(Sektorkopplung) Sector coupling refers to the integration of electricity, heating, and mobility in order to increase the share of renewable power used in the latter two, which have so far seen little progress in switching to cleaner energy sources. Sector coupling can also help stabilise the grid by providing → 'storage' (see below) for excess renewable electricity when production surges – for example in car batteries, or in the form of synthetic methane stored in the gas grid (see → power-to-x).
Find a detailed explanation in the CLEW factsheet on sector coupling.
To maximise the efficiency of the power system and to keep the grid stable with a growing share of renewable power – much of it from small, distributed providers – scientists say the power grid needs to respond to real-time information on supply and demand. Smart grid network gadgets include smart meters and appliances that automatically adjust consumption to make use of power when it is abundant (and cheap), and save it when it is scarce (and expensive). In Germany, they are yet to be deployed on a large scale – partly because Germany’s strict data protection laws complicate the collection of data on power consumption.
Germany must exit coal-fired power generation to reach its goal of becoming largely greenhouse gas neutral by mid-century. Coal workers, environmental NGOs, politicians, citizens, industry, and energy companies have already intensely debated the shape and speed of a coal exit. The federal government has proposed a multi-stakeholder commission to find a compromise. Economy minister Peter Altmaier (CDU), environment minister Svenja Schulze (SPD), labour minister Hubertus Heil (SPD), and interior minister Horst Seehofer (CSU) will jointly work in the commission. The commission’s office will be in the economy ministry.
The discussion focuses on lignite, or brown coal, as Germany still heavily relies on its mining and use. The country’s last hard coal mines will close in 2018. In its Climate Action Plan 2050, the German government decided, in 2016, to involve federal ministries, the federal states, municipalities and unions, as well as representatives of “affected” companies and regions to find ways to deal with the economic changes brought on by the transformation of the country’s energy system. The plan states that a “commission on growth, structural economic change and regional development” should start its work in 2018. This proposed entity is often referred to as a ‘coal exit commission’, even though opposition from heavy industry prompted the omission of the word “coal” from its mandate.
The February 2018 coalition agreement between Germany's government partners - Chancellor Angela Merkel's conservatives (CDU/CSU) and the Social Democrats (SPD) - elaborates on the earlier proposal in the Climate Action Plan 2050, expands the commission’s tasks and slightly changes its name. It commits the new government to set up a “special commission on growth, structural economic change and employment,” bringing together policymakers, industry representatives, environmental organisations, labour unions, and affected federal states and regions to draft an action programme by the end of 2018, which should include:
The commission’s findings will feed into a proposed law on climate protection.
(Speicher) Because renewable production fluctuates with the weather, it often causes grid congestion and cannot always be relied on (see → re-dispatch costs), while → baseload power from conventional power plants is still used to ensure security of supply. In the future, storing renewable power is predicted to play a more important role in allowing Germany to give up fossil fuels altogether, alongside flexibility options like demand-side management. Some industry players already use battery storage plants to balance short-term fluctuations in power supply and to keep the grid stable (see → grid services), but operators argue that the current design of the power market does not offer sufficient financial incentive for the development of battery plants. Longer term storage would require the availability of much larger volumes of power, which in turn would call for other solutions, for example power to gas conversion (see → power-to-x).