Therma performance of buildings with post-tensioned timber structure compared with concrete and steel alternatives

Perez Fernandez, Nicolas

January 2012

This thesis describes the influence of thermal mass on the space conditioning energy consumption and indoor comfort conditions of multi-storey buildings with concrete, steel and timber structural systems. The buildings studied were medium sized educational and commercial buildings. When calculating a building’s life-cycle energy consumption, the construction materials have a direct effect on not only the building’s embodied energy but also on the space conditioning energy. The latter depends, amongst other things, on the thermal characteristics of the building’s materials; thermal mass can also be an influence on comfort conditions in the building. A modelling comparison has been undertaken between three very similar medium-sized buildings, each designed using structural systems made primarily of timber, concrete and steel. The post-tensioned timber version of the building is a modelled representation of a real three-storey educational building that has been constructed recently in Nelson, New Zealand. The concrete- and steel-structured versions have been designed on paper to conform to the required structural codes and meet, as closely as possible, the same performance, internal space layout and external façade features as the real timber-structured building. Each of these three structurally-different buildings has been modelled with two different thermal envelopes (code-compliant and New Zealand best-practice) using a heating, ventilating and air conditioning (HVAC) system with heating only (educational scheme) and heating and cooling (commercial scheme). The commercial system (with cooling) was applied only to the buildings with the best-practice thermal envelope. The analysis of each of these nine different construction and usage categories includes the modelling of operational energy use with an emphasis on HVAC energy consumption, and the assessment of indoor comfort conditions using predicted mean vote (PMV). From an operational energy use perspective, the modelling comparison between the different cases has shown that, within each category (code-compliant, low-energy and low-energy-commercial), the principal structural material has only a small effect on overall performance. The most significant differences are in the building with the best-practice thermal envelope with the commercial HVAC system, were the concrete building has slightly lower HVAC energy consumption, being 3 and 4% lower than in the steel and timber buildings respectively The assessment of indoor comfort conditions during occupied periods through using PMV for each of the three categories shows that the timber structure consistently exhibited longer periods in the over-warm comfort zone, but this was much less pronounced in south-facing spaces. To examine the reasons for the less acceptable PMV in the timber-structure versions, an analysis of indoor timber and concrete surface temperatures was carried out in both buildings. It was found that, particularly in north-facing spaces, there were large diurnal swings in the temperatures of timber surfaces exposed to solar radiation. These swings were much less in the case of concrete surfaces so the environment was perceived to be more comfortable under such conditions because of the reduced influence of higher mean radiant temperatures. To moderate this potential downside of solar-exposed internal timber surfaces, better results are achieved if, when timber is used for thermal mass, the timber is not exposed to direct solar radiation, for example locating it in the ceilings or on the south side of the building. Two other approaches to combating the potential overheating problem in the timber-structured buildings were analysed in an illustrative mode; addition of external louvres to reduce direct solar gains at critical times of day and year; and use of phase change material (PCM) linings to act as light-mass energy buffers. Although external louvres increase comfort conditions significantly by reducing the periods of an overly warm environment, they produce an increase in heating energy consumption through reducing beneficial solar gains. The use of PCM linings shows little benefit to overall indoor comfort conditions for the building of this case-study.

Energy perfromance of buildings

Thermal performance of buildings

Thermal mass

comfort in buildings

Otimização de parâmetros de projeto de tubulações de sistemas de calefação por piso radiante. / Optimization of piping design parameters for a radiant floor heating system.

