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MÄTNING AV LUFTTÄTHET I FLERBOSTADSHUS : <em>Gällande krav, praktiskt genomförda mätningar samt en tillämpbar metod</em>Sörensen, Ida January 2009 (has links)
<p>Stor förvirring råder kring hur lufttätheten ska mätas i flerbostadshus. De metoder som finns och de resultat som erhålls vid täthetsprovning av småhus är inte alltid applicerbara på flerbostadshus även om mätenheterna är de samma. Detta föranleder problemställningen för detta examensarbete:</p><p><em>Varför och hur kontrolleras lufttätheten i ett flerbostadshus på ett praktiskt tillämpbart sätt, som också gör det möjligt att jämföra resultat från olika objekt?</em></p><p>Metoderna som används för att undersöka detta är litteraturstudier och samtal med erfarna personer, samt demonstration av en mätmetod i fullskala. En diskussion med initiativtagarna till detta examensarbete leder fram till en rekommenderad metod och en mall för hur detta ska utföras.</p><p>Byggnadsskalets luft-, diffusions- och vindtätning har stor betydelse för en byggnads energianvändning, fuktsäkerhet, termiska komfort och hygien, luftkvalitet, ljudmiljö, spridning av brand samt spridning av luftföroreningar utifrån och in. Lufttätheten är en avgörande faktor både för konstruktionens beständighet och för en god innemiljö i moderna byggnader. Lufttäta hus är dessutom lönsamma i längden för de inblandade aktörerna. På lång sikt även för miljön. Studier som gjorts visar att en byggnads energiåtgång för uppvärmning minskar med nästan 30 % om lufttätheten (egentligen luftgenomsläppligheten) förbättras från 0,8 l/s·m<sup>2</sup> till 0,4 l/s·m<sup>2</sup>. En så stor minskning av energianvändningen kunde inte åstadkommas med andra energiförbättringsåtgärder som undersöktes.</p><p>I Boverkets Regelsamling för byggande, BBR 2008 har kravet på lufttäthet tagits bort till förmån för ett funktionskrav för energianvändningen, under vilken lufttätheten faller in. Regelsamlingens allmänna råd hänvisar till standarden, SS-EN 13829 för bestämning av luftläckage.</p><p>De metoder som idag finns att tillgå för att mäta lufttätheten hos byggnader är spårgasmetoden, täthetsprovning med provisorisk vägg, det egna ventilationssystemet, med mottryck i angränsande utrymmen samt med tryckdörr. Den sistnämnda metoden provades på flerbostadshus i Umeå med goda resultat.</p><p>Observera att resultatet för denna rapport är en mall för mätningsförfarandet och den rekommenderade metoden för att mäta lufttäthet inom NCC i Umeå. Den beskriver en praktiskt tillämpbar metod där resultatet går att jämföra mellan olika objekt. Även en intern mätstorhet som beskriver ytterväggens täthet är framtagen.</p><p>Mätstorheten och standardens relevans diskuteras. Ändringen i BBR från specificerade krav till funktionskrav anses vara kunskapsdrivande. Det förfarande som beskrivs i resultatet har bedömts vara det mest optimala under rådande förhållanden med den standard som finns. En förändring av standarden skulle kunna leda till en bättre metod som ger mer informativt resultat.</p> / <p>There is a great perplexity about how air permeability should be measured in multiple-unit dwellings. The methods available and the obtained results for determination of air permeability in single-dwelling houses are not applicable for multiple-unit dwellings, even if the derived quantities are the same. This causes the problem for this report:</p><p><em>Why and how should the air permeability be determined for a multiple-unit dwelling in a functional and applicable way, which also makes it possible to compare the obtained results from different dwelling units?</em></p><p>The methods used to explore solutions are literature studies, conversation with professionals and a full-scale demonstration of one of the methods. A discussion with the initiators of this report leads to the recommended method and a model for how it should be performed.</p><p>The air-, diffusion- and windtightness of the building envelope are of big importance to the building. The use of energy, moisture transfer, thermal comfort and hygiene, air quality, noise, spreading of fire and spreading of air pollutions are all affected by it. The air tightness is a crucial element for the durability of the building and to secure a good indoor environment. Air tight buildings are also cost-effective in the long run for the involved participants. They are also good for the environment. A study that have been made show that the energy-use for heating buildings will be reduced with almost 30 % if the air permeability improves from 0,8 l/s·m<sup>2</sup> to 0,4 l/s·m<sup>2</sup>. Such a big reduction of the energy use could not be accomplished with any other energy improvement-move that was investigated in the study.</p><p>The Swedish building regulations, Boverkets Regelsamling för byggande BBR, used to have a demand for the air tightness of buildings. It has been removed in favor of a demand of the function for the energy use, which also include the air tightness. The common advices in BBR refer to the standard, SS-EN 13829 for determination of air permeability.