Difference between revisions of "Gaseous fuels - POLES"

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* Underground coal methane recovery
 
* Underground coal methane recovery
 
* Gas production fugitive emissions recovery
 
* Gas production fugitive emissions recovery
 +
* Coke oven gas is captured in the final energy demand of the iron and steel sector
 
All three are determined by the effect of carbon pricing on the relevant emissions source.
 
All three are determined by the effect of carbon pricing on the relevant emissions source.
  

Revision as of 16:45, 22 December 2016

Model Documentation - POLES

Corresponding documentation
Previous versions
Model information
Model link
Institution JRC - Joint Research Centre - European Commission (EC-JRC), Belgium, http://ec.europa.eu/jrc/en/.
Solution concept Partial equilibrium (price elastic demand)
Solution method SimulationRecursive simulation
Anticipation Myopic


Gas

Natural gas domestic production and imports directly supply gas for consumption. Additional gas production can come from:

  • Urban waste methane recovery:
  • Underground coal methane recovery
  • Gas production fugitive emissions recovery
  • Coke oven gas is captured in the final energy demand of the iron and steel sector

All three are determined by the effect of carbon pricing on the relevant emissions source.


Hydrogen

The POLES model uses a complete module to represent hydrogen production (14), transport and use in various sectors: transport (fuel cells or thermal use), but also in stationary uses in industry and buildings (fuel cells or blending with natural gas). Water electrolysis from grid is coupled with the electricity load curve (hydrogen is produced preferentially during base load).

The hydrogen module in POLES

References

  1. ^  |  European Commission (2006). World Energy Technology Outlook 2050: WETO H2. [1]. Brussels, Belgium: European Commission.