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31	Исследование тепловой и экологической эффективности работы оборудования цеха №1 минераловатных плит завода «Эковер» : магистерская диссертация / Research of thermal and ecological performance of the workshop №1 equipment of the mineral-wool plates plant «Ekover» Kholzakov, D. A., Холзаков, Д. А. January 2014 (has links) In the thesis researches of overall performance of the polymerization furnace of Uralasbest plant are executed. The existing thermal scheme and a design of the furnace is considered, thermal calculation is carried out and technical solutions on improvement of thermal and ecological characteristics of the furnace operation are proposed. Researches showed that ecological characteristics mineral-wool production doesn't satisfy to requirements to environmental standards, and for decrease in emissions of nitrogen oxides more effective burner system is proposed. On the basis of the executed measurements and balance calculations technical actions on decrease in thermal losses with the leaving gases are offered. / В диссертации выполнены исследования эффективности работы печи полимеризации цеха ОАО «Ураласбест». Рассмотрена существующая тепловая схема и конструкция печи, проведен тепловой расчет и предложены технические решения по совершенствованию тепловых и экологических характеристик работы печи. Исследования показали, что с точки зрения экологических характеристик минераловатное производство не соответствует требованиям к экологическим нормам, и для снижения выбросов оксидов азота предложена более эффективная горелочных система..На основе выполненных измерений и балансовых расчетов предложены технические мероприятия по снижения тепловых потерь с уходящими газами. MASTER'S THESIS MINERAL-WOOL PRODUCTION POLYMERIZATION FURNACE THERMAL BALANCE GASES CIRCULATION THERMAL LOSSES ENVIRONMENTAL STANDARDS ПЕЧЬ ПОЛИМЕРИЗАЦИИ ТЕПЛОВОЙ БАЛАНС ЦИРКУЛЯЦИЯ ГАЗОВ ТЕПЛОВЫЕ ПОТЕРИ ЭКОЛОГИЧЕСКИЕ НОРМЫ ВЫБРОСЫ ОКСИДОВ АЗОТА EMISSIONS OF NITROGEN OXIDES
32	Circular economy strategy for mineral wool wastes : potential secondary raw material for Alkali Activated Materials (AAMs) / Cirkulär ekonomi strategi för mineralullsavfall : potentiell sekundär råvara för Alkali-aktiverade Material (AAM) Zhao, Shuning January 2021 (has links) By recycling and reusing materials to close the resource cycle and move towards a circular economy, waste can be significantly reduced. At the same time, cities and regions offer opportunities to practice circular economy. As the main source of waste in the EU, the construction industry needs to both improve the recycling rate and find alternatives with a lower carbon footprint. Mineral wool waste is often considered non-recyclable, but the disposal of landfill will no longer be suitable in the medium to long term. At the same time, mineral wool can react with the alkaline activator to generate alkali activated concrete (AA concrete), which can be used as a substitute for cement concrete. This study is conducted on building typology to track mineral wool from individual building levels in Swiss dwellings over time and space. Afterward, Geographic Information System (GIS) was used to select the suitable location for establishing a mineral wool recycling plant, considering accessibility and transportation distance. Finally, using the life-cycle assessment (LCA) framework, emissions are calculated through the production phase. The results revealed that the mineral wool stock shows an increasing trend from 2020 to 2035, and can provide a stable supply. In addition, using mineral wool waste to produce AA concrete can effectively reduce CO2 emissions. Therefore, mineral wool waste has the potential to become raw material for alkali-activated materials (AAMs). Recycling factories can be set up in Zug, Zurich, and Bern as a priority. The recycling of mineral wool can be seen as a practical application of the circular economy strategy in the framework of urban planning. Circular Economy Construction and Demolition Waste Mineral Wool AAMs GIS LCA Cirkulär Ekonomi Bygg- och rivningsavfall mineralull AAM GIS LCA Building Technologies Husbyggnad Environmental Sciences Miljövetenskap Metallurgy and Metallic Materials Metallurgi och metalliska material
