Examensarbete Byggnadsteknik
Most of the energy required by residential buildings is for low temperature heat. Often this demand is met by the use of high quality energy sources such as fossil fuels and electricity. The energy analysis alone does not take into account the quality of energy and so it hides the real potential for...
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creator | Prandin Mosè , KTH, Byggnadsteknik Prandin Mosè, KTH, Construction Technology |
description | Most of the energy required by residential buildings is for low temperature heat. Often this
demand is met by the use of high quality energy sources such as fossil fuels and electricity.
The energy analysis alone does not take into account the quality of energy and so it hides the
real potential for the so-called energy savings. Thus the concept of exergy must be involved.
In particular the low-exergy approach shows that the energy with low exergy level has to be
supplied with energy with similar exergy content.
Consequently, the problem is shifted to find energy sources suitable for this purpose. The
electricity can be exploited with low exergy losses with high-COP heat pumps. Instead the
use of fossil fuels for thermal purposes should be avoided.
One of the possibilities is the energy cascade. In this solution the energy flow is used several
times, despite its quality decreases with each step, before being discharged into the
environment. Thus the use of the district heating from cogeneration for the space heating
seems to be an interesting choice. The issues connected to the cogeneration exploitation force
to shift the boundary layers of the analysis from the building to the community level.
In this work different solutions to meet the electricity and heat demands of a community of
houses have been compared. The aim is to show that the results obtained from the low-ex
approach allow an effective reduction of fuel consumption through a more rational use of the
resources. The comparison was addressed initially in steady-state case and then with the use
of the software HOMER also for the dynamic case. To achieve reliable results, this required
that the annual profiles for thermal and electrical demand of the reference community are
modelled to represent the actual loads as closely as possible. Finally, for each case taken into
account, the total consumption, the energy and the exergy efficiencies have been calculated.
Självständigt arbete på avancerad nivå (yrkesexamen)
30 poäng / 45 hp
Självständigt arbete på avancerad nivå (yrkesexamen)
30 poäng / 45 hp
Most of the energy required by residential buildings is for low temperature heat. Often this
demand is met by the use of high quality energy sources such as fossil fuels and electricity.
The energy analysis alone does not take into account the quality of energy and so it hides the
real potential for the so-called energy savings. Thus the concept of exergy must be involved.
In particular the low-exergy app |
format | Web Resource |
fullrecord | <record><control><sourceid>europeana_1GC</sourceid><recordid>TN_cdi_europeana_collections_9200111_BibliographicResource_1000086006593</recordid><sourceformat>XML</sourceformat><sourcesystem>PC</sourcesystem><sourcerecordid>9200111_BibliographicResource_1000086006593</sourcerecordid><originalsourceid>FETCH-europeana_collections_9200111_BibliographicResource_10000860065933</originalsourceid><addsrcrecordid>eNrjZJBxrUjMTc0rTixKSi1JVXCqTE_PS0wpLknNzsvM5mFgTUvMKU7lhdLcDB5uriHOHrqppUX5BamJeYnxyfk5OanJJZn5ecXxlkYGBoaGhvFOmUk5mfnpRYkFGZnJQanF-aVFyanxhgZAYGFmYGBmamlsTEWjACHKQD4</addsrcrecordid><sourcetype>Aggregation Database</sourcetype><iscdi>true</iscdi><recordtype>web_resource</recordtype></control><display><type>web_resource</type><title>Examensarbete Byggnadsteknik</title><source>Europeana Collections</source><creator>Prandin Mosè , KTH, Byggnadsteknik ; Prandin Mosè, KTH, Construction Technology</creator><creatorcontrib>Prandin Mosè , KTH, Byggnadsteknik ; Prandin Mosè, KTH, Construction Technology</creatorcontrib><description>Most of the energy required by residential buildings is for low temperature heat. Often this
demand is met by the use of high quality energy sources such as fossil fuels and electricity.
The energy analysis alone does not take into account the quality of energy and so it hides the
real potential for the so-called energy savings. Thus the concept of exergy must be involved.
