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Table of contents

Cyrus Ebnesajjad. Handbook of Metal Injection Molding. Donald F. Handbook of Polymer Coatings for Electronics. James J. Wood-Polymer Composites. K O Niska. Private Empire. Steve Coll. The Moral Case for Fossil Fuels. Alex Epstein. Drinking Water Treatment. Chittaranjan Ray. Handbook of Adhesives and Surface Preparation. Confronting Collapse. Michael C. Multilayer Flexible Packaging. John R. John Ghazvinian.


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Heavy Oil Production Processes. Causes, Impacts and Solutions to Global Warming. Ibrahim Dincer. Handbook of Liquefied Natural Gas. Saeid Mokhatab. Johannes Fink. Michael I. Johannes Karl Fink. Handbook of Adhesives and Sealants. Estimating Groundwater Recharge.

Power Generation from Solid Fuels | Hartmut Spliethoff | Springer

Richard W. Petroleum Geology of Libya. Don Hallett. Reservoir Engineering. Abdus Satter. Solid Fuel Blending. David Tillman. Biomass Combustion Science, Technology and Engineering.

Lasse Rosendahl. Naeim Nouri Samie. Fossil Energy. Ripudaman Malhotra. Boyun Guo. Waste to Energy Conversion Technology. Naomi B Klinghoffer. Geoff B. Qipeng Guo. Natural Gas Engineering Handbook. Boyan Guo. Advances in Clean Hydrocarbon Fuel Processing. Rashid Khan. Ultra-Supercritical Coal Power Plants. An Introduction to Thermogeology.

David Banks. To concentrate CO 2 in combustion processes by efficient and energy-saving ways is a first and very important step for its sequestration. Chemical looping combustion CLC could easily achieve this goal. However, only limited references are available that use coal as the energy resource in a CLC process even though the development of CLC of solid fuels follows the trend of energy utilization. This paper is the first in a series of two, where we present the concept of a CLC process of solid fuels using a circulating fluidized bed with three loop seals.

The riser of this circulating fluidized bed was used as the oxidizer of the oxygen carrier; one of the loop seals was used as the reducer of the oxygen carrier and the separator for ash and oxygen carrier, and the other two loop seals were used for pressure balance in the solid recycle process. Pressure profiles of recycled solids using this process are presented in detail. For the development of an oxygen carrier, we focused on the establishment of a theoretical frame of oxygen transfer capability, reaction enthalpy, a chemical equilibrium, and kinetics.

Analysis results indicated that Cu-, Ni-, and Co-based oxygen carriers may be the optimum oxygen carriers for the CLC of solid fuels. Mn-based oxygen carriers have several disadvantages in their lower oxygen transfer capability, thermodynamic limitations of purifying the CO 2 stream, or a larger endothermic reduction enthalpy.

Fe-based oxygen carriers have the disadvantage of a larger endothermic enthalpy in the reducer and lower reactivity. A Cu-based oxygen carrier is the choice that has the potential to make the reducer self-sustaining or autothermal because of its exothermic nature during reduction. This would be beneficial for simplifying the operation of the reducer.

View Author Information. Cite this: Energy Fuels 20 5 Article Views Altmetric -. Citations Abstract To concentrate CO 2 in combustion processes by efficient and energy-saving ways is a first and very important step for its sequestration. Cited By. This article is cited by publications. DOI: ACS Omega , 3 4 , Mendiara, M. Izquierdo, A. Abad, P.

Mendiara, R. Abad, L. Neathery, and Kunlei Liu.

What is Kobo Super Points?

Mendiara, A. Behdad Moghtaderi. Aurora M. Rubel, Yi Zhang, James K.

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Solid fuel

Vasilije Manovic and Edward J. Liang-Shih Fan and Fanxing Li. Ewelina Ksepko, Ranjani V. Brown, J. Dennis, S. Scott, J. Davidson and A. Fate of Light Hydrocarbons. Chemical Engineering Journal , , Studies on steel slag as an oxygen carrier for chemical looping combustion. Fuel , , Integration of chemical looping combustion and supercritical CO 2 cycle for combined heat and power generation with CO 2 capture. Energy Conversion and Management , , Journal of Energy Resources Technology , 11 , Howard, Dushyant Shekhawat, David Berry.

Abad, T. Mendiara, P. Chemical looping combustion of solid fuels. Progress in Energy and Combustion Science , 65 , Evolution of CO2 capture technology between and through the study of patent activity. Applied Energy , , A chemical looping scheme of co-feeding of coke-oven gas and pulverized coke toward polygeneration of olefins and ammonia.