Díaz Rastello, María Carolina

02 September 2013

Devido à climatização dos ambientes internos condicionar o bem estar e o conforto térmico das pessoas é que se fazem necessárias novas pesquisas que procurem potencializar as tecnologias existentes e reduzir tanto os custos de instalação quanto o consumo de energia. É sabido que os sistemas convencionais de calefação proporcionam um alto consumo de energia e uma emissão de níveis de ruído muitas vezes inaceitáveis, entretanto os sistemas radiantes ganham, a cada dia, uma maior abrangência como alternativa de climatização devido às suas vantagens comparativas com relação aos sistemas convencionais. O emprego de sistemas de calefação por piso radiante em muitos países é limitada pelo preço da instalação como consequência do elevado custo dos materiais como é o caso da fabricação das tubulações. Estas geralmente são fabricadas de polietileno ou de cobre, sendo este ultimo o que entrega um maior desempenho térmico e, por conseguinte um melhor fornecimento de energia, mas o elevado custo deste material restringe o seu uso principalmente ao setor residencial, podendo atingir um mercado maior que compreenda edifícios públicos, de escritório, escolas, hospitais, etc. Com isso, este trabalho procura reduzir a quantidade de materiais de tubulação necessários para garantir o desempenho do sistema e o conforto térmico de uma habitação aquecida com um sistema radiante. Para isto, foi desenvolvida a resolução numérica do modelo matemático da transferência de calor no interior do piso pelo método dos volumes finitos na formulação implícita e implementada em código computacional na linguagem Matlab. Para isto, foram considerados dois parâmetros fundamentais para garantir o conforto térmico da habitação que correspondem à temperatura da água e a distancia entre os tubos que compõem o sistema. A análise corresponde ao cálculo da temperatura superficial do piso para distintas temperaturas da água e distintas distâncias, obtendo resultados interessantes que permitem reduzir o custo da instalação em até um 40%. / Due to temperature control of interiors conditioning the well-being and the thermal comfort of people, it is necessary to make new researches aiming to improve the existing technologies and to reduce both installation costs and energy consumption. It is known that the use of traditional heating systems involves high energy consumption and, in some cases, unacceptable noise levels; while radiant systems are gaining a wider scope as a heating alternative due to its advantages compared to conventional systems. The use of radiant floor heating systems in Brazil is limited by installation cost due to the high price of required materials. This fact restricts the use of these systems primarily to the residential sector. However, it may be possible for this technology to reach a larger market, including public buildings, offices, schools and hospitals. Therefore, to optimize the most relevant design parameters relating to the thermal performance of the system and reduce both the amount of required materials and the system operating time, this paper elaborates on a method consisting of a high-resolution numerical mathematical model of the heat transfer within a floor using a finite control volume method with an implicit solution scheme. In this work, we consider how the properties of the materials, environmental thermal comfort factors and the performance of the system work together with the theoretical underpinnings of the heat transfer phenomenon to define the design parameters to optimize the materials and provide greater control over the energy consumption. This optimization is achieved without changing any environmental thermal comfort conditions or the well-being of the occupants. Finally, a numerical solution for the heat transfer within the floor is implemented using the computer code Matlab.

Calefação

Conforto térmico

Heating systems

Piso radiante

Radiant floor systems

Thermal comfort

Otimização de parâmetros de projeto de tubulações de sistemas de calefação por piso radiante. / Optimization of piping design parameters for a radiant floor heating system.

