TY - JOUR
T1 - Energy recovery from the water cycle
T2 - Thermal energy from drinking water
AU - van der Hoek, Jan Peter
AU - Mol, Stefan
AU - Giorgi, Sara
AU - Ahmad, Jawairia Imtiaz
AU - Liu, Gang
AU - Medema, Gertjan
PY - 2018/11/1
Y1 - 2018/11/1
N2 - Greenhouse gas (GHG) emissions contribute to climate change. The public water utility of Amsterdam wants to operate climate neutrally in 2020 to reduce its GHG emissions. Energy recovery from the water cycle has a large potential to contribute to this goal: the recovered energy is an alternative for fossil fuel and thus contributes to the reduction of GHG emissions. One of the options concerns thermal energy recovery from drinking water. In Amsterdam, drinking water is produced from surface water, resulting in high drinking water temperatures in summer and low drinking water temperatures in winter. This makes it possible to apply both cold recovery and heat recovery from drinking water. For a specific case, the effects of cold recovery from drinking water were analyzed on three decisive criteria: the effect on the GHG emissions, the financial implications, and the effect on the microbiological drinking water quality. It is shown that cold recovery from drinking water results in a 90% reduction of GHG emissions, and that it has a positive financial business case: Total Cost of Ownership reduced with 17%. The microbial drinking water quality is not affected, but biofilm formation in the drinking water pipes increased after cold recovery.
AB - Greenhouse gas (GHG) emissions contribute to climate change. The public water utility of Amsterdam wants to operate climate neutrally in 2020 to reduce its GHG emissions. Energy recovery from the water cycle has a large potential to contribute to this goal: the recovered energy is an alternative for fossil fuel and thus contributes to the reduction of GHG emissions. One of the options concerns thermal energy recovery from drinking water. In Amsterdam, drinking water is produced from surface water, resulting in high drinking water temperatures in summer and low drinking water temperatures in winter. This makes it possible to apply both cold recovery and heat recovery from drinking water. For a specific case, the effects of cold recovery from drinking water were analyzed on three decisive criteria: the effect on the GHG emissions, the financial implications, and the effect on the microbiological drinking water quality. It is shown that cold recovery from drinking water results in a 90% reduction of GHG emissions, and that it has a positive financial business case: Total Cost of Ownership reduced with 17%. The microbial drinking water quality is not affected, but biofilm formation in the drinking water pipes increased after cold recovery.
KW - Cold recovery
KW - Drinking water
KW - Greenhouse gas emissions
KW - Microbiological water quality
KW - Thermal energy
UR - http://www.scopus.com/inward/record.url?scp=85053074556&partnerID=8YFLogxK
UR - http://resolver.tudelft.nl/uuid:d07208f0-df3b-4928-874c-5c239f2a54e2
U2 - 10.1016/j.energy.2018.08.097
DO - 10.1016/j.energy.2018.08.097
M3 - Article
AN - SCOPUS:85053074556
SN - 0360-5442
VL - 162
SP - 977
EP - 987
JO - Energy
JF - Energy
ER -