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| 2. |
- Backman, Erik, et al.
(författare)
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The Changing Landscape of Sport Facilities : Consequences for Practitioners and the Environment
- 2023
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Ingår i: Sport, Performance and Sustainability. - London : Routledge. - 9781003283324 - 9781032254630 ; , s. 50-65
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Bokkapitel (refereegranskat)abstract
- The environmental impact of sports facilities has received increasing attention over the last decades. However, studies within this area primarily deal with how the actual construction of sports facilities affects the environment. We know far less about how an active presence in sports facilities influences sporting practitioners’ thoughts about their own environmental impact. Therefore, this chapter critically discusses environmental issues connected to sports facilities generally and more specifically in relation to artificial sports facilities. We use several theoretical concepts to discuss the current research with examples taken from the artificial landscapes of cross-country skiing, canoe slalom, and turf-based sports. What makes artificial sports facilities especially interesting from an environmental perspective is the ambiguity they involve. On one hand, the actual constructions involve direct interventions in nature. On the other hand, there is a lack of knowledge about the impact these facilities have on health, environmental awareness, and travel. We argue that future sports facilities will need to stimulate more logic than competition if sport and outdoor recreation is to be environmentally sustainable. The process of sportification, which has prioritised the growth of sport economies and encouraged ever higher performance levels, would need to shift its focus to incorporate environmental concerns.
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| 3. |
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| 4. |
- Danielski, Itai, et al.
(författare)
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Adaption of the passive house concept in northern Sweden : a case study of performance
- 2013
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Konferensbidrag (refereegranskat)abstract
- This study analyzes the performance of a case study of low energy house built in Östersund (lat.63°N), Sweden. The building is a semi detached house for two families, with each apartment having afloor space of 160 m2 divided on two floors. The building was constructed during 2010 according tothe Swedish passive house principles with design that meet the requirements for Swedish passivehouses as defined by the Forum for energy efficiency buildings (FEBY) and the Swedish center forzero energy houses (SCNH). The house is connected to the district heating network, which is the mainheat source for domestic water heating, floor heating in the bathroom and water based pre‐heatercoil in the ventilation system. Additionally, a wood stove is installed in the living room for thermalcomfort and convenience of the residents. The two identical residential units in the building wereinhabited in the end of 2010 by families with different characteristics; a family with two youngchildren in one unit and a middle aged couple in the other.A one year energy measurement campaign started in May 2012 for both of the residential units. Themeasurements started after a period of adjustments of the building energy system and include spaceand domestic water heating (separate measurements), household electricity, the amount of fuelwood used in the stove, and indoor thermal conditions. The results show that it is possible to buildpassive houses in the Northern regions of Sweden. The specific final energy demand of the casestudy was 23% lower than the Swedish FEBY‐requirements. Differences were found between themonitored and calculated specific final energy demand. These differences depend to a large extanton the occupants’ behavior and household characteristics. The final energy demand for heating anddomestic water heating found to vary significantly between the two households.
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| 5. |
- Danielski, Itai, 1973-, et al.
(författare)
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Air source heat pumps and their role in the Swedish energy system
- 2012
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Ingår i: Support your future today; Turning environmental problems into business opportunities.
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Konferensbidrag (refereegranskat)abstract
- Newly produced air source heat pumps can provide heat energy from outdoor air at temperature as low as -20°C. As a result they could be utilized during most days of the year even in the cold Nordic climates. The drawback of air source heat pumps is the reduction in efficiency as the outdoor air become colder, resulting in lower heat supply in times when it is most needed. Despite its inverse relationship between efficiency and outdoor temperature, air source heat pumps were installed in 57000 detached houses in Sweden during 2010 alone, which is 3% of the total detached houses stock. That makes air source heat pumps the most sold heating technology for detached houses in Sweden during 2010, 1.6 times more than the number of installations of ground source heat pump and 3 times more than the number of connections of detached houses to district heating during the same year. Similar trends can be found in other Nordic countries.This study compares the use of an air source heat pump with other existing commercial technologies in detached houses and analyzes the impacts on primary energy use, on final energy use, on electricity production and on costs benefits for house owners. It was found that converting existing electric heated Swedish detaches houses to district heating with biomass based CHP or bed-rock heat pump could reduce the use of resources, which could benefit Sweden as a society. Converting electric heated Swedish detaches houses to district heating or pellets stove could reduce power demand and level out the power demand load curve. That would benefit utilities of power supply as it could secure power supply. However cost effectiveness in one of most important drivers for house owners of detached houses to choose energy efficiency measures. For that reason house owners may most likely benefit by the installation of air-source heat pumps.
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| 7. |
- Danielski, Itai, 1973-, et al.
(författare)
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Atrium in residential buildings – a design to enhance social interaction in urban areas in Nordic climates
- 2018
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Ingår i: Cold Climate HVAC 2018. - Cham : Springer. - 9783030006617 - 9783030006624 ; , s. 773-789
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Bokkapitel (refereegranskat)abstract
- The design concept of conditioned atria receive growing popularity in both commercial and service buildings all over the world, but still not common in the residential sector. This study used a psychological framework to examine if building design with enclosed heated atria in apartment buildings can enhance sense of community and social interactions in Nordic climates. A qualitative study was conducted to understand the perception of residents living in apartment buildings with heated atrium. One of the few examples in Sweden. This was compared to the experience of residents in a “traditional” apartment building without an atrium. The questionnaire was comprised of six parts: (i) socio-demographic aspects; (ii) information about the apartment; (iii) social activities within the building; (iv) social interaction with neighbours; (v) information about principles in life; and (vi) sense of community linked to their homes.The results showed significant social differences between the residents of the atrium and “traditional” buildings, which could not be explained solely by differences in preferences and principles in life. A large proportion of the social differences between the buildings could be explained by the building design, as the common and semi-private areas within the atrium building provide opportunities to establish social interactions. The residents in the atrium building was found to have greater sense of community and higher frequency of interactions, which are both parts of social sustainability.
