Global ETD Search

1	Primary energy use of residential buildings : implications of materials, modelling and design approaches Tettey, Uniben Yao Ayikoe January 2017 (has links) Buildings can play an essential role in the transition to a sustainable society. Different strategies, including improved energy efficiency in buildings, substitution of carbon intensive materials and fuels, efficient energy supply among others can be employed for this purpose. In this thesis, the implications of different insulation materials, modelling and design strategies on primary energy use of residential buildings are studied using life cycle and system perspective. Specifically, the effects of different insulation materials on production primary energy and CO2 emission of buildings with different energy performance are analysed. The results show that application of extra insulation materials to building envelope components reduces the operating primary energy use but more primary energy is required for the insulation material production. This also slightly increases the CO2 emissions from material production. The increases in primary energy use and CO2 emissions are mainly due to the variations in the quantities, types and manufacturing processes of the insulation materials. Thus, choice of renewable based materials with energy efficient manufacturing is important to reduce primary energy use and GHG emissions for building material production. Uncertainties related to building modelling input parameters and assumptions and how they influence energy balance calculations of residential buildings are explored. The implications on energy savings of different energy efficiency measures are also studied. The results show that input data and assumptions used for energy balance simulations of buildings vary widely in the Swedish context giving significant differences in calculated energy demand for buildings. Among the considered parameters, indoor air temperature, internal heat gains and efficiency of ventilation heat recovery (VHR) have significant impacts on the simulated building energy performance as well as on the energy efficiency measures. The impact of parameter interactions on calculated space heating of buildings is rather small but increases with more parameter combinations and more energy efficient buildings. Detailed energy characterisation of household equipment and technical installations used in a building is essential to accurately calculate the energy demand, particularly for a low energy building. The design and construction of new buildings present many possibilities to minimise both heating and cooling demands over the lifecycle of buildings, and also in the context of climate change. Various design strategies and measures are analysed for buildings with different energy performance under different climate scenarios. These include household equipment and technical installations based on best available technology, bypassing the VHR unit, solar shading of windows, combinations of window u- and g-values, different proportions of glazed window areas and façade orientations and mechanical cooling. The results show that space heating and cooling demands vary significantly with the energy performance of buildings as well as climate scenarios. Space heating demand decreases while space cooling demand and the risk of overheating increase considerably with warmer climate. The space cooling demand and overheating risk are more significant for buildings with higher energy performance. Significant reductions are achieved in the operation final energy demands and overheating is avoided or greatly reduced when different design strategies and measures are implemented cumulatively under different climate change scenarios. The primary energy efficiency of heat supply systems depends on the heat production technology and type of fuel use. Analysis of the interaction between different design strategies and heat supply options shows that the combination of design strategies giving the lowest primary energy use for space heating and cooling varies between heat supply from district heating with combined heat and power (CHP) and heat only boilers (HOB). The primary energy use for space heating is significantly lower when the heat supply is from CHP rather than HOB. Operation primary energy use is significantly reduced with slight increase in production primary energy when the design strategies are implemented. The results suggest that significant primary energy reductions are achievable under climate change, if new buildings are designed with appropriate strategies. primary energy use material production simulation input parameters design strategies climate change overheating residential buildings Building Technologies Husbyggnad
2	Forest-Fuel Systems : Comparative Analyses in a Life Cycle Perspective Näslund Eriksson, Lisa January 2008 (has links) Forest fuels can be recovered, stored and handled in several ways and these different ways have different implications for CO2 emissions. In this thesis, comparative analyses were made on different forest-fuel systems. The analyses focused on the recovery and transport systems. Costs, primary energy use, CO2 emissions, storage losses and work environment associated with the use of forest fuel for energy were examined by using systems analysis methodology in a life cycle perspective. The bundle system showed less dry-matter losses and lower costs than the chip system. The difference was mainly due to more efficient forwarding, hauling and large-scale chipping. The potential of allergic reactions by workers did not differ significantly between the systems. In difficult terrain types, the loose material