33	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 användningsfasen Svensson, 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. Passiv house low energy house LCA life cycle assessment insulation rock wool (mineral wool) cellular plastic sheets (polystyrene) GWP global warming potentials CED cumulative energy demand USEtox toxicity Jämtland Östersund Passivhus lågenergihus LCA livscykelanalys isolering stenull (mineralull) cellplast(polystyren) GWP global uppvärmningspotential CED kumulativt energibehov USEtox toxicitet Jämtland Östersund
34	Dům pro seniory ve Velkém Poříčí / Retirement center in Velké Poříčí Vondrová, Michaela January 2020 (has links) It is about new-built Retirement center standing alone in the cadaster unit of the town Velké Poříčí. The building has four- floors without basement. It is located in flat terrain near the river in quiet location. The house is built as letter L form. The Retirement center is adapt for disabled people. In the first floor is dining room, doctor´s office, part for employees and technical facilities for house. In the second and third floors are apartments. There are 12 single rooms for one person, 6 single rooms for pair with sleeping in one room and 4 apartments for couple with separated bedroom. In the fourth floor is access to roof terrace. The structural systém of the building is composed of precast concrete frame by Prefa, infill wall from ceramic masonry. Vertical structures are built by prestressed concrete floor slab Spiroll. The building has ventilated facade with mineral wool with facade cladding. The roof is warm flat roof with half intensive green roof.
35	Vývoj nového samonosného zateplovacího systému s ohledem na dynamické namáhání / Development of a new self-supporting insulation system with respect to dynamic stress Machala, David January 2014 (has links) This diploma thesis deals with suggestion of self-supporting insulating system that can be used for objects which insulating is more or less complicated. In this thesis are theoretically processed information about insulation systems while focus is on their structure, composition and principle of operation. Further, there is theoretically designed self-supporting insulating system which is practically built after theoretically composed testing for finding its basic properties. The most appropriate process of realization is formulated at the end after evaluation of the individual tests.
36	Sportovní centrum / Sports center Rohlena, Jan January 2017 (has links) The objective of the present thesis is to design a sports center and provide the relevant design documentation for it. The designed building is situated on a flat plot in Hradec Králové which is intended as a building plot or a sports/relax area. The designed sports center is a two-level building without cellar with a flat roof. The building foundations are designed as foundation strips, mainly from plain concrete. The external, loadbearing, and partition walls are designed with clay blocks POROTHERM. The floor structure is designed with prestressed concrete floor slabs SPIROLL. The thermal insulation is resolved with ventilated facade with facade panels. CEMBRIT SOLID. The building is divided into three individual functional units with one shared entrance. It consists of two sports halls with facilities designed for sportsmen and staff, and a gym together with the facilities for costumers. A restaurant and a kitchen are situated in the second floor.
37	Vliv provedení zateplení bytového domu na výdaje spojené s provozem této nemovitosti / The impact of executing new thermal insulation on a apartment building on the expenses associated with its operation Machová, Petra Unknown Date (has links) The topic of the diploma thesis „The impact of executing new thermal insulation on a apartment building on the expenses associated with its operation “ is a draft and appraisal of four variants of thermal insulation of the building. The thesis deals with the assessment of the current proposal for apartment building envelopes along with proposing alternative plans with emphasis on reducing heating costs. The first section describes the types of buildings according to heating demand and a list of different variants of thermal insulation materials. The second part is devoted to a specific apartment building in the Ústí nad Labem for which there are designed in four variants of insulation. The work includes thermal assessment in original condition and the assessment of new condition modified by adding thermal insulation. Through research will bedetermined price of implementation of proposed insulation options together with the costs of operation of the apartment building. In conclusion, the diploma thesis evaluates the payback period of insulation.
