Coupling of Thermal Mass with Night Ventilation in Buildings

January 2011

abstract: Passive cooling designs & technologies offer great promise to lower energy use in buildings. Though the working principles of these designs and technologies are well understood, simplified tools to quantitatively evaluate their performance are lacking. Cooling by night ventilation, which is the topic of this research, is one of the well known passive cooling technologies. The building's thermal mass can be cooled at night by ventilating the inside of the space with the relatively lower outdoor air temperatures, thereby maintaining lower indoor temperatures during the warmer daytime period. Numerous studies, both experimental and theoretical, have been performed and have shown the effectiveness of the method to significantly reduce air conditioning loads or improve comfort levels in those climates where the night time ambient air temperature drops below that of the indoor air. The impact of widespread adoption of night ventilation cooling can be substantial, given the large fraction of energy consumed by air conditioning of buildings (about 12-13% of the total electricity use in U.S. buildings). Night ventilation is relatively easy to implement with minimal design changes to existing buildings. Contemporary mathematical models to evaluate the performance of night ventilation are embedded in detailed whole building simulation tools which require a certain amount of expertise and is a time consuming approach. This research proposes a methodology incorporating two models, Heat Transfer model and Thermal Network model, to evaluate the effectiveness of night ventilation. This methodology is easier to use and the run time to evaluate the results is faster. Both these models are approximations of thermal coupling between thermal mass and night ventilation in buildings. These models are modifications of existing approaches meant to model dynamic thermal response in buildings subject to natural ventilation. Effectiveness of night ventilation was quantified by a parameter called the Discomfort Reduction Factor (DRF) which is the index of reduction of occupant discomfort levels during the day time from night ventilation. Daily and Monthly DRFs are calculated for two climate zones and three building heat capacities. It is verified that night ventilation is effective in seasons and regions when day temperatures are between 30 oC and 36 oC and night temperatures are below 20 oC. The accuracy of these models may be lower than using a detailed simulation program but the loss in accuracy in using these tools more than compensates for the insights provided and better transparency in the analysis approach and results obtained. / Dissertation/Thesis / M.S. Mechanical Engineering 2011

Energy

Architectural engineering

Discomfort Reduction

Night Ventilation

Thermal Mass

Modelling and thermal optimization of traditional housing in a hot arid area

Murad Khan, Hayder Mirza Majeed

January 2015

This thesis studies the use of night ventilation as a passive cooling strategy for a traditional courtyard house in a hot dry climate. This was done by CFD simulation of the house and its surroundings, using weather data for Baghdad. The simulation was done for a large number of scenarios in which each represented a change in one of the house elements, such as courtyard and room dimensions, and in some cases included modern technologies such as a ceiling fan. The thesis suggests that performance should be calculated with the aid of a "Night Time Effectiveness Ratio" (NTER) and time constants. The findings show that building elements can change the performance to various degrees, that the airflow patterns inside the rooms change from day to night, and that the thermal conditions during the day depend more on the intensity of solar radiation than other factors. The results show that a courtyard house can ensure the thermal comfort for its residents. However, it needs some assistance from new techniques such as fans to keep the air quality inside the house within acceptable limits. The values for NTER from initial simulations are around ten, which indicate that night ventilation is not enough for cooling the building. However, the values drop to less than one by using a small and narrow courtyard with a two-level house and a gallery around the courtyard. Also, it is necessary to have a connection between the courtyard and alleyway at ground level in the night only and to cover the courtyard during the day. The windows have the largest role in deciding the performance of night ventilation. Ideally they should be small and tall, or preferably a pair of windows separated by a vertical distance and kept closed during the day. The effects of room dimension are clearer in affecting the thermal comfort more than improving the performance of night ventilation. The research also examines the indoor air quality and suggests ways to improve it. Some of the ways are traditional like the use of a wind catcher in ventilating the courtyard and the basement, and others are more modern like using an exhaust fan. Furthermore, it suggests an algorithm to control these ways and to introduce only a limited quantity of fresh air to avoid excessive warming. Suggestions for future work are given, including tests for more elements in the courtyard house and for longer duration runs. It would also be helpful to study the use of latent heat storage (e.g. phase change material) as an additional effective thermal mass.

697.9

Evaluation of Thermal Comfort and Night Ventilation in a Historic Office Building in Nordic Climate

Bakhtiari, Hossein

January 2020

Envelopes with low thermal performance are common characteristics in European historic buildings resulting in insufficient thermal comfort and higher energy use compared to modern buildings. There are different types of applications for the European historic buildings such as historic churches, historic museums, historic theatres, etc. In historic buildings refurbished to offices, it is vital to improve thermal comfort for the staff. Improving thermal comfort should not increase, preferably reduce, energy use in the building. The overall aim in this research is to explore how to improve thermal comfort in historic buildings without increasing, preferably reducing, energy use with the application of non-intrusive methods. This is done in form of a case study in Sweden. Thermal comfort issues in the case study building are determined through a field study. The methods include field measurements with thermal comfort equipment, data logging on BMS, and evaluating the occupant’s perception of a summer and a winter period indoor environment using a standardized questionnaire. According to questionnaire and thermal comfort measurements results, it is revealed that the summer period has the most dissatisfied occupants, while winter thermal comfort is satisfactory – but not exceptionally good. Accordingly, natural heat sinks could be used in form of NV, as a non/intrusive method, in order to improve thermal comfort in the building. For the historic building equipped with mechanical ventilation, NV strategy has the potential to both improve thermal comfort and reduce the total electricity use for cooling (i.e. electricity use in the cooling machine + the electricity use in the ventilation unit’s fans). It could decrease the percentage of exceedance hours in offices by up to 33% and reduce the total electricity use for cooling by up to 40%. The optimal (maximum) NV rate (i.e. the potential of NV strategy) is dependent on the thermal mass capacity of the building, the available NV cooling potential (dependent on the ambient air temperature), COP value of the cooling machine, the SFP model of the fans (low SFP value for high NV rate is optimal), and the offices’ door scheme (open or closed doors).

historic buildings

office buildings

Nordic climate

thermal comfort

field (on-site) measurements

standardized questionnaire

building management system (BMS)

night ventilation (NV)

building energy simulation (BES)

IDA-ICE

Energy Systems

Energisystem