Avaliação de sistemas de janela para suporte a decisões de projeto quanto à iluminação e uso de energia / Window systems evaluation for design decision support on daylight and energy use.

Lima, Kamila Mendonça de

16 February 2016

Projetar sistemas de janela considerando a adequação climática envolve lidar com os efeitos do meio externo, que são dinâmicos, e com estratégias que podem ser conflitantes, tais como o controle do ganho de calor solar e aproveitamento da iluminação natural, ambos elementos provenientes da radiação do Sol. Parte-se do princípio de que isso é feito considerando o impacto de diferentes variáveis de projeto em diferentes indicadores de desempenho simultaneamente, para suporte a decisão. O estudo do efeito dessas variáveis de projeto da janela quando combinadas ainda não é consolidado, especialmente no caso de localidades de baixa latitude. O objetivo geral desta pesquisa de doutorado é avaliar sistemas de janela estáticos e dinâmicos para suporte a decisões de projeto arquitetônico, quanto a diferentes critérios de desempenho relacionados à iluminação natural e uso de energia, de forma integrada. São estudados sistemas de janela compostos por uma abertura envidraçada e proteções solares de aletas horizontais externas, fixas e móveis. O recorte engloba edificações com uso de escritório no contexto do clima quente e úmido da cidade de Maceió-AL. Para isso, simulações computacionais integradas utilizando os softwares Daysim e EnergyPlus foram realizadas, considerando o acionamento das lâmpadas apenas quando a luz natural não fosse suficiente para atender ao uso do ambiente. As variáveis de projeto analisadas foram: percentual de área de abertura, tipo de vidro, ângulo de sombreamento, quantidade de aletas, tipo de acionamento do sistema de proteção solar e orientação da abertura. As soluções arquitetônicas resultantes das combinações de todas as variáveis entre si foram avaliadas com relação à disponibilidade e distribuição da luz natural e demanda de energia elétrica para condicionamento do ar e iluminação artificial no ambiente interno, e classificadas segundo dois indicadores principais. Foram identificadas as variáveis de projeto dentre as analisadas com maior potencial de impacto no desempenho obtido em diferentes situações. Os resultados mostraram que é possível uma alternativa se encontrar em uma faixa de 10% melhores cenários nos dois indicadores ao mesmo tempo. Observou-se ainda que, apesar de a demanda de energia para condicionamento do ar ser frequentemente maior do que a demanda para iluminação, o desempenho da abertura quanto à iluminação pode ter um peso decisivo na escolha de projeto, pois este indicador de desempenho é mais sensível às variáveis da janela estudadas do que o primeiro. Por fim, observou-se que os protetores solares dinâmicos não são garantia de melhoria de desempenho em relação a sistemas estáticos. / Designing window systems in a climate responsive way involves dealing with the effects of the external environment, which are dynamic, and strategies that may conflict, such as daylight and control of solar heat gains, both elements related to the sun. This research assumes that this is done considering the impact of different design variables in different performance indicators simultaneously, for decision support. The study of the effect of window design variables when combined is not yet consolidated, especially in case of low latitude locations. The general objective of this doctoral research is to evaluate static and dynamic window systems to support architectural design decisions regarding different performance criteria related to daylight and energy use, in an integrated manner. The studied window system consists of a glazed opening and external horizontal slat-type shading devices, fixed and mobile, in offices in the hot and humid climate of the city of Maceió-AL. For this, computer integrated simulations using Daysim and EnergyPlus software were carried out, considering the activation of the lighting system only when daylight is not sufficient to meet the usage requirements. The design variables analyzed were window-to-wall ratio, glazing type, cut-off angle, number of slats, type of shading control and orientation. Architectural solutions resulting from combinations of all variables were evaluated regarding the availability and distribution of daylight and electricity demand for air conditioning and artificial lighting in the indoor environment. The solutions were then rated and ranked according to two main indicators. The design variables among the analyzed with potential of high impact in the obtained performance in different situations were identified. The results showed that it is possible an alternative be in a range of 10% best scenarios in the two criteria at the same time. It was also observed that, although the energy demand for conditioning air often be greater than the lighting energy demand, the performance of the window on daylight can have a decisive weight on the design choice, because this performance indicator is more sensitive to the window variables than the first. Finally, it was observed that the dynamic shading systems are not performance-enhancing guarantee compared to static systems.

Avaliação de sistemas de janela para suporte a decisões de projeto quanto à iluminação e uso de energia / Window systems evaluation for design decision support on daylight and energy use.