</p><p>The methods available for determination of air permeability in buildings are the tracer-gas method, determination with a temporary wall, the ventilation system, with corresponding pressure in adjacent spaces and determination with a Blower Door. The last method was demonstrated in multiple-unit dwellings in Umeå, Sweden, with good results.</p><p>Note that the result of this report is a methodology and how the method should be performed within buildings erected by NCC in Umeå. It describes a functional and applicable method where the results can be compared between different objects. An internal quantity which describes the air permeability of the external wall has been developed.</p><p>A discussion of the relevance if the derived quantity and the standard has been made. The change in BBR to demands of the function for the energy use has been considered to be a driving force for knowledge. The procedure described in the results has been considered to be the optimum procedure for existing conditions with the standard available. A change in the standard would lead to a better method which would give more informative results.</p>
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MÄTNING AV LUFTTÄTHET I FLERBOSTADSHUS : Gällande krav, praktiskt genomförda mätningar samt en tillämpbar metodSörensen, Ida January 2009 (has links)
Stor förvirring råder kring hur lufttätheten ska mätas i flerbostadshus. De metoder som finns och de resultat som erhålls vid täthetsprovning av småhus är inte alltid applicerbara på flerbostadshus även om mätenheterna är de samma. Detta föranleder problemställningen för detta examensarbete: Varför och hur kontrolleras lufttätheten i ett flerbostadshus på ett praktiskt tillämpbart sätt, som också gör det möjligt att jämföra resultat från olika objekt? Metoderna som används för att undersöka detta är litteraturstudier och samtal med erfarna personer, samt demonstration av en mätmetod i fullskala. En diskussion med initiativtagarna till detta examensarbete leder fram till en rekommenderad metod och en mall för hur detta ska utföras. Byggnadsskalets luft-, diffusions- och vindtätning har stor betydelse för en byggnads energianvändning, fuktsäkerhet, termiska komfort och hygien, luftkvalitet, ljudmiljö, spridning av brand samt spridning av luftföroreningar utifrån och in. Lufttätheten är en avgörande faktor både för konstruktionens beständighet och för en god innemiljö i moderna byggnader. Lufttäta hus är dessutom lönsamma i längden för de inblandade aktörerna. På lång sikt även för miljön. Studier som gjorts visar att en byggnads energiåtgång för uppvärmning minskar med nästan 30 % om lufttätheten (egentligen luftgenomsläppligheten) förbättras från 0,8 l/s·m2 till 0,4 l/s·m2. En så stor minskning av energianvändningen kunde inte åstadkommas med andra energiförbättringsåtgärder som undersöktes. I Boverkets Regelsamling för byggande, BBR 2008 har kravet på lufttäthet tagits bort till förmån för ett funktionskrav för energianvändningen, under vilken lufttätheten faller in. Regelsamlingens allmänna råd hänvisar till standarden, SS-EN 13829 för bestämning av luftläckage. De metoder som idag finns att tillgå för att mäta lufttätheten hos byggnader är spårgasmetoden, täthetsprovning med provisorisk vägg, det egna ventilationssystemet, med mottryck i angränsande utrymmen samt med tryckdörr. Den sistnämnda metoden provades på flerbostadshus i Umeå med goda resultat. Observera att resultatet för denna rapport är en mall för mätningsförfarandet och den rekommenderade metoden för att mäta lufttäthet inom NCC i Umeå. Den beskriver en praktiskt tillämpbar metod där resultatet går att jämföra mellan olika objekt. Även en intern mätstorhet som beskriver ytterväggens täthet är framtagen. Mätstorheten och standardens relevans diskuteras. Ändringen i BBR från specificerade krav till funktionskrav anses vara kunskapsdrivande. Det förfarande som beskrivs i resultatet har bedömts vara det mest optimala under rådande förhållanden med den standard som finns. En förändring av standarden skulle kunna leda till en bättre metod som ger mer informativt resultat. / There is a great perplexity about how air permeability should be measured in multiple-unit dwellings. The methods available and the obtained results for determination of air permeability in single-dwelling houses are not applicable for multiple-unit dwellings, even if the derived quantities are the same. This causes the problem for this report: Why and how should the air permeability be determined for a multiple-unit dwelling in a functional and applicable way, which also makes it possible to compare the obtained results from different dwelling units? The methods used to explore solutions are literature studies, conversation with professionals and a full-scale demonstration of one of the methods. A discussion with the initiators of this report leads to the recommended method and a model for how it should be performed. The air-, diffusion- and windtightness of the building envelope