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Journal of Material Cycles and Waste Management
Published in: Journal of Material Cycles and Waste Management 4/2020

13-03-2020 | ORIGINAL ARTICLE

Biofuel production from pyrolysis of waste cooking oil fried sludge in a fixed bed

Authors: Long Wu, Jiayong Tu, Yimeng Cai, Zhonghua Wu, Zhanyong Li

Published in: Journal of Material Cycles and Waste Management | Issue 4/2020

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Abstract

Waste cooking oil was used to dry sewage sludge by fry-drying technology. The obtained oil-fried sludge, which contained waste cooking oil and sewage sludge, was converted into biofuel simultaneously via pyrolysis process in a fixed bed. The synergistic effects of sewage sludge and waste cooking oil on the pyrolysis products were also investigated. Comparing to pyrolysis of sludge, pyrolysis of oil-fried sludge can obtain 51.9% higher gas products, where H2 and CH4 yields were increased by 37.4% (up to 211 ml/g) and 163% (up to 155 ml/g), respectively. The lower heating value (LHV) of gas product from oil-fried sludge was 41.2% higher than that from sludge. The higher LHV of gaseous products can be beneficial to use for power generation and heating. This indicates that oil-fried sludge shows a potential feedstock can be converted into high valuable biofuel. Nevertheless, the experimental gas and tar yield values of oil-fried sludge were lower than calculated values, indicating that there is an anergy effect of interactions between SS and oil on gas and tar formations. This was because the oily materials layer inhibited the heat and mass transfer in the sludge pyrolysis process, and then hindering the conversion of sludge into gas and tar formation.
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Appendix
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Literature
1.
Manara P, Zabaniotou A (2012) Towards sewage sludge based biofuels via thermochemical conversion—a review. Renew Sust Energ Rev 16(5):2566–2582CrossRef
2.
Tang S, Zheng C, Zhang Z (2018) Effect of inherent minerals on sewage sludge pyrolysis: product characteristics, kinetics and thermodynamics. Waste Manag 80:175–185CrossRef
3.
Buonocore E, Mellino S, Angelis GD, Liu G, Ulgiati S (2016) Life cycle assessment indicators of urban wastewater and sewage sludge treatment. Ecol Indic 94:13–23CrossRef
4.
Xu Z-X, Xu L, Cheng J-H, He Z-X, Wang Q, Hu X (2018) Investigation of pathways for transformation of N-heterocycle compounds during sewage sludge pyrolysis process. Fuel Process Technol 182:37–44CrossRef
5.
Xu Z-X, Song H, Zhang S, Tong S-Q, He Z-X, Wang Q, Li B, Hu X (2019) Co-hydrothermal carbonization of digested sewage sludge and cow dung biogas residue: investigation of the reaction characteristics. Energy 187:115972CrossRef
6.
Trabelsi ABH, Zaafouri K, Baghdadi W, Naoui S, Ouerghi A (2018) Second generation biofuels production from waste cooking oil via pyrolysis process. Renew Energ 126:888–896CrossRef
7.
Dong R, Zhao M (2018) Research on the pyrolysis process of crumb tire rubber in waste cooking oil. Renew Energ 125:557–567CrossRef
8.
Selvaraj R, Moorthy IG, Kumar RV, Sivasubramanian V (2019) Microwave mediated production of FAME from waste cooking oil: modelling and optimization of process parameters by RSM and ANN approach. Fuel 237:40–49CrossRef
9.
Yuan HR, Lu T, Zhao DD, Huang HY, Noriyuki K, Chen Y (2013) Influence of temperature on product distribution and biochar properties by municipal sludge pyrolysis. J Mater Cycl Waste Manag 15(3):357–361CrossRef
10.
Kang JH, Kim D, Lee T-j (2012) Hydrogen production and microbial diversity in sewage sludge fermentation preceded by heat and alkaline treatment. Bioresour Technol 109:239–243CrossRef
11.
Wang R, Zhao Z, Liu J, Lv Y, Ye X (2016) Enhancing the storage stability of petroleum coke slurry by producing biogas from sludge fermentation. Energy 113:319–327CrossRef
12.
Zhang Y, Dubé MA, McLean DD, Kates M (2003) Biodiesel production from waste cooking oil: 1. Process design and technological assessment. Bioresour Technol 89(1):1–16CrossRef
13.
Tran TTV, Kaipromarat S, Kongparakul S, Reubroycharoen P, Samart C (2016) Green biodiesel production from waste cooking oil using an environmentally benign acid catalyst. Waste Manag 52:367–374CrossRef
14.
Liu H, Qiang Z, Xing H, Hu H, Li A, Hong Y (2015) Product distribution and sulfur behavior in sewage sludge pyrolysis: synergistic effect of fenton peroxidation and CaO conditioning. Fuel 159:68–75CrossRef