and roadside bundling systems become as economical as the clearcut bundle system. The stump and small roundwood systems showed the greatest increase in costs when the availability of forest fuel decreased. Stumps required the greatest increase in primary energy use. Forest fuels are a limited resource. A key factor is the amount of biomass recovered per hectare. Combined recovery of logging residues, stumps and small roundwood from thinnings from the same forest area give a high potential of reduced net CO2 emissions per hectare of forest land. Compensation fertilization becomes more cost-effective and the primary energy use for ash spreading becomes low – about 0,25‰. The total amount of available forest fuel in Sweden is 66 TWh per year. This would cost 1 billion €2007 to recover and would avoid 6.9 Mtonne carbon if fossil coal were replaced. In southern Sweden almost all forest fuel is obtainable in high-concentration areas where it is easy to recover. When determining potential CO2 emissions avoidance, the transportation distance was found to be less important than the other factors considered in this work. The type of transportation system did not have a significant influence over the CO2 avoided per hectare of forest land. The most important factor analysed here was the type of fossil fuel (coal, oil or natural gas) replaced together with the net amount of biomass recovered per hectare of forest land. Large-scale, long-distance transportation of biofuels from central Sweden has the potential to be cost-effective and also attractive in terms of CO2 emissions. A bundle recovery system meant that more biomass per hectare could be delivered to end-users than a pellet system due to conversion losses when producing pellets. forest fuels recovery systems transportation cost primary energy use CO2 emission forest-fuel potential life cycle perspective Environmental engineering Miljöteknik
3	Comparative life cycle assessment of organic building materials Yossef, Delav, Hot, Dino January 2021 (has links) The ever-increasing awareness of global warming has made the building industry startlooking for alternative building solutions in order to meet the changing demands. Thesechallenges have given rise to organization which aim to go further and construct moresustainable alternatives in the form of Ecovillages. This thesis is conducted in collaborationwith Bysjöstrans Ekoby and aims to investigate what type of organic alternatives exist andhow they perform in building elements.The study was carried out through a comparative LCA where a base case construction forboth roof and wall was established. Followed by comparing different organic materials toeach other and the base case materials in order to determine low-impact materials. The goalwas to replaces as many layers within the structure such as insulation, structure, roofcladding, façade, wind and vapor barrier.This was later followed by combing the materials together in order to identify whichalternative construction options would perform the best in regard to greenhouse gasemissions (CO2 eq kg) and primary energy use (MJ).The results of the study show that the performance or organic materials vary significantly.Whit a lot of materials being better but also worse than traditional materials. It showed thatfor internal wall and roof surface adding clay plater can reduce the GHG emission with 68%, timber frame with 98 %, façade with 43 %, roof cladding with 93 %, vapor barrier with76 % and insulation with 79 %. The best preforming construction option could reduce thebase case emission with 68 %. Organic building material Comparative LCA EN15804 EN15978 OneClick LCA Organic construction solutions CO2 eq Primary energy use Energy Engineering Energiteknik
4	Klimatpåverkan och primärenergianvändning från en multihall i två plan : En livscykelanalys av Hästhagens sporthall i Malmö / Climate impact and primary energy use of a two-level mutli-use sports facility : A life cycle assessment of Hästhagens Sporthall in Malmö Eriksson, Lovisa January 2020 (has links) Till följd av ökade utsläpp av växthusgaser har klimatförändringar blivit ett faktum och ett väldiskuterat ämne världen över. Parallellt med klimatfrågan behöver den allmänna folkhälsan gynnas, och med ett ständigt växande samhälle växer även efterfrågan på fler idrottsanläggningar. Då byggnader står för en betydande del av bidragen till den globala klimatpåverkan och primärenergianvändning blir idrottsanläggningars miljöpåverkan en allt viktigare fråga. Vilka typer av anläggningar som bör byggas för att främja den allmänna folkhälsan samtidigt som miljöpåverkan minimeras är en fråga som fler och fler av Sveriges kommuner börjar diskutera. Att bygga idrottsanläggningar som multihallar i flera plan är ett fenomen som undersöks allt mer och kan möjligen vara en potentiell lösning. Syftet med detta examensarbete var att undersöka miljöpåverkanskategorierna klimatpåverkan och primärenergianvändningen från Hästhagens sporthall i Malmö. Hallen är byggd i två plan och innehåller därmed två fullstora gymnastikhallar staplade på varandra. Miljöpåverkan från denna multihall jämfördes sedan med den från en traditionell sporthall i ett plan. För att analysera miljöpåverkanskategorierna utfördes en livscykelanalys utifrån ISO-standarderna 14040 och 14044, och avgränsningar gjordes utifrån standarden för värdering ochberäkning av byggnaders miljöprestanda, SS-EN 15978:2011. Därmed undersöktes endast modulerna A1-A5 i byggskedet, vilka innefattar produktion av byggmaterial, transport och konstruktion, samt modul B6 som hanterar energiförbrukningen i driftfasen. Materialen som studerades var de som utgör klimatskalet av Hästhagens sporthall