Your search keyword '"Leon Wang"' showing total 15 results

1. Airflow and Energy Simulations to Assess Energy Savings from Vestibules and Air Curtains.

Author

Goubran, Sherif, Liangzhu (Leon) Wang, and Dahai Qi

Subjects

*BUILDING design & construction, *ENERGY consumption of buildings, *AIR flow, *AIR curtains

Abstract

ANSI/ASHRAE/IES Standard 90.1 requires vestibules to be installed in buildings in climate zones 3 through 8 based on building energy simulations with a series of assumptions which can be avoided using a new method of airflow and energy simulations. Instead of vestibules, it is believed that air curtains can also reduce infiltration and the associated energy loss through building entrances. Therefore, this study proposes a method to estimate energy savings from vestibule and air-curtain doors for two U.S. Department of Energy reference buildings in 16 U.S. climate zone locations in terms of national weighted average energy savings and a sensitivity study of different contributing parameters. [ABSTRACT FROM AUTHOR]

Published

2018

2. An adaptive time-stepping semi-Lagrangian method for incompressible flows.

Author

Mortezazadeh, Mohammad and (Leon) Wang, Liangzhu

Subjects

*LAGRANGE equations, *ERROR functions, *INCOMPRESSIBLE flow, *ADVECTION

Abstract

The semi-Lagrangian method is widely applied to solving the advection term of the Navier–Stokes (N–S) equations whereas the role of time step is often unclear. This article proposed an adaptive time-stepping method, which first calculates local adaptive time step based on truncation error coefficient functions, and then to obtain global time step based on an averaging function for all grid points. The new method was tested for solving 1-D and 2-D advections with different initial time steps and grid resolutions, and the transient incompressible N–S equations. Better simulation accuracy can be achieved than the cases with constant time steps. [ABSTRACT FROM AUTHOR]

Published

2019

3. Modeling Urban Microclimates of Extreme Weathers by Integrating City Fast Fluid Dynamics and City Building Energy Model.

Author

Liangzhu (Leon) Wang, Katal, Ali, and Dorostkar, Mohammad Mortezazadeh

Subjects

*URBAN heat islands, *ENERGY consumption of buildings, *FLUID dynamics, *STRUCTURAL dynamics, *ATMOSPHERIC temperature, *HYGROTHERMOELASTICITY, *COMBINED sewer overflows

Abstract

Extreme weather events, such as unusually high or low temperatures, and severe winds pose a threat to people and properties in cities. Managing the risk caused by these events requires effective climate adaptation policies to strengthen urban resilience to climate-related stresses. Simulation tools are needed for this purpose. In this work, an integrated CityFFD and CityBEM platform is used to study two extreme weather events in Montreal, Canada: the snowstorm of the century, and the urban heat island (UHI) in a hot summer day. CityFFD simulates local urban microclimate of a city to find the most vulnerable areas at extreme weather events, which are then used for the calculation of building thermal loads and indoor air temperatures using the CityBEM. The results show that integrated framework can produce high-resolution microclimate and building behavior under extreme weather events. [ABSTRACT FROM AUTHOR]

Published

2019

4. Dimensionless CFD Analysis of Reynolds Independence and Similarity in Urban and Built Environment Airflows.

Author

Liangzhu (Leon) Wang and Chang Shu

Subjects

*BUILT environment, *INCOMPRESSIBLE flow, *SIMILARITY (Physics), *FLUID flow, *EDDY viscosity, *AIR flow, URBAN ecology (Sociology)

Abstract

In this study, a dimensionless CFD analysis for the isothermal incompressible fluid flow in buildings is conducted to illustrate the Reynolds number similarity among different scales and the Reynolds independent phenomenon for the same scaled setup. For the similarity in different scales, the geometry similarity is required, and the Reynolds number is conserved by the boundary condition configurations to achieve the dynamic similarity, and a good match of the dimensionless results between scales can verify the dimensionless analysis procedure. For the simulations in the same scale, the dimensionless governing equations is further simplified and revealed the role of turbulence viscosity in Reynold independent phenomenon. A series of CFD simulation are conducted to study the distribution and evolution of turbulence viscosity with its relationship to achieve Reynolds independence. This paper develops a new method of justifying the Reynolds independence with CFD simulations, and this dimensionless CFD analysis method can be an important procedure for airflow pattern scaled experiments design and problem simplifications in urban and building airflows. [ABSTRACT FROM AUTHOR]

