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 CCHHEEMMIICCAALL  EENNGGIINNEEEERRIINNGG  TTRRAANNSSAACCTTIIOONNSS  
 

VOL. 39, 2014 

A publication of 

 
The Italian Association 

of Chemical Engineering 

www.aidic.it/cet 
Guest Editors: Petar Sabev Varbanov, Jiří Jaromír Klemeš, Peng Yen Liew, Jun Yow Yong  

Copyright © 2014, AIDIC Servizi S.r.l., 

ISBN 978-88-95608-30-3; ISSN 2283-9216 DOI: 10.3303/CET1439212 

 

Please cite this article as: Yuwapornpanit R., Jitkarnka S., 2014, Quality improvement of waste tyre pyroysis oil by using 

Cu/HMOR as a catalyst, Chemical Engineering Transactions, 39, 1267-1272  DOI:10.3303/CET1439212 

1267 

Quality Improvement of Waste Tyre Pyroysis Oil by Using 

Cu/HMOR as a Catalyst 

Ritthichai Yuwapornpanit
a
, Sirirat Jitkarnka*

b
 

a
The Petroleum and Petrochemical College, Chulalongkorn University, Soi Chulalongkorn 12, Phayathai Road, 

Pathumwan, Bangkok, 10330, Thailand 
b
Center of Excellence on Petrochemical and Materials Technology, Bangkok, Thailand 

sirirat.j@chula.ac.th 

Metal-loaded zeolites are interesting catalysts for the improvement of the quality and quantity of waste tyre 

pyrolysis products. Since the catalysts exhibit multi-functions in catalysis, including hydrogenation, 

dehydrogenation, ring-opening, cracking, etc. that can be acquired from metal and zeolite properties. This 

work studied the effect of 5 wt%Cu/HMOR catalyst on waste tyre pyrolysis products. Since copper is 

widely used in several applications such as selective hydrogenation of undesired unsaturated 

hydrocarbons in a mixed-C4 stream, and sulphur removal from liquid fuels, etc. Catalytic pyrolysis of waste 

tyre was operated in a bench reactor. GCxGC-TOF/MS and SIMDIST-GC instruments were used to 

analyze the liquid products. Sulphur distribution in the pyrolysis products was determined by using an S-

analyzer. As compared with the HMOR catalyst, the Cu/HMOR decreased the amount of olefins, 

naphthenes, poly-aromatics, and polar aromatic compounds in oils while the amounts of paraffins, di- and 

mono-aromatics in oils were increased because the presence of copper can promote hydrogenation, ring-

opening, and cracking activities of HMOR zeolite. Furthermore, Cu/HMOR catalyst not only reduced heavy 

compounds in the oil but also sulphur content in the oil (reduced from 1.08 wt% to 0.907 wt% in the HMOR 

case), indicating that the quality of the oil as a combustion fuel was improved by using copper as a 

promoter of HMOR zeolite. An interesting result was that the valuable products produced in the Cu/HMOR 

case were benzene (1.14 wt% in oil), toluene (2.65 wt% in oil), and ethylbenzene (5.39 wt% in oil), which 

have never been found in the non-catalytic case or in the case when the parent HMOR was used. 

1. Introduction 

From the past to present, waste tyre elimination has been an important problem because tyres are highly 

stable in chemicals and environments. Pyrolysis is a thermal degradation method of waste tyres, which is 

more effective process than other waste tyre elimination methods because it can not only eliminate waste 

tyres but also recover usable products (Williams, 2013); so, waste tyre pyrolysis is widely adopted 

nowadays in many countries where land and resource are limited. The waste tyre pyrolysis can produce 

three parts of products consisting of gases, oils and char. The interested product is pyrolysis oil that can 

be fractionated according to boiling points into gasoline, kerosene, gas oil, heavy gas oil, light vacuum gas 

oil, and heavy vacuum gas oil (Dũng et al., 2009a). Furthermore, some components in oil can be used as 

chemicals (Boxiong et al., 2007) such as benzene, toluene, xylenes, etc.  

