Simulations Of Indoor Air Quality And Ventilation Impacts Of Demand Controlled Ventilation In Commercial And Institutional Buildings PDF Download

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Simulations of Indoor Air Quality and Ventilation Impacts of Demand Controlled Ventilation in Commercial and Institutional Buildings

Simulations of Indoor Air Quality and Ventilation Impacts of Demand Controlled Ventilation in Commercial and Institutional Buildings
Author:
Publisher:
Total Pages: 54
Release: 2013-12-04
Genre:
ISBN: 9781494374280
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Carbon-dioxide (CO2) based demand controlled ventilation (DCV) offers the potential for more energy efficient building ventilation compared with constant ventilation rates based on design occupancy levels. A number of questions related to CO2-based DCV exist regarding potential energy efficiency benefits, optimal control strategies for different building types, and sensor performance and deployment. In addition, questions have been raised concerning the indoor air quality impacts, primarily with respect to contaminants with source strengths that are not dependent on the number of occupants. In order to obtain some insight into the issueof IAQ impacts of CO2-based DCV, a simulation study was performed in six commercial and institutional building spaces using the multizone airflow and IAQ model CONTAMW. These simulations compared six different ventilation strategies, with four of them using CO2 DCV, the simulations, performed for six U.S. cities, wereused to compare ventilation rates, indoor CO2 levels, indoor concentrations of a generic volatile organic compound (VOC) as an indicator of non-occupantcontaminant sources, and energy impacts. The results indicate that these impacts are dependent on the details of the spaces including occupancy patterns, ventilation rate requirements in the relevant standards and ventilation system operating schedule as well as the numerous assumptions used in the analysis, including contaminant source strengths and system-off infiltration rates. For the cases studied, the application of CO2 DCV resulted in significant decreases in ventilation rates and energy loadsaccompanied by increased indoor CO2 and VOC concentrations. The increases in CO2 were not particularly significant, in the range of 100 ppm (v). The indoor VOC levels increased by a factor of two or three, but the absolute concentrations were still relatively low based on the assumed emission rates. The annual energy loadreductions due to the use of CO2 control were significant in most of the cases, ranging from 10% to 80% depending on the space type, climate and ventilationstrategy.

State-of-the-art Review of CO2 Demand Controlled Ventilation Technology and Application

State-of-the-art Review of CO2 Demand Controlled Ventilation Technology and Application
Author: Steven J. Emmerich
Publisher: DIANE Publishing
Total Pages: 47
Release: 2001
Genre: Science
ISBN: 0756728363
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The control of outdoor air intake rates in mechanically ventilated bldgs. based on indoor carbon dioxide (CO2) levels, often referred to as CO2 demand controlled ventilation (DCV), has the potential for reducing the energy consumption assoc. with bldg. ventilation in commercial and institutional bldgs. CO2 DCV has been studied for 20+ years, but questions still remain re: the actual energy savings potential as a function of climate, ventilation system features, and bldg. occupancy. In addition, questions exist as to the indoor air quality impacts of the approach and the best way to implement CO2 DCV in a given bldg. This report presents a state-of-the-art review of CO2 DCV technology and application incl. discussion of the concept and its application, and a literature review.

Ventilation Solutions: Improving Indoor Air Quality

Ventilation Solutions: Improving Indoor Air Quality
Author: Charles Nehme
Publisher: Charles Nehme
Total Pages: 42
Release:
Genre: Technology & Engineering
ISBN:
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Ventilation is an indispensable aspect of our built environment, yet it often operates quietly in the background, unseen and unheard. It is the invisible force that breathes life into our homes, workplaces, and public spaces, influencing our health, comfort, and overall well-being. The quality of the air we breathe indoors profoundly affects our lives, from our ability to concentrate and be productive to our susceptibility to illnesses and allergies. This book delves into the world of ventilation, unveiling its significance, principles, and applications across diverse settings. Whether you are a homeowner seeking to enhance indoor air quality, an architect striving to create sustainable buildings, or an engineer working on cutting-edge ventilation technologies, this book is a comprehensive guide to understanding, implementing, and optimizing ventilation systems. Ventilation is not a static field; it evolves in response to advancing technologies, changing environmental concerns, and the pursuit of healthier, more efficient indoor environments. In each chapter, we explore different facets of ventilation, from its role in mitigating the spread of respiratory diseases like COVID-19 to its pivotal role in green building practices aimed at reducing our carbon footprint. As we navigate the intricate world of ventilation, we emphasize best practices, emerging trends, and innovative solutions that are shaping the future of indoor environments. Whether you are seeking practical advice for improving ventilation in your home, insights into sustainable building design, or a glimpse into the technologies that will revolutionize the field, this book equips you with the knowledge to make informed decisions and contribute to creating spaces that prioritize health, comfort, and environmental responsibility. In our exploration of ventilation, we aim to illuminate the importance of this often-overlooked aspect of our daily lives. By understanding its principles and embracing best practices, we can breathe easier, work more productively, and live healthier lives in the spaces we call home, work, and play. We invite you to embark on this journey through the world of ventilation, and we hope you find the insights and knowledge within these pages both enlightening and empowering. Sincerely, Charles nehme

