Energy Conversion Engineering

Mapping Intimacies ◽

10.1017/9781108777551 ◽

2021 ◽

Author(s):

Ahmed F. Ghoniem

Keyword(s):

Energy Conversion ◽

Carbon Capture ◽

Energy Systems ◽

Worked Examples ◽

Low Carbon ◽

Thermal Systems ◽

World Energy ◽

Electrochemical Thermodynamics ◽

Energy Conversion Systems ◽

Low Carbon Energy

This unique textbook equips students with the theoretical and practical tools needed to model, design, and build efficient and clean low-carbon energy systems. Students are introduced to thermodynamics principles including chemical and electrochemical thermodynamics, moving onto applications in real-world energy systems, demonstrating the connection between fundamental concepts and theoretical analysis, modelling, application, and design. Topics gradually increase in complexity, nurturing student confidence as they build towards the use of advanced concepts and models for low to zero carbon energy conversion systems. The textbook covers conventional and emerging renewable energy conversion systems, including efficient fuel cells, carbon capture cycles, biomass utilisation, geothermal and solar thermal systems, hydrogen and low-carbon fuels. Featuring numerous worked examples, over 100 multi-component homework problems, and online instructor resources including lecture slides, solutions, and sample term projects, this textbook is the perfect teaching resource for an advanced undergraduate and graduate-level course in energy conversion engineering.

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ECOS 2012

10.36253/978-88-6655-322-9 ◽

2012 ◽

Keyword(s):

Energy Conversion ◽

Carbon Capture ◽

Industrial Ecology ◽

Process Integration ◽

Cost Optimization ◽

Energy Systems ◽

Water Desalination ◽

Diagnosis And Prognosis ◽

Energy Conversion Systems ◽

Optimization And Simulation

The 8-volume set contains the Proceedings of the 25th ECOS 2012 International Conference, Perugia, Italy, June 26th to June 29th, 2012. ECOS is an acronym for Efficiency, Cost, Optimization and Simulation (of energy conversion systems and processes), summarizing the topics covered in ECOS: Thermodynamics, Heat and Mass Transfer, Exergy and Second Law Analysis, Process Integration and Heat Exchanger Networks, Fluid Dynamics and Power Plant Components, Fuel Cells, Simulation of Energy Conversion Systems, Renewable Energies, Thermo-Economic Analysis and Optimisation, Combustion, Chemical Reactors, Carbon Capture and Sequestration, Building/Urban/Complex Energy Systems, Water Desalination and Use of Water Resources, Energy Systems- Environmental and Sustainability Issues, System Operation/ Control/Diagnosis and Prognosis, Industrial Ecology.

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Energy justice in the transition to low carbon energy systems: Exploring key themes in interdisciplinary research

Applied Energy ◽

10.1016/j.apenergy.2018.10.005 ◽

2019 ◽

Vol 233-234 ◽

pp. 916-921 ◽

Cited By ~ 34

Author(s):

Darren McCauley ◽

Vasna Ramasar ◽

Raphael J. Heffron ◽

Benjamin K. Sovacool ◽

Desta Mebratu ◽

...

Keyword(s):

Interdisciplinary Research ◽

Energy Systems ◽

Low Carbon ◽

Energy Justice ◽

Low Carbon Energy

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Life Cycle Assessment of Direct Air Carbon Capture and Storage with Low-Carbon Energy Sources

10.26434/chemrxiv.14346182 ◽

2021 ◽

Author(s):

Tom Terlouw ◽

Karin Treyer ◽

christian bauer ◽

Marco Mazzotti

Keyword(s):

Life Cycle Assessment ◽

Life Cycle ◽

Carbon Capture ◽

Large Scale ◽

Carbon Capture And Storage ◽

Low Carbon ◽

Solid Sorbent ◽

Low Carbon Energy ◽

And Storage ◽

Limited Scope

Prospective energy scenarios usually rely on Carbon Dioxide Removal (CDR) technologies to achieve the climate goals of the Paris Agreement. CDR technologies aim at removing CO2 from the atmosphere in a permanent way. However, the implementation of CDR technologies typically comes along with unintended environmental side-effects such as land transformation or water consumption. These need to be quantified before large-scale implementation of any CDR option by means of Life Cycle Assessment (LCA). Direct Air Carbon Capture and Storage (DACCS) is considered to be among the CDR technologies closest to large-scale implementation, since first pilot and demonstration units have been installed and interactions with the environment are less complex than for biomass related CDR options. However, only very few LCA studies - with limited scope - have been conducted so far to determine the overall life-cycle environmental performance of DACCS. We provide a comprehensive LCA of different low temperature DACCS configurations - pertaining to solid sorbent-based technology - including a global and prospective analysis.

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From Energy Security to the Security of Energy Services: Shortcomings of Traditional Supply-Oriented Approaches and the Contribution of a Socio-Technical and User-Oriented Perspectives

Science & Technology Studies ◽

10.23987/sts.56093 ◽

2014 ◽

Vol 27 (1) ◽

pp. 97-108

Author(s):

Yael Parag

Keyword(s):

Energy Security ◽

Energy Systems ◽

Point Of View ◽

Complex Nature ◽

Low Carbon ◽

Discussion Paper ◽

Energy Services ◽

The Public ◽

Cultural Aspects ◽

Low Carbon Energy

Traditional literature and policy approach to energy security focus on the security of energy supply. It is argued here that a supply-centric approach to energy security is too narrow to account for the complex nature of energy systems and tends to overlook energy users, their expectations from, interaction with and roles in future low carbon energy systems. From users’ point of view, be they households, businesses or governments, the supply of kWh or oil barrels is often meaningless. What matters is not the source of energy, but rather the services provided by it. Therefore, securing energy services seems to be the public and the government’s concern, and the security of supply is only one mean to achieving it. Stemming from science, technology and society studies, this discussion paper suggests that applying a multi-level socio-technical and user-oriented perspectives which focus on the energy services and considers also psychological, social and cultural aspects of energy consumption, could reveal new and overlooked actors, roles, means and strategies that may provide and contribute to energy services security.Keywords: energy security, energy services, socio-technical systems

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