In particular the low-exergy approach shows that the energy with low exergy level has to be
supplied with energy with similar exergy content.
Consequently, the problem is shifted to find energy sources suitable for this purpose. The
electricity can be exploited with low exergy losses with high-COP heat pumps. Instead the
use of fossil fuels for thermal purposes should be avoided.
One of the possibilities is the energy cascade. In this solution the energy flow is used several
times, despite its quality decreases with each step, before being discharged into the
environment. Thus the use of the district heating from cogeneration for the space heating
seems to be an interesting choice. The issues connected to the cogeneration exploitation force
to shift the boundary layers of the analysis from the building to the community level.
In this work different solutions to meet the electricity and heat demands of a community of
houses have been compared. The aim is to show that the results obtained from the low-ex
approach allow an effective reduction of fuel consumption through a more rational use of the
resources. The comparison was addressed initially in steady-state case and then with the use
of the software HOMER also for the dynamic case. To achieve reliable results, this required
that the annual profiles for thermal and electrical demand of the reference community are
modelled to represent the actual loads as closely as possible. Finally, for each case taken into
account, the total consumption, the energy and the exergy efficiencies have been calculated.
Självständigt arbete på avancerad nivå (yrkesexamen)
30 poäng / 45 hp
Självständigt arbete på avancerad nivå (yrkesexamen)
30 poäng / 45 hp
Most of the energy required by residential buildings is for low temperature heat. Often this
demand is met by the use of high quality energy sources such as fossil fuels and electricity.
The energy analysis alone does not take into account the quality of energy and so it hides the
real potential for the so-called energy savings. Thus the concept of exergy must be involved.
In particular the low-exergy approach shows that the energy with low exergy level has to be
supplied with energy with similar exergy content.
Consequently, the problem is shifted to find energy sources suitable for this purpose. The
electricity can be exploited with low exergy losses with high-COP heat pumps. Instead the
use of fossil fuels for thermal purposes should be avoided.
One of the possibilities is the energy cascade. In this solution the energy flow is used several
times, despite its quality decreases with each step, before being discharged into the
environment. Thus the use of the district heating from cogeneration for the space heating
seems to be an interesting choice. The issues connected to the cogeneration exploitation force
to shift the boundary layers of the analysis from the building to the community level.
In this work different solutions to meet the electricity and heat demands of a community of
houses have been compared. The aim is to show that the results obtained from the low-ex
approach allow an effective reduction of fuel consumption through a more rational use of the
resources. The comparison was addressed initially in steady-state case and then with the use
of the software HOMER also for the dynamic case. To achieve reliable results, this required
that the annual profiles for thermal and electrical demand of the reference community are
modelled to represent the actual loads as closely as possible. Finally, for each case taken into
account, the total consumption, the energy and the exergy efficiencies have been calculated.</description><language>eng ; swe</language><creationdate>2010</creationdate><oa>free_for_read</oa><woscitedreferencessubscribed>false</woscitedreferencessubscribed></display><links><openurl>$$Topenurl_article</openurl><openurlfulltext>$$Topenurlfull_article</openurlfulltext><thumbnail>$$Tsyndetics_thumb_exl</thumbnail><linktohtml>$$Uhttps://data.europeana.eu/item/9200111/BibliographicResource_1000086006593$$EHTML$$P50$$Geuropeana$$Hfree_for_read</linktohtml><link.rule.ids>780,38517,76176</link.rule.ids><linktorsrc>$$Uhttps://data.europeana.eu/item/9200111/BibliographicResource_1000086006593$$EView_record_in_Europeana$$FView_record_in_$$GEuropeana$$Hfree_for_read</linktorsrc></links><search><creatorcontrib>Prandin Mosè , KTH, Byggnadsteknik</creatorcontrib><creatorcontrib>Prandin Mosè, KTH, Construction Technology</creatorcontrib><title>Examensarbete Byggnadsteknik</title><description>Most of the energy required by residential buildings is for low temperature heat. Often this
demand is met by the use of high quality energy sources such as fossil fuels and electricity.
