This HTML5 document contains 26 embedded RDF statements represented using HTML+Microdata notation.

The embedded RDF content will be recognized by any processor of HTML5 Microdata.

Namespace Prefixes

PrefixIRI
n10http://linked.opendata.cz/resource/domain/vavai/cep/soutez/
n8http://linked.opendata.cz/resource/domain/vavai/cep/kategorie/
dctermshttp://purl.org/dc/terms/
n2http://linked.opendata.cz/resource/domain/vavai/cep/projekt/MSM/
n11http://linked.opendata.cz/resource/domain/vavai/cep/aktivita/
n3http://linked.opendata.cz/ontology/domain/vavai/
n4http://linked.opendata.cz/resource/domain/vavai/cep/obor/
n12http://linked.opendata.cz/resource/domain/vavai/cep/druh-souteze/
n13http://linked.opendata.cz/resource/domain/vavai/cep/smlouva/34668/
n5http://linked.opendata.cz/resource/domain/vavai/cep/faze/
rdfhttp://www.w3.org/1999/02/22-rdf-syntax-ns#
n9http://linked.opendata.cz/resource/domain/vavai/cep/typ/
n6http://linked.opendata.cz/resource/domain/vavai/cep/poskytovatel/
xsdhhttp://www.w3.org/2001/XMLSchema#

Statements

Subject Item
n2:7E12091
rdf:type
n3:Projekt
dcterms:description
The objective of this project is to develop new innovative products and advanced test methods for a next generation of compact combined renewable energy systems based on solar thermal and heat pump technology for space heating and hot water preparation, using breakthroughs in ICT, new materials and technology. The goal is to achieve 25% energy savings compared to current state of the art systems, with still competitive prices on the market. Thus, the work proposed aims for a seasonal performance factor of the system (solar and heat pump) of e.g. 6 as compared to 4.5 for the current state of the art. This will be possible by using new materials, components and ICT in an integrative approach for new system concepts where the focus is on the overall system's cost and performance. A systematic approach will be used to evaluate new breakthroughs such as e.g. low-cost materials and selective paint for solar collectors that collect solar irradiation as well as ambient heat and PV/T collectors that produce heat as well as electricity. Exergetic optimization of heat pump circuits includes using de-superheating heat exchangers for DHW preparation as a by-product of the more efficient space heating operation, and variable speed controlled compressors for heat pumps that match the collector heat input to the evaporator and/or the demand. New storage concepts include phase change materials (PCM) on the cold side of the heat pump, low cost materials for storage tank construction, improved temperature stratification and charging/discharging control. On the control and ICT side, weather and user forecast based predictive control for intelligent storage charging by different heat sources will help to increase the overall system performance significantly. Online monitoring and fault detection within small controller units will be used to increase system reliability both for the insta llation phase and for the whole operational life of the installation. The objective of this project is to develop new innovative products and advanced test methods for a next generation of compact combined renewable energy systems based on solar thermal and heat pump technology for space heating and hot water preparation, using breakthroughs in ICT, new materials and technology. The goal is to achieve 25% energy savings compared to current state of the art systems, with still competitive prices on the market. Thus, the work proposed aims for a seasonal performance factor of the system (solar and heat pump) of e.g. 6 as compared to 4.5 for the current state of the art. This will be possible by using new materials, components and ICT in an integrative approach for new system concepts where the focus is on the overall system's cost and performance. A systematic approach will be used to evaluate new breakthroughs such as e.g. low-cost materials and selective paint for so lar collectors that collect solar irradiation as well as ambient heat and PV/T collectors that produce heat as well as electricity. Exergetic optimization of heat pump circuits includes using de-superheating heat exchangers for DHW preparation as a by-product of the more efficient space heating operation, and variable speed controlled compressors for heat pumps that match the collector heat input to the evaporator and/or the demand. New storage concepts include phase change materials (PCM) on the cold side of the heat pump, low cost materials for storage tank construction, improved temperature stratification and charging/discharging control. On the control and ICT side, weather and user forecast based predictive control for intelligent storage charging by different heat sources will help to increase the overall system performance significantly. Online monitoring and fault detection within small controller units will be used to increase system reliability both for the install ation phase and for the whole operational life of the installation.
dcterms:title
New materials and control for a next generation of compact combined solar and heat pump systems with boosted energetic and exergetic performance New materials and control for a next generation of compact combined solar and heat pump systems with boosted energetic and exergetic performance
n3:cislo-smlouvy
n13:2012-32
n3:dalsi-vedlejsi-obor
n4:JR
n3:druh-souteze
n12:RP
n3:faze
n5:54620275
n3:hlavni-obor
n4:JE
n3:vedlejsi-obor
n4:JB
n3:id-aktivity
n11:7E
n3:id-souteze
n10:
n3:kategorie
n8:3
n3:klicova-slova
solar system; heat pump
n3:konec-reseni
2015-12-31+01:00
n3:pocet-koordinujicich-prijemcu
0
n3:poskytovatel
n6:MSM
n3:start-reseni
2012-01-02+01:00
n3:statni-podpora
1858
n3:typProjektu
n9:P
n3:uznane-naklady
1858
n3:pocet-prijemcu
1
n3:pocet-spoluprijemcu
0
n3:pocet-vysledku
0
n3:pocet-vysledku-zverejnovanych
0