och består främst av betong, tegel, isoleringsmaterial och fönster. I driftfasen granskades klimatpåverkan och primärenergianvändningen av fjärrvärme samt fastighets- och verksamhetsel. Resultaten visar att det är produktionen av material i modul A1-A3, samt fjärrvärmen i B6 som har störst utsläpp av CO2-ekvivalenter och därmed bidrar mest till klimatpåverkan. Utslaget på multihallens antagna livslängd på 70 år har byggfasen en något större påverkan än driftfasen, 27 respektive 23 ton CO2-ekvivalenter per år. Vad gäller energianvändning är det driftfasen som brukar majoriteten av primärenergin, 795 GJ per år, vilket är drygt tre gånger mer per år än de 254 GJ som byggfasen använder. I jämförelsen med en traditionell sporthall i ett plan framgår att Hästhagens sporthall i två plan är något mer energieffektiv och har en lägre klimatpåverkan per tillhandahållen aktivitetstimme. Miljöpåverkan från idrottsanläggningar är dock ett förbisett område och det krävs mer forskning för att kunna dra generella slutsatser om huruvida sporthallar i fler plan är mer miljövänliga än traditionella hallar. / Due to the increase in greenhouse gas emissions, the issue of climate change is now a well debated topic worldwide. Simultaneously, the municipalities in Sweden are constantly working on improving the public health and with a growing society the demand for new sports facilities is increasing. Since the construction and operation of buildings contribute to a major part of the global climate impact as well as primary energy use, the environmental impact of sports facilities is an important question. What sorts of buildings that are most beneficial to increase the health of the general public, and at the same time minimizing the environmental impact, is a question that a growing number of municipalities in Sweden are starting to discuss. The aim of this thesis was to examine the climate impact and the primary energy use of Hästhagens sporthall in Malmö. The multi-use sports facility is constructed in two levels, putting two full-sized gymnasiums on top of each other. Its environmental impact was then compared to the impact of a traditional one-level gymnasium. To conduct this analysis, a life cycle assessment was preformed according to the international standards ISO-14040 and 14044, and the definitions and boundaries of the study was set based on the standard SS-EN 15978:2011, defining the calculation method and assessment of environmental performance of buildings. Thus, modules A1-A5, which include production of building materials, transportation and construction, as well as module B6, which handles the energy use during operation, were examined. The materials that are included in the pre-use phase make up the shell of the building and consists mostly of concrete, brick, insulation and windows. In the operational or use phase, district heating and electricity use were studied. The results show that the production of materials, modules A1-A3, as well as the district heating have the highest emissions of CO2-equivalents and that, if divided upon the total life expectancy of 70 years of the building, the pre-use phase has a slightly higher climate impact than the use phase, 27 versus 23 ton CO2-equivalents per year. Regarding primary energy use, the use phase require 795 GJ per year, and has thus more than a three-fold impact than the pre-use phase, which only requires 254 GJ per year. Compared to a traditional one-level gymnasium, Hästhagens sporthall is somewhat more energy efficient and has a lower climate impact per hour performed activity. However, more research is needed to make more general conclusions about the possibility of multi-use facilities in multiple levels to be more environmentally friendly than one-level establishments. Multi-use facility sports facility gymnasium life cycle assessment LCA concrete building environmental impact climate impact primary energy use Multihall sporthall livscykelanalys LCA betong byggnad miljöpåverkan klimatpåverkan primärenergiförbrukning Environmental Sciences Miljövetenskap
5	Energikartläggning av förskola : Underlag för energieffektiviseringsåtgärder av byggnaden Metreven samt fördjupning avseende potential för uppfyllande av Boverkets krav gällande nära- nollenergibyggnad Lehtonen, Joakim January 2020 (has links) The Swedish residential sector consumes almost 39 % of Sweden’s final energy consumption. The European Union framework ”Clean Energy for all Europeans package” strives to promote a 32,5 % reduction as a result of energy efficiency measures. The Swedish legislation BBR regulates rules regarding new buildings, extensions and reconstruction of existing buildings. Excerpt 9 regards how energy is being used and determines the demands e.g. for a buildings primary energy use to be classified as a near zero energy building (NZEB). The energy use of a building, located in Västerås, Sweden, is being decided. Various energy efficiency packages are applied to a model in the simulation software IDA ICE. The results are compared with each other deciding the potential benefits of the energy efficiency measures. A substantial decrease of the energy consumption is detected, especially for the energy efficiency packages containing a geothermal heat pump (66 – 78 %). A life cycle cost analysis shows that the package containing a ventilation heat recovery system (FTX) combined with a geothermal heat pump is the optimal solution through an economical point a view. The solution yields a profit after 14 years. The analysis shows that all geothermal solutions, except a system consisting of a geothermal heat pump, FTX, energy efficient windows, rooftop insulation and a photovoltaic system, yields a profit