Energy saving options for industrial furnaces - the example of the glass industry

S.467-476 In the industrial sector approximately 30 % of the fuels used are consumed by furnaces. On top of that, 10 % of the industrial electricity demand is used in furnaces. Prior studies on industrial furnaces and ovens have concluded that potential for efficiency improvements lie between 10 and...

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Main Authors: Frassine, Clemens, Rohde, Clemens, Hirzel, Simon
Format: Conference Object
Language:English
Published: 2016
Subjects:
industrial processes
Glass
furnaces
Norway
Iceland
Online Access:https://publica.fraunhofer.de/handle/publica/394884
id ftfrauneprints:oai:publica.fraunhofer.de:publica/394884
record_format openpolar
spelling ftfrauneprints:oai:publica.fraunhofer.de:publica/394884 2023-05-15T16:51:25+02:00 Energy saving options for industrial furnaces - the example of the glass industry Frassine, Clemens Rohde, Clemens Hirzel, Simon 2016 https://publica.fraunhofer.de/handle/publica/394884 en eng European Council for an Energy-Efficient Economy (ECEEE Industrial Summer Study) 2016 eceee Industrial Summer Study 2016. Proceedings https://publica.fraunhofer.de/handle/publica/394884 industrial processes Glass furnaces conference paper 2016 ftfrauneprints 2022-11-01T20:27:45Z S.467-476 In the industrial sector approximately 30 % of the fuels used are consumed by furnaces. On top of that, 10 % of the industrial electricity demand is used in furnaces. Prior studies on industrial furnaces and ovens have concluded that potential for efficiency improvements lie between 10 and 40 % depending on the sector and the application. Within our paper we will describe an approach to assess the future energy demand of industrial furnaces. In addition, the corresponding CO2-emissions and saving potentials will be determined. The timeframe of our analysis is from 2015 to 2030 considering the EU-28 countries and Switzerland, Norway and Iceland. To show the application of our methodology, we will present the glass sector as a case study. There, we will analyse the saving options corresponding to the furnaces used in glassmaking processes. For the purpose of our study we have built a proprietary bottom-up simulation model for energy demand. We will present the underlying methodology and data of our modelling approach. The dataset represents a detailed representation of the EUs glass production sites. Therefore, we are able to model the diffusion of the efficiency technologies on a site level. In parallel, we will present an approach to derive a dataset from sources like the ETS register. Finally, we will present the results of our modelling approach and discuss the potential impacts of energy efficiency technologies in the glass sector. Furthermore we will show the transferability of our approach to other sectors. Conference Object Iceland Publikationsdatenbank der Fraunhofer-Gesellschaft Norway
institution Open Polar
collection Publikationsdatenbank der Fraunhofer-Gesellschaft
op_collection_id ftfrauneprints
language English
topic industrial processes
Glass
furnaces
spellingShingle industrial processes
Glass
furnaces
Frassine, Clemens
Rohde, Clemens
Hirzel, Simon
Energy saving options for industrial furnaces - the example of the glass industry
topic_facet industrial processes
Glass
furnaces
description S.467-476 In the industrial sector approximately 30 % of the fuels used are consumed by furnaces. On top of that, 10 % of the industrial electricity demand is used in furnaces. Prior studies on industrial furnaces and ovens have concluded that potential for efficiency improvements lie between 10 and 40 % depending on the sector and the application. Within our paper we will describe an approach to assess the future energy demand of industrial furnaces. In addition, the corresponding CO2-emissions and saving potentials will be determined. The timeframe of our analysis is from 2015 to 2030 considering the EU-28 countries and Switzerland, Norway and Iceland. To show the application of our methodology, we will present the glass sector as a case study. There, we will analyse the saving options corresponding to the furnaces used in glassmaking processes. For the purpose of our study we have built a proprietary bottom-up simulation model for energy demand. We will present the underlying methodology and data of our modelling approach. The dataset represents a detailed representation of the EUs glass production sites. Therefore, we are able to model the diffusion of the efficiency technologies on a site level. In parallel, we will present an approach to derive a dataset from sources like the ETS register. Finally, we will present the results of our modelling approach and discuss the potential impacts of energy efficiency technologies in the glass sector. Furthermore we will show the transferability of our approach to other sectors.
format Conference Object
author Frassine, Clemens
Rohde, Clemens
Hirzel, Simon
author_facet Frassine, Clemens
Rohde, Clemens
Hirzel, Simon
author_sort Frassine, Clemens
title Energy saving options for industrial furnaces - the example of the glass industry
title_short Energy saving options for industrial furnaces - the example of the glass industry
title_full Energy saving options for industrial furnaces - the example of the glass industry
title_fullStr Energy saving options for industrial furnaces - the example of the glass industry
title_full_unstemmed Energy saving options for industrial furnaces - the example of the glass industry
title_sort energy saving options for industrial furnaces - the example of the glass industry
publishDate 2016
url https://publica.fraunhofer.de/handle/publica/394884
geographic Norway
geographic_facet Norway
genre Iceland
genre_facet Iceland
op_relation European Council for an Energy-Efficient Economy (ECEEE Industrial Summer Study) 2016
eceee Industrial Summer Study 2016. Proceedings
https://publica.fraunhofer.de/handle/publica/394884
_version_ 1766041530587414528

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