Centro de Documentación
Repositorio de publicaciones de referencia y de interés para la sustentabilidad ambiental del desarrollo |
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2018
Torres, Ramón Carlos
Energía solar en hogares y negocios pequeños: una propuesta Artículo de revista
En: Configuraciones enero – abril 2018, vol. 46, pp. 4, 2018, ISBN: 1405-8847.
Resumen | Enlaces | BibTeX | Etiquetas: Energía, energía solar, Gas, Hidrocarburos
@article{Torres2018,
title = {Energía solar en hogares y negocios pequeños: una propuesta},
author = {Ramón Carlos Torres
},
editor = {Revista de la Fundación Pereyra y del Instituto de Estudios para la Transición Democrática},
url = {/publicaciones/Consejo%20Editorial/2018_ESolar_RCTorres_Config46.pdf},
isbn = {1405-8847},
year = {2018},
date = {2018-07-01},
journal = {Configuraciones enero - abril 2018},
volume = {46},
pages = {4},
abstract = {La legislación energética mexicana otorga la más alta prelación a la explotación de los hidrocarburos y a su empleo en la generación de electricidad. Esto contrasta con el deterioro secular de la oferta interna de esos energéticos observado en más de una década y con la consecuente explosiva dependencia del abasto externo de petrolíferos, gas natural, fertilizantes y productos petroquímicos, así como el debilitamiento de la exportaciones de crudo. No se advierten indicios razonables de que se modifiquen esas tendencias, al menos en los horizontes de corto y mediano plazos.
La transición energética hacia las fuentes renovables está relegada a un segundo plano. El fomento de ellas se limita a colocarlas en competencia con otras fuentes, en un espacio circunscrito a lo que la legislación define como energía limpia. La definición se establece a base de parámetros y normas de eficiencia energética e hídrica, emisiones a la atmósfera y generación de residuos. Se establece la meta de que para 2024 el 35% de la electricidad se genere con fuentes limpias, sin diferenciar entre las renovables, la nuclear u otras.},
keywords = {Energía, energía solar, Gas, Hidrocarburos},
pubstate = {published},
tppubtype = {article}
}
La legislación energética mexicana otorga la más alta prelación a la explotación de los hidrocarburos y a su empleo en la generación de electricidad. Esto contrasta con el deterioro secular de la oferta interna de esos energéticos observado en más de una década y con la consecuente explosiva dependencia del abasto externo de petrolíferos, gas natural, fertilizantes y productos petroquímicos, así como el debilitamiento de la exportaciones de crudo. No se advierten indicios razonables de que se modifiquen esas tendencias, al menos en los horizontes de corto y mediano plazos.
La transición energética hacia las fuentes renovables está relegada a un segundo plano. El fomento de ellas se limita a colocarlas en competencia con otras fuentes, en un espacio circunscrito a lo que la legislación define como energía limpia. La definición se establece a base de parámetros y normas de eficiencia energética e hídrica, emisiones a la atmósfera y generación de residuos. Se establece la meta de que para 2024 el 35% de la electricidad se genere con fuentes limpias, sin diferenciar entre las renovables, la nuclear u otras.
La transición energética hacia las fuentes renovables está relegada a un segundo plano. El fomento de ellas se limita a colocarlas en competencia con otras fuentes, en un espacio circunscrito a lo que la legislación define como energía limpia. La definición se establece a base de parámetros y normas de eficiencia energética e hídrica, emisiones a la atmósfera y generación de residuos. Se establece la meta de que para 2024 el 35% de la electricidad se genere con fuentes limpias, sin diferenciar entre las renovables, la nuclear u otras.
IRENA,
Renewable Power Generation Costs in 2017 Libro
2018, ISBN: 978-92-9260-040-2.
Resumen | Enlaces | BibTeX | Etiquetas: bionergía, electricidad, Energía renovable, energía solar, geotérmico costos, viento
@book{IRENA2018,
title = {Renewable Power Generation Costs in 2017},
author = {IRENA},
editor = {International Renewable Energy Agency (IRENA)},
url = {/publicaciones/Centro_Documentacion/Energy/IRENA_2017_Power_Costs_2018.pdf},
isbn = {978-92-9260-040-2},
year = {2018},
date = {2018-01-15},
pages = {160},
abstract = {For new projects commissioned in 2017, electricity costs from renewable power generation have continued to fall. After years of steady cost decline, renewable power technologies are becoming an increasingly competitive way to meet new generation needs.
In 2017, as deployment of renewable power generation technologies accelerated, there has
been a relentless improvement in their competitiveness. Bioenergy for power, hydropower, geothermal and onshore wind projects commissioned in 2017 largely fell within the range of fossil fuel-fired electricity generation costs data collected by the International Renewable Energy Agency (IRENA) shows. Indeed levelised cost of electricity (LCOE)1 for these technologies was at the lower end of the LCOE range for fossil fuel options.
