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Soubor řadových NED domů pro bydlení - lokalita "vinohrady" ve Vážanech nad Litavou / A set of row attached low energy houses for living in Vážany nad LitavouPfleger, Jaroslav January 2013 (has links)
Diploma´s thesis “ A set of row attached low energy houses for living in Vážany nad Litavou ” is elaborated in form of project documentation which includes all requirements of given standards. The object is placed on plat number 1746 in cadastral community Vážany nad Litavou. The character of the object is brick building. The building is covered gabled roof. It is two-floor house with no cellar. There is living room, kitchen, bedroom with it´s own sanitary facility and technical room in the ground floor. There are bedrooms with sanitary facilities in the second floor. The thesis is worked up as a complete implementation building plan.
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Studium vlivu konstrukčních systémů na energetickou náročnost staveb / Study of the influence of structural systems for the energy performance of buildingsDus, Tomáš January 2015 (has links)
The theme of the diploma thesis is study the influence of structural systems for the energy performance of buildings. The thesis compares designed and measured values of the energy consumption of selected buildings with different bearing structure materials beside the results from numerical modeling of energy consumption.
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Návrh otopného systému pro nízkoenergetický rodinný dům / Design of heating system for low-energy family houseKytýrová, Zdeňka January 2008 (has links)
This diploma thesis deals with the design of a heating system for a "low-energy" house. It is conceived as a low temperature system using a combination of radiators and underfloor heating. The design is supplemented with a calculation of heat loss, a proposal of needed components, a scheme of the system and means of regulation. The second part solves the heat source selection. A solar system with vacuum tubes is used as the primary source. The second one is an electrical water heater located in the accumulation reservoir for the hot domestic water. Necessary calculations for the design of the solar system, together with a scheme and means of regulation, are enclosed in this section.
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Smart City objekty a jejich oceňování / Smart City Buildings and their ValuationUheríková, Eliška January 2017 (has links)
The diploma thesis focuses on specification of standard type buildings and Smart City buildings differences. Thesis also contain a history part of individual buildings category, including their specification. The aim of thesis is to determine designs for changes of building valuation in Smart City standard. Theoretical part contains basic definition and limitation of terms from civil engineering branch and structural types, summary of historical development of houses and evaluation by cost method, most common used experience. Practical part is focused on calculation. According real houses cost of three detached houses in Smart standard, there are calculated new price ratio which enter into cost method valuation. Their effectiveness is verified together with newly design adaptation of cost method valuation on next five detached houses in Smart standard.
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Architektonický výraz obytných staveb energeticky efektivní výstavby / Architectural expression of residential buildings in energy-efficient housingGerö, Jiří January 2013 (has links)
These days create an enormous pressure on energy savings because of their high prices. For future it is obvious that their prices will grow. Not only the representatives of European Union realize this fact, but basicaly common people who run their houses and pay the bills. For this reason low - energy houses respectively passive houses are in the limelight. Reasons of economy should not be the only criterion of quality, but its integral part, one of several components. Energy efficient housing is a response in architecture and building to turbulent global warming. The aim of the work is try to specify how to conceive an efficient building with respect to its architectural quality in the contect of directions coming from European Union and which should be implemented soon in the Czech republic. Will zero house become driving force of architecture in Europe in 21st century? The result of the work will be useful in orientation how to conceive an efficient house with respect to its aesthetical quality.
