BCIT Thesis and other Required Graduate Degree Works | BCIT Institutional Repository

BCIT Thesis and other Required Graduate Degree Works

Development and application of an advanced green roof model
Green roofs are becoming a common application in order to improve building energy performance, runoff water control with several additional environmental benefits. Models are essential in the building science due to a necessity of prediction how different structures perform. This knowledge helps to choose right materials and material dimensions. A green roof structure is a complex system of different layers, including growing media and plants. Those two layers make the green roof modelling entirely different from ordinary modelling. Nowadays, several green roof models cover different phenomena and use different physical principles. However, a green roof model is still can be improved. Therefore, this study develops a green roof model- HAMFit-GR that better covers heat and moisture movement sources. The model is based on Heat-Air-Moisture model called HAMFit and Fast All-Season Soil Strength models from US Army Corps of engineers. A combined model is proposed to be more accurate than the most comprehensive green roof models. The result is achieved by adding uncovered components, such as coupling heat and moisture transport in growing media and runoff water flow. Green roof parameters that are required for accurate modelling are measured through laboratory and field experiments. The benchmark data is obtained from the field experiment that is being performed at Whole Building Performance Research Laboratory (WBPRL) of Building Science Centre of Excellence at British Columbia Institute of Technology (BCIT), Burnaby. A case study is prepared with the validated model. The case study includes analysis of green roof parameters impact on roof hydrothermal performance.
Experimental investigation of living architecture design tools to attenuate rooftop noise
The aim of this research is to investigate the viability of designing urban rooftop soundscapes. The prerequisite is to reduce the sound propagation from road traffic by introducing living architectural rooftops with various components of sound attenuating technologies. The final goal is to turn unused rooftop space into a livable urban green space, where soundscape is balanced, and sound energy is reduced to the limits recommended by the World Health Organization (WHO). The first part of this research is to identify the potential of living architectural technologies to attenuate noise from road traffic. More than 33 measurements are performed of living architecture design tools, such as green roofs, berms at edge, living wall barriers and overhangs, to investigate the behavior of sound attenuation in an anechoic chamber and in ODEON, a computer simulation software. The second part of this research is to use the findings on the proposed design tools for an architectural case study, a flat-roof five-storey building located on East Hastings Street. The use of a combination of green roof, berm, overhang, guard and living wall can reduced urban traffic noise from 70 dBA on the roof to 55 dBA, creating additional acoustically healthy habitable space in the urban environment.
Experimental investigation of residential building heating and ventilation systems performance
The building sector is one of the most dynamically evolving field with an expectation to provide comfortable, clean and healthy indoor environment with less energy consumption. This acceptable indoor condition is created with a combination of heating/cooling systems and ventilation strategies. There are various systems available, which can deliver heating/cooling as well as ventilation to a dwelling space. These systems involve different heat transfer mechanisms and ventilation strategies: as a result, their performance would be different. Accordingly, the performance of these systems would affect indoor conditions. The process of providing an acceptable indoor environment with minimized energy use can be challenging. In addition to that, there is also a keen interest to reduce the current trend of the building energy consumption as low as possible without affecting the required, comfortable indoor environment. Therefore, the requirement of comprehensive field research that studies and compares most of currently available space heating systems, as well as ventilation strategies, is highly vital to provide information about their actual and relative performance in a real scenario. This research project conducts a field experiment that studies, heating systems, ventilation strategies, and ventilation flow rates. The first part is done by running two different heating systems at a time out of four heating systems (electrical baseboard heater, portable radiator heater, heat pump, and Radiant floor heating systems) in identical full-scale test building with similar ventilation strategy and similar ventilation flow rate. Whereas, the second group of experiments compare two ventilation strategies (mixed ventilation and underfloor ventilation) inside two test buildings with similar heating systems and ventilation flow rate. The third group of comparison compares three ventilation flow rates (15 cfm, 7.5 cfm, and 5 cfm) in the test buildings with similar heating systems and ventilation strategies. Various indicators and indoor environmental elements are used to conduct the comparisons. In the first case where heating systems are compared, the thermal energy provide by the systems are used for comparison. In addition, the thermal comfort, local thermal discomfort, temperature distribution and RH distribution are used to assess and compare the indoor environment produced by the systems. Whereas, the ventilation strategies are compared using indoor environmental element (temperature, relative humidity, CO2, and air velocity) distributions. Finally, the comparison of ventilation flow rates is performed using contaminant removal effectiveness, indoor air quality number, and indoor environmental element distributions. The findings from the experiments indicate that all of the heating systems provide similar daily thermal energy between 10 kWh and 14 kWh based on the outdoor weather condition. In addition, all of the heating systems produce a thermally comfortable indoor environment for standing person. Whereas, the ventilation strategies comparison shows that mixed ventilation strategy performance is slightly better than an underfloor Ventilation strategy by creating marginally uniform CO2 and RH distribution. Moreover, the results of the ventilation flow rates comparison show that the temperature and air velocity distribution find similar while using all the three ventilation flow rates. But the higher ventilation flow rate removes relatively more RH and CO2 in comparison to the lower one. Accordingly, the higher ventilation flow rates depict higher contaminant removal rate and high indoor air quality number relative to lower ventilation flow rate., Ventilation Effectiveness, Ventilation Flow Rate, Indoor Air Quality Number, Thermal Energy, Portable Radiator Heater