Zeolites are widely used as a commercial catalyst in the production of petrochemicals because they have 

several interesting properties such as catalytic cracking and hydrocracking (USY), catalytic dewaxing 

(ZSM-5, ZSM-22, and SAPO-11), cracking and alkane isomerization (BETA) (Martínaz and Corma, 2011), 

and transalkylation and paraffin skeletal isomerization using HMOR (Busca, 2007), etc. For catalytic 

pyrolysis of waste tyre, zeolites can be effective catalysts for increasing desired products as proven by 

many researchers. For examples, Williams and Brindle (2003) found that ZSM-5 and Y zeolites can 

increase the amount of value added products in pyrolysis oils; for examples, benzene, toluene, xylene, 

styrene, etc. HBETA zeolite can produce the high amount of saturated hydrocarbons and the naphtha 

fraction of tyre-derived oil (Saeaeh and Jitkarnka, 2012). Dũng et al. (2009a) studied the effect of HMOR 



 
1268 

 
zeolite on catalytic pyrolysis oils. HMOR zeolite can increase the amount of mono-aromatics in the oil, and 

gasoline and kerosene yields, while heavier fractions and total-aromatics were also decreased, indicating 

that the oil quality can be upgraded. Furthermore, an introduction of metal onto a zeolite might improve 

some quality of pyrolysis products as well. Copper is widely used as a selective hydrogenation catalyst 

and adsorbent in sulphur removal from liquid fuels. Copper-loaded catalysts can be used in selective 

hydrogenation that can remove undesired compounds in the process. For examples, Cu/SiO2 catalyst was 

used to remove alkynes and butadiene in C4-stream by partial hydrogenation by converting them into 

butenes (Setiawan and Cavell, 1995). Copper loading on hydrotalcite, malachite, SiO2 and Al2O3 supports 

was used to convert propyne into propylene at high selectivity and undesired products at low selectivity 

(Bridier et al., 2010). In the other applications, Cu(I)-exchanged zeolites can be used as an adsorbent for 

thiophene removal from liquid fuels as well (Tang and Shi, 2011). For catalytic pyrolysis of waste tyre, 

copper was expected to promote hydrogenation that might cause cracking and ring-opening reactions to 

occur easily. Furthermore, copper was expected to enhance sulphur reduction of the pyrolysis oil as well. 

In this work, the effect of copper on waste tyre pyrolysis products was therefore studied, using HMOR 

zeolite as the support. 

2. Experiment 

2.1 Catalyst and sample preparation 
HMOR zeolite (Si/Al = 9.5) supplied by TOSOH Company (Singapore) was calcined in static air with the 

heating rate of 5 
o
C/min from room temperature to 500 

o
C with holding for 3 h after the final temperature 

was reached. The calcined zeolite was subsequently impregnated with the copper solution 

(Cu(NO3)2.3H2O) at the copper loading of 5 wt%, dried overnight in an oven at 120
 o

C, and calcined again 

at the same calcination condition. Next, the calcined catalyst was reduced at 600
 o

C for 2 h in hydrogen 

atmosphere. Finally, the catalyst powder was pelletized, crushed, and sieved to the size range of 40-60 

mesh. A waste tyre sample, Bridgestone TURANZA GR-80, was shredded and then sieved into a particle 

size of 20-40 mesh. 

2.2 Waste tyre pyrolysis process 

The pyrolysis system employed in the experiment was the same as in Dũng et al. (2009b). The catalytic 

pyrolysis of waste tyre was operated at atmospheric pressure from room temperature to a temperature of 

500
 o

C (the pyrolysis zone) and 350
 o

C (the catalytic zone) with a ramping rate of 10
 o

C/min and a holding 

time of 2 hours after the final temperatures were reached. 30 g of shredded tyre (20 - 40 mesh) and 7.5 g 

of HMOR or 5 wt%Cu/HMOR catalyst (40 - 60 mesh) were packed in the pyrolysis zone and the catalytic 

zone, respectively, (at catalyst/tire ratio = 0.25). Nitrogen gas was used as carrier gas. Liquid products 

were condensed in the condensers immerged in an ice-salt (NaCl) bath, while the gas products were 

collected by using a gas sampling bag. 

