High Performance Window Systems And Their Effect On Perimeter Space Commercial Building Energy Performance

High Performance Window Systems and Their Effect on Perimeter Space Commercial Building Energy Performance

Author : Ivan Yun Tong Lee

Publisher :

Page : 306 pages

File Size : 48,47 MB

Release : 2010

Category :

ISBN :

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Book Description

In the quest for improving building energy efficiency raising the level of performance of the building enclosure has become critical. As the thermal performance of the building enclosure improves so does the overall energy efficiency of the building. One key component in determining the energy performance of the building enclosure is windows. Windows have an integral role in determining the energy performance of a building by allowing light and heat from the sun to enter into a space. Energy efficient buildings take advantage of this free solar energy to help offset heating energy consumption and electric lighting loads. However, windows are traditionally the least insulating component of the modern building assembly. With excessive use, larger window areas can lead to greater occupant discomfort and energy consumption from greater night-time heat loss, higher peak and total cooling energy demand from unwanted solar gains, and discomfort glare. As a result, windows must be carefully designed to not only minimize heat loss, but also effectively control solar gains to maintain both a thermally and visually comfortable environment for the appropriate climate region and orientation. In this thesis, a complete analysis of window assemblies for commercial office buildings is presented. The analysis is divided into three sections: the Insulated Glazing Unit (IGU), the Curtain Wall Section (frames), and the overall energy performance of a typical office building. The first section investigates the performance characteristics of typical and high performance IGUs, specifically its insulating value (Ucg), its solar heat gain properties (Solar Heat Gain Coefficient, SHGC), and its visual transmittance (VT) through one-dimensional heat transfer and solar-optical modeling. Mechanisms of heat transfer across IGUs were investigated giving insight into the parameters that had the most significant effect on improving each performance characteristic. With a through understanding of IGU performance, attainable performance limits for each of property were generated from combining of different glazing materials, fill gases, and coatings. Through the right combination of materials IGU performance can be significantly altered. The U-value performance of IGUs ranges from 2.68 W/m2K (R-2.1) for a double-glazed, clear, air filled IGU to 0.27 W/m2K (R-21) for a quint-glazed, low-E, xenon filled high performance IGU. The second part of the thesis looks at the thermal performance of curtain wall sections that hold the IGU through two-dimensional heat transfer modeling. Similar to the IGUs, heat transfer mechanisms were studied to by substituting different materials to determine which components are crucial to thermal performance. From this analysis improvements were made to typical curtain wall design that significantly reduces the overall heat transfer within the frame section, producing a high performance curtain wall section. With simple modifications, a high performance curtain wall section can reduce its U-value by as much as 81% over a typical curtain wall section, going from 13.39 W/m2K to 2.57 W/m2K. Thus significantly reducing the U-value of curtain wall systems, particularly for smaller windows. The final part of the thesis examines the impact of typical and high performance windows on the energy performance of perimeter offices of a high-rise commercial building located in Southern Ontario. An hourly simulation model was set up to evaluate both the annual and peak energy consumption of a typical perimeter office space. The office faced the four cardinal directions of north, east, south, and west to evaluate the effect of orientation. The model also included continuous dimming lighting controls to make use of the available daylight. The effect of exterior shading on perimeter space energy performance was also investigated with both dynamic and static exterior shading devices. The results of the simulations revealed that window properties have very little influence on the energy performance of a high internal heat gain office, that is typical of older offices with less energy efficient office equipment and lighting and a higher occupant density. Conversely, window properties, particularly the insulating value of the window, has a greater effect on the energy performance of a mid to low internal heat gain office that is typical of most modern day commercial buildings. The results show windows with lower U-values yet higher SHGC are preferred over windows of similar U-values but with lower SHGC. The results also indicate that both static and dynamic shading have very little effect on energy performance of mid to low internal heat gain offices. From this analysis optimal window areas in the form of window-to-wall ratios (WWR) are presented for each orientation for mid to low internal heat gain offices. The optimal WWR for south-facing facades are between 0.50 to 0.66, and 0.30 to 0.50 for east-, west-, and north-facing facades, while for high internal heat gain perimeter spaces window areas should be kept to a minimum.



Window Systems for High-performance Buildings

Author : John Carmody

Publisher : W W Norton & Company Incorporated

Page : 400 pages

File Size : 46,69 MB

Release : 2004

Category : Architecture

ISBN : 9780393731217

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Book Description

The challenge in designing facades and selecting windows in commercial buildings is balancing many issues and criteria. This fact-packed handbook outlines the basics of glazing selection and provides critical information and performance data on the energy efficiency, interior environment, technical, and life-cycle-cost considerations that drive window design decisions in commercial buildings.



