Araştırma Makalesi
BibTex RIS Kaynak Göster
Yıl 2021, , 326 - 338, 15.04.2021
https://doi.org/10.16984/saufenbilder.811684

Öz

Kaynakça

  • [1] B. Rijal, S. H. Gautam, and L. LeBel, "The impact of forest disturbances on residual biomass supply: A long-term forest level analysis," Journal of Cleaner Production, vol. 248, p. 119278, 2020.
  • [2] S. de Oliveira Junior, Exergy: production, cost and renewability. Springer Science & Business Media, 2012.
  • [3] L. Rincon, M. Puri, A. Kojakovic, and I. Maltsoglou, "The contribution of sustainable bioenergy to renewable electricity generation in Turkey: Evidence based policy from an integrated energy and agriculture approach," Energy Policy, vol. 130, pp. 69-88, 2019.
  • [4] H. S. Kambo and A. Dutta, "Comparative evaluation of torrefaction and hydrothermal carbonization of lignocellulosic biomass for the production of solid biofuel," Energy conversion and management, vol. 105, pp. 746-755, 2015.
  • [5] S. Brand, R. F. Susanti, S. K. Kim, H.-s. Lee, J. Kim, and B.-I. Sang, "Supercritical ethanol as an enhanced medium for lignocellulosic biomass liquefaction: Influence of physical process parameters," Energy, vol. 59, pp. 173-182, 2013.
  • [6] E. Demirkaya, O. Dal, and A. Yüksel, "Liquefaction of waste hazelnut shell by using sub-and supercritical solvents as a reaction medium," The Journal of Supercritical Fluids, vol. 150, pp. 11-20, 2019.
  • [7] M. Phanphanich and S. Mani, "Impact of torrefaction on the grindability and fuel characteristics of forest biomass," Bioresource technology, vol. 102, no. 2, pp. 1246-1253, 2011.
  • [8] S. Sadaka, H. Liechty, M. Pelkki, and M. Blazier, "Pyrolysis and combustion kinetics of raw and carbonized cottonwood and switchgrass agroforests," BioResources, vol. 10, no. 3, pp. 4498-4518, 2015.
  • [9] Q. Li et al., "Gaseous ammonia emissions from coal and biomass combustion in household stoves with different combustion efficiencies," Environmental Science & Technology Letters, vol. 3, no. 3, pp. 98-103, 2016.
  • [10] A. Demirbas, "Political, economic and environmental impacts of biofuels: A review," Applied energy, vol. 86, pp. S108-S117, 2009.
  • [11] M. Morin, S. Pécate, and M. Hémati, "Kinetic study of biomass char combustion in a low temperature fluidized bed reactor," Chemical Engineering Journal, vol. 331, pp. 265-277, 2018.
  • [12] J. Chen, L. Mu, J. Cai, H. Yin, X. Song, and A. Li, "Thermal characteristics and kinetics of refining and chemicals wastewater, lignite and their blends during combustion," Energy Conversion and Management, vol. 100, pp. 201-211, 2015.
  • [13] A. Demirbas, "Combustion characteristics of different biomass fuels," Progress in energy and combustion science, vol. 30, no. 2, pp. 219-230, 2004.
  • [14] Q.-V. Bach, K.-Q. Tran, Ø. Skreiberg, and T. T. Trinh, "Effects of wet torrefaction on pyrolysis of woody biomass fuels," Energy, vol. 88, pp. 443-456, 2015.
  • [15] B. Ru, S. Wang, G. Dai, and L. Zhang, "Effect of torrefaction on biomass physicochemical characteristics and the resulting pyrolysis behavior," Energy & Fuels, vol. 29, no. 9, pp. 5865-5874, 2015.
  • [16] A. Toptas, Y. Yildirim, G. Duman, and J. Yanik, "Combustion behavior of different kinds of torrefied biomass and their blends with lignite," Bioresource technology, vol. 177, pp. 328-336, 2015.
  • [17] X. Peng, X. Ma, and Z. Xu, "Thermogravimetric analysis of co-combustion between microalgae and textile dyeing sludge," Bioresource Technology, vol. 180, pp. 288-295, 2015.
  • [18] W. Cao, J. Li, and L. Lue, "Study on the ignition behavior and kinetics of combustion of biomass," Energy Procedia, vol. 142, pp. 136-141, 2017.
  • [19] H. H. Sait, A. Hussain, A. A. Salema, and F. N. Ani, "Pyrolysis and combustion kinetics of date palm biomass using thermogravimetric analysis," Bioresource Technology, vol. 118, pp. 382-389, 2012.
  • [20] M. V. Gil, D. Casal, C. Pevida, J. Pis, and F. Rubiera, "Thermal behaviour and kinetics of coal/biomass blends during co-combustion," Bioresource Technology, vol. 101, no. 14, pp. 5601-5608, 2010.
