Presentation is loading. Please wait.

Presentation is loading. Please wait.

Neutrally Buoyant Gas Dispersion Instructor: Dr. Simon Waldram

Published byJasmine Clark Modified over 6 years ago

Similar presentations

Presentation on theme: "Neutrally Buoyant Gas Dispersion Instructor: Dr. Simon Waldram"— Presentation transcript:

1 Neutrally Buoyant Gas Dispersion Instructor: Dr. Simon Waldram
CHEN 459 – Spring ‘09 Neutrally Buoyant Gas Dispersion By Khaldoon AlObaidi Instructor: Dr. Simon Waldram

2 Outline Goals of The Project. Introduction. Gas Dispersion Models.
Pasquill-Gifford Model. Model Inputs/Outputs. Isopleths. Demonstration. A. Part 1 of the model. B. Cave demonstration. Recommendations. References.

3 Goals 1. Investigate the characteristics of neutrally buoyant gas dispersion at different conditions. 2. Determine the isopleth of the dangerous area using the TLV-TWA value. 3. Using the Cave facility to represent the change of concentration over time and distance ( 3-D representation). * It can be added that comparison between the dispersion of various gases can be studied. TLV-TWA: The average concentration under which most people can work consistently for eight hours, day in, day out, with no harmful effects. Gas or vapors are expressed in Parts Per Million (ppm),

4 Introduction Gas is state of matter, consisting of a collection of particles (molecules, atoms, ions, electrons, etc.) without a definite shape or volume that is in more or less random motion. Weak attractive forces. Different gases will diffuse and disperse at different rates. All around us and used in large quantities in industries. Some are toxic and harmful and their study is required.

5 Gas Dispersion Models Models have been developed for the study of gas dispersion: all of them consider the conditions that may have an effect on the dispersion of the gas. Important to provide evacuation scenarios in case of leakage. Help to determine shape and concentration of the cloud and the area affected. Help to generate some risk assessments.

6 Pasquill-Gifford Model
Applicable for neutral buoyant gases (or those with densities close to air’s density like carbon monoxide). Classic Gaussian plume/puff model that was generated originally for smokestack emissions. The governing equation is <C> = the average concentration of the chemical in the air. <uj> = is the average velocity. Kj = eddy diffusivity with units of area/time

7 Pasquill-Gifford Model
Since Kj changes with position, time, wind velocity, and prevailing weather conditions, new terms were introduced to solve this difficulty by Sutton. These terms are defined as the standard deviation of horizontal distribution (y) and vertical distribution (z) of pollutant concentration. Both y and z are themselves functions of x, the distance downwind from the gas release point when the x axis is aligned with the wind direction.

8 Pasquill-Gifford Model
Consider the distance (x, y, z), wind speed, and atmospheric stability as the main parameters to determine the concentration. All the work of this project is based on this model.

9 Pasquill-Gifford Stability Index

10 The Model Inputs

11 The Model Outputs

12 The Model Outputs CO release Plume day, 2 kg/s, u = 3.5 m/s, Strong Isolation (B)

13 C&L, p194, Case 15, Puff, instantaneous point release at height h = 20 m
above ground, wind at 2 ms-1, PG dispersion coefficients, stability class E (slightly stable). Qm = 100 kg Time t = 5, 100, 200, seconds 7/29

14 Recommendations It is recommended that further studies should be performed using this model, or another, to investigate the release of gases that are more dense than air. Also, as an aid to risk assessments, detailed maps can be used to project the release over a specific geographical region. The model works for specified gases for which the probit equations for specific causative variables have been defined. Other gases and their causative variable probit laws can be added to the Excel Sheets.

15 Thanks To Dr Simon P. Waldram, Senior Professor, as supervisor.
Use of the Cave Facility in the ITS Department was facilitated through the help and work of Mr. Ali Sheharyar.

16 Literature Cited Crowl/Louvar. Chemical Process Safety Fundamentals with Applications. 2nd. Edition. Prentice Hall PTR: New Jersey; 2002. Hemond/Fechner-Levy‏. Chemical Fate and Transport in the Environment‏.2nd. Edition. Academic Press; 2000. Till/Grogan‏. Radiological Risk Assessment and Environmental Analysis‏. Oxford University Press: US; 2008. Authority Civil Aviation, Qatar Weather Website.