Published

2019

5. Froude-Stanton modeling of heat and mass transfer in large vertical spaces of high-rise buildings.

Author

Qi, Dahai, (leon) Wang, Liangzhu, and Zhao, Guanchao

Subjects

*MASS transfer, *HEAT transfer, *TALL buildings, *FIRE prevention, *SUSTAINABLE buildings

Abstract

Understanding physics of heat and mass transfer inside large vertical spaces is a major challenge for high-rise fire safety. Due to the size of a high-rise building, experimental studies based on sub-scaled models play an important role in high-rise heat and mass transfer research. Froude modeling method is probably the most common approach for sub-scaling. However, Froude modeling has been found incapable of obtaining accurate temperature predictions from the sub-scaled experiments, especially near building boundaries where there exists significant heat transfer between smoke and the boundaries. In this paper, a new modeling method, Froude-Stanton modeling, is developed for both mechanically-driven and naturally-driven thermal smoke spreads, in which heat transfer is taken into consideration in the energy balance equation. The flow resistance of the internal shaft structure is also considered using a lumped method. To verify the new method, series of experiments were conducted on three shafts with different sizes and material using both Froude and Froude-Stanton methods. The results, including temperature profile, relative neutral plane level and thermal smoke flow rate, are compared between the two modeling methods, and it was found that the new Froude-Stanton modeling method is more accurate. [ABSTRACT FROM AUTHOR]

Published

2017

6. Modeling Smoke Movement in Shafts During High-Rise Fires by a Multizone Airflow and Energy Network Program.

Author

Dahai (Darren) Qi, Liangzhu (Leon) Wang, and Radu Zmeureanu

Subjects

*ATTENUATION coefficients, *SMOKE, *TEMPERATURE distribution, *ENERGY conservation, *TALL buildings

Abstract

Multizone airflow network programs are increasingly used to study smoke movement during fires in buildings. Multizone programs often do not solve energy conservation equations, so temperatures ofrooms/zones need to be specified. The lack of energy models limits the capability of a multizone program for modeling building smoke movement, especially in shafts, where temperature distribution is often unknown. This paper introduces a multizone program with an added energy equation, CONTAM97R, with the focus of its application to simulations of smoke movement, especially in shafts of highrise buildings. First, CONTAM97R was validated by experimental data from a 1/3-scale building stairwell under fires, and verified by an analytical model of high-rise fires. The program was then used to model a 16-storey building with a fire located at the firstfloor. To model the building shaft by CONTAM97R, we proposed and compared two zoning methods, floor zoning strategy (FZS) and adaptive zoning strategy (AZS), when the shaft is with and without air infiltrations. It shows that the accuracy of FZS is inversely related to a dimensionless parameter, the temperature attenuation coefficient, a, but can be improved by increasing the number of zones dividing the shaft until the results do not depend on zone numbers. Compared to FZS, AZS obtains results ofsimilar level of accuracy but with fewer zones for the simulations. [ABSTRACT FROM AUTHOR]

Published

2015

7. A Hand Calculation Method of Smoke Movement through A High-Rise Airtight Single Shaft.

Author

Dahai (Darren) Qi, Liangzhu (Leon) Wang, and Zmeureanu, Radu

Subjects

*SMOKE control systems in buildings, *HEAT transfer, *TEMPERATURE effect, *COMPUTATIONAL fluid dynamics, *NUMERICAL analysis

Published

2014

8. Comparison of Simulation Programs for Airflow and Smoke Movement during High-Rise Fires.

Author

Liangzhu (Leon) Wang, Black, William Z., and Guanchao Zhao

Subjects

*SMOKE control systems in buildings, *FIRE prevention, *COMPUTER simulation, *AIR flow, *SKYSCRAPERS, *STRUCTURAL analysis (Engineering), *CONSTRUCTION

