Citizens could drive Europe’s energy transition

A new study conducted by consultancy CE Delft for four European NGOs finds that practically all households in the EU can play a role in the transition. Craig Morris takes a look.

Middelgrunden offshore wind farm (40 MW) observed in Øresund

Middelgrunden offshore wind farm in Denmark : a community wind project (Photo by Kim Hansen, edited, CC BY-SA 3.0)


Released in September (PDF), the study focuses on what citizens can do with wind, solar, and demand management (including storage) by 2030 and 2050 – at home, in community groups, in the public sector, and in small businesses. The main finding is that 83 percent of European households could eventually become “energy citizens” (the paper’s term for what is usually called “prosumers.”) Nearly two thirds of them, so roughly half of all households, could make their own energy. In this scenario (which is available as a spreadsheet in the report’s Annex), the EU would be 100% renewable for all of its energy – not just electricity.

In terms of total power generation, SMEs (with fewer than 50 employees) have the greatest potential, though the contribution from “collectives” (which this website generally refers to as community projects) outstrips households alone by a wide margin. (Source: CE Delft)

In terms of total power generation, SMEs (with fewer than 50 employees) have the greatest potential; the contribution from “collectives” (which this website generally refers to as community projects) outstrips households alone by a wide margin. (Source: CE Delft)

For community wind and solar, the study is based on average coop sizes in France and the Netherlands. Household investment potential plays a role, as does local resource availability. For solar, residential roofs also play a role. Note for wind that the study assumes citizen co-ownership of large wind turbines, not small wind generators – because the latter don’t work. (That’s not the official reason given in the study, however, which merely states, “individual households owning wind power are currently very scarce and are therefore ignored in this analysis.”)

Interestingly, the study implicitly (unfortunately not explicitly – but that’s what I’m here for) says that Europe has more space for PV than it needs. Specifically, the potential of rooftop PV had to be reduced based on the “total capacity solar PV capacity needed according to the Energy Revolutions scenario” published by Greenpeace.

Germany would apparently be able to get half of its current power supply from energy citizens alone, and the same holds true for most other countries on this list, whose annual power demand today is close to double the potential of community energy estimated above for 2050. (Source: CE Delft)

Germany would apparently be able to get half of its current power supply from energy citizens alone. The same holds true for most other countries on this list, whose annual power demand today is close to double the potential of community energy estimated above for 2050. (Source: CE Delft)

Storage and demand management

The study assumes that the number of cars will stay the same by 2050 (probably unrealistic if we get self-driving vehicles and car ownership plummets), giving us 115 million households with an EV (just over half of 210 million). These cars would be charged largely when the grid has excess green power.

While the press croons over battery storage, smart electric boilers turn out to have greater potential for dissemination. While 42 million households (20 percent) might have stationary batteries, 70 million might have smart water boilers – even more than the 60 million expected to have solar on their roofs. Yet, practically no one (outside of Denmark and community energy campaigners in Germany) is even talking about smart water boilers.

Stated in terms of the energy amount (see Fig 15 below), EVs clearly have the greatest storage potential by 2050, and the role of stationary batteries becomes much bigger than that of electric boilers. This finding runs contrary to previous German studies (such as IWES’s), which found that stationary batteries will mainly be used to store and release small amounts of power for brief periods (ancillary services), not store large amounts for a long time (arbitration). The situation may, however, be different in southern Europe, where more solar is available and less heat in needed than in Germany.

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(Source: CE Delft)

The main takeaway from the study is that energy citizens can play a central role, not a marginal one, in our energy supply. We are talking about roughly half of our electricity alone, with the other half left up to all of the utilities – municipal and corporate – that today cover nearly 100% of power supply in most countries.

The EU now says it aims to focus on the “active participation of citizens and local communities in the supply and demand of electricity,” as Euractiv quotes one official. The report certainly suggests that the potential is great. One wonders, though, whether officials in Brussels will have the stamina to stick with community energy once it becomes clear that the big energy firms that have pushed the concept of an integrated European market (and opposed renewables) would be sidelined in the process.

Craig Morris (@PPchef) is the lead author of German Energy Transition. He is co-author of Energy Democracy, the first history of Germany’s Energiewende, and is currently Senior Fellow at the IASS.

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Craig Morris (@PPchef) is co-author of Energy Democracy, the first history of Germany’s Energiewende.

3 Comments

  1. Mike Parr says

    There is a certaint seasonal production asymmetry between PV & wind. If a large number/most HH roofs had PV you would have some over production problems – in summer possibly solved by storage in houses that do not have roof orientations that are OK & implementation of local energy “markets”. Local wind would take over in autumn/winter/spring – I’m guessing 1MW+ WTs.

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