2.3 Catalyst characterization 
XRD machine (Rikagu) was used to acquire the XRD patterns of the catalysts using CuKα radiation 

operated at 40 kV and 30 mA. The angles in the range of 5-65
o
 were scanned at a scanning speed of 5

 

o
/min. Surface area and pore volume of catalysts were determined by N2 physisorption using Thermo 

Finnigan Sorptomatic 1990 equipment. The amount of coke on spent catalysts was determined by using 

Perkin Elmer/Pyris Diamond (Thermogravimetric/Differential Thermal Analysis, TG/DTA). The temperature 

was ramped up from room temperature to 900 
o
C with the heating rate of 10

 o
C/min. Sulphur content on 

catalyst surface was determined by using LECO®Elemetal Analyzer (TruSpec®S). 

2.4 Product analysis 
Liquid and solid products were weighed for calculating the product yield. Before analysis, asphaltene was 

firstly precipitated from the liquid products via mixing with n-pentane in the oil/n-pentane mass ratio of 

40:1. After that the precipitated asphaltene was filtered from the solutions using a Teflon membrane (0.45 

μm) in a vacumm system, and then the maltene solutions were analyzed for the composition by using Gas 

Chromatography-Mass Spectrometry (GCxGC-TOF/MS). The Agilent gas chromatograph 6890 system 

consists of a cryogenic modulator and a Pegasus 4D TOF/MS. The 1
st
 column was a non-polar Rtx®-5 Sil 

MS with 30 m x 0.25 mm ID x 0.25 μm film thickness. The 2
nd

 column was an Rxi®-17 MS with 1.10 m x 

0.10 mm ID x 0.10 μm film thickness. Furthermore, the true boiling point curves of maltene solutions were 

also analyzed by using a Varian GC-3800 simulated distillation gas chromatograph (SIMDIST-GC) 

conformed to the ASTM-D2887 method. The instrument equipped with FID and WCOT fused silica 

capillary column (15 m x 0.25 mm x 0.25 μm) The true boiling point curves were cut into petroleum 

fractions according to their boiling points; full range naphtha (< 200 
o
C), kerosene (200-250

 o
C), light gas 

oil (250-300
 o

C), heavy gas oil (300-370 
o
C) and long residue (> 370

 o
C). The gas products were analyzed 



 
1269 

for hydrocarbon species and concentrations by using a GC-FID, Agilent Technologies 6890 Network GC 

system (HP-PLOT Q column: 20 μm film thickness and 30 m x 0.32 mm ID). Furthermore, the liquid and 

solid products was also analyzed for their sulphur content by using a LECO®Elemetal Analyzer 

(TruSpec®S); whereas the sulphur content in gas products was calculated via mass balance. 

3. Results and discussion 

3.1 Catalyst characterization 
XRD patterns of HMOR and Cu/HMOR catalysts are displayed in Figure 1. The results show that the 

introduction of copper onto the zeolite does not affect the zeolite structure. The peaks of copper appear at 

the 2θ of 43.47
o
 and 50.67

o
. The BET specific surface area and pore volume of catalysts are shown in 

Table 1. These results indicate that the introduction of copper onto HMOR zeolite reduces the specific 

surface area and pore volume because copper might partially block the pore of zeolites (Garrido Pedrosa 

et al., 2006). 

3.2 Effect of Cu/HMOR on waste tyre pyrolysis products 

Figure 2 shows that HMOR does not increase the gas yield even though the liquid yield decreased 

because the catalyst generates a considerable amount of coke on the surface. The presence of copper on 

HMOR zeolite promotes gas production, and reduces the liquid yield while the solid yield is constant. 

Furthermore, the amount of coke is increased with using the copper-loaded catalyst as well. It can be 

concluded that copper promotes the cracking activity of the zeolite. 

