Showing total 4 results

1. Mitigation of CO2 emissions by transforming to biofuels: Optimization of biofuels production processes.

Author

Mukhtar, Ahmad, Saqib, Sidra, Mubashir, Muhammad, Ullah, Sami, Inayat, Abrar, Mahmood, Abid, Ibrahim, Muhammad, and Show, Pau Loke

Subjects

*MANUFACTURING processes, *BIOMASS energy, *VEGETABLE oils, *CARBON dioxide, *RAW materials, *BIODIESEL fuels, *WASTE products

Abstract

Biodiesel is typically produced from a wide variety of edible vegetable oils. The cost of biofuels is projected to rise in the future as an alternative and ecologically suitable replacement to traditional fuel. Reliable and inexpensive raw materials, including meat processing by-products or waste animal fats, have rapidly attracted interest in biodiesel production. The operational and reaction parameters play an important role in the conversion of processes and biodiesel yield. Kinetic models explain the reaction rate and process optimization to improve the biodiesel conversion process. The process intensification approaches applied by different researchers are illustrated in the current study. This paper proposes a groundbreaking solution to stepping up biodiesel development by utilizing a coalescer reactor and a preliminary review to justify the solution's potential for further analysis. Optimization techniques and kinetics studies used to enhance biodiesel production from renewable sources are explored in the current review paper. • Biodiesel is projected to rise in the future as an alternative and ecologically suitable replacement to traditional fuel. • The effect of operational and reaction parameters on the conversion/yield of processes are reviewed. • To avoid these biodiesel development problems, the process intensification approaches applied by different researchers are also illustrated. • Method optimization, kinetics, and enhancing biodiesel output from renewable sources are explored in detail. [ABSTRACT FROM AUTHOR]

Published

2021

2. Sustainable energy development strategies: implications of energy demand management and renewable energy in Thailand

Author

Tanatvanit, Somporn, Limmeechokchai, Bundit, and Chungpaibulpatana, Supachart

Subjects

*ENERGY consumption

Abstract

A brief review of energy use patterns in three economic sectors; namely, residential, industrial and transport sectors is provided in this paper. The transport sector is the largest energy-consuming sector in Thailand, followed by the industrial and residential sectors, respectively. In order to reduce both imported energy and environmental emissions, energy conservation programs would be implemented. This paper forecasts the growth in energy demand and corresponding emissions to the year 2020 for those three sectors by using a model based on the end-use approach. The energy savings from the energy conservation strategies, such as energy efficiency improvement and energy demand management, are assessed and also the implications on electricity generation expansion planning are examined. The integrated resource planning (IRP) model is used to find the least-cost electricity generation expansion plans. Energy conservation options, including energy efficiency improvement programs, are introduced in the residential and industrial sectors. Public transportation and engine technology improvements are introduced in the transport sector. The effects of energy conservation options are analyzed using a scenario-based approach. The results of analysis reveal that the improvement of public transportation can reduce future energy requirements and CO2 emissions in 2020 by 635 thousand ton of oil equivalent (toe) and 2024 thousand ton of CO2 equivalent, respectively. If all options are simultaneously implemented, the potential of energy savings and CO2 mitigation in 2020 are estimated to be 1240 thousand toe and 3622 thousand ton of CO2 equivalent, respectively. [Copyright &y& Elsevier]

Published

2003

3. Carbon capture and biomass in industry: A techno-economic analysis and comparison of negative emission options.

Author

Yang, F., Meerman, J.C., and Faaij, A.P.C.

Subjects

*CARBON dioxide, *BIOMASS, *GREENHOUSE gases, *PETROLEUM, *REDUCTION potential, *CHEMICAL-looping combustion, *CARBON sequestration, *CARBON dioxide mitigation

Abstract

Meeting the Paris Agreement will most likely require the combination of CO 2 capture and biomass in the industrial sector, resulting in net negative emissions. CO 2 capture within the industry has been extensively investigated. However, biomass options have been poorly explored, with literature alluding to technical and economic barriers. In addition, a lack of consistency among studies makes comparing the performance of CO 2 capture and/or biomass use between studies and sectors difficult. These inconsistencies include differences in methodology, system boundaries, level of integration, costs, greenhouse gas intensity of feedstock and energy carriers, and capital cost estimations. Therefore, an integrated evaluation of the techno-economic performance regarding CO 2 capture and biomass use was performed for five energy-intensive industrial sub-sectors. Harmonization results indicate that CO 2 mitigation potentials vary for each sub-sector, resulting in reductions of 1.4–2.7 t CO 2 /t steel (77%–149%), 0.7 t CO 2 /t cement (92%), 0.2 t CO 2 /t crude oil (68%), 1.9 t CO 2 /t pulp (1663%–2548%), and 34.9 t CO 2 /t H 2 (313%). Negative emissions can be reached in the steel, paper and H 2 sectors. Novel bio-based production routes might enable net negative emissions in the cement and (petro)chemical sectors as well. All the above-mentioned potentials can be reached for 100 €/t CO 2 or less. Implementing mitigation options could reduce industrial CO 2 emissions by 10 Gt CO 2 /y by 2050, easily meeting the targets of the 2 °C scenario by the International Energy Agency (1.8 Gt CO 2 /y reduction) for the industrial sector and even the Beyond 2 °C scenario (4.2 Gt CO 2 /y reduction). • Literature review on CO 2 mitigation in steel, cement, chemical, H 2 and paper sectors. • Introduction harmonized methodology to allow comparison between industrial sectors. • All investigated sectors have large reduction potentials for <100 €/t CO 2 avoided. • Negative emissions possible in iron/steel, H 2 and paper sectors. • Potential CO 2 emission reduction of 10 Gt/yr in 2050, easily meeting climate target. [ABSTRACT FROM AUTHOR]

Published

2021

4. Role of renewable energy investment in India: An alternative to CO2 mitigation.

Author

Mahesh, A. and Shoba Jasmin, K.S.

Subjects

*RENEWABLE energy sources, *CARBON dioxide mitigation, *RENEWABLE energy industry, *ENERGY conservation, *POWER resources

Abstract

Abstract: This paper discusses the potential of renewable energy, investment and CO2 mitigation by renewable energy technologies. Currently, India's per-capita emissions are around one tonne of CO2/year. The present energy scene offers India a window of opportunity to invest in renewable energy. The annual turnover of renewable energy industry has reached $12.3 billion in 2011, which is 36% higher than 2010 investment of $7.5 billion. Increasing the share of renewable energy in overall energy mix is an effective option to mitigate CO2 emission. Presently, the share of renewable energy is around 12% in the energy mix. The present study estimated CO2 mitigation potential of Indian renewable energy sector about 203milliontonnes with an installed capacity of 24GW in 2012. However, enormous potential identified in renewable energy sector with favorable CO2 mitigation the government is compromising with limited financial resources. However, policy efforts need to be strengthened to encourage a massive scale-up of renewable technologies to build sustained low carbon economy. [Copyright &y& Elsevier]

Published

2013