Journal of Research & Opinion peer-reviewed open access journal

Thermochemical Treatment of Sewage Sludge Waste: A Pyrolysis Study

M.Y. Guida
Department of Chemistry and Environment, Faculty of Sciences and Techniques (FST), University of SultanMoulay Slimane, 23000 Béni-Mellal, Morocco.
Z. Rbihi
Organic Chemistry and Analytical Laboratory, Faculty of Sciences and Techniques (FST), University of SultanMoulay Slimane, 23000 Béni-Mellal, Morocco
S. E. Lanaya
Organic Chemistry and Analytical Laboratory, Faculty of Sciences and Techniques (FST), University of SultanMoulay Slimane, 23000 Béni-Mellal, Morocco
A. Hannioui
Department of Chemistry and Environment, Faculty of Sciences and Techniques (FST), University of SultanMoulay Slimane, 23000 Béni-Mellal, Morocco. Organic Chemistry and Analytical Laboratory, Faculty of Sciences and Techniques (FST), University of SultanMoulay Slimane, 23000 Béni-Mellal, Morocco
Share:

How to Cite

1.
Thermochemical Treatment of Sewage Sludge Waste: A Pyrolysis Study. Journal of Research and Opinion [Internet]. 2019 Sep. 30 [cited 2024 Nov. 21];6(9):2481-9. Available from: https://researchopinion.in/index.php/jro/article/view/24
  • Articles
  • Submited: October 31, 2019
  • Published: September 30, 2019

Abstract

In this study, the thermal behavior of sewage sludge waste (SSW) samples was examined at three different heating rates 5, 10 and 15 °C/min in inert atmosphere using the technique of thermogravimetric analysis and pyrolysis in a stainless steel tubular reactor. As the increment of pyrolysis temperature and heating rate, the variations of characteristic parameters from TG-DTG curves and the yield of bio-oil, bio-char and gaseous products were determined. Three methods were used for the determination of activation energy: Friedman (FR), Ozawa-Flynn-Wall (OFW) and Vyazovkin (VYA) methods. The results showed that the mean values of apparent activation energy for sewage sludge waste were 162.40 KJ/mol, 141.08 KJ/mol and 150.91 KJ/mol for FR, VYA and OFW methods respectively. The results of our work showed that the amount of liquid product (bio-oil) from pyrolysis in a stainless steel tubular reactor of SSW samples increases with increasing the final temperature and decreases with increasing the heating rate. The highest yield of liquid product is obtained from the samples at 500 °C and at heating rate of 5 °C/min, the maximal average yield achieved almost 30.6 wt%. The yield of char generally decreases with increasing the temperature, the char yield passes from 35.21 wt% to 20 wt% at the heating rate of 5 °C/min and from 31.2 wt% to 17.5 wt% at the heating rate of 15 °C/min at the same range of temperature (200-700 °C). Concerning the yield of gaseous product and conversion degree (x), we notice that the efficiency increase with increasing the final temperature. The results show that final temperature and heating rate have a remarkable effect on the yields products.