Abstract

Computer modeling of structural fires can play a significant role in simulating the development of a fire and the subsequent movement of smoke throughout the building. Computer programs have evolved to such an extent that they are able to predict where smoke will travel and to what extent it will contaminate various areas throughout the building such as fire escape stairwells and elevator shafts. Therefore, they can be employed to suggest modifications in the building construction, employment of building HVAC equipment, and use of pressurization fans in order to formulate a building life-safety plan that has a reasonable chance of reducing injuries due to smoke inhalation. In this work, the results provided by two computer programs that are capable of simulating smoke movement during building fires are compared for a simulated fire in a high-rise structure. Major differences in the formulation of the two programs are identified, and the differences in the predicted smoke movement results are explained. The temperature distribution throughout the building is shown to be a major factor in moving smoke within the building. Overall, there is reasonable comparison between the two computer predictions; however, large errors can result if the models employ unrealistic temperature distributions throughout the building structure. [ABSTRACT FROM AUTHOR]

Published

2013

9. Evaluating Approaches to Developing Building Archetype Models for Estimating Cooling Energy Consumption in Hot and Arid Climate.

Author

Moujahed, Majd, Danlin Hou, Liangzhu (Leon) Wang, and Hassan, Ibrahim

Subjects

*ENERGY consumption, *ARCHETYPES, *COOLING loads (Mechanical engineering), *SENSITIVITY analysis, *FACTORY design & construction

Abstract

District Cooling is an energy-efficient technology that can satisfy the cooling demands of regions with extremely hot climates such as the middle east. Designing and operating these plants requires accurate modeling of the existing cooling load created by the building stock connected to the central plant. During the design stage, building archetype models can be used for sizing district cooling load, whereas both the input and output uncertainties of these models have not been well addressed. This paper conducts a comparative analysis of two methodologies of building archetype development, develops an importance ranking for the input parameters of these models, and tries to quantify the uncertainty of the cooling energy output due to input value uncertainty. It develops a region-specific highrise residential archetype and compares it to the US DOE Prototype models. It also develops the parameter ranking using a global sensitivity analysis methodology. It is found that the most practical approach towards the development of building archetypes for a specific region is the development of region-specific models adapted to local practices rather than converting standard models for accuracy and computational cost considerations. It was also concluded that a set number of parameters are responsible for most of the model's output variability. Finally, this study demonstrated the usability of the building archetype models for the hot and arid climate. [ABSTRACT FROM AUTHOR]

Published

2022

10. Comparing Two Simulation Approaches for Quantifying Urban Microclimate Impact on Building Energy Performance.

Author

Dongxue Zhan, Danlin Hou, Liangzhu (Leon) Wang, and Hassan, Ibrahim Galal

Subjects

*BUILDING performance, *ENERGY consumption of buildings, *ATMOSPHERIC temperature, *WEATHER, *WIND speed

Abstract

Building energy modeling (BEM) involves many input parameters, including weather conditions, building geometry and properties, and building system and occupant information. Typical Meteorological Year (TMY) data are often used for the definition of weather conditions without considering urban microclimate variations. Compared to other inputs, the impacts of urban microclimate on BEM results are not adequately understood, and the literature also often presents inconsistent conclusions. In this paper, we conducted a sensitivity analysis (SA) to quantify the importance of urban microclimate and to identify the key parameters for the model output variations. Based on the Sensitivity Value Index (SVI), 13 BEM inputs were evaluated. It shows that the outdoor air temperature and wind speed play an essential role in building cooling energy usages in the hot and arid climate. Then, two approaches to estimating urban climate impacts on BEMs were compared in terms of outdoor air temperature, wind speed, and humidity in Lusail, Qatar by the 3D urban microclimate CFD model, City Fast Fluid Dynamics (CityFFD), and the simplified microclimate model, Urban Weather Generator (UWG). A comparative analysis of the simulation results to the local weather station measurements reveals the capabilities of the two approaches to estimating urban microclimate impacts on building energy performance. [ABSTRACT FROM AUTHOR]

Published

2022

11. Development and Application of BIR-BEM: A Bayesian Inference R Platform for Building Energy Model Calibration.

Author

Danlin Hou, Hassan, Ibrahim Galal, and Liangzhu (Leon) Wang

Subjects

*ENERGY consumption of buildings, *BAYESIAN field theory, *MARKOV chain Monte Carlo, *CALIBRATION, *ENERGY consumption, *COMMERCIAL buildings

