Integration of a magnetocaloric heat pump in energy flexible buildings

Hicham Johra

Integration of a magnetocaloric heat pump in energy flexible buildings

Publikation: Ph.d.-afhandling

1446 Downloads (Pure)

Abstract

To prevent future energy crisis and tackle the problems of climate change, modern society must promote a radical evolution in our energy systems. The building sector, and in particular its heating needs, have clearly been identified as one of the main targets for the reduction of the global energy usage. In addition, buildings are a key actor for the development of renewable energy sources.
The main objective of this research study is to investigate and demonstrate the possibility of integrating an innovative magnetocaloric heat pump in a single-family house under Danish weather conditions. Moreover, the study includes a numerical analysis to increase the understanding of the heating energy flexibility potential of residential buildings using thermal storage in the indoor environment.

Originalsprog	Engelsk
Vejledere	Heiselberg, Per Kvols, Hovedvejleder
Udgiver	Aalborg Universitetsforlag
ISBN'er, elektronisk	978-87-7210-181-1
Status	Udgivet - 2018

Bibliografisk note

PhD supervisor:
Prof. Per K. Heiselberg, Aalborg University

Emneord

Magnetocaloric heat pump
Magnetic heating
Active magnetic regenerator
Innovative heating system
Building energy flexibility
Demand-side management
Building thermal energy storage
Building thermal inertia
Indoor thermal mass
Indoor content
Furniture
Phase change material
Building simulation

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PHD_Hicham_Johra_E-pdfForlagets udgivne version, 19,2 MB

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1 Afsluttet

EnovHeat Project
Johra, H.
01/02/2014 → 31/01/2018
Projekter: Projekt › Forskning

Can We Solve the Air Conditioning Paradox?
Hicham Johra
15/03/2023
1 element af Mediedækning
Presse/medie
Ph.d.-grad
Hicham Johra
30/06/2018
1 element af Mediedækning
Presse/medie

1 Tidsskriftartikel

Influence of internal thermal mass on the indoor thermal dynamics and integration of phase change materials in furniture for building energy storage: A review
Johra, H. & Heiselberg, P. K., 2017, I: Renewable & Sustainable Energy Reviews. 69, March, s. 19-32
Publikation: Bidrag til tidsskrift › Tidsskriftartikel › Forskning › peer review

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100 Citationer (Scopus)

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Citationsformater

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title = "Integration of a magnetocaloric heat pump in energy flexible buildings",

abstract = "To prevent future energy crisis and tackle the problems of climate change, modern society must promote a radical evolution in our energy systems. The building sector, and in particular its heating needs, have clearly been identified as one of the main targets for the reduction of the global energy usage. In addition, buildings are a key actor for the development of renewable energy sources.The main objective of this research study is to investigate and demonstrate the possibility of integrating an innovative magnetocaloric heat pump in a single-family house under Danish weather conditions. Moreover, the study includes a numerical analysis to increase the understanding of the heating energy flexibility potential of residential buildings using thermal storage in the indoor environment.",

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year = "2018",

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AB - To prevent future energy crisis and tackle the problems of climate change, modern society must promote a radical evolution in our energy systems. The building sector, and in particular its heating needs, have clearly been identified as one of the main targets for the reduction of the global energy usage. In addition, buildings are a key actor for the development of renewable energy sources.The main objective of this research study is to investigate and demonstrate the possibility of integrating an innovative magnetocaloric heat pump in a single-family house under Danish weather conditions. Moreover, the study includes a numerical analysis to increase the understanding of the heating energy flexibility potential of residential buildings using thermal storage in the indoor environment.

KW - Magnetocaloric heat pump

KW - Magnetic heating

KW - Active magnetic regenerator

KW - Innovative heating system

KW - Building energy flexibility

KW - Demand-side management

KW - Building thermal energy storage

KW - Building thermal inertia

KW - Indoor thermal mass

KW - Indoor content

KW - Furniture

KW - Phase change material

KW - Building simulation

KW - Magnetocaloric heat pump

KW - Magnetic heating

KW - Active magnetic regenerator

KW - Innovative heating system

KW - Building energy flexibility

KW - Demand-side management

KW - Building thermal energy storage

KW - Building thermal inertia

KW - Indoor thermal mass

KW - Indoor content

KW - Furniture

KW - Phase change material

KW - Building simulation

M3 - PhD thesis

T3 - Ph.d.-serien for Det Ingeniør- og Naturvidenskabelige Fakultet, Aalborg Universitet

PB - Aalborg Universitetsforlag

ER -

Integration of a magnetocaloric heat pump in energy flexible buildings

Abstract

Bibliografisk note

Emneord

Adgang til dokumentet

AUB Link

Fingeraftryk

Projekter

EnovHeat Project

Presse/Medier

Can We Solve the Air Conditioning Paradox?

Ph.d.-grad

Publikation

Influence of internal thermal mass on the indoor thermal dynamics and integration of phase change materials in furniture for building energy storage: A review

Citationsformater