Three main cost reduction drivers have emerged for renewable power: 1) technology improvements; 2) competitive procurement; and 3) a large base of experienced, internationally active project developers.},
keywords = {bionergía, electricidad, Energía renovable, energía solar, geotérmico costos, viento},
pubstate = {published},
tppubtype = {book}
}
For new projects commissioned in 2017, electricity costs from renewable power generation have continued to fall. After years of steady cost decline, renewable power technologies are becoming an increasingly competitive way to meet new generation needs.
In 2017, as deployment of renewable power generation technologies accelerated, there has
been a relentless improvement in their competitiveness. Bioenergy for power, hydropower, geothermal and onshore wind projects commissioned in 2017 largely fell within the range of fossil fuel-fired electricity generation costs data collected by the International Renewable Energy Agency (IRENA) shows. Indeed levelised cost of electricity (LCOE)1 for these technologies was at the lower end of the LCOE range for fossil fuel options.
Three main cost reduction drivers have emerged for renewable power: 1) technology improvements; 2) competitive procurement; and 3) a large base of experienced, internationally active project developers.
In 2017, as deployment of renewable power generation technologies accelerated, there has
been a relentless improvement in their competitiveness. Bioenergy for power, hydropower, geothermal and onshore wind projects commissioned in 2017 largely fell within the range of fossil fuel-fired electricity generation costs data collected by the International Renewable Energy Agency (IRENA) shows. Indeed levelised cost of electricity (LCOE)1 for these technologies was at the lower end of the LCOE range for fossil fuel options.
Three main cost reduction drivers have emerged for renewable power: 1) technology improvements; 2) competitive procurement; and 3) a large base of experienced, internationally active project developers.
IRENA,
Renewable Power Generation Costs in 2017 (Summary) Libro
2018, ISBN: 978-92-9260-040-2.
Resumen | Enlaces | BibTeX | Etiquetas: bionergía, electricidad, Energía renovable, energía solar, geotérmico costos, viento
@book{IRENA2018b,
title = {Renewable Power Generation Costs in 2017 (Summary)},
author = {IRENA},
editor = {IRENA, KEY FINDINGS AND EXECUTIVE SUMMARY},
url = {/publicaciones/Centro_Documentacion/Energy/IRENA_2017_Power_Costs_2018_summary.pdf},
isbn = {978-92-9260-040-2},
year = {2018},
date = {2018-01-15},
abstract = {• After years of steady cost decline for solar and wind technologies, renewable power is becoming an increasingly competitive way to meet new generation needs.
• For projects commissioned in 2017, electricity costs from renewable power generation have continued to fall.
• Bioenergy-for-power, hydropower, geothermal and onshore wind projects commissioned in 2017 largely fell within the range of generation costs for fossil-based electricity. Some projects undercut fossil fuels, data collected by the International Renewable Energy Agency (IRENA) shows.
The global weighted average cost of electricity was USD 0.05 per kilowatt-hour (kWh) from new hydropower projects in 2017. It was USD 0.06/kWh for onshore wind and 0.07/kWh for bioenergy and geothermal projects.},
keywords = {bionergía, electricidad, Energía renovable, energía solar, geotérmico costos, viento},
pubstate = {published},
tppubtype = {book}
}
• After years of steady cost decline for solar and wind technologies, renewable power is becoming an increasingly competitive way to meet new generation needs.
• For projects commissioned in 2017, electricity costs from renewable power generation have continued to fall.
• Bioenergy-for-power, hydropower, geothermal and onshore wind projects commissioned in 2017 largely fell within the range of generation costs for fossil-based electricity. Some projects undercut fossil fuels, data collected by the International Renewable Energy Agency (IRENA) shows.
The global weighted average cost of electricity was USD 0.05 per kilowatt-hour (kWh) from new hydropower projects in 2017. It was USD 0.06/kWh for onshore wind and 0.07/kWh for bioenergy and geothermal projects.
• For projects commissioned in 2017, electricity costs from renewable power generation have continued to fall.
• Bioenergy-for-power, hydropower, geothermal and onshore wind projects commissioned in 2017 largely fell within the range of generation costs for fossil-based electricity. Some projects undercut fossil fuels, data collected by the International Renewable Energy Agency (IRENA) shows.
The global weighted average cost of electricity was USD 0.05 per kilowatt-hour (kWh) from new hydropower projects in 2017. It was USD 0.06/kWh for onshore wind and 0.07/kWh for bioenergy and geothermal projects.
2010
WEC,
2010 Survey of Energy Resources Libro
2010, ISBN: 978 0 946121 021.
