Smith A. How lower carbon factors in SAP will change heating design. CIBSE J 2018; August: 1–12.
2.
ReesSCurtisR. National deployment of domestic geothermal heat pump technology: observations on the UK experience 1995–2013. Energies2014; 7: 5460–5499.
3.
DECC. Updated energy and emissions projections 2015. Technical Report, Department of Energy and Climate Change, London, November 2015.
4.
Lowe R, Summerfield A, Oikonomou E, et al. Final report on analysis of heat pump data from the renewable heat premium payment (RHPP) scheme. Technical report, UCL for the Department of Energy and Climate Change, London, UK, 2017.
5.
DECC. The future of heating: meeting the challenge, London, UK: Department of Energy and Climate Change, 2013.
6.
Committee on Climate Change. UK housing: fit for the future? London, UK: The Committee on Climate Change, 2019, www.theccc.org.uk/publications (accessed 10 September 2019).
7.
Jones E, Ward E, Banks N, et al. The carbon gap; analysis of the effects of grid decarbonisation on building CO2 emissions and design. In: Proceedings of CIBSE technical symposium 2017. Loughborough, 2015, p.23. Chartered Institution of Building Services Engineers.
8.
Allison S, Bird J and Ozmumcu A. An operational lifetime assessment of the carbon performance of gas fired CHP led district heating. Proc CIBSE Technical Symposium 2016; April: 1–15. Chartered Institution of Building Services Engineers.
9.
SumnerJA. A summary of heat-pump development and use in Great Britain. J Inst Fuel1953; 25: 318–321.
GriffithMV. Some aspects of heat pump operation in Great Britain. Proc IEE Part A: Power Eng1957; 104: 262–271.
12.
Karlsson F, Axell M and Fahlén P. Heat pump systems in Sweden – Country Report for IEA HPP Annex 28. Technical report, SP Swedish Technical Research Institute, Borås, Sweden, 2003.
13.
Ploskić A. Technical solutions for low-temperature heat emission in buildings. PhD Thesis, KTH, Stockholm, 2013.