  • [21] A. Álvarez, C. Pizarro, R. García, J. Bueno, and A. Lavín, "Determination of kinetic parameters for biomass combustion," Bioresource technology, vol. 216, pp. 36-43, 2016.
  • [22] K. Jayaraman, M. V. Kök, and I. Gökalp, "Combustion mechanism and model free kinetics of different origin coal samples: Thermal analysis approach," Energy, p. 117905, 2020.
  • [23] R. Junga, W. Knauer, P. Niemiec, and M. Tańczuk, "Experimental tests of co-combustion of laying hens manure with coal by using thermogravimetric analysis," Renewable Energy, vol. 111, pp. 245-255, 2017.
  • [24] T. Ozawa, "A new method of analyzing thermogravimetric data," Bulletin of the chemical society of Japan, vol. 38, no. 11, pp. 1881-1886, 1965.
  • [25] J. H. Flynn and L. A. Wall, "General treatment of the thermogravimetry of polymers," Journal of Research of the National Bureau of Standards. Section A, Physics and Chemistry, vol. 70, no. 6, p. 487, 1966.
  • [26] T. Akahira and T. Sunose, "Method of determining activation deterioration constant of electrical insulating materials," Res Rep Chiba Inst Technol (Sci Technol), vol. 16, no. 1971, pp. 22-31, 1971.
  • [27] R. Barzegar, A. Yozgatligil, H. Olgun, and A. T. Atimtay, "TGA and kinetic study of different torrefaction conditions of wood biomass under air and oxy-fuel combustion atmospheres," Journal of the Energy Institute, vol. 93, no. 3, pp. 889-898, 2020.
  • [28] H. L. Friedman, "Kinetics of thermal degradation of char‐forming plastics from thermogravimetry. Application to a phenolic plastic," in Journal of polymer science part C: polymer symposia, 1964, vol. 6, no. 1: Wiley Online Library, pp. 183-195.
  • [29] U. Özveren, "Theoretical and experimental investigation of biomass and coal gasification," 2013.
  • [30] K. Chrissafis, "Kinetics of thermal degradation of polymers," Journal of Thermal Analysis and Calorimetry, vol. 95, no. 1, pp. 273-283, 2009.
  • [31] J. Opfermann, "Kinetic analysis using multivariate non-linear regression. I. Basic concepts," Journal of thermal analysis and calorimetry, vol. 60, no. 2, pp. 641-658, 2000.
  • [32] N. Tudorachi and F. Mustata, "Curing and thermal degradation of diglycidyl ether of bisphenol A epoxy resin crosslinked with natural hydroxy acids as environmentally friendly hardeners," Arabian Journal of Chemistry, vol. 13, no. 1, pp. 671-682, 2020.
  • [33] H. Şenol, "Biogas potential of hazelnut shells and hazelnut wastes in Giresun City," Biotechnology Reports, vol. 24, p. e00361, 2019.
  • [34] S. Karata et al., "Examination of modern and traditional applications in hazelnut production," in IX International Congress on Hazelnut 1226, 2017, pp. 329-332.
  • [35] A. Sezer, F. S. Dolar, S. J. Lucas, Ç. Köse, and E. Gümüş, "First report of the recently introduced, destructive powdery mildew Erysiphe corylacearum on hazelnut in Turkey," Phytoparasitica, vol. 45, no. 4, pp. 577-581, 2017.
  • [36] S. Niu, M. Chen, Y. Li, and T. Lu, "Combustion characteristics of municipal sewage sludge with different initial moisture contents," Journal of Thermal Analysis and Calorimetry, vol. 129, no. 2, pp. 1189-1199, 2017.
  • [37] C. Di Blasi, "Modeling chemical and physical processes of wood and biomass pyrolysis," Progress in energy and combustion science, vol. 34, no. 1, pp. 47-90, 2008.
  • [38] I. Mian et al., "Combustion kinetics and mechanism of biomass pellet," Energy, p. 117909, 2020.
  • [39] L. Burhenne, J. Messmer, T. Aicher, and M.-P. Laborie, "The effect of the biomass components lignin, cellulose and hemicellulose on TGA and fixed bed pyrolysis," Journal of Analytical and Applied Pyrolysis, vol. 101, pp. 177-184, 2013.
  • [40] S. D. Stefanidis, K. G. Kalogiannis, E. F. Iliopoulou, C. M. Michailof, P. A. Pilavachi, and A. A. Lappas, "A study of lignocellulosic biomass pyrolysis via the pyrolysis of cellulose, hemicellulose and lignin," Journal of analytical and applied pyrolysis, vol. 105, pp. 143-150, 2014.