References

1.Chris de wet and al. Developing a systematicrelational approach to environmental ethics in water resource management. Environmental science & policy. 93 (2019) 139-145.
2.G. Jinjing and al. Insights into water-energy co-benefits and trade-offs in water resources management. Journal of cleaner production. 213 (2019) 1188-1203.
3.L. N. Alekseiko and al. Combination ofwastewater treatment plants and heat pumps. Pacific science review. 16 (2014) 36-39.
4.N. Abdel-raouf and al. Microalgae andwastewater treatment. Saudi journal of biological sciences. 19 (2012) 257-275.
5.M. M. Perez-villar and al. Vertical subsurfacewet lands for wastewater purification. Procedia engineering. 42 (2012) 1960-1968.
6.T. Yi-Wen and al. Treatment and reuse oftunnel construction wastewater. Separation and purification technology. 84 (2012) 169-175.
7.E. Yilmaz and al. Co-pelletization of sewagesludge and agricultural wastes. Journal of environmental management. 216 (2018) 169-175.
8.A. Zaker and al. Microwave-assisted pyrolysisof sewage sludge: a review. Fuel processing technology. 187 (2019) 84-104.
9.H. Subrata and al. Vermistabilization ofprimary sewage sludge. Bioresource technology. 102 (2011) 2812-2820.
10.P. Oleszczuk and al. Comparison of sewagesludge toxicity to plants and invertebrates in three different soils. Chemosphere. 83 (2011) 502-509.
11.U. Tezel and al. Anaerobic biotreatment ofmunicipal sewage sludge. Comprehensive biotechnology. 6 (2011) 396-410.
12.W. Qingbo and al. Study on activated carbonderived from sewage sludge for adsorption of gaseous formaldehyde. Bioresource technology. 102 (2011) 942-947.
13.A.B. Hernandez and al. Mineralogy andleachability of gasified sewage sludge residues. Journal of hazardous materials. 191 (2011) 219-227.
14.M. Bourioug and al. Sewage sludge used asorganic manure in Moroccan sunflower culture: effects on certain soil properties, growth and yield components. Science of the total environment. 627 (2018) 681-688.
15.S. Chaoua and al. Efficiency of two sewagetreatment systems (activated sludge and natural lagoons) for helminth egg removal in morocco. Journal of infection and public health. 11 (2018) 197-202.
16.F.Y. Wang and al. Sewage sludgetechnologies. Encyclopedia of ecology. 2008. 3227-3242.
17.E. Diaz and al. Effect of sewage sludgecomposition on the susceptibility to spontaneous combustion. Journal of hazardous materials. 361 (2019) 267-272.
18.M. Y. Guida, H. Bouaik, A. Tabal, A.Hannioui, A. Solhy, A. Barakat, A. Aboulkas, K. Elharfi. Thermochemical treatment of olive mill solid waste and olive mill wastewater. Journal Thermal. Anal and colori, 123 (2016) 1657-1666
19.M.Y. Guida, A. Hannioui. A review onthermochemical treatment of biomass: Pyrolysis of olive mill wastes in comparison with other types of biomass. Progress in agricultural engineering sciences, 12 (2016) 1-23.
20.E.E. Kwon, S. Kim, J. Lee. Pyrolysis of wastefeedstocks in CO2 for effective energy recovery and waste treatment. Journal of CO2 utilization, 31 (2019) 173-180.
21.A. Magdziarz and al. Thermogravimetricstudy of biomass, sewage sludge and coal combustion. Energy conversion and management. 75 (2013) 425-430.
22.Y. Lin and al. Co-pyrolysis kinetics of sewagesludge and oil shale thermal de compositing using TGA-FTIR analysis. Energy conversion and management. 118 (2016) 345-352.
23.M. Park and al. A study of solubilization ofsewage sludge by hydrothermal treatment. Journal of environmental management. 250 (2019) 109490.
24.W.D. Chanaka udayanga and al. Effects ofsewage sludge organic and inorganic constituents on the properties of pyrolysis products. Energy conversion and management. 196 (2019) 1410-1419.
25.J.M. Jung and al. Valorization of sewagesludge via non-catalytic transesterification. Environment international.131 (2019) 105035.
26.A. Skreiberg and al. TGA and maro-TGAcharacterization of biomass fuels and fuel mixtures. Fuel 90 (2011 ) 2182-2197.
27.R.W. Nachenius and al. Chapter two-biomasspyrolysis. Advances in chemical engineering. 42 (2013) 75-139.
28.A.O. Oyedun and al. Optimization of multi-stage pyrolysis. Applied thermal engineering. 61 (2013) 123-127.
29.J. Yanik and al. Pyrolysis of algal biomass.Journal of analytical and applied pyrolysis. 103 (2013) 134-141.
30.A.O. Oyedun and al. Mechanism andmodeling of bamboo pyrolysis. Fuel processing technology. 106 (2013) 595-604.
31.M. Y. Guida, H. Bouaik, L. ElMouden, A.Moubarik, A. Aboulkas, K. Elharfi, A. Hannioui. Utilization of starink approach and avrami theory to evaluate the kinetic parameters of the pyrolysis of olive mill solid waste and olive mill wastewater. J Adv Chem Eng, 6 (2016) 1-8.
32.L. Mu, J. Chen, H. Yin, X. Song, A. Li.Pyrolysis behaviors and kinetics of refining and chemicals wastewater, lignite and their blends through TGA. Bioresour Technol. 2015
33.S. Yaman. Pyrolysis of biomass to producefuels and chemical feedstocks. Energy Convers Manag, 45(2004) 651–671.
34.H.L. Friedman. Kinetics of thermaldegradation of char-forming plastics from thermogravimetry. Application to a phenolic plastic. Journal of Polymer Science Part C: Polymer Symposia; Wiley Online Library; 1964.
35.J.H. Flynn, L.A. Wall. A quick, direct methodfor the determination of activation energy from thermogravimetric data. J Polym Sci, Part C: Polym Lett, 4(1966) 323–328
36.J.H. Flynn, L.A. Wall. General treatment ofthe thermogravimetry of polymers. J Res Nat Bur Stand, 70 (1966) 487–523.
37.T. Ozawa. A new method of analyzingthermogravimetric data. Bull Chem Soc Jpn, 38(1965) 1881–1886.
38.T. Ozawa, Kinetic analysis of derivativecurves in thermal analysis,J Therm Anal Calorim, 2(1970) 301-324
39.S. Vyazovkin, A. Lesnikovick.Transformation of ‘‘degree of conversion against temperature’’ into ‘‘degree of conversion against time’’ kinetic data. Russ J Phys Chem, 62(1988) 1525-1570.
40.M. Y. Guida, A. Hannioui. Properties of bio-oil and bio-char produced by sugar cane bagasse pyrolysis in a stainless steel tubular reactor. Progress in Agricultural Engineering Sciences, 13 (2017) 13-33.
How to Cite
1.
Thermochemical Treatment of Sewage Sludge Waste: A Pyrolysis Study. Journal of Research and Opinion [Internet]. 2019 Sep. 30 [cited 2024 Nov. 21];6(9):2481-9. Available from: https://researchopinion.in/index.php/jro/article/view/24

Send mail to Author


Send Cancel

Custom technologies based on your needs

Journal of Research and Opinion  invites original research and review articles not published/submitted for publications anywhere. The journal accepts review articles only if author (s) has included his/her own research work and is an authority in the particular field. Invited or submitted review articles on current medical research developments will also be included. Medical practitioners are encouraged to contribute interesting case reports.

 

  • Manuscript template
  • Make a submission
  • Beta visitors

Why publish with us?

Open Access and Free

Full open-access. No processing & publication fees for authors

Refereed

The journal has rigorous peer-reviews

Indexed

The journal is indexed in DOAJ, SINTA and under review by ERIC