during a 30-year investment period. None of the packages containing a district heat exchanger yield a profit. The simulation results show that by implementing any of the geothermal heat pump packages, the demands for classifying the building according to an NZE building are fulfilled. Regarding the district heating packages, only the package containing all the energy efficiency measures (energy efficient windows, rooftop insulation and PV) meets the demands to be classified as an NZE building. Regarding the environmental impact due to implementing the energy efficiency measures, the results show a reduced impact from applying the geothermal heat pump packages is equivalent to the energy consumption reductions. The results show that by implementing a district heating system, more than one additional energy efficiency measure must be applied to avoid an increased environmental impact. This thesis shows that implementing energy efficiency measures can decrease energy consumption and yield an economical profit to the existing building stock. Energy efficiency measures Primary energy use NZEB IDA ICE BBR Geothermal heat pump District heating LCC Energieffektiviseringsåtgärder Primärenergital NNE IDA ICE BBR Bergvärme Fjärrvärme LCC Miljöanalys och bygginformationsteknik Energy Systems Energisystem
6	Life cycle assessment and life cycle cost analysis of a single-family house Petrovic, Bojana January 2021 (has links) The building industry is responsible for 35% of final energy use and 38% of CO2 emissions at a global level. The European Union aims to reduce CO2 emissions in the building industry by up to 90% by the year 2050. Therefore, it is important to consider the environmental impacts buildings have. The purpose of this thesis was to investigate the environmental impacts and costs of a single-family house in Sweden. In the study, the life cycle assessment (LCA) and the life cycle cost (LCC) methods have been used by following the “cradle to grave” life cycle perspective. This study shows a significant reduction of global warming potential (GWP), primary energy (PE) use and costs when the lifespan of the house is shifted from 50 to 100 years. The findings illustrate a total decrease in LCA outcome, of GWP to 27% and PE to 18%. Considering the total LCC outcome, when the discount rate increases from 3% to 5% and then 7%, the total costs decrease significantly (60%, 85% to 95%). The embodied carbon, PE use and costs from the production stage/construction stage are significantly reduced, while the maintenance/replacement stage displays the opposite trend. Operational energy use, water consumption and end-of-life, however, remain largely unchanged. Furthermore, the findings emphasize the importance of using wood-based building materials due to its lower carbon-intensive manufacturing process compared to non-wood choices. The results of the LCA and LCC were systematically studied and are presented visually. Low carbon and cost-effective materials and installations have to be identified in the early stage of a building design so that the appropriate investment choices can be made that will reduce a building’s total environmental and economic impact in the long run. Findings from this thesis provide a greater understanding of the environmental and economic impacts that are relevant for decision-makers when building single-family houses. / Byggbranschen svarar för 35% av den slutliga energianvändningen och 38 % av koldioxidutsläppen på global nivå. Europeiska unionen strävar efter att minska koldioxidutsläppen i byggnadsindustrin med upp till 90% fram till 2050. Därför är det viktigt att beakta byggnaders miljöpåverkan. Syftet med denna avhandling var att undersöka miljöpåverkan och kostnader för ett enfamiljshus i Sverige. I studien har livscykelbedömningen (LCA) och livscykelkostnadsmetoderna (LCC) använts genom att tillämpa livscykelperspektivet ”vagga till grav”. Studien visar en stor minskning av global uppvärmningspotential (GWP), användning av primärenergi (PE) och kostnader vid växling från 50 till 100 års husets livslängd. Resultaten visar en årlig minskning med 27% för utsläpp av växthusgaser och med 18% för användningen av primärenergi. Med tanke på det totala LCC-utfallet, när diskonteringsräntan ökar från 3%, 5% till 7%, minskar de totala kostnaderna avsevärt (60%, 85% till 95%). Det noteras att klimatavtrycket, primärenergianvändningen och kostnaderna från produktionssteget/konstruktionssteget minskar avsevärt, medan underhålls- / utbytessteget visar den motsatta trenden när man byter från 50 till 100 års livslängd. Den operativa energianvändningen, vattenförbrukningen och avfallshanteringen är fortfarande nästan samma när man ändrar livslängden. Vidare betonar resultaten vikten av att använda träbaserade byggmaterial på grund av lägre klimatpåverkan från tillverkningsprocessen jämfört med alternativen. LCA- och LCC-resultaten studerades systematiskt och redovisades visuellt. De koldioxidsnåla och kostnadseffektiva materialen och installationerna måste identifieras i ett tidigt skede av en byggnadskonstruktion genom att välja lämpliga investeringsval som kommer att minska de totala miljö och ekonomiska effekterna på lång sikt. Resultaten från denna avhandling ger ökad förståelse för miljömässiga och ekonomiska konsekvenser som är relevanta för beslutsfattare vid byggnation av ett enfamiljshus. Building carbon-dioxide equivalent emissions global warming potential primary energy use life cycle assessment life cycle cost Byggnad koldioxidekvivalenta utsläpp global uppvärmningspotential pri-märenergianvändning livscykelbedömning livscykelkostnad Energy Systems Energisystem