Kamila Mendonça de Lima

16 February 2016

Projetar sistemas de janela considerando a adequação climática envolve lidar com os efeitos do meio externo, que são dinâmicos, e com estratégias que podem ser conflitantes, tais como o controle do ganho de calor solar e aproveitamento da iluminação natural, ambos elementos provenientes da radiação do Sol. Parte-se do princípio de que isso é feito considerando o impacto de diferentes variáveis de projeto em diferentes indicadores de desempenho simultaneamente, para suporte a decisão. O estudo do efeito dessas variáveis de projeto da janela quando combinadas ainda não é consolidado, especialmente no caso de localidades de baixa latitude. O objetivo geral desta pesquisa de doutorado é avaliar sistemas de janela estáticos e dinâmicos para suporte a decisões de projeto arquitetônico, quanto a diferentes critérios de desempenho relacionados à iluminação natural e uso de energia, de forma integrada. São estudados sistemas de janela compostos por uma abertura envidraçada e proteções solares de aletas horizontais externas, fixas e móveis. O recorte engloba edificações com uso de escritório no contexto do clima quente e úmido da cidade de Maceió-AL. Para isso, simulações computacionais integradas utilizando os softwares Daysim e EnergyPlus foram realizadas, considerando o acionamento das lâmpadas apenas quando a luz natural não fosse suficiente para atender ao uso do ambiente. As variáveis de projeto analisadas foram: percentual de área de abertura, tipo de vidro, ângulo de sombreamento, quantidade de aletas, tipo de acionamento do sistema de proteção solar e orientação da abertura. As soluções arquitetônicas resultantes das combinações de todas as variáveis entre si foram avaliadas com relação à disponibilidade e distribuição da luz natural e demanda de energia elétrica para condicionamento do ar e iluminação artificial no ambiente interno, e classificadas segundo dois indicadores principais. Foram identificadas as variáveis de projeto dentre as analisadas com maior potencial de impacto no desempenho obtido em diferentes situações. Os resultados mostraram que é possível uma alternativa se encontrar em uma faixa de 10% melhores cenários nos dois indicadores ao mesmo tempo. Observou-se ainda que, apesar de a demanda de energia para condicionamento do ar ser frequentemente maior do que a demanda para iluminação, o desempenho da abertura quanto à iluminação pode ter um peso decisivo na escolha de projeto, pois este indicador de desempenho é mais sensível às variáveis da janela estudadas do que o primeiro. Por fim, observou-se que os protetores solares dinâmicos não são garantia de melhoria de desempenho em relação a sistemas estáticos. / Designing window systems in a climate responsive way involves dealing with the effects of the external environment, which are dynamic, and strategies that may conflict, such as daylight and control of solar heat gains, both elements related to the sun. This research assumes that this is done considering the impact of different design variables in different performance indicators simultaneously, for decision support. The study of the effect of window design variables when combined is not yet consolidated, especially in case of low latitude locations. The general objective of this doctoral research is to evaluate static and dynamic window systems to support architectural design decisions regarding different performance criteria related to daylight and energy use, in an integrated manner. The studied window system consists of a glazed opening and external horizontal slat-type shading devices, fixed and mobile, in offices in the hot and humid climate of the city of Maceió-AL. For this, computer integrated simulations using Daysim and EnergyPlus software were carried out, considering the activation of the lighting system only when daylight is not sufficient to meet the usage requirements. The design variables analyzed were window-to-wall ratio, glazing type, cut-off angle, number of slats, type of shading control and orientation. Architectural solutions resulting from combinations of all variables were evaluated regarding the availability and distribution of daylight and electricity demand for air conditioning and artificial lighting in the indoor environment. The solutions were then rated and ranked according to two main indicators. The design variables among the analyzed with potential of high impact in the obtained performance in different situations were identified. The results showed that it is possible an alternative be in a range of 10% best scenarios in the two criteria at the same time. It was also observed that, although the energy demand for conditioning air often be greater than the lighting energy demand, the performance of the window on daylight can have a decisive weight on the design choice, because this performance indicator is more sensitive to the window variables than the first. Finally, it was observed that the dynamic shading systems are not performance-enhancing guarantee compared to static systems.

Parametric study of energy retrofit options for a historical building

El Tayara, Khaled

January 2022

Retrofitting measures in old buildings aimed at reducing energy consumption has become a widespread subject and an urgent matter to counteract the effects of climate change and GHGs emissions. The globe has reaffirmed its agreement taken in COP21 to reduce emissions in COP26. The building sector is one of the culprits with a 70 % future energy consumption forecasted by 2050 i.e., the year certain countries aim to carbon neutral (e.g., Sweden). An old building with a severe problem of energy leakage has been studied under the influence of multiple parameters such as building orientation, shading systems, location, Low-E film and an alternative energy supply (GHP). The original building’s EnU amounted to 194.5 kWh/m2•yr; the parameters were applied and orientation of 90⁰ worked best, if the building was being designed, contrary to this case. However, energy reductions, compared to the base model, were actually achieved with the application of Low-E (5%) films and when substituting the heating demand with a GHP (57.5%), LEF-GHP reached (59.2%) and a corresponding decrease in CO2 emissions. Thermal comfort was best achieved with models that had the highest energy consumption such as LEF and ES making it counterproductive in fulfilling the aim of reducing GHG footprint of Rådhuset. The economic feasibility study showed that the installation of a GHP with at least the COP of 4.0 would lead to a shorter payback period than solely applying LEF. A tailored solution of a change in the energy source such as electrified heat supply from renewables combined with LEFs would reduce the energy and emission impact of any building; this would help the building sector reach the envisioned goal of carbon neutrality in 2050.