Abstract

The building sector accounts for nearly 40% of global energy consumption and plays a critical role in societal energy security and sustainability. A building energy model (BEM) simulates complex building physics and provides insights into the performance of various energy-saving measures. The analysis based on BEMs has thus become an essential approach to slowing down the process of increasing building energy consumption. The reliability and accuracy of BEMs have a high impact on decision-making. However, how to calibrate a building energy model has remained a challenge. Existing calibrations are often deterministic without uncertainties quantified. In this study, a new automated multi-module calibration platform, BIRBEM (Bayesian Inference on R for Building Energy Model), is developed using an R programming language for calibrating building energy models. The sensitivity analysis module determines the calibration parameters, and the building energy model is replaced by the developed meta-model module for the Markov Chain Monte Carlo (MCMC) process to save computing time. An application of a high-rise residential building case in a hot and arid climate was demonstrated. The coefficient of variation with a root-mean-square error (CVRMSE) value of the monthly total cooling energy consumption is 13.95%, which satisfies the monthly calibration tolerance of 15% required by ASHRAE Guideline 14. [ABSTRACT FROM AUTHOR]

Published

2022

12. Use of Vertical Shafts as Routes of Smoke Extraction and Safe Egress During High-Rise Fires.

Author

Guanchao Zhao, Black, W. Z., and Liangzhu (Leon) Wang

Subjects

*FIRE victims, *SMOKE, *COMPUTATIONAL fluid dynamics, *DISCHARGE coefficient, *GAS flow, *FIRE prevention

Abstract

Smoke inhalation is the leading cause of death during structural fires. In order to improve life safety during a fire, smoke must be managed and kept away from building occupants. In high-rise buildings, the problem of smoke movement is compounded by a strong stack effect that draws smoke into the vertical shafts within the building and contaminates the fire-escape stairwells as well as the elevator shafts. I f the smoke can be managed so that the stack effect can be used to advantage and egress routes can be maintained smoke free, then occupants will have a greater opportunity to avoid the effects of the smoke generated by the fie. This paper investigates a smoke control strategy that involves using the elevator shafts as a route ofsmoke extraction coupled with pressurizing the stairwells with sufficient fresh air to maintain smoke-free conditions in thefire escapes for the entire height of the building. The practicality and efficacy of this smoke management strategy is evaluated by employing a differential-network smoke management computer program that simulates the paths that smoke will take during a simulated fire. The computer program is verified by comparing its results with a computational fluid dynamics (CFD) software tool, Fire Dynamics Simulator, for a simple building geometry. Both programs compare well when a reasonable set of discharge coefficients is used to calculate the gas flows through various openings in the modeled building. The differential-network model quantifies the paths that the smoke will take and determines the smoke properties with a significant reduction of computational time when compared to the time required to provide the CFD simulations. Smoke generated by the fire will naturally tend to gravitate toward the elevator shafts, which exist at the lowest pressure within the building. Computer results show that large quantities ofsmoke can be directed away from occupants by controlling and exhausting the smoke through the top vent of the elevator shaft. If exhaust fans are used for smoke venting at the top of the elevator shafts and pressurization fans are used to maintain smoke-free conditions in the stairwells, then a prudent fire safety plan will result. The program output is used to quantify the amount of elevator exhaust and stainvell pressurization that is necessary to achieve safe conditions during the fire for various building geometries and fire conditions. [ABSTRACT FROM AUTHOR]

Published

2015

13. Computer modeling of multiscale fluid flow and heat and mass transfer in engineered spaces

Author

Chen, Qingyan (Yan), (John) Zhai, Zhiqiang, and (Leon) Wang, Liangzhu

Subjects

*CHEMICAL engineering, *FLUID dynamics, *COMPUTER simulation, *METALLOGRAPHY, *MASS transfer

