An evolutionary approach to modeling and control of space heating and thermal storage systems

[Display omitted] Home Energy Management systems are in a rapid development curve, supported by the advancements in computational intelligence, smart appliances, and new smart-grid frameworks. These systems are a fundamental part to implement demand-side management strategies and to shift local ener...

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Veröffentlicht in:	Energy and buildings 2021-03, Vol.234, p.110674, Article 110674
Hauptverfasser:	Devia, William, Agbossou, Kodjo, Cardenas, Alben
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms Artificial intelligence Computer applications Consumption Cost control Cost reduction Demand-side management Distributed model predictive control Electric thermal storage Electronic devices Energy consumption Energy demand Energy management systems Energy storage Energy usage Evolutionary algorithms Heating Heating load Heating systems Intelligence NSGA-II Optimization Peak demand Residential energy Smart grid Space heating Storage systems Thermal parameter estimation Thermal storage Thermostats
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container_title	Energy and buildings
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creator	Devia, William Agbossou, Kodjo Cardenas, Alben
description	[Display omitted] Home Energy Management systems are in a rapid development curve, supported by the advancements in computational intelligence, smart appliances, and new smart-grid frameworks. These systems are a fundamental part to implement demand-side management strategies and to shift local energy demand to periods of lower consumption effectively. In this paper, we explore the application of distributed co-evolutionary optimization algorithms and an agent-based architecture to reduce the consumption profile signature of the heating system during the critical peak demand periods, by reducing costs and respecting the comfort constraints of the occupants. The proposed control architecture targets the typical baseboard space heating systems and electrical thermal storage systems, as these represent a large portion of the energy usage in Nordic countries and are commonly controlled by room independent thermostats, which could be easily replaced by smart devices running an algorithm as the one presented in this work. Results prove the strategy proposed getting a cost reduction of up to 23% and a peak-to-average ratio decrease of up to 25% for reference scenarios. Also, an emulation Simulink model is developed to recreate a house and the different heating loads studied in this paper and an experimental test bed is built to model a real ETS system, two different complexity degree RC models are proposed to describe such systems.
doi_str_mv	10.1016/j.enbuild.2020.110674
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These systems are a fundamental part to implement demand-side management strategies and to shift local energy demand to periods of lower consumption effectively. In this paper, we explore the application of distributed co-evolutionary optimization algorithms and an agent-based architecture to reduce the consumption profile signature of the heating system during the critical peak demand periods, by reducing costs and respecting the comfort constraints of the occupants. The proposed control architecture targets the typical baseboard space heating systems and electrical thermal storage systems, as these represent a large portion of the energy usage in Nordic countries and are commonly controlled by room independent thermostats, which could be easily replaced by smart devices running an algorithm as the one presented in this work. Results prove the strategy proposed getting a cost reduction of up to 23% and a peak-to-average ratio decrease of up to 25% for reference scenarios. 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subjects	Algorithms Artificial intelligence Computer applications Consumption Cost control Cost reduction Demand-side management Distributed model predictive control Electric thermal storage Electronic devices Energy consumption Energy demand Energy management systems Energy storage Energy usage Evolutionary algorithms Heating Heating load Heating systems Intelligence NSGA-II Optimization Peak demand Residential energy Smart grid Space heating Storage systems Thermal parameter estimation Thermal storage Thermostats
title	An evolutionary approach to modeling and control of space heating and thermal storage systems
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