are of big importance to the building. The use of energy, moisture transfer, thermal comfort and hygiene, air quality, noise, spreading of fire and spreading of air pollutions are all affected by it. The air tightness is a crucial element for the durability of the building and to secure a good indoor environment. Air tight buildings are also cost-effective in the long run for the involved participants. They are also good for the environment. A study that have been made show that the energy-use for heating buildings will be reduced with almost 30 % if the air permeability improves from 0,8 l/s·m2 to 0,4 l/s·m2. Such a big reduction of the energy use could not be accomplished with any other energy improvement-move that was investigated in the study. The Swedish building regulations, Boverkets Regelsamling för byggande BBR, used to have a demand for the air tightness of buildings. It has been removed in favor of a demand of the function for the energy use, which also include the air tightness. The common advices in BBR refer to the standard, SS-EN 13829 for determination of air permeability. The methods available for determination of air permeability in buildings are the tracer-gas method, determination with a temporary wall, the ventilation system, with corresponding pressure in adjacent spaces and determination with a Blower Door. The last method was demonstrated in multiple-unit dwellings in Umeå, Sweden, with good results. Note that the result of this report is a methodology and how the method should be performed within buildings erected by NCC in Umeå. It describes a functional and applicable method where the results can be compared between different objects. An internal quantity which describes the air permeability of the external wall has been developed. A discussion of the relevance if the derived quantity and the standard has been made. The change in BBR to demands of the function for the energy use has been considered to be a driving force for knowledge. The procedure described in the results has been considered to be the optimum procedure for existing conditions with the standard available. A change in the standard would lead to a better method which would give more informative results.
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Budoucnost brněnského výstaviště / Brno Trade Fairs FutureKnot, Tomáš January 2018 (has links)
The theme of my diploma thesis is reconstruction of old exhibition hall “B” of BVV Trade Fairs Brno which is located at Křižkovského street near BVV gate no. 4. The exhibition hall is converted to multifunctional sports hall. This function is result of complex urban analysis, which was theme of winter semester thesis of the academic year 2017/2018. The exhibition hall gets a new curtain wall facade. Curtain wall sustains of steel construction and semi-transparent polycarbonate panels. The study converts rooms according to new usage of the hall. There are smaller halls for indoor sports, dividable central hall, tribunes, bars, locker rooms, roof wellness and outdoor multifunctional playgrounds at the roof of the hall. The study takes advantage of uncommon technical solutions of the hall. For example bridge crane which is newly used as carrying construction for LED multimedia cube.
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Sportovní centrum ve Zlíně / Sports Centre in ZlínStudený, Marek January 2019 (has links)
The diploma thesis deals with project documentation for the realization of the sports centre in Zlín. Object is located on the edge of the city Zlín in build-up area of the sports halls. Object is defined from two sides by major roads, that are connected with family and residential buildings. Building site of the object is sligtly sloping, however with ground adapting adjusts into seeming flat land. The hall is devided on three operation parts. First and dominant unit is formed by gaming area with grandstrand, corresponding facilities included. Second unit is formed by mountaineering wall, corresponding included. Third unit is formed by bar, corresponding facilities included. Object is drafted with consideration of the Baťas architecture. Object is designed like a skeleton construction with combinated system of frames. Main supporting vertical construction of skeleton is designed from reinforced prefabricated concrete column. Main supporting horizontal construction of skeleton is designed like a system solution slimfloor, that is based on placing prestressed segment onto bottom side of a special beam Deltabeam. Within the main supporting construction is designed stifenner and construction of grandstrand as well, maid from reinforced prefabricard concrete. Sheathing of the object is combinated. From the second floor is designed system from thermal insulated sandwich panels, which is anchored into the pre-set steel construction. Roof is designed as a flat roof with trapezoidal metal sheet with thermal insulation and waterproofing layer made from m-PVC. Fillings of the object including light curtain wall is designed from system Schüco.