The energy analysis alone does not take into account the quality of energy and so it hides the
real potential for the so-called energy savings. Thus the concept of exergy must be involved.
In particular the low-exergy approach shows that the energy with low exergy level has to be
supplied with energy with similar exergy content.
Consequently, the problem is shifted to find energy sources suitable for this purpose. The
electricity can be exploited with low exergy losses with high-COP heat pumps. Instead the
use of fossil fuels for thermal purposes should be avoided.
One of the possibilities is the energy cascade. In this solution the energy flow is used several
times, despite its quality decreases with each step, before being discharged into the
environment. Thus the use of the district heating from cogeneration for the space heating
seems to be an interesting choice. The issues connected to the cogeneration exploitation force
to shift the boundary layers of the analysis from the building to the community level.
In this work different solutions to meet the electricity and heat demands of a community of
houses have been compared. The aim is to show that the results obtained from the low-ex
approach allow an effective reduction of fuel consumption through a more rational use of the
resources. The comparison was addressed initially in steady-state case and then with the use
of the software HOMER also for the dynamic case. To achieve reliable results, this required
that the annual profiles for thermal and electrical demand of the reference community are
modelled to represent the actual loads as closely as possible. Finally, for each case taken into
account, the total consumption, the energy and the exergy efficiencies have been calculated.
Självständigt arbete på avancerad nivå (yrkesexamen)
30 poäng / 45 hp
Självständigt arbete på avancerad nivå (yrkesexamen)
30 poäng / 45 hp
Most of the energy required by residential buildings is for low temperature heat. Often this
demand is met by the use of high quality energy sources such as fossil fuels and electricity.
The energy analysis alone does not take into account the quality of energy and so it hides the
real potential for the so-called energy savings. Thus the concept of exergy must be involved.
In particular the low-exergy approach shows that the energy with low exergy level has to be
supplied with energy with similar exergy content.
Consequently, the problem is shifted to find energy sources suitable for this purpose. The
electricity can be exploited with low exergy losses with high-COP heat pumps. Instead the
use of fossil fuels for thermal purposes should be avoided.
One of the possibilities is the energy cascade. In this solution the energy flow is used several
times, despite its quality decreases with each step, before being discharged into the
environment. Thus the use of the district heating from cogeneration for the space heating
seems to be an interesting choice. The issues connected to the cogeneration exploitation force
to shift the boundary layers of the analysis from the building to the community level.
In this work different solutions to meet the electricity and heat demands of a community of
houses have been compared. The aim is to show that the results obtained from the low-ex
approach allow an effective reduction of fuel consumption through a more rational use of the
resources. The comparison was addressed initially in steady-state case and then with the use
of the software HOMER also for the dynamic case. To achieve reliable results, this required
that the annual profiles for thermal and electrical demand of the reference community are
modelled to represent the actual loads as closely as possible. Finally, for each case taken into
account, the total consumption, the energy and the exergy efficiencies have been calculated.</description><fulltext>true</fulltext><rsrctype>web_resource</rsrctype><creationdate>2010</creationdate><recordtype>web_resource</recordtype><sourceid>1GC</sourceid><recordid>eNrjZJBxrUjMTc0rTixKSi1JVXCqTE_PS0wpLknNzsvM5mFgTUvMKU7lhdLcDB5uriHOHrqppUX5BamJeYnxyfk5OanJJZn5ecXxlkYGBoaGhvFOmUk5mfnpRYkFGZnJQanF-aVFyanxhgZAYGFmYGBmamlsTEWjACHKQD4</recordid><startdate>2010</startdate><enddate>2010</enddate><creator>Prandin Mosè , KTH, Byggnadsteknik</creator><creator>Prandin Mosè, KTH, Construction Technology</creator><scope>1GC</scope></search><sort><creationdate>2010</creationdate><title>Examensarbete Byggnadsteknik</title><author>Prandin Mosè , KTH, Byggnadsteknik ; Prandin Mosè, KTH, Construction Technology</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-europeana_collections_9200111_BibliographicResource_10000860065933</frbrgroupid><rsrctype>web_resources</rsrctype><prefilter>web_resources</prefilter><language>eng ; swe</language><creationdate>2010</creationdate><toplevel>online_resources</toplevel><creatorcontrib>Prandin Mosè , KTH, Byggnadsteknik</creatorcontrib><creatorcontrib>Prandin Mosè, KTH, Construction Technology</creatorcontrib><collection>Europeana Collections</collection></facets><delivery><delcategory>Remote Search Resource</delcategory><fulltext>fulltext_linktorsrc</fulltext></delivery><addata><au>Prandin Mosè , KTH, Byggnadsteknik</au><au>Prandin Mosè, KTH, Construction Technology</au><format>book</format><genre>unknown</genre><ristype>GEN</ristype><btitle>Examensarbete Byggnadsteknik</btitle><date>2010</date><risdate>2010</risdate><abstract>Most of the energy required by residential buildings is for low temperature heat. Often this
demand is met by the use of high quality energy sources such as fossil fuels and electricity.
