ABSTRACT
This
research involves developing and thermo-economic evaluation of a small-scale
waste plastic pyrolysis plant for recovery from petroleum oil. The plant was
developed using locally sourced materials to provide an alternative method of
reducing waste plastics from the environment. The design of the reactor,
catalytic-cracker, diffuser and air-condenser components of the plant was made
subject to energy and exergoeconomic analysis to identify thermal and cost-related
improvements in the system. During the plant's pilot batch, the plant's feed
rate was designed to be 2kg/h of waste plastics and 1.0kg of the iron catalyst
with reactor pyrolysis temperatures in the range of 310 -500oC to
produce diesel and aviation kerosene. Performance analysis was made, and
several key parameters were investigated on the thermal and economic
performance of the plant. The experimental results showed that the volumetric
flow rate and the
maximum product yield of diesel (AGO) oil are one lit/h and 87.3%,
respectively. The oil samples were characterized, and the results from the
laboratory revealed that liquid oil with a reactor inlet temperature of 310,
360, 400, and 460oC have the same results as standard diesel oil. Additionally,
it was shown that the diesel oil (Olefins) with a reactor inlet temperature of
360oC had the best impact and can be approximated to the regular
conventional diesel oil. The liquid oil with a reactor inlet temperature of 500oC
fell within the range of standard aviation kerosene (Naphthenes) according to
the ASTM standard. Subsequently,
the various petroleum products yield were 84.24, 87.3, 84.25,82, and 82%, at
corresponding inlet reactor temperatures of 310, 360, 400,460 and 500oC,
respectively. The data
from different pilot-batches were fitted on the thermal and exergoeconomic
equation models for the performance of the plant. The reactor, catalytic
cracker, diffuser and air-condenser energy efficiencies were 85.75, 82.17, 80.4
and 70.19 %, respectively. Furthermore, the exergoeconomic analysis indicates
thermal improvement of the condenser due to its low exergoeconomic factor of
0.00261 and high total cost rate of 1.895 $/h. Finally, the diffuser component in the plant regulate the fluid
flow rate and enhance the production of petroleum products.
MICHAEL, U (2023). Development And Thermo-Economic Performance Of A Small Scale Waste Plastics Pyrolysis Plant For Petroleum Product Recovery. Repository.mouau.edu.ng: Retrieved Nov 21, 2024, from https://repository.mouau.edu.ng/work/view/development-and-thermo-economic-performance-of-a-small-scale-waste-plastics-pyrolysis-plant-for-petroleum-product-recovery-7-2
UNIVERSITY, MICHAEL. "Development And Thermo-Economic Performance Of A Small Scale Waste Plastics Pyrolysis Plant For Petroleum Product Recovery" Repository.mouau.edu.ng. Repository.mouau.edu.ng, 30 Jun. 2023, https://repository.mouau.edu.ng/work/view/development-and-thermo-economic-performance-of-a-small-scale-waste-plastics-pyrolysis-plant-for-petroleum-product-recovery-7-2. Accessed 21 Nov. 2024.
UNIVERSITY, MICHAEL. "Development And Thermo-Economic Performance Of A Small Scale Waste Plastics Pyrolysis Plant For Petroleum Product Recovery". Repository.mouau.edu.ng, Repository.mouau.edu.ng, 30 Jun. 2023. Web. 21 Nov. 2024. < https://repository.mouau.edu.ng/work/view/development-and-thermo-economic-performance-of-a-small-scale-waste-plastics-pyrolysis-plant-for-petroleum-product-recovery-7-2 >.
UNIVERSITY, MICHAEL. "Development And Thermo-Economic Performance Of A Small Scale Waste Plastics Pyrolysis Plant For Petroleum Product Recovery" Repository.mouau.edu.ng (2023). Accessed 21 Nov. 2024. https://repository.mouau.edu.ng/work/view/development-and-thermo-economic-performance-of-a-small-scale-waste-plastics-pyrolysis-plant-for-petroleum-product-recovery-7-2