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| 9. |
- Danielski, Itai, 1973-, et al.
(författare)
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Design för energieffektiv vardag : Slutrapport projekt DEVA-skolor
- 2021
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Rapport (övrigt vetenskapligt/konstnärligt)abstract
- Dålig inomhusmiljö i grundskolor i Sverige verkar vara ett problem i många kommuner. I det här projektet har man tittat på om en installation av en stor mängd växter i ett klassrum skulle kunna ändra på det. Det finns nämligen forskning om visar att vi mår, både fysiskt och psykiskt, bättre om vi är omgivna av växter. Fysiskt för att de kan rena luften och omvandla koldioxiden till syre. Dessutom ökar de luftfuktigheten och reglerar temperaturen. Psykiskt kanske för att vi är en del av naturen och har levt i den största delen av mänsklighetens historia. Växter kan också skapa bättre akustik i rummet genom att absorbera ljudvågor. Dessutom finns det tidigare studier som visar att växterna kan öka både koncentrationsförmågan och minnet.Projektet hade tre olika perspektiv; design, miljö och hälsa. Platsen för projektet var en grundskola belägen i ett mindre landsbygdssamhälle i norra delarna av Sverige. Totalt installerades 350 gröna växter i fyra växtställningar, dessa fördelades sedan på två olika klassrum med ca 25 elever ur årskurs 8 vardera. Ett liknande klassrum (åk9) bredvid dessa användes som referensobjekt. Växtställningarna designades av industridesignstudenter på Mittuniversitetet och skulle resultera i fungerande prototyper med automatisk bevattning. Projektet pågick under två terminer, höstterminen 2019 och vårterminen 2020.Mätningar av inomhustemperaturen visade att de gröna växterna bidrar till en mer stabil temperatur och till och med kan öka temperaturen något, vilket kan användas för att minska värmebehovet. Effekterna på luftfuktighet var endast högre i klassrummen med växter under natten när ventilationsflödet var lågt. Koldioxidnivåerna i klassrummen med växterna var 10 % lägre under undervisningstiden jämfört med kontrollklassrummet vilket indikerar att gröna växter skulle kunna användas för att minska ventilationsluftflödet och därigenom minska värmeenergiförluster. Energiberäkningen visade upp till 18% minskning på uppvärmningsbehovet. Mängden luftburna partiklar var redan låg och man kunde inte se någon förändring efter installationen av växterna.I början uppskattade både lärare och elever att de hade fått ett “grönt klassrum”. Minnet och koncentrationsförmågan hos eleverna blev bättre. I mätningen ett halvår senare hade dock effekten avtagit. Det är svårt att säga om detta berodde på hemmablindhet, Covid 19-pandemin (som hade brutit ut en månad tidigare) eller för att det var problem med några av bevattningssystemen som gjorde att vissa växter vissnade. Kanske en kombination.Resultaten av det här projektet kan ge kunskap och inspiration till kommuner och skolor om hur de kan förbättra inomhusklimatet med växter som ett kostnadseffektivt komplement till befintliga ventilationssystem som också kan förbättra elevernas och lärarnas prestationer och välbefinnande. Det är värt att notera att den här studien genomfördes på landsbygden där det redan är en bra luftkvalitet. Därför vore intressant att genomföra en liknande studie i ett storstadsområde men sämre luftkvalitet och även i andra med typer av byggnader med lägre ventilationsflöde.Det är också värt att notera att när projektet befanns sig i halvtid inträffade en pandemi, covid-19, som gav en betydande påverkan på både många samhällsfunktioner och för många människor. Detta kan ha påverkat resultatet av effekterna i mätningarna av hälsa och koncentration.
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| 10. |
- Danielski, Itai, 1973-, et al.
(författare)
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Diagnosis of buildings' thermal performance - a quantitative method using thermography under non-steady state heat flow
- 2015
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Ingår i: Energy Procedia. - : Elsevier BV. - 1876-6102. ; 83, s. 320-329
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Tidskriftsartikel (refereegranskat)abstract
- This study describes a quantitative method using thermography to measure the thermal performance of complete building envelope elements that are subjected to non-steady state heat flow. The method presumes that thermal properties of external walls, like conductivity, could still be obtained by a linear regression over values of independent measurements. And therefore could be used during fluctuating indoor and outdoor thermal conditions. The method is divided into two parts. First, the convection heat transfer coefficient is measured by heat flux meters (HFM) and thermography. And then, the overall heat transfer coefficient of a complete building element is measured by thermography to include all non-uniformities.In this study the thermal performance of a 140 mm thick laminated timber wall was measured. The wall was subjected to the outdoor weather conditions in Östersund, Sweden during January and February. The measurement values were found to have a large disparity as expected due to the rapid change in weather conditions. But still a linear regression with low confidence interval was obtained. The thermography results from a small uniform wall segment were validated with HFM measurements and 4% difference was found, which suggest that the two methods could be equally effective. Yet, thermography has the advantage of measuring surface temperature over large area of building element. The overall heat transfer coefficient of a large wall area was found to be 11% higher in comparison to the HFM measurements. This indicates that thermography could provide a more representative result as it captures areas of imperfections, point and linear thermal bridges.
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