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Life cycle assessment of the semidetached passive house "Röda lyktan" in northern Sweden : A comparison between the construction phase and the use phase / Livscykelanalys av det tvådelade passivhuset "Röda lyktan" i norra Sverige : En jämförelse mellan konstruktionsfasen och användningsfasenSvensson, Michelle January 2013 (has links)
This report is a life cycle assessment of a relatively newly built semidetached passive house/low energy house located in Östersund/Jämtland. The analysis concentrates on the building materials in the construction phase and the energy in the use phase for 50 years. The construction phase include frame, foundation, interior and exterior walls, ceiling and roof, middle floor structure, floor coverings, interior and exterior doors, windows, interior staircase with banisters, stove and FTX-ventilation system. The inventory to obtain the volume of each material has been made with the help of blueprints and interviews. The inventory of the use phase has been made using measurements from a parallel study by Itai Danielski of the energy use in the house (Danielski, Svensson & Fröling, 2013). The database Ecoinvent has been used to get a result for the volume and energy values. The inventory data is allocated and the characterization methods GWP, CED (cumulative energy demand) and USEtox are used. The aim of this study was to compare the construction phase with the use phase to see which phase that has the highest energy values and environmental impact. Another goal was to examine which materials in the construction phase that has the highest embodied energy and environmental impact. The result shows that in a comparison between the construction phase and the use phase, and when considering the parameters included in this study, the use phase has the highest values for global warming potentials (around 54 %), cumulative energy demand (around 80 %), ecotoxicity (around 56 %), human non-carcinogenic toxicity (around 77 %) and total human toxicity (around 75 %). The construction phase has the highest values for human carcinogenic toxicity (around 57 %). Even if the use phase has the highest values in most categories the construction phase also has high values. As buildings become more energy efficient and with increasing use of renewable energy, the construction phase becomes more important from an environmental perspective. This means that the material choices which are made in passive houses become increasingly important if passive houses should be considered to be environmentally friendly also in the future. The study also shows that the FTX-ventilation system, some of the insulation materials (with cellular plastic sheets and rock wool in top), metals (with sheet metal roofing of steel in top), glued laminated timber and wood fiber boards have some of the highest values of environmental impact and the highest embodied energy. These materials should in future buildings be considered, if possible, to be replaced with materials with less environmental impact. / Den här rapporten är en livscykelanalys av ett relativt nybyggt passivhus/lågenergihus som också är ett parhus (ett hus delat i två separata lägenheter) beläget i Östersund/Jämtland. Analysen koncentrerar sig på byggnadsmaterialen i konstruktionsfasen och energin i användningsfasen under 50 år. Konstruktionsfasen inkluderar stomme, grund, inner- och ytterväggar, inner- och yttertak, mellanbjälklag, golvbeklädnader, inner- och ytterdörrar, fönster, invändig trappa med trappräcke, kamin och FTX-ventilationssystem. Inventeringen för att få fram volymen på varje material har gjorts med hjälp av ritningar och intervjuer. Inventeringen av användningsfasen har gjorts med hjälp av mätvärden från en parallell studie av Itai Danielski på energianvändningen i huset (Danielski, Svensson & Fröling, 2013). Databasen Ecoinvent har sedan använts för att få fram ett resultat för volym- och energivärdena. Inventeringsdatan är allokerad och karaktäriseringsmetoderna GWP (globalt uppvärmingspotential), CED (kumulativt energibehov) och USEtox (toxicitet) har använts. Målet med studien är att jämföra konstruktionsfasen med användningsfasen för att kunna se vilken fas som har högst energivärden och miljöpåverkan. Målet är också att undersöka vilka material i konstruktionsfasen som har högst förkroppsligad energi och miljöpåverkan, i syftet att eventuellt kunna byta ut vissa material till miljövänligare alternativ, för att få ett miljövänligare hus i framtida liknande byggnationer. Resultaten visar att i en jämförelse mellan konstruktionsfasen och användningsfasen, och med hänsyn till de parametrar som ingår i studien, att användningsfasen har de högsta värdena för globalt uppvämingspotential (runt 54 %), kumulativt energibehov (runt 80 %), ekotoxicitet (runt 56 %), human icke-cancerogen toxicitet (runt 77 %) och total human toxicitet (runt 75 %). Konstruktionsfasen har högst värden för human cancerogen toxicitet (runt 57 %). Även om användningsfasen har högst värden i de flesta kategorierna så har även konstruktionsfasen höga värden. Ju mer energieffektiva husen blir och med en ökad användning av energi från förnyelsebara källor, desto viktigare blir konstruktionsfasen ur ett miljöperspektiv. Det betyder att materialvalen som görs i huset blir väldigt viktiga om passivhus ska fortsätta anses som miljövänliga även i framtiden. Denna studie visar också att FTX-ventilationssystemet, några av isoleringsmaterialen (med cellplasten och stenullen i topp), metallerna (med plåttaket av stål i topp), limträbalkar och träfiberskivor har några av de högsta värdena av miljöpåverkan och den högsta förkroppsligade energin. Dessa material borde i framtida byggnationer övervägas att om möjligt ersättas med andra material med mindre miljöpåverkan.