15.
Wang Z, Xie L, Liu K, Wang J, Zhu H, Song Q, Shu X (2019) Co-pyrolysis of sewage sludge and cotton stalks. Waste Manag 89:430–438CrossRef
16.
Gerasimov G, Khaskhachikh V, Potapov O, Dvoskin G, Kornileva V, Dudkina L (2019) Pyrolysis of sewage sludge by solid heat carrier. Waste Manag 87:218–227CrossRef
17.
Deng S, Tan H, Wang X, Yang F, Cao R, Wang Z, Ruan R (2017) Investigation on the fast co-pyrolysis of sewage sludge with biomass and the combustion reactivity of residual char. Bioresour Technol 239:302–310CrossRef
18.
Zhou J, Liu S, Zhou N, Fan L, Zhang Y, Peng P, Anderson E, Ding K, Wang Y, Liu Y, Chen P, Ruan R (2018) Development and application of a continuous fast microwave pyrolysis system for sewage sludge utilization. Bioresour Technol 256:295–301CrossRef
19.
Maneerung T, Kawi S, Dai Y, Wang CH (2016) Sustainable biodiesel production via transesterification of waste cooking oil by using CaO catalysts prepared from chicken manure. Energy Convers Manag 123:487–497CrossRef
20.
Li M, Zheng Y, Chen Y, Zhu X (2014) Biodiesel production from waste cooking oil using a heterogeneous catalyst from pyrolyzed rice husk. Bioresour Technol 154(3):345–348CrossRef
21.
Wang J, Zhong Z, Zhang B, Ding K, Xue Z, Deng A, Ruan R (2017) Upgraded bio-oil production via catalytic fast co-pyrolysis of waste cooking oil and tea residual. Waste Manag 60:357–362CrossRef
22.
Wan AWM, Cheng TC, Wei HL, Anuar TNST, Ma NL, Ibrahim MD, Su SL (2018) Microwave co-pyrolysis of waste polyolefins and waste cooking oil: Influence of N2 atmosphere versus vacuum environment. Energy Convers Manag 171:1292–1301CrossRef
23.
Chen GY, Liu C, Ma WC, Zhang XX, Li YB, Yan BB, Zhou WH (2014) Co-pyrolysis of corn cob and waste cooking oil in a fixed bed. Bioresour Technol 166:500–507CrossRef
24.
Peregrina C, Arlabosse P, Lecomte D, Rudolph V, Kudra T, Mujumdar AS (2006) Heat and mass transfer during fry-drying of sewage sludge. Dry Technol 24(7):797–818CrossRef
25.
Ohm TI, Chae JS, Kim JE, Kim HK, Moon SH (2009) A study on the dewatering of industrial waste sludge by fry-drying technology. J Hazard Mater 168(1):445–450CrossRef
26.
Ohm TI, Chae JS, Lim KS, Moon SH (2010) The evaporative drying of sludge by immersion in hot oil: effects of oil type and temperature. J Hazard Mater 178(1):483–488CrossRef
27.
Park KT, Lim BR, Lee SK (2010) Drying characteristics of sewage sludge using vacuum evaporation and frying. J Mater Cycles Waste Manag 12(3):235–239CrossRef
28.
Wu Z, Zhang J, Li Z, Xie J, Mujumdar AS (2012) Production of a solid fuel using sewage sludge and spent cooking oil by immersion frying. J Hazard Mater 243:357–363CrossRef
29.
Chen W, Yang H, Chen Y, Chen X, Fang Y, Chen H (2016) Biomass pyrolysis for nitrogen-containing liquid chemicals and nitrogen-doped carbon materials. J Anal Appl Pyrol 120:186–193CrossRef
30.
Othman MR, Park YH, Ngo TA, Kim SS, Kim J, Lee KS (2010) Thermogravimetric characteristics and pyrolysis kinetics of Giheung Respia sewage sludge. Korean J Chem Eng 27(1):163–167CrossRef
31.
Wiggers VR, Meier HF, Wisniewski A Jr, Barros AAC, Maciel MRW (2009) Biofuels from continuous fast pyrolysis of soybean oil: a pilot plant study. Bioresour Technol 100(24):6570–6577CrossRef
32.
Maher KD, Bressler DC (2007) Pyrolysis of triglyceride materials for the production of renewable fuels and chemicals. Bioresour Technol 98(12):2351–2368CrossRef
33.
Dong Q, Niu M, Bi D, Liu W, Gu X, Lu C (2018) Microwave-assisted catalytic pyrolysis of moso bamboo for high syngas production. Bioresour Technol 256:145–151CrossRef
34.
Chen W, Chen YQ, Yang HP, Li KX, Chen X, Chen HP (2018) Investigation on biomass nitrogen-enriched pyrolysis: influence of temperature. Bioresour Technol 249:247–253CrossRef
35.
Wei C, Haiping Y, Yingquan C, Mingwei X, Zixu Y, Xianhua W, Hanping C (2017) Algae pyrolytic poly-generation: influence of component difference and temperature on products characteristics. Energy 131:1–12CrossRef
36.
Ma W, Du G, Li J, Fang Y, La H, Chen G, Ma D (2017) Supercritical water pyrolysis of sewage sludge. Waste Manag 59:371–378CrossRef
Metadata
Title
Biofuel production from pyrolysis of waste cooking oil fried sludge in a fixed bed
Authors
Long Wu
Jiayong Tu
Yimeng Cai
Zhonghua Wu
Zhanyong Li
Publication date
13-03-2020
Publisher
Springer Japan
Published in
Journal of Material Cycles and Waste Management / Issue 4/2020
Print ISSN: 1438-4957
Electronic ISSN: 1611-8227
DOI
https://doi.org/10.1007/s10163-020-01007-4

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