Differences

This shows you the differences between two versions of the page.

Link to this comparison view

Both sides previous revisionPrevious revision
Next revision		Previous revision
topics:flexibility [2026/04/15 18:30] vso_vsotopics:flexibility [2026/04/15 20:24] (current) vso_vso
Line 19: Line 19:
 </WRAP> </WRAP>
  
-=====Why this matters===== +===== Why this matters ===== 
- +Smart grid transitions expand both the need for flexibility and the range of resources that can provide it. Flexibility is delivered through various means: dispatchable generation, storage, demand response, infrastructure, and operational practices, each with distinct response times, costs, and technical characteristics.
-Flexibility is delivered through various means: dispatchable generation, [[topics:storage|storage]], demand response, [[topics:infrastructure|grid interconnection]], and operational practices, each with distinct response times, costs, and technical characteristics.+
  
 <WRAP callout> <WRAP callout>
-Improving flexibility within the current system architecture differs fundamentally from transforming the architecture itself. Most policy attention focuses on operational flexibility; the deeper transition challenge lies in architectural change.+Improving flexibility within the current system architecture differs from transforming the architecture itself.
 </WRAP> </WRAP>
  
-Smart grid transitions expand both the need for flexibility and the range of resources that can provide it. Distributed energy resources, [[topics:storage|battery storage]], smart appliances, and electric vehicles create new options at the [[topics:grid_edge|grid edge]]. Realising this potential depends on [[topics:markets|market structures]] that can procure and value flexibility, communication and control systems that coordinate distributed resources, and [[topics:regulation|regulatory frameworks]] that define how flexibility providers participate and are compensated.((Hillberg, E., Zegers, A., Herndler, B., Wong, S., Pompee, J., Bourmaud, J.-Y., Lehnhoff, S., Migliavacca, G., Uhlen, K., Oleinikova, I., Philp, H., Norstrom, M., Persson, M., Rossi, J., & Beccuti, G. (2019). //Flexibility needs in the future power system.// ISGAN Annex 6. https://doi.org/10.13140/RG.2.2.22580.71047))+Distributed energy resources, [[topics:storage|battery storage]], smart appliances, and electric vehicles create new options at the [[topics:grid_edge|grid edge]]. Realising this potential depends on [[topics:markets|market structures]] that can procure and value flexibility, communication and control systems that coordinate distributed resources, and [[topics:regulation|regulatory frameworks]] that define how flexibility providers participate and are compensated.((Hillberg, E., Zegers, A., Herndler, B., Wong, S., Pompee, J., Bourmaud, J.-Y., Lehnhoff, S., Migliavacca, G., Uhlen, K., Oleinikova, I., Philp, H., Norstrom, M., Persson, M., Rossi, J., & Beccuti, G. (2019). //Flexibility needs in the future power system.// ISGAN Annex 6. https://doi.org/10.13140/RG.2.2.22580.71047))
  
 As variable renewable energy penetration increases, the flexibility challenge shifts from managing predictable load profiles to accommodating supply-side variability and demand-side uncertainty simultaneously. This compounds with growing [[topics:sector_coupling|sector coupling]], where electrification of transport, heating, and industrial processes introduces new load patterns that are themselves variable and partially controllable. As variable renewable energy penetration increases, the flexibility challenge shifts from managing predictable load profiles to accommodating supply-side variability and demand-side uncertainty simultaneously. This compounds with growing [[topics:sector_coupling|sector coupling]], where electrification of transport, heating, and industrial processes introduces new load patterns that are themselves variable and partially controllable.