Opportunities and Life Cycle Energy Impacts of High-performance Windows in Reducing Energy Use in Residential Buildings

Author : Negar Ashrafi

Publisher :

Page : pages

File Size : 42,91 MB

Release : 2016

Category :

ISBN :

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Book Description

Today's energy-efficient windows can dramatically lower heating and cooling costs associated with windows while increasing occupant comfort. However, consumers are often confused about how to select the most efficient window for a residence. Furthermore, how this efficiency is defined is another problem that needs to be addressed.Energy consumption is a scale that is used for defining energy efficiency. In most cases, the amount of energy that is used during the products service life (operational energy) will be measured as the total energy consumption of the product. However, the amount of energy that is used for producing a product is also as much important as operational energy, which should be taken into consideration.In this thesis, it was attempted to provide useful recommendations for selecting the most efficient window glazing systems with regard to their overall energy consumption, using a Life-Cycle Energy Analysis (LCEA) method. The effect of using thirteen (13) different commonly used types of glazing systems on the annual energy use for a residential building was compared in various climate conditions across the U.S. Moreover, the amount of energy required for producing these glazing systems were identified. The results obtained from the analyses of these two phases of the study was used to create a simple set of guidelines, which can be utilized to select the most efficient glazing systems in terms of overall energy consumption based on different climate condition.



The Energy Performance of Buildings' Window Systems

Author : Ali Tahouri

Publisher : LAP Lambert Academic Publishing

Page : 100 pages

File Size : 18,30 MB

Release : 2015-12-29

Category :

ISBN : 9783659786808

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Book Description

Buildings are responsible for over 30% of the heat loss in the building envelop. However, window creates a sense of spacious for the room and provides natural lighting, view and ventilation for the interior space. It is important to consider windows with the highest rate of energy consumption in the building envelop, being five times more than the other elements. With proper selection of window glazing and their design its help to minimize the energy consumption level. The limitation of this research is that it has only focused on vertical and fixed window plates without any shading devices; how they will minimize the heat loss by improving the glazing material or replacing the glass material to block the infrared radiation and prevent unwanted heat gain in summer period, in the Colored Building of the Faculty of Architecture at Eastern Mediterranean University, North Cyprus.



High Performance Commercial Fenestration Framing Systems

Author :

Publisher :

Page : pages

File Size : 31,86 MB

Release : 2010

Category :

ISBN :

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Book Description

A major objective of the U.S. Department of Energy is to have a zero energy commercial building by the year 2025. Windows have a major influence on the energy performance of the building envelope as they control over 55% of building energy load, and represent one important area where technologies can be developed to save energy. Aluminum framing systems are used in over 80% of commercial fenestration products (i.e. windows, curtain walls, store fronts, etc.). Aluminum framing systems are often required in commercial buildings because of their inherent good structural properties and long service life, which is required from commercial and architectural frames. At the same time, they are lightweight and durable, requiring very little maintenance, and offer design flexibility. An additional benefit of aluminum framing systems is their relatively low cost and easy manufacturability. Aluminum, being an easily recyclable material, also offers sustainable features. However, from energy efficiency point of view, aluminum frames have lower thermal performance due to the very high thermal conductivity of aluminum. Fenestration systems constructed of aluminum alloys therefore have lower performance in terms of being effective barrier to energy transfer (heat loss or gain). Despite the lower energy performance, aluminum is the choice material for commercial framing systems and dominates the commercial/architectural fenestration market because of the reasons mentioned above. In addition, there is no other cost effective and energy efficient replacement material available to take place of aluminum in the commercial/architectural market. Hence it is imperative to improve the performance of aluminum framing system to improve the energy performance of commercial fenestration system and in turn reduce the energy consumption of commercial building and achieve zero energy building by 2025. The objective of this project was to develop high performance, energy efficient commercial fenestration framing systems, by investigating new technologies that would improve the thermal performance of aluminum frames, while maintaining their structural and life-cycle performance. The project targeted an improvement of over 30% (whole window performance) over conventional commercial framing technology by improving the performance of commercial framing systems.



Effective Daylighting with High-Performance Facades

Author : Kyle Konis

Publisher : Springer

Page : 282 pages

File Size : 19,31 MB

Release : 2017-05-09

Category : Technology & Engineering

ISBN : 3319394630

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Book Description

The book explores advanced building-facade daylighting design practices based on diverse energy and human-factor performance metrics. It also defines effective daylighting by rethinking the simplified approach to glazing and facade systems to incorporate the local climate and the needs of building occupants as critical drivers of building performance, design solutions and technological innovation. It discusses state-of-the-art approaches in the context of simulation-based design workflows, innovative technologies and real project case studies, all targeting low and net-zero energy solutions that enhance occupant comfort. Readers benefit from a comprehensive approach that improves the feedback loop between design intent and performance in use. The book is intended for architects, lighting designers, facade engineers, manufacturers and building owners/operators, as well as advanced students.



