TY - JOUR
T1 - Waste tires pyrolysis oil and its blend with diesel fuel spectral flame analysis, temperature contours, and emissions
AU - Emara, Karim
AU - Ayoub, H. S.
AU - El-Sherif, Ashraf F.
AU - Ali, Mohamed I.Hassan
N1 - Funding Information:
This study is accomplished through the collaboration between Helwan University in Cairo, Egypt, and Khalifa University in Abu Dhabi, UAE.
Publisher Copyright:
© 2022
PY - 2022/11
Y1 - 2022/11
N2 - The purpose of this research paper is to investigate the energy valorization from the pyrolysis of waste tires using coaxial continuous flame burners. For such an investigation, both the Tire Pyrolysis Oil (TPO) along with its blend (B1) with light diesel oil (LDO) were prepared, physically and chemically characterized, and then combusted in coaxial burners. To distinguish the spectral emission peaks, for the vaporization and combustion zone and the hot recirculation zone of the produced flame, flame spectroscopy techniques were utilized. The mass-specific emission indices and the axial inflame temperatures were used as indicators of the flame radiation intensity in the flame zones. The coaxial flame was inspected for excess air factors of 1.33, 1.04, and 0.9. In the study, a higher radiation intensity of TPO/LDO blend flame was recognized in the B1 flame length which was taller than that of LDO by 48% at λ=1.33. Furthermore, a decrease in CO emissions levels was also noticed in the combustion of waste tire pyrolysis oil and B1 by an average of 4%–12% compared to that from HDO, and the NOx emissions were also reduced by 8.5%–26%. The highest axial inflame temperature of 1,205 °C was recorded for TPO at condition λ=0.9, where the presence of oxygen molecules in fuel helps flame improvements.
AB - The purpose of this research paper is to investigate the energy valorization from the pyrolysis of waste tires using coaxial continuous flame burners. For such an investigation, both the Tire Pyrolysis Oil (TPO) along with its blend (B1) with light diesel oil (LDO) were prepared, physically and chemically characterized, and then combusted in coaxial burners. To distinguish the spectral emission peaks, for the vaporization and combustion zone and the hot recirculation zone of the produced flame, flame spectroscopy techniques were utilized. The mass-specific emission indices and the axial inflame temperatures were used as indicators of the flame radiation intensity in the flame zones. The coaxial flame was inspected for excess air factors of 1.33, 1.04, and 0.9. In the study, a higher radiation intensity of TPO/LDO blend flame was recognized in the B1 flame length which was taller than that of LDO by 48% at λ=1.33. Furthermore, a decrease in CO emissions levels was also noticed in the combustion of waste tire pyrolysis oil and B1 by an average of 4%–12% compared to that from HDO, and the NOx emissions were also reduced by 8.5%–26%. The highest axial inflame temperature of 1,205 °C was recorded for TPO at condition λ=0.9, where the presence of oxygen molecules in fuel helps flame improvements.
KW - Axial inflame temperature
KW - C2 radicals
KW - CH radicals
KW - Emission flame spectroscopy
KW - Spectral emission peaks
KW - Waste tires pyrolysis oil
UR - http://www.scopus.com/inward/record.url?scp=85140400777&partnerID=8YFLogxK
U2 - 10.1016/j.egyr.2022.10.115
DO - 10.1016/j.egyr.2022.10.115
M3 - Article
AN - SCOPUS:85140400777
SN - 2352-4847
VL - 8
SP - 1550
EP - 1564
JO - Energy Reports
JF - Energy Reports
ER -