Table 1: BET specific surface area and pore volume of catalysts 

Catalyst  Specific surface area (m
2
/g) Specific pore volume (cm

3
/g) 

HMOR 395 0.199 

Cu/HMOR 345 0.180 

2 Theta (degrees)

10 20 30 40 50 60

In
te

n
s
it
y
 (

a
.u

)

Cu/HMOR

HMOR

 

Figure 1: XRD patterns of HMOR and Cu/HMOR catalysts 

 

Figure 2: Product distribution in HMOR and Cu/HMOR cases 

0 

20 

40 

60 

Gas Liquid Soild Coke 

w
t%

 t
y

re
 

Non-Cat HMOR Cu/HMOR 

* 



 
1270 

 

 

 

Figure 3: Oil analysis in HMOR and Cu/HMOR cases; (A) Concentrations of each group in maltene, (B) 

Petroleum cuts, (C) Asphaltene content in oils, and (D) Petrochemical valuable products 

Table 2: Average carbon number of each group in maltenes in HMOR and Cu/HMOR cases 

Catalyst  P O Nap Mono Di Poly Polar Total 

No catalyst 15.7 12.2 12.3 11.8 12.1 14.7 11.4 12.5 

HMOR 16.1 11.9 12.1 11.6 11.9 14.7 11.6 12.2 

Cu/HMOR 14.1 11.3 11.0 10.9 11.8 14.4 11.7 11.6 

 

For oil analysis (Figure 3A), the oil components were categorized into seven groups: paraffins (P), olefins 

(O), naphthenes (Nap), mono-aromatics (Mono), di-aromatics (Di), poly-aromatics (Poly), and polar-

aromatics (Polar). HMOR reduces the concentrations of olefins and naphthenes while the concentration of 

mono-aromatics is highly increased as compared with the non-catalyst case, indicating that HMOR 

catalyst exhibits aromatization ability. Furthermore, the concentration of poly-aromatics is decreased 

because the catalyst might also exhibit hydrogenation and ring-opening abilities (Du et al., 2005) that it can 

convert poly-aromatics into mono-aromatics. The oil obtained from HMOR has the lower overall average 

carbon number (Table 2) than that from the non-catalyst case, resulting in a significant increase in full-

range naphtha and subsequent decrease in heavier petroleum cuts as shown in Figure 3B. As compared 

with HMOR zeolite, copper promotes the production of mono-aromatics in the oil (Figure 3A) possibly via 

hydrogenation and ring-opening of poly-aromatics, and via aromatization of olefins and naphthenes. Full-

range naphtha (Figure 3B) is also increased because copper promotes cracking activity, resulting in the 

decrement of the overall average carbon numbers of the maltene (Table 2). Furthermore, Cu/HMOR also 

reduces polar-aromatic concentration and asphaltene content. As observed from the species in mono-

aromatics shown in Figure 3D, the valuable petrochemicals highly produced are styrene (1.37 wt% in oil) 

in the HMOR case, and benzene (1.14 wt% in oil), toluene (2.65 wt% in oil) and ethylbenzene (5.39 wt% in 

oil) in the Cu/HMOR case. It can indicate that the catalytic pyrolysis of waste tyre has high potential for 

chemical production as well. 

0 

10 

20 

30 

40 

50 

60 
C

o
n

ce
n

tr
a

ti
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n
 in

 
m

a
lt

e
n

e
 (

w
t%

) 

Non-Cat HMOR 5CuHMOR 

(A) 

0 
10 
20 
30 
40 
50 
60 

C
o

n
ce

n
tr

a
ti

o
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 in
 

m
a

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n
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 (
w

t%
) Non-Cat HMOR 5CuHMOR 

(B) 

0 

0.001 

0.002 

0.003 

Asphaltne/Oil (g/g) 

A
sp

h
a

lt
e

n
e

 i
n

 o
il

s 
(g

/g
) 

Non-Cat HMOR Cu/HMOR 

(C) 

0 

2 

4 

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C
o

n
ce

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a
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o
n

 in
 

m
a

lt
e

n
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 (
w

t%
) Non-Cat HMOR Cu/HMOR 

(D) 