38	Återanvändning av kemiska riskbedömningar : Förutsättningar, fördelar och svårigheter. / Reuse of chemical risk assessments : Prerequisites, advantages and difficulties. Larsen, Anna January 2019 (has links) Kemiska arbetsmiljörisker förekommer inom ett flertal branscher och behöver förebyggas för att skydda arbetstagare mot ohälsa, sjukdom och olycksfall. Det förebyggande arbetet görs genom att identifierade risker bedöms och kontrolleras med ändamålsenliga åtgärder, med målet att riskerna minskar eller helt försvinner. Att genomföra kemiska riskbedömningar är dock ofta både svårt och komplext med många olika aspekter att beakta och kräver både tid och kunskap. Som ett sätt att förenkla och effektivisera processen kring kemisk riskbedömning önskar Skanska, ett företag inom bygg- och anläggningsbranschen, se över om det är möjligt att återanvända kemiska riskbedömningar. Syftet med detta examensarbete blev därmed att utreda möjligheten i återanvändning av redan genomförda kemiska riskbedömningar där de kemiska produkterna ska användas igen. Utredningen har fokuserat på fördelar, hinder eller svårigheter och förutsättningar för återanvändning. Europeiskt och svenskt regelverk och vetenskaplig litteratur har genomlysts och data har samlats in från intervjuer med olika nyckelpersoner på tre arbetsplatser inom Skanska samt utifrån riskbedömningar av några utsedda produkter. Resultatet har därefter jämförts med svenskt regelverk, för att därigenom dra slutsatser om möjligheten i återanvändning av kemiska riskbedömningar. Examensarbetet har resulterat i slutsatsen att återanvändning av kemiska riskbedömningar bör vara möjlig, under förutsättning att de mallar eller checklistor som används som stöd uppfyller de krav som finns för kemisk riskbedömning. Det behöver säkerställas genom ändamålsenliga rutiner av personal med rätt kompetens om kemiska arbetsmiljörisker. Det behöver också stämmas av att exempelvis arbetssätt, omgivning och tillgången av åtgärder är likvärdiga på den arbetsplats som först genomfört riskbedömningen, och den arbetsplats som därefter återanvänder riskbedömningen, eller att dessa faktorer kan bli likvärdiga genom vidtagna åtgärder. Några risker eller hinder för återanvändning har identifierats. En av de mest framträdande riskerna är att kemiska arbetsmiljörisker förbises i samband med återanvändningen och därigenom också de åtgärder som behöver vidtas. Orsaker till detta kan vara bristande kunskap och engagemang eller möjligen fusk och slarv. I situationer där arbete ska ske med farligare kemiska produkter kan det vara svårare med återanvändning av riskbedömningar. Några fördelar med återanvändning bedöms vara förkortad tidsåtgång för kemiska riskbedömningar, en effektivare hantering, samt ett ökat stöd och lärande om kemiska arbetsmiljörisker genom att man lär av varandra och tidigare riskbedömningar. Möjligen kan återanvändning också bidra till att fler riskbedömningar genomförs, för att därigenom trygga yrkesarbetarnas säkerhet och hälsa. / Chemical risks in the work environment occur in several industries, and need to be prevented to protect workers from ill-health, illness and accidents. By performing risk assessments and taking appropriate measures, it is possible to reach the goal to reduce or even eliminate chemical risks. However, performing chemical risk assessments is often a quite difficult and complex issue with several different aspects to consider, requiring both time and knowledge. As a way to simplify and streamline the process of chemical risk assessment, Skanska, a company within the construction industry, wants to investigate whether it is possible to reuse chemical risk assessments. The purpose of this thesis was thus to investigate the possibility of reusing already performed chemical risk assessments in situations where the chemical products will be used again. The investigation has focused on the advantages, obstacles or difficulties and prerequisites for reuse. European and Swedish regulations and scientific literature have been reviewed and data have been collected from interviews with managers, safety representatives and employees at three workplaces at Skanska and from performed risk assessments of some selected products. Thereafter, the results have been compared with Swedish regulations, in order to draw conclusions about the possibility of reusing chemical risk assessments. The conclusion is that it should be possible to reuse chemical risk assessments, provided that the templates or checklists used as a support meet the requirements for chemical risk assessments. This needs to be ensured through appropriate routines by personnel with the right expertise about chemical risks in the work environment. It must also be ensured that some factors, as way of working, the work environment and measures taken, need to be similar for the workplace first performing the risk assessment, and the workplace that will reuse the same risk assessment, or at least that these factors can become similar after measures taken. Some