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Books on the topic 'Electric steam generator'

Author: Grafiati
Published: 28 June 2021
Last updated: 6 February 2022

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1

Dodd, C. V. Improved eddy-current inspection for steam generator tubing progress report for period January 1985 to December 1987. Washington, DC: Division of Engineering, Office of Nuclear Regulatory Research, U.S. Nuclear Regulatory Commission, 1990.

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2

Dodd, C. V. Improved eddy-current inspection for steam generator tubing progress report for period January 1985 to December 1987. Washington, DC: Division of Engineering, Office of Nuclear Regulatory Research, U.S. Nuclear Regulatory Commission, 1990.

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3

Chen, M. J. Generation systems software: Steam, gas and diesel plant. London: Chapman & Hall, 1996.

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4

Suzor, Norland C. Identifying the basic conditions for economic generation of public electricity from surplus bagasse in sugar mills: A study prepared for the World Bank. Washington, D.C., U.S.A. (1818 H. St., N.W., Washington 20433): the World Bank, Industry and Energy Dept., 1991.

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5

Institution of Engineering and Technology. Thermal Power Plant Simulation and Control. Stevenage: IET, 2003.

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6

International Joint Power Generation Conference (1990 Boston, Mass.). Cogeneration and combined cycle plants--design, interconnection, and turbine applications: Presented at the 1990 International Joint Power Generation Conference, Boston, Massachusetts, October 21-25, 1990. New York, N.Y: American Society of Mechanical Engineers, 1990.

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7

International Symposium on Turbomachinery, Combined-Cycle Technologies, and Cogeneration (3rd 1989 Nice, France). 1989 ASME COGEN-TURBO. New York N.Y: American Society of Mechanical Engineers, 1989.

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8

K, Serovy G., Fransson T, Farbi J, and ASME International Gas Turbine Institute., eds. 1989 ASME COGEN-TURBO: 3rd International Symposium on Turbomachinery, Combined-Cycle Technologies, and Cogeneration, held in Nice, France, August 30-September 1, 1989. New York, N.Y. (345 E. 47th St., New York 10017): American Society of Mechanical Engineers, 1989.

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9

U.S. Nuclear Regulatory Commission. Office of Nuclear Regulatory Research. Division of Engineering Technology. and Oak Ridge National Laboratory, eds. Data analysis for steam generator tubing samples. Washington, DC: Division of Engineering Technology, Office of Nuclear Regulatory Research, U.S. Nuclear Regulatory Commission, 1996.

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10

IEEE Power Engineering Society. Power Generation Committee., ed. IEEE recommended practice for functional and performance characteristics of control systems for steam turbine-generator units. New York, NY: Institute of Electrical and Electronics Engineers, 1992.

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11

IEEE Power Engineering Society. Power Generation Committee., ed. IEEE recommended practice for functional and performance characteristics of control systems for steam turbine-generator units. New York, NY: Institute of Electrical and Electronics Engineers, 1985.

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12

Evaluation of eddy current reliability from steam generator mock-up round-robin. Washington, DC: Division of Engineering Technology, Office of Nuclear Regulatory Research, U.S. Nuclear Regulatory Commission, 2002.

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13

Nguyen, Quang Huy. Modeling the differential eddy current probe for steam generator tubing inspections using Z parameters. 1993.

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14

United States. Environmental Protection Agency. Office of Air Quality Planning and Standards, ed. Study Of Hazardous Air Pollutant Emissions From Electric Utility Steam Generator Units--Final Report To Congress... Volume 2. Appendices... U.S. Environmental Protection Agency... Feb. 1998. [S.l: s.n., 1998.

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15

Water Demand for Steam Electric Generation (Routledge Revivals). Taylor & Francis Group, 2015.

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16

6103004474. Fuel Choice in Steam Electric Generation: Historical Overview. United States Government Printing, 1985.

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17

Cootner, Paul H. Water Demand for Steam Electric Generation (Routledge Revivals). Routledge, 2015. http://dx.doi.org/10.4324/9781315718736.

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18

Fuel choice in steam electric generation: Historical overview. Washington, DC: Energy Information Administration, Office of Coal, Nuclear, Electric, and Alternate Fuels, U.S. Dept. of Energy, 1985.

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19

Cootner, Paul H., and George O. G. Lof. Water Demand for Steam Electric Generation (Routledge Revivals). Taylor & Francis Group, 2016.

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20

Rez, Peter. Electrical Power Generation: Fossil Fuels. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198802297.003.0004.