Resumen | Enlaces | BibTeX | Etiquetas: Bioenergía, Conversión de energía térmica oceánica, Energía de la ola, Energía de las mareas, Energía eólica, Energía geotérmica, energía solar, Gas natural
@book{WEC2010,
title = {2010 Survey of Energy Resources},
author = {WEC},
editor = {World Energy Council},
url = {/publicaciones/Centro_Documentacion/Energy/2010_Energy.Resources.Report_wenergycouncil.pdf},
isbn = {978 0 946121 021},
year = {2010},
date = {2010-05-09},
pages = {618},
abstract = {In 1936 the World Power Conference, the organisation which eventually became the World Energy Council, published the first of a series of Statistical Year-books. This pioneer work represented ‘an attempt to compile and publish international statistics of power resources, development and utilization, upon a comprehensive and comparable basis’. Nearly three-quarters of a century later, this essentially remains the objective of the Year-book’s direct descendant, namely the twenty-second edition of the WEC’s Survey of Energy Resources.
Despite considerable development along the way, with gradually extended coverage of energy resources (notably in the field of the ‘Renewables’) and the provision of more comprehensive tables and increasingly detailed Country Notes, the basic problems facing the compilers of the Survey remain much the same. They were indeed foreshadowed by a somewhat
melancholy comment in the Introduction to Statistical Year-book No. 1: ‘The work of editing the tables, and more particularly the definitions, proved even more arduous and difficult than had been anticipated’.},
keywords = {Bioenergía, Conversión de energía térmica oceánica, Energía de la ola, Energía de las mareas, Energía eólica, Energía geotérmica, energía solar, Gas natural},
pubstate = {published},
tppubtype = {book}
}
In 1936 the World Power Conference, the organisation which eventually became the World Energy Council, published the first of a series of Statistical Year-books. This pioneer work represented ‘an attempt to compile and publish international statistics of power resources, development and utilization, upon a comprehensive and comparable basis’. Nearly three-quarters of a century later, this essentially remains the objective of the Year-book’s direct descendant, namely the twenty-second edition of the WEC’s Survey of Energy Resources.
Despite considerable development along the way, with gradually extended coverage of energy resources (notably in the field of the ‘Renewables’) and the provision of more comprehensive tables and increasingly detailed Country Notes, the basic problems facing the compilers of the Survey remain much the same. They were indeed foreshadowed by a somewhat
melancholy comment in the Introduction to Statistical Year-book No. 1: ‘The work of editing the tables, and more particularly the definitions, proved even more arduous and difficult than had been anticipated’.
Despite considerable development along the way, with gradually extended coverage of energy resources (notably in the field of the ‘Renewables’) and the provision of more comprehensive tables and increasingly detailed Country Notes, the basic problems facing the compilers of the Survey remain much the same. They were indeed foreshadowed by a somewhat
melancholy comment in the Introduction to Statistical Year-book No. 1: ‘The work of editing the tables, and more particularly the definitions, proved even more arduous and difficult than had been anticipated’.
1970
AMERICAN, SCIENTIFIC (Ed.)
Biosphere, Special of Scientific American 1970. Ejemplar de colección. Colección
SCIENTIFIC AMERICAN, INC, 1970.
Resumen | Enlaces | BibTeX | Etiquetas: Energía, energía solar, entropía, termodinámica
@collection{Varios1970,
title = {Biosphere, Special of Scientific American 1970. Ejemplar de colección. },
author = {Varios},
editor = {SCIENTIFIC AMERICAN},
url = {https://ceiba.org.mx/publicaciones/Centro_Documentacion/Biosphere/1970_Biosphere_ScientificAmerican.pdf},
year = {1970},
date = {1970-09-15},
volume = {223},
number = {3},
publisher = {SCIENTIFIC AMERICAN, INC},
abstract = {THE BIOSPHERE, by G. Evelyn Hutchinson
Introducing an issue on the grand-scale cyclic mechanisms of life on the earth.
THE ENERGY CYCLE OF THE EARTH, by Abraham H. Oort
Energy from the sun is broadly distributed by the atmosphere and the ocean.
},
keywords = {Energía, energía solar, entropía, termodinámica},
pubstate = {published},
tppubtype = {collection}
}
THE BIOSPHERE, by G. Evelyn Hutchinson
Introducing an issue on the grand-scale cyclic mechanisms of life on the earth.
THE ENERGY CYCLE OF THE EARTH, by Abraham H. Oort
Energy from the sun is broadly distributed by the atmosphere and the ocean.
Introducing an issue on the grand-scale cyclic mechanisms of life on the earth.
THE ENERGY CYCLE OF THE EARTH, by Abraham H. Oort
Energy from the sun is broadly distributed by the atmosphere and the ocean.
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