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Penzion Amerika / Boarding House AmerikaPokorný, Patrik Unknown Date (has links)
This diploma thesis elaborates project documentation for the construction of building. The building is situated in outskirts of the town Velké Meziříčí. The boarding house for fooding and lodging with separated private zone and restaurant. Both parts connect entrance hall with reception and communication spaces. The lodging section is divided into three stories. Ground floor restaurant and salon with terrace on the second floor have south-facing oriented glazed curtain wall. That is the main part of building with stunning views on the ambient nature.
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Bytový dům ve Vsetíně - stavebně technologická příprava / Residential house in Vsetin - construction-technological preparationSelníková, Klára January 2013 (has links)
I occupy with selected parts of the technological prepariation of building proces of a residential building in Vsetín in my diploma thesis. The building will be used for housing and retailing. The project is composed of eight building objects, while the main building structure is designed in detail. The subject of this thesis is the preparation of the technical report of the building, the treatise of the main technological stages, the design of the building site, the design of the main building machinery, the technology solutions including HSF and CTP, the construction budget, the time and financial planning of the construction and the specialization in the field of civil engineering.
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Elizabeth - Muzeum Motorsportu / Elizabeth - Museum of MotorsportFilgasová, Tereza January 2015 (has links)
Diploma thesis, that cover project documentation of building part of the new build museum of motosport. The object include two above grand floors without basement. Ground plan consist of four mutually adjacent rectangles. On the first floor is an exhibicion space of the museum. Second floor provides space for the administrative part of museum. The building is covered with a flat green roof and is designed as a reinforced concrete skeleton. The facade is composed of the curtaim wall
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Knihovnické informační centrum / Library Information CenterBoreš, Jiří January 2015 (has links)
Thesis "Library Information Centre" is processed in the form of detailed project documentation containing all requirements in accordance with applicable standards and regulations. The proposed building is designed as a four-storey building shape of a rounded rectangular triangle with dimensions of 33.5 x 33.5 m, which is a full basement. The building is used for administration, services and information centers. In 1PP is located technical facilities, warehouses and supply. On the 1st floor there is space for services and administration. In the 2nd floor-3rd floor spaces are located Information Center. In the last nadzemím floor space technical background. The building is based on a baseplate. Used a support system is a combined structural system of walls and columns. The building is designed with an offset raster light curtain wall system complete with sun protection. The object is implemented to suit the requirements of the wheelchair. For the object will be set up areas for landscaping and furniture for visitors to the building. On the southwest side of the parking lot will be built with 39 stalls including 5 places for the disabled with a reduced pavement. In the Northeast will be built with 44 parking spaces for cars.
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Knihovna v Českých Budějovicích / Library in České BudějoviceErnst, Oliver January 2016 (has links)
Diploma thesis deals with a project of a new building of a new science library building. The building has four floors and basement. The building will be located in České Budějovice town. The building fulfills the function of the study of books and technical standards. There is designed spaces for organizing lectures and refreshments in cafeteria in the first floor of the building. Library space made available barrier free. Its architectural design resembles the shape of an open book. The structural system meets modern trends in construction and architecture, and it does not interfere with the surrounding buildings.
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Univerzitní knihovna / University LibrarySubally, Pavel January 2016 (has links)
The content of this diploma project is to design an university library in the city of Brno, Czech Republic. The object is designed as multistory building with underground stories included. The design is created based on requests brought by the investor and includes architectural, constructional and technological proposes for the building. The aim is to create not only a modern cultural and educational center but also a place of entertainment and relax for students of Vysoké Učení Technické. During the design it is taken in an account the request of having the auditorium and lecture rooms available for public, also.
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