Investigation of Hazelnut Husk Combustion by using A Novel Non-linear Kinetic Model through Thermogravimetric Analysis

Yıl 2021, , 326 - 338, 15.04.2021
https://doi.org/10.16984/saufenbilder.811684

Öz

Considering economic and environmental issues, boosting renewable energy source is the main subject to fulfill energy demand in these days. Biomass as natural and abundant energy source can be typically used to produce electricity, fuels and heat applying thermochemical conversion processes such as combustion, pyrolysis or gasification. Biomass combustion is the most common process to produce electricity and useful heat in Turkey and all over the world. The aim of this study is to investigate the considerable influence of heating rates on combustion characteristics and kinetics employing a new developed non-linear kinetic model for hazelnut husk samples through thermogravimetric analysis. Furthermore, this work comprehensively assesses the variations in the reactivity of hazelnut husk combustion, expressed from thermogravimetric curves. The non-linear kinetic model developed in this study integrates the various kinetic pathway to estimate the major controlling parameter of combustion reactivity, its activation energy, pre-exponential factor and reaction order. According to comparison of results from the non-linear kinetic model for volatile combustion and fixed carbon combustion, correlation coefficients (R2) for both models are higher than 0.9985. These results proved the non-linear regression model for kinetic pathways in combustion reactivity worked properly to estimate thermal decomposition behavior.