The energy analysis alone does not take into account the quality of energy and so it hides the
real potential for the so-called energy savings. Thus the concept of exergy must be involved.
In particular the low-exergy approach shows that the energy with low exergy level has to be
supplied with energy with similar exergy content.
Consequently, the problem is shifted to find energy sources suitable for this purpose. The
electricity can be exploited with low exergy losses with high-COP heat pumps. Instead the
use of fossil fuels for thermal purposes should be avoided.
One of the possibilities is the energy cascade. In this solution the energy flow is used several
times, despite its quality decreases with each step, before being discharged into the
environment. Thus the use of the district heating from cogeneration for the space heating
seems to be an interesting choice. The issues connected to the cogeneration exploitation force
to shift the boundary layers of the analysis from the building to the community level.
In this work different solutions to meet the electricity and heat demands of a community of
houses have been compared. The aim is to show that the results obtained from the low-ex
approach allow an effective reduction of fuel consumption through a more rational use of the
resources. The comparison was addressed initially in steady-state case and then with the use
of the software HOMER also for the dynamic case. To achieve reliable results, this required
that the annual profiles for thermal and electrical demand of the reference community are
modelled to represent the actual loads as closely as possible. Finally, for each case taken into
account, the total consumption, the energy and the exergy efficiencies have been calculated.
Självständigt arbete på avancerad nivå (yrkesexamen)
30 poäng / 45 hp
Självständigt arbete på avancerad nivå (yrkesexamen)
30 poäng / 45 hp
Most of the energy required by residential buildings is for low temperature heat. Often this
demand is met by the use of high quality energy sources such as fossil fuels and electricity.
The energy analysis alone does not take into account the quality of energy and so it hides the
real potential for the so-called energy savings. Thus the concept of exergy must be involved.
In particular the low-exergy approach shows that the energy with low exergy level has to be
supplied with energy with similar exergy content.
Consequently, the problem is shifted to find energy sources suitable for this purpose. The
electricity can be exploited with low exergy losses with high-COP heat pumps. Instead the
use of fossil fuels for thermal purposes should be avoided.
One of the possibilities is the energy cascade. In this solution the energy flow is used several
times, despite its quality decreases with each step, before being discharged into the
environment. Thus the use of the district heating from cogeneration for the space heating
seems to be an interesting choice. The issues connected to the cogeneration exploitation force
to shift the boundary layers of the analysis from the building to the community level.
In this work different solutions to meet the electricity and heat demands of a community of
houses have been compared. The aim is to show that the results obtained from the low-ex
approach allow an effective reduction of fuel consumption through a more rational use of the
resources. The comparison was addressed initially in steady-state case and then with the use
of the software HOMER also for the dynamic case. To achieve reliable results, this required
that the annual profiles for thermal and electrical demand of the reference community are
modelled to represent the actual loads as closely as possible. Finally, for each case taken into
account, the total consumption, the energy and the exergy efficiencies have been calculated.</abstract><oa>free_for_read</oa></addata></record> |
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title | Examensarbete Byggnadsteknik |
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