Difference between revisions of "Decarbonising heating in Britain"

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And for many of our poorer fellow-citizens, already suffering most from the effects of austerity, the combination of fuel poverty and poorer quality, harder to heat housing, will cause greater hardship, ill-health and, for some, death.
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And for those already suffering from poverty in the UK<ref>
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"Inequality and poverty in Britain",
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[https://www.cisl.cam.ac.uk/resources/sustainability-horizons/december-2018/inequality-and-poverty-in-britain Cambridge Institute for Sustainability Leadership],
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Dec 2018
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</ref>, the combination of extreme cold weather with fuel poverty and poorer quality, harder to heat housing, will cause yet greater hardship, ill-health and, for some, death.  
  
 
We can do a little to help reduce our fuel use (and bills) by putting on warmer clothes instead of turning up the thermostat, by shutting doors and windows, and blocking up draughts, but personal efforts can only help marginally. The big changes have to be made at government levels, but they’re not easy.
 
We can do a little to help reduce our fuel use (and bills) by putting on warmer clothes instead of turning up the thermostat, by shutting doors and windows, and blocking up draughts, but personal efforts can only help marginally. The big changes have to be made at government levels, but they’re not easy.

Revision as of 12:13, 20 November 2019

An abridged version of this article was written for Extinction Rebellion's newspaper "The Hourglass" in November 2019 under the title: "Staying warm in a house on fire".


Paradoxically, global heating is likely to result in colder winters in the British Isles for some decades to come, as the temperate Gulf Stream falters[1][2] and disruption to the polar vortex unleashes the Beast from the East[3]. This is particularly bad news since British housing is built for our relatively mild winters and is poorly suited to much colder conditions. Burning yet more fossil fuels to stay warm is the last thing we need, but even if Carbon emissions were no problem, heating systems designed for winter temperatures that rarely dip below zero are no match for the temperatures our neighbours in continental Europe experience — and build for — which can drop tens of degrees below freezing. Worse still, gas supplies struggle to keep pace with peak demands[4]. And for those already suffering from poverty in the UK[5], the combination of extreme cold weather with fuel poverty and poorer quality, harder to heat housing, will cause yet greater hardship, ill-health and, for some, death.

We can do a little to help reduce our fuel use (and bills) by putting on warmer clothes instead of turning up the thermostat, by shutting doors and windows, and blocking up draughts, but personal efforts can only help marginally. The big changes have to be made at government levels, but they’re not easy.

Heating consumes more than half the energy we use in our homes[6], and about a third of the energy we use nationally[7], and most of that is CO2-emitting gas and oil. How can we decarbonise our heating?

UK final energy consumption 2009 (DECC).jpg

There are reckoned to be 26 million gas boilers in the UK.[8] The Climate Change Council wants a ban on gas boilers in new houses[9] and, with improvements in building regulations, houses could be built which require practically no heating (or cooling) at all[10], or their modest needs could be met using heat pumps. However, new houses are only a tiny proportion of all our housing, and most existing buildings were built to far poorer standards. Improving their insulation and draughtproofing can significantly reduce their heating demands, but nowhere near enough to eliminate the need for heating at all.

Could we replace oil and gas boilers with electric heating - perhaps using heat pumps? In France a lot of heating is electric, but they practically decarbonised their grid decades ago with cheap, low-carbon nuclear electricity. In Britain we’re not even on course to replace our existing nuclear power stations as they reach the end of their lives, let alone to massively expand our generation capacity. Wind provides useful amounts of clean electricity (although solar is little use in the winter, when demand is highest[11], and other clean renewables are, as yet, poorly developed), and we can also decarbonise our fossil- and biomass-fuelled power stations using carbon capture and storage, but we still have a huge job to even decarbonise our existing electricity supplies. Generating lots more clean electricity for heating (and upgrading grid capacity to get all the extra power to where it’s needed) would add further to the challenge[12]. Not to mention that electric boilers and heat pumps are very far from being a drop-in replacement for the common domestic combi boiler[13].

SEWTHA.jpg

The challenge of decarbonising all of Britain's energy – not just heating – was addressed by David MacKay in his classic Sustainable Energy Without The Hot Air, in which he discusses not only the various technologies available for moving to sustainable energy, but the physical potentials and limitations of different technologies, and how we can devise plans that add up for balancing supplies with demand.

The Energy Research Partnership has also published reports on its work on decarbonising Electricity, heating buildings, and the use of Hydrogen to decarbonise the UK's energy.

An approach being tested in the North of England[14] is to decarbonise our gas network. Natural gas coming ashore from the North Sea will be split into Hydrogen and Carbon Dioxide by a process known as Steam Methane Reformation (SMR). The CO2 will be pumped back into disused gas reservoirs deep underground while the Hydrogen would be fed into the existing gas pipe network (and salt caverns for temporary storage) to feed modified cookers and boilers in homes and businesses.

Schematic of H21 project

It will require a massive conversion effort but we did something similar between 1968 and 1976 when we converted from town gas (which was a mixture of mostly Hydrogen and deadly Carbon Monoxide) to “North Sea Gas”.[15]

Whatever approach, or combination of approaches, this country chooses will ideally be a matter for a Citizen’s Assembly to decide, informed by the science, engineering, economics and other experts they call upon to advise them.

Footnotes and References

  1. "Avoid Gulf stream disruption at all costs, scientists warn", Damian Carrington, The Guardian, 13 Apr 2018
  2. "Is the Gulf Stream about to collapse and is the new ice age coming sooner than scientists think?", Josh Gabbatiss, The Independent, 12 Apr 2018
  3. "What is the polar vortex – and how is it linked to climate change?", Oliver Milman, The Guardian, 31 Jan 2019
  4. "Gas consumption during the ‘Beast from the East’", UK Energy Research Centre (UKERC), 17 Aug 2018
  5. "Inequality and poverty in Britain", Cambridge Institute for Sustainability Leadership, Dec 2018
  6. "The UK Housing Context", Jonas Rooze, Carbon Descent blog, 18 May 2011.
  7. Figure cited by David MacKay in his TEDx talk "A reality check on renewables".
  8. "GLOBAL BOILER MARKET HEATS UP AS THE UK IS NO LONGER THE LARGEST MARKET", HVP magazine, 26 Jul 2017
  9. "UK homes unfit for the challenges of climate change", Climate Change Council, 21 Feb 2019
  10. For example Tony Cowling's house in Reading.
  11. The amount of energy supplied by solar PV in Britain over a year can be seen from this display from Sheffield University's Live PV generation web pages: Power supplied to from solar over a year
  12. Britain's gas consumption during the "Beast" peaked at over 200Gw, whereas the whole of our electricity supply is about 50GW: see "Gas consumption during the ‘Beast from the East’", UK Energy Research Centre, 17 Aug 2018
  13. Heat pumps produce far lower temperatures than gas and oil boilers and can't produce sufficient heating with existing radiators, which need to be replaced with bulky fan-assisted radiators or, ideally, Under-Floor Heating (UFH). They require a large fan-assisted heat exchanger out-doors, connected by pipework to an indoor unit, which can pose problems for siting. And a heat pump capable of producing hot water on demand would generally be much bigger and more expensive than one just for space heating (e.g. combis have power outputs of at least 24kW in order to supply hot water at reasonable rates, but a small house or flat may only require half that power for space heating), so domestic hot water is usually provided by a fairly bulky hot water cylinder, which adds to the challenges of fitting everything in, especially in small houses and flats.
  14. see article on the H21 North of England project
  15. "Gas industry timeline", National Gas Museum website