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Nearly all electrical power is generated by rotating a coil in a magnetic field. In most cases, the coil is turned by a steam turbine operating according to the Rankine cycle. Water is boiled and heated to make high-pressure steam, which drives the turbine. The thermal efficiency is about 30–35%, and is limited by the highest steam temperature tolerated by the turbine blades. Alternatively, a gas turbine operating according to the Brayton cycle can be used. Much higher turbine inlet temperatures are possible, and the thermal efficiency is higher, typically 40%. Combined cycle generation, in which the hot exhaust from a gas turbine drives a Rankine cycle, can achieve thermal efficiencies of almost 60%. Substitution of coal-fired by combined cycle natural gas power plants can result in significant reductions in CO2 emissions.
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21

Environmental codes of practice for steam electric power generation: Construction phase. Ottawa: The Branch, 1989.

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22

Canada. Environmental Protection Directorate. Industrial Programs Branch. and Canada Environment Canada, eds. Environmental codes of practice for steam electric power generation: Decommissioning phase. Ottawa: Environment Canada, 1992.

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23

Canada. Environmental Protection Directorate. Industrial Programs Branch. and Canada Environment Canada, eds. Environmental codes of practice for steam electric power generation: Design phase. [Ottawa]: Environment Canada, 1986.

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24

Environmental codes of practice for steam electric power generation: Siting phase. Ottawa: Environment Canada, 1987.

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25

Canada, Canada Environment, and Canada. Environmental Protection Directorate. Industrial Programs Branch., eds. Environmental codes of practice for steam electric power generation: Operations phase. Ottawa: Environment Canada, 1992.

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26

Development, Alberta Alberta Resource, ed. New power generation in Alberta: A guide to bringing new electric generation on stream. [Edmonton]: Alberta Resource Development, 2000.

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27

Cost Effective Steam and Power Generation by the Combustion of Waste. Wiley, 1993.

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28

Rez, Peter. Electrical Power Distribution. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780198802297.003.0006.

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It is very difficult to store electrical energy in sufficient quantities, and transmission over long distances results in unacceptable losses. Generation of electrical power therefore has to match demand. The peaks in electrical demand usually come from domestic rather than industrial consumers. Generating systems that are best left running continuously, such as nuclear, are used to meet the base load, which is the demand that does not change with time of day or season. Generally, anything involving a steam cycle is better suited to meeting base load demand. Gas turbines that can respond quickly are used to meet demand peaks.
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29

Canada, Canada Environment, and River Road Environmental Technology Centre. Pollution Measurement Division., eds. Protocols and performance specifications for continuous monitoring of gaseous emissions from thermal power generation. [Ottawa]: Canada Environment Canada, 1993.

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30

Canada. Environmental Protection Directorate. Industrial Programs Branch. Electric Power Section. and Canada Environment Canada, eds. A discussion document on the environmental codes of practice for steam electric power generation: Decommissioning phase. Ottawa: Environment Canada, 1991.

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31

Canada. Environmental Protection Directorate. Industrial Programs Branch. Electric Power Section. and Canada Environment Canada, eds. A discussion document on the environmental codes of practice for steam electric power generation: Operations phase. Ottawa: Environment Canada, 1991.

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32

R, Pate J., U.S. Nuclear Regulatory Commission. Office of Nuclear Regulatory Research. Division of Engineering Technology., and Oak Ridge National Laboratory, eds. Evaluation and field validation of eddy-current array probes for steam generator tube inspection. Washington, DC: Division of Engineering Technology, Office of Nuclear Regulatory Research, U.S. Nuclear Regulatory Commission, 1996.

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33

Application of Expert Systems in the Power Generation Industry: Papers Presented at a Seminar Organized by the Steam Plant Committee. Wiley, 1993.

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34

Salinas-Rodríguez, Sergio G., Juan Arévalo, Juan Manuel Ortiz, Eduard Borràs-Camps, Victor Monsalvo-Garcia, Maria D. Kennedy, and Abraham Esteve-Núñez, eds. Microbial Desalination Cells for Low Energy Drinking Water. IWA Publishing, 2021. http://dx.doi.org/10.2166/9781789062120.