 
1271 

 

Figure 4: Sulphur analysis in HMOR and Cu/HMOR cases; (A) Overall sulphur distribution, and (B) 

Distribution of major groups of sulphur-containing compounds in maltenes 

3.3 Quality improvement of pyrolysis oil 

The quality of pyrolysis oil can be improved using Cu/HMOR not only due to light oil production and the 

reduction of concentration of poly- and polar-aromatics, and asphaltene content in the oil, but also due to 

the reduction of sulphur content in the oil. HMOR can reduce sulphur content in the oil (Figure 4A) by 

converting sulphur-containing compounds in the oil, and releasing sulphur into gas and coke. The 

increment of sulphur in gas indicates that the catalyst also exhibits cracking and desulphurization abilities. 

Furthermore, HMOR catalyst can reduce the average carbon number of all groups of sulphur-containing 

compounds in maltene (Table 2), indicating that the sulphur-containing compounds in the oils can be 

removed easily via desulphurization. Sulphur-containing compounds found in the oils were classified into 

five groups: thiophenes (T), benzothiophenes (BT), dibenzothiophenes (DBT), benzothiazoles (BTz), and 

isothiocyanates (ICT). For sulphur species in the maltenes, the proportions of benzothiazoles and 

isothiocyanates are decreased with using HMOR, indicating that HMOR can promote breaking C-S and C-

N bonds, and/or can adsorb these species more on the catalyst surface. Cu/HMOR gives lower sulphur 

content (0.907 wt%) in the oil than HMOR zeolite (1.08 wt%) because copper can adsorb sulphur-

containing compounds in both oil and gas onto the catalyst surface, subsequently forming coke, which is 

similar to the work of Twigg and Spencer (2001) reporting that copper is rapidly deactivated by sulphur-

containing compounds. For the species of sulphur-containing compound (Figure 4B), Cu/HMOR reduces 

benzothiazoles, and thiophenes more than HMOR zeolite. Moreover, the reduction of average carbon 

numbers in all groups of sulphur-containing compounds also indicates that copper can help remove 

sulphur atoms more easily. 

4.  Conclusions 

Cu/HMOR catalyst was studied in this work to determine its effect on the quality of waste tyre pyrolysis oil.  

It was found that the introduction of copper on HMOR zeolite can promote gas and full-range naphtha 

productions, indicating that copper promoted cracking activity. Cu/HMOR also enhanced the selectivity of 

mono-aromatics due to the increasing activities in hydrogenation and ring-opening of poly-aromatics, as 

well as the aromatization of olefins and naphthenes. Interestingly, the introduction of copper highly 

promoted the production of valuable products in oils. HMOR was found to be more selective for styrene 

production (1.37 wt% in oil) than thermal pyrolysis. Cu loading to HMOR resulted in better production of 

benzene (1.14 wt% in oil), toluene (2.65 wt% in oil) and ethylbenzene (5.39 wt% in oil). So, the catalytic 

pyrolysis of waste tyre using HMOR or Cu/HMOR as catalysts had high potential for chemical production 

as well. However, the presence of copper on HMOR zeolite increased coke formation possibly occurred 

from the deposition of polar-aromatics and asphaltene on the catalyst surface. Nevertheless, the quality of 

pyrolysis oil using Cu/HMOR can be improved since the poly-, polar-aromatics, and asphaltene contents in 

the oil was reduced in conjunction with the production of lighter and sweeter oil. Cu/HMOR catalyst can 

reduce sulphur content in the oil from 1.08 wt% to 0.907 wt%. 

Acknowledgements 

The authors would like to acknowledge the financial supports from The Petroleum and Petrochemical 

College, Chulalongkorn University, Center of Excellence on Petrochemical and Materials Technology, and 

Thailand Research Fund (TRF). 

0 

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Oil Spent Cat. Gas Char 

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(A) 
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T BT DBT BTz ITC 

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(w
t%

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(B) 



 
1272 

 
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