Thermal Decomposition and Kinetic Studies of Pyrolysis of Spirulina Platensis Residue

Jamilatun, Siti; Budhijanto, Budhijanto; Rochmadi, Rochmadi; Budiman, Arief

doi:10.14710/ijred.6.3.193-201

Cited by 22 publications

(31 citation statements)

References 21 publications

Supporting

Mentioning

Contrasting

Unclassified

Order By: Relevance

“…Despite not competing for resources with food production as they are derived from renewable resources, and with lower costs of production, the raw material resources used in the first and second generations did require extensive land; hence, biofuel production per area is relatively low (Pradana et al, 2017a;Sudibyo et al, 2017). To that end, microalgae, which requires less land to produce, offers the potential to be developed as a resource for use in the third generation of biofuels (Jamilatun et al, 2017b;Pradana et al, 2017b). Microalgae can be converted into biofuels through either a thermal or biological process.…”

Section: Introductionmentioning

confidence: 99%

Effect of Grain Size, Temperature and Catalyst Amount on Pyrolysis Products of Spirulina Platensis Residue (SPR)

Jamilatun¹,

Budhijanto²,

Rochmadi³

et al. 2019

IJTech

Self Cite

View full text Add to dashboard Cite

Spirulina platensis microalgae is one of the feedstocks used in the production of the third generation of biofuel. The extraction of its lipid for biodiesel leaves behind a residue, which can be treated by pyrolysis to create certain other value-added products. This paper discusses the effects of Spirulina platensis residue (SPR) with respect to grain size (0.105, 0.149 and 0.177 mm), temperature (300 to 600°C) and amount of catalyst (0, 10, 20 and 40 wt.%) on the characteristics of products (bio-oil, water phase, char and gas) obtained from pyrolysis in a fixedbed reactor. The results of the study show that the higher the pyrolysis temperature, the higher the conversion. For the bio-oil product, the optimum temperature is 500°C, which produces a peak yield of 35.99 wt.%. The larger the grain size, the lower the bio-oil yield, gas water and gas, for all of the tested temperatures (300-600°C). The amount of catalyst and the pyrolysis temperature greatly influence the quality of bio-oil products, grouping them into the fractions of LPG (C ≤ 4), gasoline (C5-C11), biodiesel (C12-C18) and heavy naphtha (C ≥ 19). The tendency for LPG-Gasoline formation at optimum conditions, considering the use of a 10 wt.% catalyst at a temperature of 400-500°C, was reported.

show abstract

Section: Introductionmentioning

confidence: 99%

Effect of Grain Size, Temperature and Catalyst Amount on Pyrolysis Products of Spirulina Platensis Residue (SPR)

Jamilatun¹,

Budhijanto²,

Rochmadi³

et al. 2019

IJTech

Self Cite

View full text Add to dashboard Cite

show abstract

“…Bio-oil from microalgae has better quality than other biomass and can produce energy of 39.7 MJ/kg. The development of bio-oil can be a substitute for hydrocarbon fuels in the industry and effectively used as a substitute for diesel, heavy fuel oil, light fuel oil, and can be used in various types of boilers [12][13][14][15].…”

Section: Introductionmentioning

confidence: 99%

Bio-Oil Characterizations of <i>Spirulina Platensis</i> Residue (SPR) Pyrolysis Products for Renewable Energy Development

Jamilatun

Rahayu

Pradana

et al. 2020

KEM

Self Cite

View full text Add to dashboard Cite

Nowadays, energy consumption has increased as a population increases with socio-economic developments and improved living standards. Therefore, it is necessary to find a replacement for fossil energy with renewable energy sources, and the potential to develop is biofuels. Bio-oil, water phase, gas, and char products will be produced by utilizing Spirulina platensis (SPR) microalgae extraction residue as pyrolysis raw material. The purpose of this study is to characterize pyrolysis products and bio-oil analysis with GC-MS. Quality fuel is good if O/C is low, H/C is high, HHV is high, and oxygenate compounds are low, but aliphatic and aromatic are high. Pyrolysis was carried out at a temperature of 300-600°C with a feed of 50 grams in atmospheric conditions with a heating rate of 5-35°C/min, the equipment used was a fixed-bed reactor. The higher the pyrolysis temperature, the higher the bio-oil yield will be to an optimum temperature, then lower. The optimum temperature of pyrolysis is 550°C with a bio-oil yield of 23.99 wt%. The higher the pyrolysis temperature, the higher the H/C, the lower O/C. The optimum condition was reached at a temperature of 500°C with the values of H/C, and O/C is 1.17 and 0.47. With an increase in temperature of 300-600°C, HHV increased from 11.64 MJ/kg to 20.63 MJ/kg, the oxygenate compound decreased from 85.26 to 37.55 wt%. Aliphatics and aromatics increased, respectively, from 5.76 to 36.72 wt% and 1.67 to 6.67 wt%.