Kaynakça

  • [1] B. Rijal, S. H. Gautam, and L. LeBel, "The impact of forest disturbances on residual biomass supply: A long-term forest level analysis," Journal of Cleaner Production, vol. 248, p. 119278, 2020.
  • [2] S. de Oliveira Junior, Exergy: production, cost and renewability. Springer Science & Business Media, 2012.
  • [3] L. Rincon, M. Puri, A. Kojakovic, and I. Maltsoglou, "The contribution of sustainable bioenergy to renewable electricity generation in Turkey: Evidence based policy from an integrated energy and agriculture approach," Energy Policy, vol. 130, pp. 69-88, 2019.
  • [4] H. S. Kambo and A. Dutta, "Comparative evaluation of torrefaction and hydrothermal carbonization of lignocellulosic biomass for the production of solid biofuel," Energy conversion and management, vol. 105, pp. 746-755, 2015.
  • [5] S. Brand, R. F. Susanti, S. K. Kim, H.-s. Lee, J. Kim, and B.-I. Sang, "Supercritical ethanol as an enhanced medium for lignocellulosic biomass liquefaction: Influence of physical process parameters," Energy, vol. 59, pp. 173-182, 2013.
  • [6] E. Demirkaya, O. Dal, and A. Yüksel, "Liquefaction of waste hazelnut shell by using sub-and supercritical solvents as a reaction medium," The Journal of Supercritical Fluids, vol. 150, pp. 11-20, 2019.
  • [7] M. Phanphanich and S. Mani, "Impact of torrefaction on the grindability and fuel characteristics of forest biomass," Bioresource technology, vol. 102, no. 2, pp. 1246-1253, 2011.
  • [8] S. Sadaka, H. Liechty, M. Pelkki, and M. Blazier, "Pyrolysis and combustion kinetics of raw and carbonized cottonwood and switchgrass agroforests," BioResources, vol. 10, no. 3, pp. 4498-4518, 2015.
  • [9] Q. Li et al., "Gaseous ammonia emissions from coal and biomass combustion in household stoves with different combustion efficiencies," Environmental Science & Technology Letters, vol. 3, no. 3, pp. 98-103, 2016.
  • [10] A. Demirbas, "Political, economic and environmental impacts of biofuels: A review," Applied energy, vol. 86, pp. S108-S117, 2009.
  • [11] M. Morin, S. Pécate, and M. Hémati, "Kinetic study of biomass char combustion in a low temperature fluidized bed reactor," Chemical Engineering Journal, vol. 331, pp. 265-277, 2018.
  • [12] J. Chen, L. Mu, J. Cai, H. Yin, X. Song, and A. Li, "Thermal characteristics and kinetics of refining and chemicals wastewater, lignite and their blends during combustion," Energy Conversion and Management, vol. 100, pp. 201-211, 2015.
  • [13] A. Demirbas, "Combustion characteristics of different biomass fuels," Progress in energy and combustion science, vol. 30, no. 2, pp. 219-230, 2004.
  • [14] Q.-V. Bach, K.-Q. Tran, Ø. Skreiberg, and T. T. Trinh, "Effects of wet torrefaction on pyrolysis of woody biomass fuels," Energy, vol. 88, pp. 443-456, 2015.
  • [15] B. Ru, S. Wang, G. Dai, and L. Zhang, "Effect of torrefaction on biomass physicochemical characteristics and the resulting pyrolysis behavior," Energy & Fuels, vol. 29, no. 9, pp. 5865-5874, 2015.
  • [16] A. Toptas, Y. Yildirim, G. Duman, and J. Yanik, "Combustion behavior of different kinds of torrefied biomass and their blends with lignite," Bioresource technology, vol. 177, pp. 328-336, 2015.
  • [17] X. Peng, X. Ma, and Z. Xu, "Thermogravimetric analysis of co-combustion between microalgae and textile dyeing sludge," Bioresource Technology, vol. 180, pp. 288-295, 2015.
  • [18] W. Cao, J. Li, and L. Lue, "Study on the ignition behavior and kinetics of combustion of biomass," Energy Procedia, vol. 142, pp. 136-141, 2017.
  • [19] H. H. Sait, A. Hussain, A. A. Salema, and F. N. Ani, "Pyrolysis and combustion kinetics of date palm biomass using thermogravimetric analysis," Bioresource Technology, vol. 118, pp. 382-389, 2012.
  • [20] M. V. Gil, D. Casal, C. Pevida, J. Pis, and F. Rubiera, "Thermal behaviour and kinetics of coal/biomass blends during co-combustion," Bioresource Technology, vol. 101, no. 14, pp. 5601-5608, 2010.
  • [21] A. Álvarez, C. Pizarro, R. García, J. Bueno, and A. Lavín, "Determination of kinetic parameters for biomass combustion," Bioresource technology, vol. 216, pp. 36-43, 2016.
  • [22] K. Jayaraman, M. V. Kök, and I. Gökalp, "Combustion mechanism and model free kinetics of different origin coal samples: Thermal analysis approach," Energy, p. 117905, 2020.
  • [23] R. Junga, W. Knauer, P. Niemiec, and M. Tańczuk, "Experimental tests of co-combustion of laying hens manure with coal by using thermogravimetric analysis," Renewable Energy, vol. 111, pp. 245-255, 2017.
  • [24] T. Ozawa, "A new method of analyzing thermogravimetric data," Bulletin of the chemical society of Japan, vol. 38, no. 11, pp. 1881-1886, 1965.
  • [25] J. H. Flynn and L. A. Wall, "General treatment of the thermogravimetry of polymers," Journal of Research of the National Bureau of Standards. Section A, Physics and Chemistry, vol. 70, no. 6, p. 487, 1966.
  • [26] T. Akahira and T. Sunose, "Method of determining activation deterioration constant of electrical insulating materials," Res Rep Chiba Inst Technol (Sci Technol), vol. 16, no. 1971, pp. 22-31, 1971.
  • [27] R. Barzegar, A. Yozgatligil, H. Olgun, and A. T. Atimtay, "TGA and kinetic study of different torrefaction conditions of wood biomass under air and oxy-fuel combustion atmospheres," Journal of the Energy Institute, vol. 93, no. 3, pp. 889-898, 2020.
  • [28] H. L. Friedman, "Kinetics of thermal degradation of char‐forming plastics from thermogravimetry. Application to a phenolic plastic," in Journal of polymer science part C: polymer symposia, 1964, vol. 6, no. 1: Wiley Online Library, pp. 183-195.
  • [29] U. Özveren, "Theoretical and experimental investigation of biomass and coal gasification," 2013.
  • [30] K. Chrissafis, "Kinetics of thermal degradation of polymers," Journal of Thermal Analysis and Calorimetry, vol. 95, no. 1, pp. 273-283, 2009.
  • [31] J. Opfermann, "Kinetic analysis using multivariate non-linear regression. I. Basic concepts," Journal of thermal analysis and calorimetry, vol. 60, no. 2, pp. 641-658, 2000.
  • [32] N. Tudorachi and F. Mustata, "Curing and thermal degradation of diglycidyl ether of bisphenol A epoxy resin crosslinked with natural hydroxy acids as environmentally friendly hardeners," Arabian Journal of Chemistry, vol. 13, no. 1, pp. 671-682, 2020.
  • [33] H. Şenol, "Biogas potential of hazelnut shells and hazelnut wastes in Giresun City," Biotechnology Reports, vol. 24, p. e00361, 2019.
  • [34] S. Karata et al., "Examination of modern and traditional applications in hazelnut production," in IX International Congress on Hazelnut 1226, 2017, pp. 329-332.
  • [35] A. Sezer, F. S. Dolar, S. J. Lucas, Ç. Köse, and E. Gümüş, "First report of the recently introduced, destructive powdery mildew Erysiphe corylacearum on hazelnut in Turkey," Phytoparasitica, vol. 45, no. 4, pp. 577-581, 2017.
  • [36] S. Niu, M. Chen, Y. Li, and T. Lu, "Combustion characteristics of municipal sewage sludge with different initial moisture contents," Journal of Thermal Analysis and Calorimetry, vol. 129, no. 2, pp. 1189-1199, 2017.
  • [37] C. Di Blasi, "Modeling chemical and physical processes of wood and biomass pyrolysis," Progress in energy and combustion science, vol. 34, no. 1, pp. 47-90, 2008.
  • [38] I. Mian et al., "Combustion kinetics and mechanism of biomass pellet," Energy, p. 117909, 2020.
  • [39] L. Burhenne, J. Messmer, T. Aicher, and M.-P. Laborie, "The effect of the biomass components lignin, cellulose and hemicellulose on TGA and fixed bed pyrolysis," Journal of Analytical and Applied Pyrolysis, vol. 101, pp. 177-184, 2013.
  • [40] S. D. Stefanidis, K. G. Kalogiannis, E. F. Iliopoulou, C. M. Michailof, P. A. Pilavachi, and A. A. Lappas, "A study of lignocellulosic biomass pyrolysis via the pyrolysis of cellulose, hemicellulose and lignin," Journal of analytical and applied pyrolysis, vol. 105, pp. 143-150, 2014.
Toplam 40 adet kaynakça vardır.

