom ash.
(4) Lower molecular weight PAHs -- Nap, AcPy, Acp, and Flu -- had dominant
fractions of their mass discharged by the stack flue gas. The distribution of
the individual PAH exhausted by incinerating PP and HDPE wastes were similar.
When PVC plastics were incinerated, higher-ringed PAHs constituted a larger
percentage in the bottom ash as compared to those from PP and HDPE plastics.
(5) By judging the O/I ratio of the PAH from incineration trials of plastic
wastes, the PAHs of incineration of three plastic wastes were almost entirely
destroyed, leaving a low residual amount, between 0.00018 and 0.00032, in the
emission. The key points are that the plastic wastes themselves are suitable for
incineration and the PAH content in the plastic wastes is not high.
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Corresponding author. Tel.: +886-6-275-7575 ext. 54520; fax: +886-6-275-2790
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