Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

Post combustion --- Combustible liquide --- Congresses --- Congresses

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

More and more, the CO2 issue is making people talk about it. Increasing emissions are impacting our entire society. CO2-emitting companies and governments must act quickly to avoid excessive global warming. 
As an engineering company, John Cockerill designs various equipment for thermal power plants and recovery boilers to optimize energy production. Its position on the energy market gives it the credibility to invest in CO2 capture and recovery technologies. To determine where John Cockerill should invest, it is necessary to analyze the opportunities available to the company. 
Capture techniques are the first to have been developed. They were developed in the 1970s to clean natural gas from its CO2 content. Now, we hope to apply them to thermal power plants, which produce more than 40% of anthropogenic CO2. The capture technology is mature but not yet well adapted to thermal power plants. Currently, capture processes are not part of John Cockerill's portfolio, however the design of the structure to accommodate the reaction and its optimization are two actions that can be included in John Cockerill's portfolio. 
The second area analysed is the recovery of captured CO2. Once isolated, it is necessary to use this CO2 to produce another product or to store it permanently. The second option, completely out of John Cockerill's midst, remains its revaluation as raw materials. 
This rapidly expanding environment is increasingly moving to the forefront as the ideal alternative to CO2 emissions. Since capture does not bring any benefit to the company, its reuse offers the possibility of obtaining a refund or, better still, an added value. This rapidly expanding market is very large, leaving room for John Cockerill to establish himself. Despite the multitude of possible reactions, CO2 hydrogenation remains the most affordable for John Cockerill, who, with these green electrolysers, produces decarbonated hydrogen. The other possibilities use too specific reactions, they do not offer a real interest for John Cockerill. However, it is still possible for John Cockerill to offer his process optimization services.

Carbon Capture and Utilization --- Post-combustion --- Power Plant --- carbon dioxide --- Sciences économiques & de gestion > Stratégie & innovation

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

The urgently needed carbon neutral economy requires a portfolio of strategies, among which, CO2 capture and renewable energy will need to play a decisive role. Dispatchable renewables, such as bioenergy, will play an increasing role in maintaining electricity security, in producing heat in the industry and residential sectors, and in reducing the emissions from the transport sector. Biomethane, also known as a renewable natural gas, can be directly blended with or fully replace natural gas in existing pipelines and end-user equipment, with the added advantage of being carbon neutral. CO2 capture and storage (CCS) will also be of paramount importance in abating CO2 emissions from existing infrastructure in the power and industrial sectors. There are many industries that will be difficult or impossible to decarbonize in the short term, such as the cement sector, in which CO2 emissions are intrinsic to the production process. In such cases, CCS will be mandatory to achieve the goal of net zero emissions. Permanent CO2 removal technologies, such as bioenergy with carbon capture and storage (BECCS) and direct air capture and storage (DACS), will also be necessary in the medium term to compensate for emissions from the hard-to-abate sectors, and in the long term, even to remove atmospheric CO2 from past emissions. This book consists of six peer-reviewed scientific articles that cover a range of high-interest subjects related to the aforementioned hot topics.

Technology: general issues --- History of engineering & technology --- zeolite --- ZSM-5 --- adsorption --- biogas upgrading --- shaping --- extrusion --- CO2 capture --- cement --- post-combustion --- absorption --- membranes --- calcium looping --- oxyfuel --- direct separation --- CO2 emissions --- CCS --- CCUS --- global facilities --- Zn(dcpa) --- MOF --- framework flexibility --- gas storage --- biogas --- carbon capture --- carbon footprint --- carbon capture and storage --- zero/low emission building --- greenhous effect --- environmental protection --- carbon capture (CC) --- carbon capture and storage (CCS) --- micro-combined heat and power (micro-CHP) --- micro-cogeneration --- energy systems --- buildings --- GHG emissions --- n/a --- Technology --- History.

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

A wide variety of technologies and products have already become widespread in our society. However, policies have not been well-implemented to effectively reduce energy consumptions and CO2 emissions by promoting low-carbon technologies and products. This Special Issue focuses on studies targeting specific products (e.g., motor vehicle, household dishwashers, etc.) and/or technologies (e.g., information and communication technology, transport technology, CO2 capture technology, etc.) and quantifying resource and energy consumptions and CO2 emissions associated with products and technology systems using the reliable inventory database. Thus, this Special Issue provides important studies on how demand- and supply-side policies can contribute to reducing energy consumptions and CO2 emissions from consumption- and production-based perspectives.

History of engineering & technology --- lifecycle analysis --- CAFE standards --- fuel economy --- automobile manufacture --- carbon footprint --- hybrid MRIO --- SDA --- energy saving --- energy composition --- China --- information and communications technology --- productivity --- renewable energy --- energy sector --- distributed energy system --- resource security --- domestic mineral production --- input-output analysis --- environmental assessment --- transition --- low carbon technologies --- low carbon transition --- decarbonisation --- zero carbon --- air pollution --- diesel ban --- electric vehicles --- transport policy --- transport planning --- London --- CO2 emissions --- household consumption --- index decomposition analysis --- structural decomposition analysis --- aging society --- Japan --- CO2 capture --- thermal power plants --- oxyfuel combustion --- allam cycle --- post-combustion --- pre-combustion --- energy efficiency policy --- household appliances --- eco-design --- energy labelling --- indirect impacts --- general equilibrium model --- FIDELIO model --- road transport --- low carbon scenario --- GHG mitigation measures --- cost-benefit --- mitigation cost --- financing --- climate change --- energy-saving --- attitude --- Big Five --- personality traits --- office --- household --- pro-environment

Choose an application

• Reference Manager
• EndNote
• RefWorks (Direct export to RefWorks)

A wide variety of technologies and products have already become widespread in our society. However, policies have not been well-implemented to effectively reduce energy consumptions and CO2 emissions by promoting low-carbon technologies and products. This Special Issue focuses on studies targeting specific products (e.g., motor vehicle, household dishwashers, etc.) and/or technologies (e.g., information and communication technology, transport technology, CO2 capture technology, etc.) and quantifying resource and energy consumptions and CO2 emissions associated with products and technology systems using the reliable inventory database. Thus, this Special Issue provides important studies on how demand- and supply-side policies can contribute to reducing energy consumptions and CO2 emissions from consumption- and production-based perspectives.

lifecycle analysis --- CAFE standards --- fuel economy --- automobile manufacture --- carbon footprint --- hybrid MRIO --- SDA --- energy saving --- energy composition --- China --- information and communications technology --- productivity --- renewable energy --- energy sector --- distributed energy system --- resource security --- domestic mineral production --- input-output analysis --- environmental assessment --- transition --- low carbon technologies --- low carbon transition --- decarbonisation --- zero carbon --- air pollution --- diesel ban --- electric vehicles --- transport policy --- transport planning --- London --- CO2 emissions --- household consumption --- index decomposition analysis --- structural decomposition analysis --- aging society --- Japan --- CO2 capture --- thermal power plants --- oxyfuel combustion --- allam cycle --- post-combustion --- pre-combustion --- energy efficiency policy --- household appliances --- eco-design --- energy labelling --- indirect impacts --- general equilibrium model --- FIDELIO model --- road transport --- low carbon scenario --- GHG mitigation measures --- cost-benefit --- mitigation cost --- financing --- climate change --- energy-saving --- attitude --- Big Five --- personality traits --- office --- household --- pro-environment