Investigation of the biogas production potential from algal wastes

Koçer, Anıl Tevfik; Özçimen, Didem

doi:10.1177/0734242x18798447

Cited by 37 publications

(18 citation statements)

References 45 publications

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“…The dry weight mainly consists of cellulose, namely 35-50%, a further 20-35% of hemicellulose, and around 10-25% of lignin [29]. Lignocellulosic waste can come from several sources, namely industrial waste (e.g., recycled newspaper, food industry residues, sawdust), agricultural waste (e.g., bagasse, rice straw, corn stover), forestry waste (e.g., wood chips, grasses, hard and softwood), bioenergy crops (e.g., common reeds, switchgrass), and municipal solid waste [30][31][32]. The lignocellulosic biomass can be converted into bioethanol via a biochemical pathway.…”

Section: Introductionmentioning

confidence: 99%

Feasibility Assessment of a Bioethanol Plant in the Northern Netherlands

et al. 2019

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Due to the exhaustion and increased pressure regarding the environmental and political aspects of fossil fuels, the industrial focus has switched towards renewable energy resources. Lignocellulosic biowaste can come from several sources, such as industrial waste, agricultural waste, forestry waste, and bioenergy crops and processed into bioethanol via a biochemical pathway. Although much research has been done on the ethanol production from lignocellulosic biomass, the economic viability of a bioethanol plant in the Northern Netherlands is yet unknown, and therefore, examined. In this thesis, the feasibility study of a bioethanol plant treating sugar beet pulp, cow manure, and grass straw is conducted using the simulation software SuperPro Designer. Results show that it is not economically viable to treat the tested lignocellulosic biomass for the production of bioethanol, since all three original cases result in a negative net present value (NPV). An alternative would be to exclude the pretreatment step from the process. Although this results in a lower production of bioethanol per year, the plant treating sugar beet pulp (SBP) and grass straw (GS) becomes economically viable since the costs have significantly decreased.

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Section: Introductionmentioning

confidence: 99%

Feasibility Assessment of a Bioethanol Plant in the Northern Netherlands

et al. 2019

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“…Higher biogas yields from Ulva biorefinery facilities yielded up to 271 mL CH 4 /kg volatile solids (VS) in the range of methane production from cattle manure and crop land-based energies [41]. Enhanced bio methane production was observed in pretreated biomass and also in co-digestion processes [55].…”

Section: Potential Riches Of Ulvamentioning

confidence: 99%

Ulva lactuca, A Source of Troubles and Potential Riches

2019

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Ulva lactuca is a green macro alga involved in devastating green tides observed worldwide. These green tides or blooms are a consequence of human activities. Ulva blooms occur mainly in shallow waters and the decomposition of this alga can produce dangerous vapors. Ulva lactuca is a species usually resembling lettuce, but genetic analyses demonstrated that other green algae with tubular phenotypes were U. lactuca clades although previously described as different species or even genera. The capacity for U. lactuca to adopt different phenotypes can be due to environment parameters, such as the degree of water salinity or symbiosis with bacteria. No efficient ways have been discovered to control these green tides, but the Mediterranean seas appear to be protected from blooms, which disappear rapidly in springtime. Ulva contains commercially valuable components, such as bioactive compounds, food or biofuel. The biomass due to this alga collected on beaches every year is beginning to be valorized to produce valuable compounds. This review describes different processes and strategies developed to extract these different valuable components.

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“…The multiple utilization of biogas for heat and electricity generation or vehicle fuel (upgrade biogas) can support the drive for its application [19][20][21]. It is also obvious that the AD antagonism will be affected by the use of other energy sources (e.g., wind, nuclear, shale oil/gas) [22][23][24][25][26].…”

Section: Introductionmentioning

confidence: 99%

Effect of Temperature and Organic Load on the Performance of Anaerobic Bioreactors Treating Grasses

Achinas

Euverink

2020

Environments

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The organic residues generated in grasslands can be treated by adopting anaerobic digestion technology. This technology can enhance the efforts for sustainable waste management around the world. In the northern Netherlands, there is a vast amount of ditch clippings and canal grasses that can be used as a renewable source of energy; however, optimal bioenergy production from grasses is still under research and this study aims to evaluate biogas production from grassy residues at the local level in the context of a sustainable waste management scheme. Batch tests were facilitated to investigate the impact of temperature and organic load on the anaerobic digestion performance of grass mixtures (ditch clippings and canal grasses). The results showed that high temperature favors the degradation of high lignocellulosic materials like grasses. Specifically, bioreactors at 55 °C with an organic load of 30 g volatile solids (VS)∙L−1 reached 360.4 mL∙g VSsubstrate−1. Moreover, reactors with low organic loads resulted in a lower methane yield. The kinetics study also showed good fitting of the predicted and experimental values.

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Investigation of the biogas production potential from algal wastes

Cited by 37 publications

References 45 publications

Feasibility Assessment of a Bioethanol Plant in the Northern Netherlands

Feasibility Assessment of a Bioethanol Plant in the Northern Netherlands

Ulva lactuca, A Source of Troubles and Potential Riches

Effect of Temperature and Organic Load on the Performance of Anaerobic Bioreactors Treating Grasses

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