Investigation of Multiple Indoor Air Quality and Energy Use Tradeoffs to Inform the Development of Next-generation Ventilation Strategies for Office Buildings

Investigation of Multiple Indoor Air Quality and Energy Use Tradeoffs to Inform the Development of Next-generation Ventilation Strategies for Office Buildings
Author: Adams Edwin Rackes
Publisher:
Total Pages: 432
Release: 2018
Genre: Civil engineering
ISBN:
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In commercial buildings, ventilation, or air exchange between an indoor environment and the outdoors, is necessary for controlling contaminants emitted by indoor sources such as occupants, cleaning and personal care products, and building materials. In offices, increased ventilation has also been shown to significantly increase worker productivity and reduce sick leave. At the same time, increasing ventilation introduces more outdoor air pollutants, including ones with known public health consequences like particulate matter and ozone. Furthermore, ventilation accounts for about one-fourth of U.S. commercial heating, ventilation, and air-conditioning (HVAC) energy use and changes can have significant effects on building energy consumption. This research project aims to quantify, compare, and optimally or nearly optimally balance these multiple impacts for office buildings, while remaining alert to the fact that outcomes differ significantly by building, operating conditions, and user preference. The project had three objectives. The first was to use Monte Carlo analysis over a wide range of climates and office building characteristics to evaluate combinations of mature existing technologies including demand-controlled ventilation (DCV), economizing, supply air temperature reset, and increased ventilation rate (VR). Some combinations were 'win-win,' reducing HVAC energy consumption by 12-27% while increasing work performance by 0.5% and eliminating 5 hours of absenteeism per year. Annually, such strategies could save U.S. $1.25 billion in energy costs and generate $28-55 billion in total net benefits. The second objective was to develop an outcome-based ventilation (OBV) decision-making framework, using a loss function to combine scientific knowledge, uncertainty, and parameters to express user preferences. The OBV framework confirmed that human-related outcomes are much more valuable than energy use. For example, we evaluated an intervention that increased the VR by ~10 L/s/occ on a dataset representing the office sector. With "best estimate" user parameters, the average loss impact of every other outcome was greater than the one related to HVAC energy costs--by a factor of 47 for work performance, 25 for excess absence, 3.9 for particle exposure, and 1.1 for ozone exposure. Even the most ventilation-adverse user preferences still produced VRs that were very often as high as 30 L/s/occ and only rarely lower than 15 L/s/occ. The third objective was to use optimization with the OBV framework to minimize loss over a daylong horizon and take advantage of weather, pollution, occupancy, and other transient dynamics. An optimal control problem was formulated, then translated to a nonlinear optimization problem, and solved by interior point methods. Results showed that, contrary to our hypothesis, numerically optimizing ventilation control for a single day did not provide substantial Pareto improvements over existing control methods. In fact, a strategy with economizer and DCV was very close to Pareto optimal on most days. Neither time-of-use pricing nor any factor in a sensitivity analysis revealed opportunities in which optimizing ventilation within each day of the year saved more than 5% of annual HVAC energy costs. In concluding, we used the insights of this research to outline a procedure for next-generation ventilation that takes advantage of opportunities to optimize over an annual horizon and adjust for the influential climate and building parameters identified by sensitivity analysis. For daily control, it would employ existing successful technology components, like DCV and economizer controls, that we have shown to be capable of significant energy savings and, on a daily timescale, nearly optimal. These methods would be embedded in and guided by a more conscious annual strategy that includes an initial preference elicitation step and an offline annual optimization to intelligently allocate ventilation resources across the year. Such an approach could help make ventilation more effective and reliable, and allow users to make informed decisions about ventilation tradeoffs and understand their consequences.

Demand Controlled Ventilation

Demand Controlled Ventilation
Author: Canada Mortgage and Housing Corporation
Publisher:
Total Pages: 159
Release: 1991
Genre:
ISBN:
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Recent Advances in Urban Ventilation Assessment and Flow Modelling