7	Life cycle assessment and life cycle cost analysis of a single-family house Petrovic, Bojana January 2021 (has links) The building industry is responsible for 35% of final energy use and 38% of CO2 emissions at a global level. The European Union aims to reduce CO2 emissions in the building industry by up to 90% by the year 2050. Therefore, it is important to consider the environmental impacts buildings have. The purpose of this thesis was to investigate the environmental impacts and costs of a single-family house in Sweden. In the study, the life cycle assessment (LCA) and the life cycle cost (LCC) methods have been used by following the “cradle to grave” life cycle perspective. This study shows a significant reduction of global warming potential (GWP), primary energy (PE) use and costs when the lifespan of the house is shifted from 50 to 100 years. The findings illustrate a total decrease in LCA outcome, of GWP to 27% and PE to 18%. Considering the total LCC outcome, when the discount rate increases from 3% to 5% and then 7%, the total costs decrease significantly (60%, 85% to 95%). The embodied carbon, PE use and costs from the production stage/construction stage are significantly reduced, while the maintenance/replacement stage displays the opposite trend. Operational energy use, water consumption and end-of-life, however, remain largely unchanged. Furthermore, the findings emphasize the importance of using wood-based building materials due to its lower carbon-intensive manufacturing process compared to non-wood choices. The results of the LCA and LCC were systematically studied and are presented visually. Low carbon and cost-effective materials and installations have to be identified in the early stage of a building design so that the appropriate investment choices can be made that will reduce a building’s total environmental and economic impact in the long run. Findings from this thesis provide a greater understanding of the environmental and economic impacts that are relevant for decision-makers when building single-family houses. / Byggbranschen svarar för 35% av den slutliga energianvändningen och 38 % av koldioxidutsläppen på global nivå. Europeiska unionen strävar efter att minska koldioxidutsläppen i byggnadsindustrin med upp till 90% fram till 2050. Därför är det viktigt att beakta byggnaders miljöpåverkan. Syftet med denna avhandling var att undersöka miljöpåverkan och kostnader för ett enfamiljshus i Sverige. I studien har livscykelbedömningen (LCA) och livscykelkostnadsmetoderna (LCC) använts genom att tillämpa livscykelperspektivet ”vagga till grav”. Studien visar en stor minskning av global uppvärmningspotential (GWP), användning av primärenergi (PE) och kostnader vid växling från 50 till 100 års husets livslängd. Resultaten visar en årlig minskning med 27% för utsläpp av växthusgaser och med 18% för användningen av primärenergi. Med tanke på det totala LCC-utfallet, när diskonteringsräntan ökar från 3%, 5% till 7%, minskar de totala kostnaderna avsevärt (60%, 85% till 95%). Det noteras att klimatavtrycket, primärenergianvändningen och kostnaderna från produktionssteget/konstruktionssteget minskar avsevärt, medan underhålls- / utbytessteget visar den motsatta trenden när man byter från 50 till 100 års livslängd. Den operativa energianvändningen, vattenförbrukningen och avfallshanteringen är fortfarande nästan samma när man ändrar livslängden. Vidare betonar resultaten vikten av att använda träbaserade byggmaterial på grund av lägre klimatpåverkan från tillverkningsprocessen jämfört med alternativen. LCA- och LCC-resultaten studerades systematiskt och redovisades visuellt. De koldioxidsnåla och kostnadseffektiva materialen och installationerna måste identifieras i ett tidigt skede av en byggnadskonstruktion genom att välja lämpliga investeringsval som kommer att minska de totala miljö och ekonomiska effekterna på lång sikt. Resultaten från denna avhandling ger ökad förståelse för miljömässiga och ekonomiska konsekvenser som är relevanta för beslutsfattare vid byggnation av ett enfamiljshus. Building carbon-dioxide equivalent emissions global warming potential primary energy use life cycle assessment life cycle cost Byggnad koldioxidekvivalenta utsläpp global uppvärmningspotential pri-märenergianvändning livscykelbedömning livscykelkostnad Energy Systems Energisystem
8	A systematic approach for major renovation of residential buildings Liu, Linn January 2017 (has links) In Sweden, buildings are responsible for about 40 % of total energy use and about 10 % of total CO2 emissions Today more than 60 % of existing Swedish residential buildings are over 40 years old and are in need of major renovation. In addition, 15 % of all multi-family buildings and 27 % of all single-family houses were built before 1945. The increased energy use and threat from CO2 emissions of the building sector create a need for energy efficiency. The important role that renovation of residential buildings will play in reducing the total energy used by the Swedish building sector as well as in reducing primary energy use and CO2 emissions on both the national and global levels has been the impetus for the studies included in this thesis. The aim of the current research is to develop a methodology from a system perspective which can be used to analyze the energy use, optimal life cycle cost (LCC), energy efficiency measure (EEM) package, indoor environment, CO2 emissions, and primary energy use of a building or a community during major renovation. The developed methodology accomplished at three different levels, i.e. building level, cluster level and district level. The methodology considers both energy efficiency and economic viability during building renovation and will