Passive energy storage using distributed electric loads with thermal storage
This paper presents the concept of controlling distributed electric loads with thermal energy storage as a passive electric energy storage system (PEESS). Examples of such loads include different types of thermostatically controlled appliances (TCAs) such as hot water heaters, air conditioners, and...
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Online Access: | https://ieeexplore.ieee.org/document/8986817/ |
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doaj-6d4d555e8a1546adb0bee737eebfd6742021-04-23T16:12:02ZengIEEEJournal of Modern Power Systems and Clean Energy2196-54202013-01-011326027010.1007/s40565-013-0033-z8986817Passive energy storage using distributed electric loads with thermal storageNing Lu0Maziar Vanouni1North Carolina State University,Electrical and Computer Engineering Department,Raleigh,NC,USANorth Carolina State University,Electrical and Computer Engineering Department,Raleigh,NC,USAThis paper presents the concept of controlling distributed electric loads with thermal energy storage as a passive electric energy storage system (PEESS). Examples of such loads include different types of thermostatically controlled appliances (TCAs) such as hot water heaters, air conditioners, and refrigerators. Each TCA can be viewed as a thermal cell that stores electricity as thermal energy. A centralized control mechanism can be used to control the timing of each thermal cell to consume electric energy so that the aggregated electricity consumption of the thermal cells will vary against a baseline consumption. Thus, when the aggregated consumption is higher than the baseline, the PEESS is charging; otherwise, the PEESS is discharging. The overall performance of a PEESS will be equivalent to that of a battery energy storage device. This paper presents the configuration and formulates the control of a PEESS. The modeling results demonstrate the feasibility of implementing the PEESS.https://ieeexplore.ieee.org/document/8986817/Energy storageDemand responseLoad managementThermostatically controlled appliancesDistributed controlSmart grid |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Ning Lu Maziar Vanouni |
spellingShingle |
Ning Lu Maziar Vanouni Passive energy storage using distributed electric loads with thermal storage Journal of Modern Power Systems and Clean Energy Energy storage Demand response Load management Thermostatically controlled appliances Distributed control Smart grid |
author_facet |
Ning Lu Maziar Vanouni |
author_sort |
Ning Lu |
title |
Passive energy storage using distributed electric loads with thermal storage |
title_short |
Passive energy storage using distributed electric loads with thermal storage |
title_full |
Passive energy storage using distributed electric loads with thermal storage |
title_fullStr |
Passive energy storage using distributed electric loads with thermal storage |
title_full_unstemmed |
Passive energy storage using distributed electric loads with thermal storage |
title_sort |
passive energy storage using distributed electric loads with thermal storage |
publisher |
IEEE |
series |
Journal of Modern Power Systems and Clean Energy |
issn |
2196-5420 |
publishDate |
2013-01-01 |
description |
This paper presents the concept of controlling distributed electric loads with thermal energy storage as a passive electric energy storage system (PEESS). Examples of such loads include different types of thermostatically controlled appliances (TCAs) such as hot water heaters, air conditioners, and refrigerators. Each TCA can be viewed as a thermal cell that stores electricity as thermal energy. A centralized control mechanism can be used to control the timing of each thermal cell to consume electric energy so that the aggregated electricity consumption of the thermal cells will vary against a baseline consumption. Thus, when the aggregated consumption is higher than the baseline, the PEESS is charging; otherwise, the PEESS is discharging. The overall performance of a PEESS will be equivalent to that of a battery energy storage device. This paper presents the configuration and formulates the control of a PEESS. The modeling results demonstrate the feasibility of implementing the PEESS. |
topic |
Energy storage Demand response Load management Thermostatically controlled appliances Distributed control Smart grid |
url |
https://ieeexplore.ieee.org/document/8986817/ |
work_keys_str_mv |
AT ninglu passiveenergystorageusingdistributedelectricloadswiththermalstorage AT maziarvanouni passiveenergystorageusingdistributedelectricloadswiththermalstorage |
_version_ |
1721512542022402048 |