María Carolina Díaz Rastello

02 September 2013

Devido à climatização dos ambientes internos condicionar o bem estar e o conforto térmico das pessoas é que se fazem necessárias novas pesquisas que procurem potencializar as tecnologias existentes e reduzir tanto os custos de instalação quanto o consumo de energia. É sabido que os sistemas convencionais de calefação proporcionam um alto consumo de energia e uma emissão de níveis de ruído muitas vezes inaceitáveis, entretanto os sistemas radiantes ganham, a cada dia, uma maior abrangência como alternativa de climatização devido às suas vantagens comparativas com relação aos sistemas convencionais. O emprego de sistemas de calefação por piso radiante em muitos países é limitada pelo preço da instalação como consequência do elevado custo dos materiais como é o caso da fabricação das tubulações. Estas geralmente são fabricadas de polietileno ou de cobre, sendo este ultimo o que entrega um maior desempenho térmico e, por conseguinte um melhor fornecimento de energia, mas o elevado custo deste material restringe o seu uso principalmente ao setor residencial, podendo atingir um mercado maior que compreenda edifícios públicos, de escritório, escolas, hospitais, etc. Com isso, este trabalho procura reduzir a quantidade de materiais de tubulação necessários para garantir o desempenho do sistema e o conforto térmico de uma habitação aquecida com um sistema radiante. Para isto, foi desenvolvida a resolução numérica do modelo matemático da transferência de calor no interior do piso pelo método dos volumes finitos na formulação implícita e implementada em código computacional na linguagem Matlab. Para isto, foram considerados dois parâmetros fundamentais para garantir o conforto térmico da habitação que correspondem à temperatura da água e a distancia entre os tubos que compõem o sistema. A análise corresponde ao cálculo da temperatura superficial do piso para distintas temperaturas da água e distintas distâncias, obtendo resultados interessantes que permitem reduzir o custo da instalação em até um 40%. / Due to temperature control of interiors conditioning the well-being and the thermal comfort of people, it is necessary to make new researches aiming to improve the existing technologies and to reduce both installation costs and energy consumption. It is known that the use of traditional heating systems involves high energy consumption and, in some cases, unacceptable noise levels; while radiant systems are gaining a wider scope as a heating alternative due to its advantages compared to conventional systems. The use of radiant floor heating systems in Brazil is limited by installation cost due to the high price of required materials. This fact restricts the use of these systems primarily to the residential sector. However, it may be possible for this technology to reach a larger market, including public buildings, offices, schools and hospitals. Therefore, to optimize the most relevant design parameters relating to the thermal performance of the system and reduce both the amount of required materials and the system operating time, this paper elaborates on a method consisting of a high-resolution numerical mathematical model of the heat transfer within a floor using a finite control volume method with an implicit solution scheme. In this work, we consider how the properties of the materials, environmental thermal comfort factors and the performance of the system work together with the theoretical underpinnings of the heat transfer phenomenon to define the design parameters to optimize the materials and provide greater control over the energy consumption. This optimization is achieved without changing any environmental thermal comfort conditions or the well-being of the occupants. Finally, a numerical solution for the heat transfer within the floor is implemented using the computer code Matlab.

Calefação

Conforto térmico

Piso radiante

Heating systems

Radiant floor systems

Thermal comfort

Thermal performance of dwellings in Cyprus and approaches for energy conservation

Panayiotou, Gregoris

January 2014

Energy has always been the dominant driving force for the socio-economic development of mankind. Nowadays, the global energy system is highly depended on fossil fuels. A great share of the final energy consumption, over 40%, in the EU-27 is consumed by the existing building stock whereas dwellings account for 66.62% of this. Thus, the need to increase the energy performance of dwellings is an important instrument in the efforts to lessen Europe’s energy dependency. In order to define measures to increase the energy performance of dwellings a deeper understanding of their characteristics should be gained. Unfortunately, in Cyprus there is a gap in knowledge on this aspect. In this thesis the characteristics of the dwellings in Cyprus are defined through a sample of 500 dwellings. The results revealed that more than 80% of dwellings in Cyprus do not have thermal insulation installed on their envelope. From this it is clear that the definition of the optimum thermal insulation material to be applied in dwellings is very important. Thus, the commercially available thermal insulation materials and topologies used in Cyprus were reviewed and defined through a market survey and the typical dwelling was modelled. The effect of the application of thermal insulation to its energy behaviour was simulated using TRNSYS. This resulted in the definition of the optimum thermal insulation materials and topologies to be applied in both new and existing dwellings. Accordingly, the application of advanced commercially available materials such as Phase Change Materials (PCM) to the envelope of the typical dwelling was investigated. The energy savings achieved by the addition of a PCM layer on the envelope of the typical dwelling was found to be 28.6%. The optimum PCM case was also combined with the optimum thermal insulation combination and an energy saving of 68% was predicted. The incorporation of Renewable Energy Sources (RES) to the typical dwelling was also simulated and studied. Specifically, two types of standalone RES systems were initially evaluated; a solely photovoltaic (PV) system and a hybrid PV-Wind system. The results showed that the solely PV system is a much better option due to the very high solar potential of Cyprus in comparison to the poor wind profile of the island. Subsequently, a grid-connected PV system was also evaluated and the results showed that when a RES system is grid-connected the cost of the system is reduced to half of that of the standalone cases. This research has revealed that the optimum topology combinations to be applied in both new and existing dwellings in Cyprus is thermal insulation plaster or thermal insulation bricks (only for new dwellings) on the external walls combined with expanded polystyrene on the roof. These results will provide valuable information that will assist both engineers and architects in the efficient design of dwellings in Cyprus. The investigation of the application of macroencapsulated PCM showed that these materials are not yet an economically viable solution for application in Cyprus The findings also show that a solely PV system is the optimum RES system to be applied in Cyprus especially when it is grid-connected. The findings of this project are useful for individuals, house builders and designers as well as policy makers for the design of energy saving subsidy schemes.