also play an important role in overall urban planning. The studied buildings include both non-listed and listed residential buildings and the tools used include building energy simulation (BES), survey, technical measurements, LCC optimization and building categorization. The results show that the combination of BES, technical measurements and surveys provides a holistic approach for evaluation of energy use and indoor environment of the studied residential buildings. The results from the current study also show that the 2020 energy target, i.e., reduction of energy use by 20 %, for the building sector can be achieved by all the studied building types and that the total LCC of these buildings are below the cost-optimal point. In comparison, the 2050 energy target, i.e., reduction of energy use by 50 %, for the building sector may be achieved by the non-listed buildings, but when the constraints relevant to listed buildings are added the cost-optimality changes as some EEMs in direct conflict with the building’s heritage value may not be implemented. The investigation of primary energy use and CO2 emissions by the residential buildings show that the higher the energy saving, the lower the primary energy use becomes, and vice versa. With the same energy saving, the heating system with higher primary energy factor results in higher primary energy use. From a CO2 emissions point of view, EEM packages proposed to help buildings connected to a CHP based district heating system, to reduce the energy use or LCC are not consistently effective. Since these EEM packages will reduce district heating demand, the electricity produced in the CHP plant will also decrease. When the biomass is considered a limited resource, measures such as investment in a biofuel boiler are not favourable from the CO2 emissions point of view. The current study has also shown that combining building categorization method and LCC optimization method will help the community to reduce its energy use, primary energy use and CO2 emissions in a systematic and strategic way. / I Sverige, står byggnadssektorn för cirka 40 % av den totala energianvändningen och cirka 10 % av CO2-utsläppen. Idag är mer än 60 % av befintliga svenska bostäder över 40 år gamla och i stort behov av renovering. Dessutom är 15 % av alla flerbostadshus och 27 % av alla småhus byggda före 1945. Den ökade energianvändningen och hotet från CO2-utsläpp från byggsektorn skapar ett behov av energieffektivisering. Grunden för studierna i denna avhandling är den stora betydelse som renoveringen av bostäder har, såväl för att kunna minska den totala energianvändningen som den primärenergianvändningen och CO2-utsläppen på både nationell och global nivå. Syftet med denna forskning är att utveckla en metodik ur ett systematiskt perspektiv som kan användas för att analysera energianvändning, finna optimal livscykelkostnad (LCC), skapa energieffektiviseringsåtgärdspaket, undersöka inomhusmiljöer, beräkna CO2-utsläpp och primärenergianvändning i en byggnad eller ett samhälle vid omfattande renovering. Den utvecklade metodiken som har använts i de aktuella studierna är på tre olika nivåer: byggnadsnivå, klusternivå och stadsdelsnivå. Metodiken avser både energieffektivitet och ekonomisk lönsamhet vid renovering av byggnader och kommer också att spela en viktig roll i den övergripande stadsplaneringen. De studerande byggnaderna i denna avhandling innefattar både historiska och icke-historiska bostäder. De använda verktygen inkluderar building energy simulering (BES), enkätundersökning, tekniska mätningar, LCC-optimering och byggnadskategorisering. Resultaten visar att kombinationen av BES, tekniska mätningar och enkätundersökning ger en god helhetsbild för utvärdering av energianvändning och inomhusmiljö av den studerade byggnaden. Resultaten från den aktuella studien visar också att 2020-energimålet, d.v.s. en minskning av energianvändningen med 20 % till 2020 av byggsektorn, kan uppnås i alla undersökta byggnader och att den totala LCC av dessa byggnader ligger under den kostnadsoptimala punkten. I jämförelse, kan 2050-energimålet, d.v.s. en minskning av energianvändningen med 50 % till 2050, kan uppnås i icke-historiska byggnader, men med hänsyn tagen till begränsningarna för historiska byggnader, ändras de kostnadsoptimala lösningarna, eftersom vissa energieffektiviseringsåtgärder är i direkt konflikt med byggnadens kulturhistoriska värde och därför inte kan genomföras. Undersökningen av primärenergianvändning och CO2-utsläpp i de studerade byggnaderna visar, att ju högre energibesparingen är, desto lägre blir primärenergianvändningen, och vise versa. Med lika mycket energibesparing, resulterar värmesystemet med högre primärenergifaktor i högre primärenergianvändning. Sett från CO2-utsläppssynvinkel, är de energieffektiviseringsåtgärdspaket, som kan hjälpa byggnader anslutna till ett kraftvärmebaserat fjärrvärmesystem att minska energianvändningen eller LCC, inte effektiva, eftersom dessa åtgärdspaket kommer att minska fjärrvärmeanvändningen. Detta leder till att mängden producerad el i ett kraftvärmeverk också kommer att minskas. När biobränsle betraktas som en begränsad resurs, är åtgärder som investering i en biobränslepanna inte energieffektiva från en CO2-utsläppssynvikel. Den aktuella studien visar också att kombinationen av byggnadskategorisering och LCC-optimering kommer att hjälpa byggnadssektorn att minska sin energianvändning, primärenergianvändning och CO2-utsläpp på ett systematiskt och strategiskt sätt. energy efficiency renovation residential buildings listed buildings simulation optimization LCC categorization energy efficiency measure package indoor environment energy targets CO2 emission primary energy use energieffektivisering renovering bostäder historiska byggnader simulering optimering LCC kategorisering energieffektiviseringsåtgärdspaket inomhusmiljö energimål CO2-utsläpp primärenergianvändning Energy Systems Energisystem Building Technologies Husbyggnad Construction Management Byggproduktion Miljöanalys och bygginformationsteknik Environmental Sciences Miljövetenskap