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The world's largest demonstrator of a revolutionary energy system in desalination for drinking water production is in operation. MIDES uses Microbial Desalination Cells (MDC) in a pre-treatment step for reverse osmosis (RO), for simultaneous saline stream desalination and wastewater treatment. MDCs are based on bio-electro-chemical technology, in which biological wastewater treatment can be coupled to the desalination of a saline stream using ion exchange membranes without external energy input. MDCs simultaneously treat wastewater and perform desalination using the energy contained in the wastewater. In fact, an MDC can produce around 1.8 kWh of bioelectricity from the energy contained in 1 m3 of wastewater. Compared to traditional RO, more than 3 kWh/m3 of electrical energy is saved. With this novel technology, two low-quality water streams (saline stream, wastewater) are transformed into two high-quality streams (desalinated water, treated wastewater) suitable for further uses. An exhaustive scaling-up process was carried out in which all MIDES partners worked together on nanostructured electrodes, antifouling membranes, electrochemical reactor design and optimization, life cycle assessment, microbial electrochemistry and physiology expertise, and process engineering and control. The roadmap of the lab-MDC upscaling goes through the assembly of a pre-pilot MDC, towards the development of the demonstrator of the MDC technology (patented). Nominal desalination rate between 4-11 Lm-2h-1 is reached with a current efficiency of 40 %. After the scalability success, two MDC pilot plants were designed and constructed consisting of one stack of 15 MDC pilot units with a 0.4 m2 electrode area per unit. This book presents the information generated throughout the EU funded MIDES project and includes the latest developments related to desalination of sea water and brackish water by applying microbial desalination cells. ISBN: 9781789062113 (Paperback) ISBN: 9781789062120 (eBook)
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35

Institution of Mechanical Engineers (Great Britain). Steam Plant Committee., ed. Cost effective steam and power generation by the combustion of waste: Papers presented at a seminar organized by the Steam Plant Committee of the Institution of Mechanical Engineers, and held at the Institution of Mechanical Engineers on 23 September 1993. London: Mechanical Engineering for the Institution of Mechanical Engineers, 1993.

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36

Postma, Alex V., David Sedmera, Frantisek Vostarek, Vincent M. Christoffels, and Connie R. Bezzina. Developmental aspects of cardiac arrhythmias. Edited by José Maria Pérez-Pomares, Robert G. Kelly, Maurice van den Hoff, José Luis de la Pompa, David Sedmera, Cristina Basso, and Deborah Henderson. Oxford University Press, 2018. http://dx.doi.org/10.1093/med/9780198757269.003.0027.

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The rhythmic and synchronized contraction of atria and ventricles is essential for efficient pumping of blood throughout the body. This process relies on the proper generation and conduction of the cardiac electrical impulse. Electrophysiological properties differ in various regions of the heart, revealing intrinsic heterogeneities rooted, at least in part, in regional differences in expression of ion channel and gap junction subunit genes. A causal relation between transcription factors and such regionalized gene expression has been established. Abnormal cardiac electrical function and arrhythmias in the postnatal heart may stem from a developmental changes in gene regulation. Genome-wide association studies have provided strong evidence that common genetic variation at developmental gene loci modulates electrocardiographic indices of conduction and repolarization and susceptibility to arrhythmia. Functional aspects are illustrated by description of selected prenatally occurring arrhythmias and their possible mechanisms. We also discuss recent findings and provide background insight into these complex mechanisms.
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37

Schroeter, J. W., and International Joint Power Generation Conference (1990 Boston, Mass.). Cogeneration and Combined Cycle Plants Design Interconnection: Presented at the 1990 International Joint Power Generation Conference, Boston, Massachusetts, ... October 21-25, 1990 (Pwr (Series), Vol. 11.). Amer Society of Mechanical, 1990.

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38

Combined-Cycle technologies International Symposium on Turbomachinery, Torsten H. Fransson, and G. K. Serovy. 1989 Asme Cogen-Turbo: 3rd International Symposium on Turbomachinery, Combined-Cycle Technologies and Cogeneration (Igti, Vol. 4). Amer Society of Mechanical, 1989.

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39

Daniel, Mahr, Nechvatal Timothy, American Society of Mechanical Engineers. Fuels Handling, Transportation, and Storage Technical Committee., and International Joint Power Generation Conference (1991 : San Diego, Calif.), eds. Fuel strategies for conventional and unconventional fuels: Presented at the 1991 International Joint Power Generation Conference, October 6-10, 1991, San Diego, California. New York, N.Y: American Society of Mechanical Engineers, 1991.

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40

W, Schroeter J., American Society of Mechanical Engineers. Cogeneration and Small Power Producers Committee., American Society of Mechanical Engineers. Power Division. Industrial Operations Committee., and International Joint Power Generation Conference (1991 : San Diego, Calif.), eds. Cogeneration power plants: Combined cycle design, operation, control, and unit auxiliaries : presented at the 1991 International Joint Power Generation Conference, October 6-10, 1991, San Diego, California. New York, N.Y: American Society of Mechanical Engineers, 1991.

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