Abstract

Design and analysis of fluid flow and heat and mass transfer in engineered spaces require information of spatial scales ranging from to and time scales from to . The studies of such a multiscale problem often use multiple computer models, while each of computer models is applied to a small range of spatial and time scales. Accurate solution normally requires exchanging information between a macroscopic model and a microscopic model that can be done by coupling the two models. With the approach, it is possible to obtain an informative solution with the current computer memory and speed. This paper used a few examples of fluid flow and heat and mass transfer in engineered spaces to conclude that a coupled macroscopic and microscopic model is likely to have a solution and the solution is unique. A stable solution for the coupled model can be obtained if some criteria are met. The information transfer between the macroscopic and microscopic models is mostly two ways. A one-way assumption can be accepted when the impact from small scale on large scale is not very significant. [Copyright &y& Elsevier]

Published

2007

14. Ring currents modulate optoelectronic properties of aromatic chromophores at 25 T.

Author

Kudisch, Bryan, Maiuri, Margherita, Moretti, Luca, Oviedo, Maria B., Leon Wang, Oblinsky, Daniel G., Prud'homme, Robert K., Wong, Bryan M., McGill, Stephen A., and Scholes, Gregory D.

Subjects

*MAGNETIC field effects, *TIME-dependent density functional theory, *MAGNETICS, *NUCLEAR magnetic resonance spectroscopy, *MAGNETIC fields

Abstract

The properties of organic molecules can be influenced by magnetic fields, and these magnetic field effects are diverse. They range from inducing nuclear Zeeman splitting for structural determination in NMR spectroscopy to polaron Zeeman splitting organic spintronics and organic magnetoresistance. A pervasive magnetic field effect on an aromatic molecule is the aromatic ring current, which can be thought of as an induction of a circular current of π-electrons upon the application of a magnetic field perpendicular to the π-system of the molecule. While in NMR spectroscopy the effects of ring currents on the chemical shifts of nearby protons are relatively well understood, and even predictable, the consequences of these modified electronic states on the spectroscopy of molecules has remained unknown. In this work, we find that photophysical properties of model phthalocyanine compounds and their aggregates display clear magnetic field dependences up to 25 T, with the aggregates showing more drastic magnetic field sensitivities depending on the intermolecular interactions with the amplification of ring currents in stacked aggregates. These observations are consistent with ring currents measured in NMR spectroscopy and simulated in time-dependent density functional theory calculations of magnetic field-dependent phthalocyanine monomer and dimer absorption spectra. We propose that ring currents in organic semiconductors, which commonly comprise aromatic moieties, may present new opportunities for the understanding and exploitation of combined optical, electronic, and magnetic properties. [ABSTRACT FROM AUTHOR]

Published

2020

15. Application of the EnKF method for real-time forecasting of smoke movement during tunnel fires.

Author

Ji, Jie, Tong, Qi, Gao, Zihe, Fang, Jun, (Leon) Wang, Liangzhu, Lin, Cheng-Chun, and Zhang, Cong

Subjects

*COMPUTATIONAL fluid dynamics, *KALMAN filtering, *DATA, *DETECTORS, *SIMULATION methods & models, *COMPUTER software

Abstract

Real-time prediction of smoke layer temperature and height of tunnel fires are crucial in guiding emergency rescue. However, current fire simulation tools are often not able to provide reliable modeling results due to poorly known input parameters and model errors. Besides, fire modeling are subject to computer resources, for instance, fire modeling by computational fluid dynamics (CFD) tools is often time-consuming. Moreover, sensors located in tunnels can only detect certain physical quantities within a certain level of uncertainties. In order to gain more reliable predictions of temperature and smoke layer height of tunnel fires in real time, a proposed method, inverse modeling based on Ensemble Kalman Filter (EnKF), is presented in this study to improve the predictability and address problems of demanding computer resources of tunnel fire simulation by doing data assimilation. The basic formulas of EnKF method are introduced and the application of EnKF to tunnel fires is implemented by connecting the fire simulation tool, CFAST, with a data assimilation software, OpenDA. In current study, observation data are generated under the framework of Observation System Simulation Experiment (OSSE), i.e., synthetic observations are generated by CFAST simulation assuming true value of control parameters are known. Studies are conducted to show the feasibility of real-time predicting smoke movement during tunnel fires. Results show that prediction performance are improved after applying the EnKF method compared to the standalone tunnel fires modeling. [ABSTRACT FROM AUTHOR]

Published

2018