9	Consumption of sustainable food products : A study of the Sustainable purchase perception matrix and Sustainable lead consumers; A life cycle assessment of BäR smoothie Melén, Cecilia, Wolff, Mirea January 2021 (has links) Part 1 The scientific community has identified an attitude-action gap for demographic and psychographic variables when studying sustainable purchase behaviour. By focusing on what happens during the purchase instead of the purchaser, this cross-sectional study aims to understand sustainable purchase behaviour when consumers purchase sustainable food. The scope of this study focused on the consumer’s perceived degree of Confidence and Com- promise when purchasing sustainable food products as suggested by Peattie in the Green purchase perception matrix. However, since the study included environmental and social responsibility, we renamed the matrix to the Sustainable purchase perception matrix. The focus was also on a new construct created in this study called the Sustainable lead consumer. The degree of Confidence was measured through the consumer’s own belief in the ability to have a positive sustainability impact, i.e. Perceived consumer effectiveness (PCE) and the consumer’s domain-specific sustainability interests. The degree of Compromise was measured through the consumer’s Willingness to pay (WTP) for certain sustainability attributes. The data was collected through a questionnaire (N=436), and the result showed that the correlation between consumers’ WTP and PCE was weak, positive and significant within the sustainability interests Organic food, Animal welfare and Natural resources. As mentioned, Confidence and Compromise was examined through the variables PCE, sustainability interests and WTP. To reveal if the consumers experienced other variables within Confidence and Compromise a thematic analysis of consumers’ perceived scepticism towards sustainability marketing was conducted. The result identified 15 themes that could be associated with the variable Confidence and 17 themes that could be associated with the variable Compromise. By creating a new construct, the Sustainable lead consumer, the study identified a consumer who was considered ahead of the sustainability trend and benefited greatly from solutions in this trend. The correlation between WTP and domain-specific sustainability interests for Sustainable lead consumers was non-significant but strong (n=377). When comparingSustainable lead consumers’ WTP to the remaining population, the Wilcoxon rank-sum test showed no significant evidence that the Sustainable lead consumers had a higher WTP for their domain-specific sustainability interests. A potential attitude-action gap among the Sustainable lead consumers was examined by evaluating if a high degree of Confidence and Compromise led to actual sustainable purchase behaviour. The analysis showed that only a small proportion of Sustainable lead consumers with a high degree of PCE and WTP had an actual sustainable purchase behaviour. This was likely due to the existing attitude-action gap where the consumers’ attitude is not reflected in their actual behaviour. Part 2 Food production and consumption have a major impact on the environment, primarily from agriculture, but also from the processing of food, transportation and waste management. Increased environmental awareness among consumers has led to a demand for transparency in the food production chain and thus an increased demand for knowledge about food’s environmental impact. By studying the environmental impact of the product BäR smoothie from the Finnish company Toripiha, this study aims to identify environmental hotspots in the product’s production chain. A life cycle assessment (LCA) was conducted in accordance with the ISO standards ISO 14040 and ISO 14044, to investigate the environmental impact of a bottle of BäR smoothie á 250 ml. The LCA was attributional, meaning that it aims to depict the product’s environmental impact over its life cycle. The environmental impact categories global warming, eutrophication and primary energy use were included, and measured with the impact category indicators carbon dioxide equivalents (CO2-eq), phosphate equivalents (PO4-eq) and megajoule (MJ). Inventory data were collected mainly from the database Ecoinvent version 3.7, but also from scientific articles and previous studies, as well as the calculation tool NTMCalc Basic 4.0. The results of this study highlight the parts of the production chain of BÄR smoothie that have the most significant environmental impact concerning the chosen impact categories. A bottle of BäR smoothie á 250 ml contributed to a total of 120 g CO2-eq, 0.39 g PO4-eq and 2.8 MJ. The smoothie bottle, i.e. the production of the virgin bottle grade PET granulate (vPET) and recycled bottle grade PET granulate (rPET), had the largest impact on global warming and primary energy use of all the components, and also had a significant impact on eutrophication. As most of this contribution comes from the production of vPET granulate, Toripiha was advised to purchase bottles that have a higher content of rPET granulate to decrease the smoothie’s environmental impact. It was also evident that the transportation of components was a significant contributor to global warming, eutrophication