Energy Retrofitting

Building Performance

Thermal Comfort

Shading

Building Orientation

Location

Low-E films

Solar Gains

Energy Systems

Energisystem

Design, fabrication and performance analysis of vacuum glazing units fabricated with low and high temperature hermetic glass edge sealing materials

Memon, Saim

January 2013

Vacuum glazing is a vital development in the move to more energy efficient buildings. In vacuum glazing, an evacuated cavity supresses gaseous conduction and convection to provide high thermal resistance. A high vacuum pressure (less than 0.1 Pa) is required and must be maintained by a hermetic seal around the periphery, currently formed with either indium (i.e. low temperature sealing method) or solder glass (i.e. high temperature sealing method). This thesis reports the results of an experimental and theoretical investigation into the development of new low temperature (less than 200°C) and novel high temperature (up to 450°C) glass edge seals. A new low temperature composite edge seal was developed in which double and triple vacuum glazings each of dimensions 300x300mm were fabricated with measured vacuum pressures of 4.6x10-2Pa and 4.8x10-2Pa achieved respectively. A three dimensional finite element model of the fabricated design of composite edge sealed triple vacuum glazing was developed.

621.5

Pasivní bytový dům / Passive apartment building

Čejka, Radek

January 2016

The aim of the thesis is the proposal and the preparation of project documentation for the construction of passive residential building on a plot number 1691/96 cadastral area of Černovice in a Brno city. The residential building will be built in a sloping terrain. It is a five-storey residential building with one floor below ground. The house has 16 residential units and is designed for a maximum of 40 people. Two of the units are designed as a wheelchair accessible. The skeletal staircase of a building is located outside the main building. The residential units are connected by porch. The porch is built from a steel skeleton and is standing outside the main building. At the south side of building is free standing steel construction used as balcony for residential units. Perimeter wall is made of sand-lime blocks which are insulated by graphite expanded polystyrene. Perimeter wall of basement is made of permanent formwork filled with concrete. The wall is also insulated with extruded polystyrene. The ceilings are made of prestressed concrete panels Spiroll. The supporting roof structure is made of wood trusses. The roof is pitched and the roof deck is designed vegetational. The building is ventilated using forced air handling unit. Heating and hot water is provided sources: pellet boiler and photothermic panels. The apartment house is designed with regard to energy saving as passive. Emphasis is placed on a compact building envelope, simplicity of shape, air tightness, low heat loss and high solar gain arising due the building orientation to the cardinal directions.

Solární zisky v budovách / Solar Gains in Buildings

Tenora, Tomáš

January 2013

Master’s thesis deals with solar gains in buildings. The thesis presents an overview of the theoretical knowledge to solve solar gain. The thesis deals possibilities of measuring the intensity of solar radiation and evaluation of data from the meteorological station in the experimental part. Application of topic is then used for polyfunctional building. This part aims to show possibilities of design of air conditioning systems for the purpose of making indoor microclimate and their subsequent evaluation.

Wellness Čeladná / Wellness Čeladná

Kozumplíková, Markéta

January 2022

The aim of this master thesis is to design a low-energy building for civic amenities, specifically the design of a recreational wellness centre. The building has an L-shaped floor plan with a flat roof and is designed with two above ground and one underground floor. The ground floor will serve as a wellness centre with a swimming pool and saunas. Massages and solariums are proposed on the 2nd floor. Technical facilities are located in the basement. The first part of the thesis is devoted to the architectural and structural design. Structurally, the building is divided into two parts. The part of the administrative facilities and the massage rooms consists of a construction of the character of a transverse wall system made of cut brick blocks and insulated with ETICS. The internal masonry is designed in ceramic ground bricks. Ceiling structures are in the form of continuous reinforced concrete slab. The building is based on footings and waist foundations. The roof of the building is single-skin flat with a gravel. The wellness part is made up of a monolithic diaphragm skeleton with high slenderness columns. The horizontal load-bearing structure in this case again consists of a continuous monolithic reinforced concrete slab. The second part of the thesis deals mainly with the environmental engineering of the buildings. The building will be heated by a pellet boiler and will also use energy from photovoltaic panels. Ventilation in the building is provided by air handling units with heat recovery. The third part of the thesis deals with the assessment of solar gains in the indoor environment of the pool hall. Three variants are proposed with multi-criteria evaluation and the optimal option is selected. The thesis is mainly elaborated in Archicad, Deksoft, MS Excel and Word software.