show abstract

“…The intermediate pyrolysis at 400-500 °C, a heating rate at 1-1000 °C/sec, hot vapor residence at 10-30 seconds will produce 25% char, 50% tar, and 25% gas. In contrast, fast pyrolysis can provide 12% char, 75% tar, and 13% gas with a heating rate of 10 to more than 1000 °C/sec, a residence time of fewer than 2 seconds, and an optimum temperature between 400-650 °C (Jamilatun et al, 2017;Suganya et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

Biochar from Slow Catalytic Pyrolysis of Spirulina platensis Residue: Effects of Temperature and Silica-Alumina Catalyst on Yield and Characteristics

et al. 2020

Self Cite

View full text Add to dashboard Cite

The use of biochar varies on its ability as an adsorbent which adsorbs liquid or gas molecules. Biochar from Spirulina platensis residue (SPR) as an energy source, as its richness in nutrients, can be used as fertilizer and maintain water resources in plantations. Biochar can be used as an intermediary for the synthesis of nanotubes, activated carbon, carbon black, and carbon fiber. One of the essential things to be considered in the application of activated carbon from SPR is char’s characteristics. This study aimed to obtain data on the biochar and components from the pyrolysis of Spirulina platensis residue. The study was conducted in a fixed-bed reactor with electric heaters with a variety of temperatures (300-700 ⁰C) and the amount of silica-alumina catalyst (0-20%). The biochar weight was obtained by weighing the char formed at the end of the pyrolysis. The char characteristics were obtained by the surface area, total pore volume, and pore size analysis. Based on the study results, the relationship between temperature and the amount of catalyst on the characteristics of biochar was studied. The higher the pyrolysis temperature, the less biochar. Also, the use of catalysts can reduce the amount of biochar. The higher the temperature, the higher the surface area and the total pore volume while the pore radius was reduced. The optimum condition for maximum biochar yield in non-catalytic pyrolysis at a temperature of 300 ⁰C was 49.86 wt.%. The surface area, the total pore volume, and the pore radius at 700 ⁰C catalytic pyrolysis with 5% silica-alumina was obtained as 36.91 m2/g, 0.052 cm3/g, and 2.68 nm, respectively.Keywords: biochar; pore radius; silica-alumina; surface area; total pore volumeA B S T R A KPenggunaan biochar bervariasi pada kemampuannya sebagai adsorben dalam menjerap molekul cairan atau gas. Biochar dari residu Spirulina platensis merupakan sumber energi, karena kaya akan unsur hara, dapat digunakan sebagai pupuk dan pemeliharaan sumber daya air di perkebunan. Biochar dapat juga digunakan sebagai perantara untuk sintesis nanotube, karbon aktif, carbon black, dan serat karbon. Salah satu hal penting yang harus diperhatikan dalam aplikasi karbon aktif dari SPR adalah karakteristik arang. Penelitian ini bertujuan untuk mendapatkan data biochar dan komponen dari pirolisis residu Spirulina platensis. Penelitian dilakukan di reaktor fixed-bed dengan pemanas listrik dengan variasi suhu (300-700 ⁰C) dan jumlah katalis silika-alumina (0-20%). Berat biochar diperoleh dengan cara menimbang arang yang terbentuk pada akhir pirolisis. Sedangkan karakteristik arang diperoleh dari analisis luas permukaan, volume pori total, dan ukuran pori. Berdasarkan hasil studi hubungan antara suhu dan jumlah katalis terhadap karakteristik biochar yang telah diteliti, semakin tinggi suhu pirolisis maka biochar semakin sedikit. Selain itu, penggunaan katalis dapat mengurangi jumlah biochar. Sebaliknya, semakin tinggi suhu semakin besar luas permukaan, dan volume pori total serta radius pori-pori semakin berkurang. Kondisi optimum untuk biochar maksimum pada pirolisis non katalitik pada suhu 300 ⁰C adalah 49,86 wt.%. Luas permukaan, total volume pori, dan radius pori pada suhu 700 ⁰C untuk pirolisis katalitik silika-alumina 5% diperoleh masing-masing sebesar 36,91 m2/g, 0,052 cm3/g, dan 2,68 nm.Kata kunci: biochar; luas permukaan; radius pori; silika-alumina; total volume pori

show abstract

Thermal Decomposition and Kinetic Studies of Pyrolysis of Spirulina Platensis Residue

Cited by 22 publications

References 21 publications

Effect of Grain Size, Temperature and Catalyst Amount on Pyrolysis Products of Spirulina Platensis Residue (SPR)

Effect of Grain Size, Temperature and Catalyst Amount on Pyrolysis Products of Spirulina Platensis Residue (SPR)

Bio-Oil Characterizations of <i>Spirulina Platensis</i> Residue (SPR) Pyrolysis Products for Renewable Energy Development

Biochar from Slow Catalytic Pyrolysis of Spirulina platensis Residue: Effects of Temperature and Silica-Alumina Catalyst on Yield and Characteristics

Contact Info

Product

Resources

About