The light of learning: design and siting of Rawlins Elementary School, Fraser Riverfront Park, Vancouver, BC

Coleman, Graham Cameron

11 1900

"The Light of Learning-siting and designing a regionally appropriate elementary school." Every place on earth is uniquely composed of various phenomena, such as climate, topography, qualities of light, latitude, ambient moisture levels, etc. We are each profoundly affected by the unique way these general qualities combine in our particular region, and Norberg-Schultz argues that this connection begins at a very young age. It allows us to know our place in the world, to orient ourselves, and to find our "home." Here on the West Coast, one of the most powerful characteristics of place is the quality of our regional light: which fluctuates from a warm August Yellow, to a low winter white. In summer our skies are broad, blue and bounded only by the mountains and sea. During the rainy season, ambient moisture turns the air solid, as white light ebbs and flows through the cedar boughs and around our buildings. Through the design of an elementary school sited on the north bank of the Fraser River Estuary, I attempt to explore how one makes "place"-in this case a place of learning-which is both responsive to site and appropriate to the unique characteristics of region. During my design process the qualities of Regional Light remain the principal generative tool, with the central circulation spine acting as an organizing light scoop/stack ventilation, and each classroom pod bringing natural light in on at least two sides to create a non-glare learning environment. Other key considerations are the programmatic need for dual school/public access to the site, the reintroduction of natural habitat from the adjacent river-front park, and a respect for the layers of history which have shaped the site before its current zoning as an elementary school.

The light of learning: design and siting of Rawlins Elementary School, Fraser Riverfront Park, Vancouver, BC

Coleman, Graham Cameron

11 1900

"The Light of Learning-siting and designing a regionally appropriate elementary school." Every place on earth is uniquely composed of various phenomena, such as climate, topography, qualities of light, latitude, ambient moisture levels, etc. We are each profoundly affected by the unique way these general qualities combine in our particular region, and Norberg-Schultz argues that this connection begins at a very young age. It allows us to know our place in the world, to orient ourselves, and to find our "home." Here on the West Coast, one of the most powerful characteristics of place is the quality of our regional light: which fluctuates from a warm August Yellow, to a low winter white. In summer our skies are broad, blue and bounded only by the mountains and sea. During the rainy season, ambient moisture turns the air solid, as white light ebbs and flows through the cedar boughs and around our buildings. Through the design of an elementary school sited on the north bank of the Fraser River Estuary, I attempt to explore how one makes "place"-in this case a place of learning-which is both responsive to site and appropriate to the unique characteristics of region. During my design process the qualities of Regional Light remain the principal generative tool, with the central circulation spine acting as an organizing light scoop/stack ventilation, and each classroom pod bringing natural light in on at least two sides to create a non-glare learning environment. Other key considerations are the programmatic need for dual school/public access to the site, the reintroduction of natural habitat from the adjacent river-front park, and a respect for the layers of history which have shaped the site before its current zoning as an elementary school. / Applied Science, Faculty of / Architecture and Landscape Architecture (SALA), School of / Graduate

Evaluation of bioaerosols in elementary school classrooms in a coastal temperate zone

Bartlett, Karen Hastings

05 1900

Potential determinants of exposure to culturable airborne fungal and bacterial aerosols and carbon dioxide were examined as an aid to the interpretation and evaluation of indoor air quality assessments. Concentration measurments for culturable bioaerosols and CO2 were evaluated against published standards and guidelines. METHOD: All 39 schools from one British Columbia school district were enrolled in the study to ensure different building ages and construction materials, but the same maintenance protocols, were included. Schools were randomly assigned to winter, spring or fall sampling. Data collected included: number of occupants and patterns of occupancy, CO2 levels, temperature and relative humidity, total suspended particles, and air exchange rates using tracer gas (SF6) decay. Other characteristics of the classrooms included the presence or absence of forced air heat, carpets, live animals or aquaria, plants, and the siting of the school or portable classroom. Culturable indoor and outdoor aerosols of fungi and bacteria were collected. Determinants of exposure were modelled by constructing multiple linear regression equations for indoor fungi, indoor bacteria and indoor carbon dioxide. RESULTS: The multiple regression models were able to explain a considerable proportion of the variance for the outcomes of interest (total R2 = 0.59 for mesophilic fungi, 0.61 for bacteria, and 0.68 for CO2). Increased outdoor temperature and outdoor fungal counts were associated with higher concentrations for indoor fungi. Variables describing ventilation and conditions of occupancy were significant to all outcomes of interest but functioned differently in the models. For example, fungal concentration was higher in the presence of natural ventilation, but lower with increased mechanical ventilation. In contrast, CO2 was lower with both ventilation types, and lower with higher outdoor temperature. CONCLUSIONS: Using variables measured during an indoor air quality investigation, predictive models can be constructed which are useful in identifying determinants of bioaerosol and bioeffluent concentrations. Ranges of bioaerosol and bioeffluent concentrations for high occupancy buildings in a coastal temperate zone may differ from guidelines written for other indoor settings and climate zones.

School buildings -- British Columbia

Evaluation of bioaerosols in elementary school classrooms in a coastal temperate zone

Bartlett, Karen Hastings

05 1900

Potential determinants of exposure to culturable airborne fungal and bacterial aerosols and carbon dioxide were examined as an aid to the interpretation and evaluation of indoor air quality assessments. Concentration measurments for culturable bioaerosols and CO2 were evaluated against published standards and guidelines. METHOD: All 39 schools from one British Columbia school district were enrolled in the study to ensure different building ages and construction materials, but the same maintenance protocols, were included. Schools were randomly assigned to winter, spring or fall sampling. Data collected included: number of occupants and patterns of occupancy, CO2 levels, temperature and relative humidity, total suspended particles, and air exchange rates using tracer gas (SF6) decay. Other characteristics of the classrooms included the presence or absence of forced air heat, carpets, live animals or aquaria, plants, and the siting of the school or portable classroom. Culturable indoor and outdoor aerosols of fungi and bacteria were collected. Determinants of exposure were modelled by constructing multiple linear regression equations for indoor fungi, indoor bacteria and indoor carbon dioxide. RESULTS: The multiple regression models were able to explain a considerable proportion of the variance for the outcomes of interest (total R2 = 0.59 for mesophilic fungi, 0.61 for bacteria, and 0.68 for CO2). Increased outdoor temperature and outdoor fungal counts were associated with higher concentrations for indoor fungi. Variables describing ventilation and conditions of occupancy were significant to all outcomes of interest but functioned differently in the models. For example, fungal concentration was higher in the presence of natural ventilation, but lower with increased mechanical ventilation. In contrast, CO2 was lower with both ventilation types, and lower with higher outdoor temperature. CONCLUSIONS: Using variables measured during an indoor air quality investigation, predictive models can be constructed which are useful in identifying determinants of bioaerosol and bioeffluent concentrations. Ranges of bioaerosol and bioeffluent concentrations for high occupancy buildings in a coastal temperate zone may differ from guidelines written for other indoor settings and climate zones. / Graduate and Postdoctoral Studies / Graduate

School buildings -- British Columbia