Low Energy Source Synthetic Thermal Energy Storage (STES)

Veronika Sipkova; Jiri Labudek; Otakar Galas

doi:10.4028/www.scientific.net/AMR.899.143

Paper Titles

Experimental Measurements and Numerical Simulations of Dynamic Thermal Performance of External Timber Frame Wall
p.126

Hot Water Temperature Drop in a Pipe as a Parameter in Order to Define Operation Time of a Circulation Loop in Domestic Hot Water Distribution System
p.131

Impact of Façade Colouring on Temperature and Light Conditions of Buildings, Housing Estates, and Environment
p.135

Improvements of Energy Balance of Existing Residential Buildings
p.139

Low Energy Source Synthetic Thermal Energy Storage (STES)
p.143

Numerical Analysis and Measurement Results of a Window Sill
p.147

Optimization of Swimming Pool Hall's Envelope with Respect to Thermal and Moisture Design
p.151

Possibilities of Simulations in the Planning of the Retrofit of Historical Double Skin Windows
p.155

The Impact of the Choice of Computational Methods on the Results of Simulations of Specific Heat Consumption for Heating a Family House
p.161

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Low Energy Source Synthetic Thermal Energy Storage (STES)

Abstract:

The team of Building environment in VŠB-Technical university of Ostrava works intensively on options in long-term accumulation of heat in underground storages. The new concept follows the Directive of the European Parliament and of the Council 2010/31/EU on the energy performance of buildings [1]. The Directive requires that energy should be extensively covered of renewable sources produced at or in the vicinity of building, where it will be consumed. The aim of the research is create thermal energy storage with model structure for complex of family house. For the storage will be used recycled materials especially recycled concrete. This system will be heat source in winter period and heat consumer in summer period.

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Periodical:

Advanced Materials Research (Volume 899)

Pages:

143-146

DOI:

https://doi.org/10.4028/www.scientific.net/AMR.899.143

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Online since:

February 2014

Authors:

Veronika Sipkova*, Jiri Labudek, Otakar Galas

Keywords:

Heat Gain, Recycled Concrete, Underground Heat Storage

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References

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