Recent Advances in Urban Ventilation Assessment and Flow Modelling
Author: Riccardo Buccolieri
Publisher: MDPI
Total Pages: 448
Release: 2019-04-23
Genre: Science
ISBN: 303897806X
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This book contains twenty-one original papers and one review paper published by internationally recognized experts in the Atmosphere Special Issue "Recent Advances in Urban Ventilation Assessment and Flow Modelling", years 2017–2019. The Special Issue includes contributions on recent experimental and modelling works, techniques, and developments mainly tailored to the assessment of urban ventilation on flow and pollutant dispersion in cities. The study of ventilation is of critical importance, as it addresses the capacity with which a built urban structure is capable of replacing the polluted air with ambient fresh air. Here, ventilation is recognized as a transport process that improves local microclimate and air quality and closely relates to the term “breathability”. The efficiency with which street canyon ventilation occurs depends on the complex interaction between the atmospheric boundary layer flow and the local urban morphology. The individual contributions to this Issue are summarized and categorized into four broad topics: (1) outdoor ventilation efficiency and application/development of ventilation indices, (2) relationship between indoor and outdoor ventilation, (3) effects of urban morphology and obstacles to ventilation, and (4) ventilation modelling in realistic urban districts. The results and approaches presented and proposed will be of great interest to experimentalists and modelers, and may constitute a starting point for the improvement of numerical simulations of flow and pollutant dispersion in the urban environment, for the development of simulation tools, and for the implementation of mitigation strategies.

Impact of Ventilation

Impact of Ventilation
Author: Tom Ben-David
Publisher:
Total Pages: 210
Release: 2018
Genre: Building
ISBN:
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Ventilation plays a significant part in building dynamics, affecting building energy consumption and indoor air quality (IAQ) in complex and often conflicting ways. Ventilation standards often prescribe minimum ventilation rates (VRs) in a one-size-fits-all manner that ignores the unique impact ventilation has on different buildings. This Thesis investigates the existing knowledge of ventilation outcomes to develop a customizable ventilation control strategy that would result in specific, predicted ventilation outcomes. The ways in which ventilation may affect building energy use and IAQ were explored through a literature review and three research objectives were established to develop this strategy. The first objective included an exploration of the impact that ventilation has on the indoor concentration of atmospheric contaminants. While ventilation can introduce these harmful pollutants indoors, the most potent of which (particulate matter) can be much more effectively controlled by improved filtration. It was further shown that filtration becomes more efficacious that higher VRs. The second objective was designed to create a methodology that would allow one to optimize daily VRs based on desired outcomes. This was done by constraining energy cost to levels currently achieved using an existing ventilation strategy and optimizing positive IAQ outcomes of introducing more outdoor air-which is generally considered cleaner than indoor air-indoors based on building parameters, climate, and user preferences. Thus, the premise of this ventilation strategy was to improve IAQ to a theoretical optimum by introducing more fresh air indoors at no additional energy cost. Potential ventilation outcomes were shown on a Pareto frontier that represents a tradeoff between energy use and IAQ. Pareto optimized VRs were shown to be weather dependent, and a method to generate predictive models to estimate optimal ventilation based on outdoor conditions was developed. In the third objective, a control scheme was developed to implement the proposed ventilation strategy in real buildings using a CO2-based demand-controlled ventilation approach. This optimization and control scheme was implemented in a virtual testbed emulating ventilation control in a real building. Overall, ventilation was successfully maintained at target levels, except for when very low VRs were desired, where damper leakiness, infiltration, and CO2's slow buildup indoors impeded proper control. An analysis of the implementation this ventilation strategy over the entire small-to-medium-large U.S. office sector found that it can improve occupant productivity by improving IAQ by 1.3% on average, or an equivalent $50 billion of potential benefit for the entire sector, while only increasing energy cost by 1% or $0.1 billion for the entire sector.

Modeling Indoor Air Pollution

Modeling Indoor Air Pollution
Author: Darrell W. Pepper
Publisher: Imperial College Press
Total Pages: 361
Release: 2009
Genre: Science
ISBN: 1848163258
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Emission of pollutants and their accumulation due to poor ventilation and air exchange are serious problems currently under investigation by many researchers. Of particular concern are issues involving air quality within buildings. Toxic fumes and airborne diseases are known to produce undesirable odors, eye and nose irritations, sickness, and occasionally death. Other products such as tobacco smoke and carbon monoxide can also have serious health effects on people exposed to a poorly ventilated environment; studies indicate that indirect or passive smoking can also lead to lung cancer.Design for prevention or remediation of indoor air pollution requires expertise in optimizing geometrical configurations; knowledge of HVAC systems, perceived or expected contaminants and source locations; and economics. Much of the design concept involves ways in which to optimize the benefits or balance the advantages and disadvantages of various configurations and equipment. The fact that a room or building will conceivably become contaminated is generally an accepted fact OCo to what extent indoor air pollution will become critical is not really known until it happens.A series of numerical models that run in MATLAB are described in the text and placed on the Web. These models include the finite difference method, finite volume method, finite element method, the boundary element method, particle-in-cell, meshless methods, and lagrangian particle transport. In addition, all example problems can be run using COMSOL, a commercial finite-element-based computer code with a great deal of flexibility and application. By accessing AutoCad ICES or DWG file structures, COMSOL permits a building floor plan to be captured and the interior walls discretized into elements.