333.79

Verificação dos valores dos coeficientes de convecção do ar no exterior de edifícios no estado da Paraíba

Porto, Eduardo Figueiredo

05 March 2007

Submitted by Viviane Lima da Cunha (viviane@biblioteca.ufpb.br) on 2017-07-18T13:27:53Z No. of bitstreams: 1 arquivototal.pdf: 2894407 bytes, checksum: 993603497277207e108988a17bd6d3b2 (MD5) / Made available in DSpace on 2017-07-18T13:27:53Z (GMT). No. of bitstreams: 1 arquivototal.pdf: 2894407 bytes, checksum: 993603497277207e108988a17bd6d3b2 (MD5) Previous issue date: 2007-03-05 / This research investigated and analysed the characteristics and peculiarities of wind flowing that take place in the state of Paraiba in order to verify the local values for the air coefficients of external convection (hc’s), based in non-dimensional numbers like Prandlt, Reynolds and Nusselt, and empirical correlations as suggested by Hilpert. These correlations are widely used and the results demonstrate that the verified values significantly differ from the ones currently recommended by the Brazilian norms concerning the thermal performance of buildings and the basic parameters of projects for central air-conditioners. The results highlighted the need to review these coefficients and take into consideration the interrelationship between the standards of local ventilation and construction regulations when calculating the thermal conditioning of buildings in order to minimize environmental impact and improve energy performance of buildings, which will reduce costs. / Este trabalho investigou e analisou as características e as condições de escoamento dos ventos que ocorrem no estado da Paraíba, a fim de determinar valores locais para os coeficientes de convecção do ar externo (hc’s), com base nos números adimensionais de Prandlt, Reynolds e Nusselt, e correlações empíricas com as sugeridas por Hilpert, que são largamente utilizadas, cujos resultados demonstraram que os valores verificados diferem significativamente dos valores atualmente recomendados palas Normas Brasileiras referentes ao desempenho térmico de edificações, e aos parâmetros básicos de projeto de centrais de ar-condicionado, conduzindo à necessidade de se reverem tais coeficientes e considerarem as inter-relações entre o padrão de ventilação local e o de ocupação do solo, quando do cálculo de acondicionamento térmico de edifícios, para se minimizar os impactos ambientais, otimizar o desempenho energético de edificações, aumentando a economia de energia reduzindo custos.

Coeficiente de convecção externo

Desempenho térmico de edificações

Transferência de calor

Vento

Coefficient of external convection

Thermal performance of buildings

Thermal conditioning of buildings

Heat transfer

Wind

ENGENHARIAS::ENGENHARIA CIVIL

Využití knihovny HAM-Tools pro simulaci tepelného chování rodinného domu / HAM-Tools library use for the simulation of the thermal performance of the house

Zábojník, Jakub

January 2015

In terms of master’s thesis HAM-Tools library designed for MATLAB/Simulink was modified for the use in simulations of houses in the Czech Republic. Modified library and its parts were described in detail and tested by the simulation of the one-zone and two-zones models of the house. The simulations of models with same parameters were also realized in program TRNSYS. The corresponding results achieved in mentioned simulation tools were compared to each other. The one-zone model created by using HAM-Tools library is tested by the simulation of ventilating, heating, cooling, and sources of moisture. A demonstration of the practical use of the simulation is carried out in the thesis, namely by examining the influence of the insulation thickness on the thermal performance of the house (resp. its heat loss) on real atmospheric conditions. Among others, available resources of meteorological data are mentioned and compared to each other. The function for processing of the meteorological data to a file compatible with the HAM-Tools library was created. It was also created a material data file containing commonly used materials of building structures in the Czech Republic and their parameters.