Ayrıntılar

Birincil Dil İngilizce
Konular Kimya Mühendisliği
Bölüm Araştırma Makalesi
Yazarlar

Senem Sezer 0000-0002-1732-4840

Uğur Özveren 0000-0002-3790-0606

Yayımlanma Tarihi 15 Nisan 2021
Gönderilme Tarihi 16 Ekim 2020
Kabul Tarihi 26 Ocak 2021
Yayımlandığı Sayı Yıl 2021

Kaynak Göster

APA Sezer, S., & Özveren, U. (2021). Investigation of Hazelnut Husk Combustion by using A Novel Non-linear Kinetic Model through Thermogravimetric Analysis. Sakarya University Journal of Science, 25(2), 326-338. https://doi.org/10.16984/saufenbilder.811684
AMA Sezer S, Özveren U. Investigation of Hazelnut Husk Combustion by using A Novel Non-linear Kinetic Model through Thermogravimetric Analysis. SAUJS. Nisan 2021;25(2):326-338. doi:10.16984/saufenbilder.811684
Chicago Sezer, Senem, ve Uğur Özveren. “Investigation of Hazelnut Husk Combustion by Using A Novel Non-Linear Kinetic Model through Thermogravimetric Analysis”. Sakarya University Journal of Science 25, sy. 2 (Nisan 2021): 326-38. https://doi.org/10.16984/saufenbilder.811684.
EndNote Sezer S, Özveren U (01 Nisan 2021) Investigation of Hazelnut Husk Combustion by using A Novel Non-linear Kinetic Model through Thermogravimetric Analysis. Sakarya University Journal of Science 25 2 326–338.
IEEE S. Sezer ve U. Özveren, “Investigation of Hazelnut Husk Combustion by using A Novel Non-linear Kinetic Model through Thermogravimetric Analysis”, SAUJS, c. 25, sy. 2, ss. 326–338, 2021, doi: 10.16984/saufenbilder.811684.
ISNAD Sezer, Senem - Özveren, Uğur. “Investigation of Hazelnut Husk Combustion by Using A Novel Non-Linear Kinetic Model through Thermogravimetric Analysis”. Sakarya University Journal of Science 25/2 (Nisan 2021), 326-338. https://doi.org/10.16984/saufenbilder.811684.
JAMA Sezer S, Özveren U. Investigation of Hazelnut Husk Combustion by using A Novel Non-linear Kinetic Model through Thermogravimetric Analysis. SAUJS. 2021;25:326–338.
MLA Sezer, Senem ve Uğur Özveren. “Investigation of Hazelnut Husk Combustion by Using A Novel Non-Linear Kinetic Model through Thermogravimetric Analysis”. Sakarya University Journal of Science, c. 25, sy. 2, 2021, ss. 326-38, doi:10.16984/saufenbilder.811684.
Vancouver Sezer S, Özveren U. Investigation of Hazelnut Husk Combustion by using A Novel Non-linear Kinetic Model through Thermogravimetric Analysis. SAUJS. 2021;25(2):326-38.

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