EHP in low voltage networks: Understanding the effects of heat emitters and room temperatures

Alejandro Navarro-Espinosa; Nicholas Good; Lingxi Zhang; Pierluigi Mancarella; Luis nando Ochoa

EHP in low voltage networks: Understanding the effects of heat emitters and room temperatures

Alejandro Navarro-Espinosa, Nicholas Good, Lingxi Zhang, Pierluigi Mancarella, Luis nando Ochoa

Research output: Chapter in Book/Conference proceeding › Conference contribution

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Abstract

The adoption of Electric Heat Pumps (EHPs) at residential level can support the decarbonization of domestic heating. However, these new loads can produce technical problems in low voltage (LV) distribution networks. This work studies the EHP technical impacts in LV feeders, analyzing potential actions to minimize them. Particularly, two cases are investigated: the utilization of different heat emitters and the selection of different indoor temperatures. These cases are explored by using a Monte Carlo approach to cater for the uncertainty of LV demand. Daily one-minute resolution profiles are adopted for the domestic energy consumption in each of the sensitivities considered. The methodology is applied on three real UK LV networks. Results show that the decrease in the set temperature leads to a small reduction in the likelihood of technical impacts, whereas the utilization of underfloor heating can significantly reduce the likelihood of such impacts, resulting in a higher EHP penetration.

Original language	English
Title of host publication	IEEE/PES PowerTech 2015
Pages	1-5
Number of pages	5
Publication status	Published - 2015
Event	IEEE/PES PowerTech 2015 - Duration: 29 Jun 2015 → 2 Jul 2015

Conference

Conference	IEEE/PES PowerTech 2015
Period	29/06/15 → 2/07/15

Keywords

electric heat pumps, low carbon technologies, low voltage distribution networks.

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@inproceedings{e6cbfbf57889494aac6e3fcf50193fb1,

title = "EHP in low voltage networks: Understanding the effects of heat emitters and room temperatures",

abstract = "The adoption of Electric Heat Pumps (EHPs) at residential level can support the decarbonization of domestic heating. However, these new loads can produce technical problems in low voltage (LV) distribution networks. This work studies the EHP technical impacts in LV feeders, analyzing potential actions to minimize them. Particularly, two cases are investigated: the utilization of different heat emitters and the selection of different indoor temperatures. These cases are explored by using a Monte Carlo approach to cater for the uncertainty of LV demand. Daily one-minute resolution profiles are adopted for the domestic energy consumption in each of the sensitivities considered. The methodology is applied on three real UK LV networks. Results show that the decrease in the set temperature leads to a small reduction in the likelihood of technical impacts, whereas the utilization of underfloor heating can significantly reduce the likelihood of such impacts, resulting in a higher EHP penetration.",

keywords = "electric heat pumps, low carbon technologies, low voltage distribution networks.",

author = "Alejandro Navarro-Espinosa and Nicholas Good and Lingxi Zhang and Pierluigi Mancarella and Ochoa, {Luis nando}",

year = "2015",

language = "English",

pages = "1--5",

booktitle = "IEEE/PES PowerTech 2015",

note = "IEEE/PES PowerTech 2015 ; Conference date: 29-06-2015 Through 02-07-2015",

}

TY - GEN

T1 - EHP in low voltage networks: Understanding the effects of heat emitters and room temperatures

AU - Navarro-Espinosa, Alejandro

AU - Good, Nicholas

AU - Zhang, Lingxi

AU - Mancarella, Pierluigi

AU - Ochoa, Luis nando

PY - 2015

Y1 - 2015

N2 - The adoption of Electric Heat Pumps (EHPs) at residential level can support the decarbonization of domestic heating. However, these new loads can produce technical problems in low voltage (LV) distribution networks. This work studies the EHP technical impacts in LV feeders, analyzing potential actions to minimize them. Particularly, two cases are investigated: the utilization of different heat emitters and the selection of different indoor temperatures. These cases are explored by using a Monte Carlo approach to cater for the uncertainty of LV demand. Daily one-minute resolution profiles are adopted for the domestic energy consumption in each of the sensitivities considered. The methodology is applied on three real UK LV networks. Results show that the decrease in the set temperature leads to a small reduction in the likelihood of technical impacts, whereas the utilization of underfloor heating can significantly reduce the likelihood of such impacts, resulting in a higher EHP penetration.

AB - The adoption of Electric Heat Pumps (EHPs) at residential level can support the decarbonization of domestic heating. However, these new loads can produce technical problems in low voltage (LV) distribution networks. This work studies the EHP technical impacts in LV feeders, analyzing potential actions to minimize them. Particularly, two cases are investigated: the utilization of different heat emitters and the selection of different indoor temperatures. These cases are explored by using a Monte Carlo approach to cater for the uncertainty of LV demand. Daily one-minute resolution profiles are adopted for the domestic energy consumption in each of the sensitivities considered. The methodology is applied on three real UK LV networks. Results show that the decrease in the set temperature leads to a small reduction in the likelihood of technical impacts, whereas the utilization of underfloor heating can significantly reduce the likelihood of such impacts, resulting in a higher EHP penetration.

KW - electric heat pumps, low carbon technologies, low voltage distribution networks.

M3 - Conference contribution

SP - 1

EP - 5

BT - IEEE/PES PowerTech 2015

T2 - IEEE/PES PowerTech 2015

Y2 - 29 June 2015 through 2 July 2015

ER -

EHP in low voltage networks: Understanding the effects of heat emitters and room temperatures

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Conference

Keywords

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