IEA ECES Annex 31 Final Report - Energy Storage with Energy Efficient Buildings and Districts: Optimization and Automation

Fariborz Haghigat; Paul Tuohy; Gilles Fraisse; Claudio Del Pero

IEA ECES Annex 31 Final Report - Energy Storage with Energy Efficient Buildings and Districts: Optimization and Automation

Fariborz Haghigat, Paul Tuohy, Gilles Fraisse, Claudio Del Pero

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Abstract

At present, the energy requirements in buildings are majorly met from non-renewable sources where the contribution of renewable sources is still in its initial stage. Meeting the peak energy demand by non-renewable energy sources is highly expensive for the utility companies and it critically influences the environment through GHG emissions. In addition, renewable energy sources are inherently intermittent in nature. Therefore, to make both renewable and nonrenewable energy sources more efficient in building/district applications, they should be integrated with energy storage systems.

Nevertheless, determination of the optimal operation and integration of energy storage with buildings/districts are not straightforward. The real strength of integrating energy storage technologies with buildings/districts is stalled by the high computational demand (or even lack of) tools and optimization techniques. Annex 31 aims to resolve this gap by critically addressing the challenges in integrating energy storage systems in buildings/districts from the perspective of
design, development of simplified modeling tools and optimization techniques.

Original language	English
Place of Publication	Paris, France
Number of pages	341
Publication status	Published - 12 Feb 2019

Keywords

renewable energy
storage energy
demand side management
smart grid
flexible demand
DSM
energy modelling
district energy
demand response
thermal storage

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Haghigat-etal-2019-Energy-storage-with-energy-efficient-buildings-and-districts-optimization-and-automationFinal published version, 10.4 MBLicence: All rights reserved

Cite this

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title = "IEA ECES Annex 31 Final Report - Energy Storage with Energy Efficient Buildings and Districts: Optimization and Automation",

abstract = "At present, the energy requirements in buildings are majorly met from non-renewable sources where the contribution of renewable sources is still in its initial stage. Meeting the peak energy demand by non-renewable energy sources is highly expensive for the utility companies and it critically influences the environment through GHG emissions. In addition, renewable energy sources are inherently intermittent in nature. Therefore, to make both renewable and nonrenewable energy sources more efficient in building/district applications, they should be integrated with energy storage systems.Nevertheless, determination of the optimal operation and integration of energy storage with buildings/districts are not straightforward. The real strength of integrating energy storage technologies with buildings/districts is stalled by the high computational demand (or even lack of) tools and optimization techniques. Annex 31 aims to resolve this gap by critically addressing the challenges in integrating energy storage systems in buildings/districts from the perspective ofdesign, development of simplified modeling tools and optimization techniques.",

keywords = "renewable energy, storage energy, demand side management, smart grid, flexible demand, DSM, energy modelling, district energy, demand response, thermal storage",

author = "Fariborz Haghigat and Paul Tuohy and Gilles Fraisse and {Del Pero}, Claudio",

year = "2019",

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TY - BOOK

T1 - IEA ECES Annex 31 Final Report - Energy Storage with Energy Efficient Buildings and Districts: Optimization and Automation

AU - Haghigat, Fariborz

AU - Tuohy, Paul

AU - Fraisse, Gilles

AU - Del Pero, Claudio

PY - 2019/2/12

Y1 - 2019/2/12

N2 - At present, the energy requirements in buildings are majorly met from non-renewable sources where the contribution of renewable sources is still in its initial stage. Meeting the peak energy demand by non-renewable energy sources is highly expensive for the utility companies and it critically influences the environment through GHG emissions. In addition, renewable energy sources are inherently intermittent in nature. Therefore, to make both renewable and nonrenewable energy sources more efficient in building/district applications, they should be integrated with energy storage systems.Nevertheless, determination of the optimal operation and integration of energy storage with buildings/districts are not straightforward. The real strength of integrating energy storage technologies with buildings/districts is stalled by the high computational demand (or even lack of) tools and optimization techniques. Annex 31 aims to resolve this gap by critically addressing the challenges in integrating energy storage systems in buildings/districts from the perspective ofdesign, development of simplified modeling tools and optimization techniques.

AB - At present, the energy requirements in buildings are majorly met from non-renewable sources where the contribution of renewable sources is still in its initial stage. Meeting the peak energy demand by non-renewable energy sources is highly expensive for the utility companies and it critically influences the environment through GHG emissions. In addition, renewable energy sources are inherently intermittent in nature. Therefore, to make both renewable and nonrenewable energy sources more efficient in building/district applications, they should be integrated with energy storage systems.Nevertheless, determination of the optimal operation and integration of energy storage with buildings/districts are not straightforward. The real strength of integrating energy storage technologies with buildings/districts is stalled by the high computational demand (or even lack of) tools and optimization techniques. Annex 31 aims to resolve this gap by critically addressing the challenges in integrating energy storage systems in buildings/districts from the perspective ofdesign, development of simplified modeling tools and optimization techniques.

KW - renewable energy

KW - storage energy

KW - demand side management

KW - smart grid

KW - flexible demand

KW - DSM

KW - energy modelling

KW - district energy

KW - demand response

KW - thermal storage

UR - https://iea-eces.org/publications/final-report-annex-31/

M3 - Commissioned report

BT - IEA ECES Annex 31 Final Report - Energy Storage with Energy Efficient Buildings and Districts: Optimization and Automation

CY - Paris, France

ER -

IEA ECES Annex 31 Final Report - Energy Storage with Energy Efficient Buildings and Districts: Optimization and Automation

Abstract

Keywords

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ORIGIN

Cite this

IEA ECES Annex 31 Final Report - Energy Storage with Energy Efficient Buildings and Districts: Optimization and Automation

Abstract

Keywords

Access to Document

Other files and links

Fingerprint

Projects

SIES 2022: Smart Integrated Energy Systems: Enhanced Virtual Power Plant VPP+ Energy Pool Intergration for Local and Regional Resistance

FITS-LCD: FITS-LCD: Fabric Integrated Thermal Storage for Low-Carbon Dwellings

ORIGIN

Cite this