  1. Organisational Learning and Effectiveness?
  2. Investigation of Chemical Looping Combustion by Solid Fuels. 1. Process Analysis | Energy & Fuels?
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  4. WHO | Indoor air pollution and household fuels.
  5. Further Study of the Atomic Weight of Lead of Radioactive Origin (1916)(en)(7s).
  6. Nutrition and the Eye: A Practical Approach.
  7. The high efficient synthesis of natural gas from a joint-feedstock of coke-oven gas and pulverized coke via a chemical looping combustion scheme. Brazilian Journal of Chemical Engineering , 35 1 , Aulice Scibioh, B. CO 2 —Capture and Storage. Chemical Research in Chinese Universities , 33 6 , A novel path toward methanol and olefins production fueled by syngas via a coupling of coke-oven gas reforming with pulverized coke chemical looping combustion.

    Energy , , Investigation on gasification performance of sewage sludge using chemical looping gasification with iron ore oxygen carrier. International Journal of Hydrogen Energy , 42 40 , Relationship between electronic properties of Fe3O4 substituted by Ca and Ba and their reactivity in chemical looping process: A first-principles study. Gaseous state oxygen carrier for coal chemical looping process. Bueno, R.

    Comparative Evaluation of the Performance of Coal Combustion in 0. Energy Procedia , , The investigations of hematite-CuO oxygen carrier in chemical looping combustion. Evaluation of ash-free coal for chemical looping combustion - part I: Thermogravimetric single cycle study and the reaction mechanism.

    The Canadian Journal of Chemical Engineering , 95 4 , Energy Technology , 5 3 , The search of proper oxygen carriers for chemical looping partial oxidation of carbon. Bukur, Angeliki A.

    Coal & Solid Fuels

    Reduction and oxidation kinetic modeling of NiO-based oxygen transfer materials. Physical Chemistry Chemical Physics , 19 43 , Park, Paul S. Biomass-based chemical looping technologies: the good, the bad and the future. Experimental and kinetic studies of coal—CO 2 gasification in isothermal and pressurized conditions. RSC Advances , 7 4 , Energy Technology , 4 10 , Tilland, J. Prieto, D. Petitjean, E. Study and analyses of a CLC oxygen carrier degradation mechanism in a fixed bed reactor. Coal combustion in a 50kWth Chemical Looping Combustion unit: Seeking operating conditions to maximize CO2 capture and combustion efficiency.

    International Journal of Greenhouse Gas Control , 50 , Karmakar, Pradip K. Present status and overview of Chemical Looping Combustion technology. Renewable and Sustainable Energy Reviews , 59 , Process integration of chemical looping combustion with oxygen uncoupling in a coal-fired power plant. AIChE Journal , 62 4 , Haber process and steam-coal gasification: Two standard thermodynamic problems elucidated using two distinct approaches. Temperature control in the reheat steam will be handled by passing part of the sand returned form the cyclone past a hot reheater, which is located in the return of the hot cyclone.

    This solution enables the highest possible electrical efficiency ratio. Thanks to advanced technology, emissions are extremely low even when fuels with totally different thermal values are combusted simultaneously. Most of the more than 80 plants delivered by Valmet worldwide are multi-fuel boilers, which combust bio mass and fossil fuels, the proportion of which may vary continuously. Multi-fuel combustion is an environmentally friendly method, which enables high availability.

    A possibility to use several different fuels offers a good opportunity for optimization of operating costs. Figure 3. This provides optimal conditions for using a diverse fuel portfolio in energy production. In addition to coal and other solid fossil fuels, the technology of CYMIC boilers enables utilization of recycled fuels, bio mass, and agro fuel, as well as combinations of these in energy production.

    The development of the boiler construction, sand super heaters among others, has continued since the Alholmen delivery. Turun Seudun Energiantuotanto Oy produces district heat and electricity for the Turku and Naantali city areas, and process steam for the needs of nearby companies. The first unit was built in In , this plant, formed by three units, was the biggest coal power plant in the Nordic countries. The Naantali plant was changed into a back pressure power plant at the beginning of the s, and distribution of heat produced at the plant to the district heat networks of Turku, Raisio, and Kaarina was started.

    The distance between the power plant and the center of Turku is approximately 15 kilometers. Fortum sold the power plant to Turun Seudun Energiantuotanto Oy in Today, the plant is operated by around Fortum employees. The Naantali plant produces heat for approximately , inhabitants in the city of Turku and the surrounding counties. By continuing to use the site, you agree to the use of cookies. You can find out more by following this link.


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