risks or obstacles of reusing chemical risk assessments have been identified. One of the most prominent risks is that chemical hazards will be missed and thereby also the measures that need to be taken. This may be due to lack of knowledge and commitment or possibly cheating or carelessness. In situations where more hazardous chemical products are being used, it may be more difficult to reuse risk assessments. Some benefits of reusing risk assessments may be less time required for chemical risk assessments, more efficient management and increased support and learning about chemical hazards by learning from each other and previous risk assessments. Possibly, reuse can also contribute to more risk assessments being carried out, thereby ensuring the safety and health of professional workers. Chemical risk assessment chemical hazard risk working environment occupational safety and health construction industry reuse recycling advantages obstacles difficulties prerequisites factors KemiRisk work preparation template checklist mineral wool thermosetting plastic diisocyanate Kemisk riskbedömning kemisk arbetsmiljörisk risk arbetsmiljö bygg- och anläggningsbranschen återanvändning fördelar hinder svårigheter förutsättningar krav faktorer åtgärder KemiRisk arbetsberedning mall checklista mineralull härdplast diisocyanat Arbetsmedicin och miljömedicin
39	Novostavba hotelu u Přehrady / Hotel "U Prehrady" Černý, Dávid January 2018 (has links) The subject of this diploma thesis was to process the study and the design documentation for a newly built hotel in Brno, in city district “Kníničky” near the artificial dam “Přehrada” in a rest area. The hotel will serve as temporary accommodation for up to 64 hotel guests in single, double and four bed rooms. The object also contains training rooms, offices, a meeting room, a café, a small grocery store and a restaurant with kitchen. Parking is possible in one of the two mass garages and there is an outdoor parking possibility in front of the hotel too. The building has a cast-in-place concrete frame with longitudinal beams and sway bracings. The external wall consists of aerated concrete bricks with contact thermal insulation system ETICS (insulation material mineral wool), the ceilings will be cast-in-place reinforced concrete ceilings and the roof flat green roof or flat roof with gravel on it above the 5th floor. The foundation construction consists of reinforced concrete foundation strips, which expand to foundation pads under the load-bearing columns and will be supported by piled foundations under the most exposed elements. As long as the hotel is situated into a fairly steep slope, the vertical alignment of some building parts is various so part of the project is the design of landscaping works. Design documentation was processed using the program AutoCAD 2017, the study and the visualization using both SketchUp 2015, LayOut 2015 and Lumion 5.
40	Sportovně relaxační centrum / Sports and wellness center Libřický, Zdeněk January 2018 (has links) The final thesis is focused on the design and elaboration of the project documentation of the sports and relaxation center. The proposed building is located in the south-eastern part of the town of Hradec Králové, in a location supposed for buildings and areas of sports and relaxation use. It is a three-storey building with a flat roof and partial basement. The construction system is wall-mounted with a combination of skeleton. The building is based on plain concrete and reinforced concrete foundation footing. The peripheral, supporting and partition walls are designed from ceramic blocks POROTHERM. The inner load-bearing elements consist mainly of reinforced concrete columns. The ceiling structure is designed from reinforced concrete slabs supported locally. The perimeter walls of the first overground floor and part of the perimeter walls of the basement are insulated by an external contact thermal insulation system. The thermal insulation of the perimeter walls of the second floor is designed by means of a ventilated facade with facade tiles except the squash courts and the relaxation area. The building is functionally divided into three main parts, where the central part forms an entrance hall with comunication spaces of all floors. In this part a basement with technical facilities is designed. The right part of the ground floor consists of a restaurant with a bowling alley and a kitchen with storage and hygienic facilities. As part of this section, a gym and exercise rooms for fitness exercises, spinning and TRX are designed on the second floor. The left part consists of two squash courts with the appropriate facilities and massage areas. There is also a relaxing facilities with a north-facing terrace on the second floor. There are also dressing rooms and hygienic facilities. The designed object is accessible for disabled people. There is a parking lot for 40 cars, 3 motorcycles, one bus and three barracks for cars.

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