and primary energy use. Since transportation had such an impact on the result, Toripiha needs to strive towards short and efficient transport of the different components to reduce the environmental impact from transportation. / Del 1 Forskare inom hållbart konsumtionsbeteende har identifierat en diskrepans mellan attityd och beteende för demografiska och psykografiska variabler. Genom att studera vad som händer hos konsumenten under ett köp, i stället för tidigare nämnda variabler, vill denna tvärsnittsstudie identifiera vad som driver hållbart konsumtionsbeteende av livsmedel. Denna studie fokuserade på konsumenters upplevda nivå av Confidence och Compromise vid köp av hållbar mat så som föreslås av Peattie’s Green purchase perception matrix. Dock så användes matrisen till att studera både miljömässig och social hållbarhet och döptes således om till Sustainable purchase perception matrix. Studien undersökte även ett nytt koncept som skapades i detta examensarbete, nämligen Sustainable lead consumer adapterat från Von Hippel’s Lead user. Graden av Confidence mättes genom att studera konsumentens tro på den egna förmågan att ha en positiv hållbarhetspåverkan, dvs. Percieved consumer effectiveness (PCE), samt domän-specifika hållbarhetsintressen. Graden av Compromise mättes genom konsumentens villighet att kompromissa genom att betala för olika hållbarhetsattribut, även kallat Willingness to pay (WTP). Data samlades in genom en enkät (N=436), och resultatet visade att det fanns en svag, positiv och signifikant korrelation mellan PCE och WTP inom hållbarhetsintressena Ekologisk mat, Djurvälfärd och Naturresurser. Vidare utfördes en tematisk analys av kvalitativ data för att studera vilka andra variabler än hållbarhetsintressen, WTP och PCE som påverkade variablerna Confidence och Compromise. Detta resulterade i 15 teman som kunde relateras till Confidence och 17 teman till Compromise. Genom att skapa ett nytt koncept, Sustainable lead consumer, identifierade denna studie en konsument som ansågs vara i framkant av hållbarhetstrenden och som drog stora fördelar av denna trend. Korrelationen mellan WTP och Sustainable lead consumer’s var stark men ej signifikant (n=377). När dessa konsumenter jämfördes med resterande population, visade Wilcoxon rank-sum test inga signifikanta bevis på att Sustainable lead consumer’s hade ett högre WTP än resterande population. Huruvida en attityd och beteende diskrepans existerade för Sustainhable lead consumers studerades genom att se om en hög grad av Confidence och Compromise ledde till en högre av hållbar konsumtionsbeteende. Analysen visade att det endast var en liten andel av Sustainable lead consumers med ett högt PCE och WTP som också hade ett hållbart konsumtionsbeteende. Detta beror troligen på diskrepansen mellan attityd och beteende där konsumenternas attityd inte reflekteras i deras faktiska konsumtionsbeteenden. Del 2 Produktion och konsumtion av livsmedel har en stor påverkan på miljön, primärt från jordbruket men även genom behandling av livsmedel, transporter och avfallshantering. En ökad medvetenhet hos konsumenter har resulterat i en ökad efterfrågan av transparens i produktionskedjan av livsmedel, och därmed ett ökat behov av kunskap gällande olika livsmedels miljöpåverkan. Genom att studera miljöpåverkan från produkten BäR smoothie från det finska företaget Toripiha är syftet med denna studie att identifiera delar i produktens produktionskedja som har en betydande miljöpåverkan, så kallade hotspots. För att studera miljöpåverkan från en flaska BäR smoothie á 250 ml utfördes en livscykelanalys (LCA) i enlighet med ISO-standarderna ISO 14040 och ISO 14044. Närmare bestämt utfördes en bokförings-LCA, vilket innebär att miljöpåverkan studeras utifrån produktens livscykel. De miljöpåverkanskategorier som inkluderades i studien var global uppvärmning, övergödning och primärenergianvändning, som mättes med kategoriindikatorerna koldioxidekvivalenter (CO2-ekv), fosfatekvivalenter (PO4-ekv) och megajoule (MJ). Den inventeringsdata som användes hämtades främst från databasen Ecoinvent version 3.7, men även från vetenskapliga artiklar och tidigare studier, samt från beräkningsverktyget NTMCalc Basic 4.0. Resultaten av denna studie belyser de delar i produktionskedjan för BÄR smoothie som har störst miljöpåverkan med avseende de valda miljöpåverkanskategorierna. En flaska BäR smoothie á 250 ml bidrog totalt med 120 g CO2-ekv, 0,39 g PO4-ekv och 2,8 MJ. Den komponent med störst miljöpåverkan med avseende på global uppvärmning och primär energianvändning och som även hade en betydande inverkan på övergödning var flaskan, dvs. produktion av PET-granulat (vPET) och återvunnen PET-granulat (rPET). Eftersom majoriteten av detta bidrag kom från produktionen av vPET-granulat, rekommenderades Toripiha att använda flaskor som har ett högre innehåll av rPET-granulat för att minska produktens totala miljöpåverkan. Det var också tydligt att transporten av komponenter stod för en betydande del av miljöpåverkan med avseende på samtliga miljöpåverkanskategorier. För att minska miljöpåverkan från transporter bör Toripiha därför sträva efter kortare och mer effektiva transporter för de olika komponenterna. Compromise Confidence WTP PCE Sustainable lead consumer Sustainability marketing Scepticism Life cycle assessment LCA Environmental impact Global warming Eutrophication Primary energy use Smoothie Kompromiss Självförtroende WTP PCE Hållbar marknadsföring Skepticism Livscykelanalys LCA Miljöpåverkan Global uppvärmning Övergödning Primärenergianvändning Smoothie Environmental Management Miljöledning Economics and Business Ekonomi och näringsliv

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