Residential Windows

Author : John Carmody

Publisher : W. W. Norton & Company

Page : 236 pages

File Size : 47,3 MB

Release : 2000

Category : Architecture

ISBN : 9780393730531

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Book Description

This edition covers every aspect of window design and technology and includes a much-expanded sextion on energy performance, with an extended list of climate zones and glazing options.



Evaluation of the Potential Impact of Electrochromic Windows on the Energy Performance of Commercial Buildings

Author : Maria Corsi

Publisher :

Page : 0 pages

File Size : 47,74 MB

Release : 2000

Category : Buildings

ISBN :

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Book Description

Electrochromic windows appear to be the most promising emerging technology to improve building performance as they provide greater control of solar gains; they have a potentially significant impact on the indoor visual environment and energy requirements of commercial buildings. The research work presented in this thesis, which is accomplished using computer simulation, proposes to undertake an engineering evaluation of the performance of electrochromic glazings and to advance knowledge in the field by developing a new model to simulate their control. First, the performance of an experimental electrochromic coating is compared relative to conventional glazing types. The APPLIED FILM LAMINATOR and WINDOW 4.1 computer programs are used to evaluate the global parameters characterizing window performance (solar and visible transmittance, U-value, and solar heat gain coefficient). A critical evaluation of existing control strategies is performed using DOE-2.1E to study the effect of several driving variables for switching on the cooling load of an existing large commercial building. The present capabilities of the DOE program are expanded using the Functional Values approach in order to study the effect of the electrochromic glazing switching time for the building's perimeter zones. Since electrochromic windows affect both building energy consumption and visual quality, the optimization of the switching time is formulated as a multi-objective model with two conflicting objectives (energy and visual quality). Pareto optimum solutions are shown for different weighting coefficients applied to both objectives. This approach constitutes the basis of an automated optimized electrochromic glazing switching strategy that is developed and incorporated in the DOE-2.1E program.



The Environmental Performance of Tall Buildings

Author : Joana Carla Soares Goncalves

Publisher : Routledge

Page : 401 pages

File Size : 22,92 MB

Release : 2010-09-23

Category : Architecture

ISBN : 1136531319

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Book Description

Not simply another showcase for future utopian designs and ideals, the information presented here is based on hard research from operating buildings. This insightful book takes in: an overview of the tall building and its impacts (looking at cityscape, place, mobility, microclimate, energy and economics) design principles and the development of the sustainable tall building global perspectives (covering North and South America, Europe, the Middle East and Asia) detailed, qualitative case studies of buildings in design and operation the future for sustainable tall buildings. Highly illustrated and combining analysis with solid detail for practice, this is essential reading for architects, building engineers, design consultants, retrofitters and urban planners interested in or working with tall buildings, and researchers/students in these disciplines.



Achieving High-Performance Federal Facilities

Author : National Research Council

Publisher : National Academies Press

Page : 158 pages

File Size : 13,84 MB

Release : 2011-11-07

Category : Technology & Engineering

ISBN : 0309211719

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Book Description

The design, construction, operation, and retrofit of buildings is evolving in response to ever-increasing knowledge about the impact of indoor environments on people and the impact of buildings on the environment. Research has shown that the quality of indoor environments can affect the health, safety, and productivity of the people who occupy them. Buildings are also resource intensive, accounting for 40 percent of primary energy use in the United States, 12 percent of water consumption, and 60 percent of all non-industrial waste. The processes for producing electricity at power plants and delivering it for use in buildings account for 40 percent of U.S. greenhouse gas emissions. The U.S. federal government manages approximately 429,000 buildings of many types with a total square footage of 3.34 billion worldwide, of which about 80 percent is owned space. More than 30 individual departments and agencies are responsible for managing these buildings. The characteristics of each agency's portfolio of facilities are determined by its mission and its programs. In 2010, GSA's Office of Federal High-Performance Green Buildings asked the National Academies to appoint an ad hoc committee of experts to conduct a public workshop and prepare a report that identified strategies and approaches for achieving a range of objectives associated with high-performance green federal buildings. Achieving High-Performance Federal Facilities identifies examples of important initiatives taking place and available resources. The report explores how these examples could be used to help make sustainability the preferred choice at all levels of decision making. Achieving High-Performance Federal Facilities can serve as a valuable guide federal agencies with differing missions, types of facilities, and operating procedures.