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Návrh teplovzdušného vytápění a větrání nízkoenergetického domku / Design of warm air heating system for low-energy houseKoutník, Martin January 2008 (has links)
The diploma thesis deals with design of warm air heating and ventilating system for low energy house. Introduction of this thesis is focused on dividing residential buildings by their heat requirement. Then problems of residential building ventilation and possibilities of warm air heating systems including heat recovery are presented. In the next chapter summary of ventilating units with heat recovery and warm air heating units for residential low energy buildings and pasive family houses is presented. Calculation of low energy house heat losses, which is solved, is based on CSN 06 0210, CSN 73 0540 and CSN EN 12831 standards. Design and calculation of warm air heating and ventilation system and ground heat exchangers is also described. Floor heating system, fireplace insert and solar heating system are designed as supplementary systems. At the end of this thesis the control system is presented. Project documentation is enclosed in appendix.
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Teplovzdušný vytápěcí a větrací systém pro nízkoenergetický rodinný dům / Warm-air heating and ventilating system for low-energy family houseMusil, Zdeněk January 2012 (has links)
The diploma thesis deals with warm-air heating and ventilation system of energyefficient family house. The part of thesis is theoretical introduction to low-energy and passive houses, ventilation and heating. The proposal itself is based on the applicable standards and includes all progressive steps, including the calculation of the thermal performance and sizing individual parts of the system. The drawing project documentation is listed in appendixes.
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Optimalizace nákladů životního cyklu rodinných domů / Optimization of life cycle costs of family housesServusová, Michaela January 2022 (has links)
The theoretical part deals at the beginning with wooden buildings and suitable materials. Then information about low energy houses, passive houses and requirements for new buildings is introduced. The theoretical part of the work also summarizes the selection of the technological solution. Important part is about individual life cycle stages of the building, wear and tear of the buildings and whole life costs of the building that the investor is interested in. Practical part of the thesis consists of a case study of the wooden family house where the whole life costs of the building life cycle are solved.
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Vliv architektonického konceptu na potřebu tepla na vytápění energeticky úsporných budov pro bydlení. / Impact of the architectural concept on the energy consumption of heating of the energy-saving residential buildingsKřeček, David January 2012 (has links)
Human efforts to increase their comfort rise in density of population in congested city areas, rapid growth of traffic and electric smog created due to constantly transforming communication technologies all resulted in an increase of stress in the immediate human environment. All of this, along with frequent reports about changes in global climate, gradually contributes to an alteration of thinking of the whole society, which is forced to face the consequences of economic damages caused by climatic changes. If we want to tenably assert adequate economic and social living conditions, we have to approach the natural environment in a more profound way. In accordance with the trend of substantional development for the purpose of enhancement of the quality of the living environment in the field of building industry, it is logical to concentrate on buildings, which are conceptually focused on saving of the energy. That is on energy-efficient houses. Pathway to sustainable building is not based on discovering one or several multipurpose technological solutions, but on usage of new designing principles, new materials and methods of processing them as well as new techniques of construction. For an effective creation of a building concept it is essential to have that kind of device which quickly responds to changes performed on a design, enables an easier work on variants and produces the most accurate results. Consistent application of energy optimizing methods is necessary particularly for designs of energy saving houses. Beginning efficient building design is the most “abstract factor of concept linked with very uncertain inputs,” because a lot of parameters in that moment is still unknown. Many mutually connected factors are invoked during designing passive house e.g. trajectory of the sun and the shielding effect of the surroundings, the aspect of sunlight and interior lighting, power quality construction, etc. Currently, the architect has no choice, he can use only well-known precepts, such as large windows are facing the South not the North. Unfortunately this "empirical formula" for the design of a real passive house is not enough. And yet the first draft of the house is most affected by not only its shape, form, but user´s comfortable, cost, feasibility and future energy behavior of buildings and related operating costs of the house too. It is obvious that this stage should not be underestimated, because “minor variation of the initial inputs greatly influence the outcomes.” With this reasoning, the work focuses on early stage design decision, i.e. the architectural concept of a passive house (an idea, vision). Therefore the aim of this work is to simplify the issue into understandable form, i.e. the creation of relatively simple and illustrative sketches, which generalize the issue satisfactorily, show the individual parameters (glazing, shading, shape, size, etc.) and change need of heat for heating passive house. The results of the work will be useful when the architect picks up the pencil and starts to think about his future house. At this point, he will have on hand sketches, which give him an idea and streamline his further design. Therefore the main goal is to create new outcomes and identify energy behaviour of buildings with a computational tool. This research works with virtual idealized mathematical model in the software PHPP 2007 CZ and uses "phenomenon" of parametric equations and sensitivity analysis.
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