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    Demand Response Design of Domestic Heat Pumps

    This paper proposes an emergency-based demand response (DR) controller of domestic heat pump (DHP) units based on an estimated frequency of the UK electricity in 2035. The normal pattern of DHP demand is adjusted to maintain system frequency within its limit using a linear model of power and temperature inside low-carbon houses, while considering consumer comfort. Simulation results show that the proposed DR design of static/dynamic frequency-controlled DHPs will increase the amount of power reserve by 75% and the amount of electricity market by 70%, as compared to their values of the current frequency response by flexible loads.

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    Demand Response Design of Domestic Heat Pumps

    This paper proposes an emergency-based demand response (DR) controller of domestic heat pump (DHP) units based on an estimated frequency of the UK electricity in 2035. The normal pattern of DHP demand is adjusted to maintain system frequency within its limit using a linear model of power and temperature inside low-carbon houses, while considering consumer comfort. Simulation results show that the proposed DR design of static/dynamic frequency-controlled DHPs will increase the amount of power reserve by 75% and the amount of electricity market by 70%, as compared to their values of the current frequency response by flexible loads.

    Access

    Download

    Demand Response Design of Domestic Heat Pumps

    This paper proposes an emergency-based demand response (DR) controller of domestic heat pump (DHP) units based on an estimated frequency of the UK electricity in 2035. The normal pattern of DHP demand is adjusted to maintain system frequency within its limit using a linear model of power and temperature inside low-carbon houses, while considering consumer comfort. Simulation results show that the proposed DR design of static/dynamic frequency-controlled DHPs will increase the amount of power reserve by 75% and the amount of electricity market by 70%, as compared to their values of the current frequency response by flexible loads.

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    Title:

    Demand Response Design of Domestic Heat Pumps

    Contributors:

    Mohammed Jasim M. Al Essa (author)

    Published in:

    Designs, Vol 2, Iss 1, p 1 (2017)

    Publication date:

    2017

    ISSN:

    2411-9660

    DOI:

    https://doi.org/10.3390/designs2010001

    Type of media:

    Article (Journal)

    Type of material:

    Electronic Resource

    Language:

    Unknown

    Keywords:

    demand response , domestic heat pumps , frequency control by load management , frequency response , Technology , T , Engineering design , TA174

    Metadata by DOAJ is licensed under ​CC BY-SA 1.0

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