17 THANK YOU! ? Questions

Download ppt "Neutrally Buoyant Gas Dispersion Instructor: Dr. Simon Waldram"

Similar presentations

Session 11: Modeling Dispersion of Chemical Hazards, using ALOHA 1 Modeling Dispersion of Chemical Hazards, using ALOHA Prepared by Dr. Erno Sajo, Associate.

Session 11: Modeling Dispersion of Chemical Hazards, using ALOHA 1 Modeling Dispersion of Chemical Hazards, using ALOHA Prepared by Dr. Erno Sajo, Associate.
Introduction to SCREEN3 smokestacks image from Univ. of Waterloo Environmental Sciences Marti Blad NAU College of Engineering and Technology.

Introduction to SCREEN3 smokestacks image from Univ. of Waterloo Environmental Sciences Marti Blad NAU College of Engineering and Technology.
Introduction to SCREEN3 smokestacks image from Univ. of Waterloo Environmental Sciences Marti Blad.

Introduction to SCREEN3 smokestacks image from Univ. of Waterloo Environmental Sciences Marti Blad.
Transport of Air Pollutants

Transport of Air Pollutants
ADMS ADMS 3.3 Modelling Summary of Model Features.

ADMS ADMS 3.3 Modelling Summary of Model Features.
Introduction REU is the abbreviation for Research Experience for Undergraduates. The project on Hazard Mitigation is funded by the National Science Foundation.

Introduction REU is the abbreviation for Research Experience for Undergraduates. The project on Hazard Mitigation is funded by the National Science Foundation.
page 0 Prepared by Associate Prof. Dr. Mohamad Wijayanuddin Ali Chemical Engineering Department Universiti Teknologi Malaysia.

page 0 Prepared by Associate Prof. Dr. Mohamad Wijayanuddin Ali Chemical Engineering Department Universiti Teknologi Malaysia.
Module 9 Atmospheric Stability Photochemistry Dispersion Modeling.

Module 9 Atmospheric Stability Photochemistry Dispersion Modeling.
1 AirWare : R elease R5.3 beta AERMOD/AERMET DDr. Kurt Fedra Environmental Software & Services GmbH A-2352 Gumpoldskirchen AUSTRIA

1 AirWare : R elease R5.3 beta AERMOD/AERMET DDr. Kurt Fedra Environmental Software & Services GmbH A-2352 Gumpoldskirchen AUSTRIA
page 0 Prepared by Associate Prof. Dr. Mohamad Wijayanuddin Ali Chemical Engineering Department Universiti Teknologi Malaysia.

page 0 Prepared by Associate Prof. Dr. Mohamad Wijayanuddin Ali Chemical Engineering Department Universiti Teknologi Malaysia.
Introduction REU is the abbreviation for Research Experience for Undergraduates. The project on Hazard Mitigation is funded by the National Science Foundation.

Introduction REU is the abbreviation for Research Experience for Undergraduates. The project on Hazard Mitigation is funded by the National Science Foundation.
Toxic Release and Dispersion Models

Toxic Release and Dispersion Models
page 0 Prepared by Associate Prof. Dr. Mohamad Wijayanuddin Ali Chemical Engineering Department Universiti Teknologi Malaysia.

page 0 Prepared by Associate Prof. Dr. Mohamad Wijayanuddin Ali Chemical Engineering Department Universiti Teknologi Malaysia.
Introduction to the ISC Model Marti Blad NAU College of Engineering.

Introduction to the ISC Model Marti Blad NAU College of Engineering.
Derivation of the Gaussian plume model Distribution of pollutant concentration c in the flow field (velocity vector u ≡ u x, u y, u z ) in PBL can be generally.

Derivation of the Gaussian plume model Distribution of pollutant concentration c in the flow field (velocity vector u ≡ u x, u y, u z ) in PBL can be generally.
1 Omowumi Alabi Department of Geosciences University of Missouri-Kansas City Kansas City, MO.

1 Omowumi Alabi Department of Geosciences University of Missouri-Kansas City Kansas City, MO.
Air Quality Modeling.

Air Quality Modeling.
Air Chemistry GISAT 112. Scientific and Technical Concepts Phases of airborne matter- gases, particles Inorganic and organic chemicals Balancing chemical.

Air Chemistry GISAT 112. Scientific and Technical Concepts Phases of airborne matter- gases, particles Inorganic and organic chemicals Balancing chemical.
Environmental Modeling Steven I. Gordon Ohio Supercomputer Center June, 2004.

Environmental Modeling Steven I. Gordon Ohio Supercomputer Center June, 2004.
CHAPTER 5 Concentration Models: Diffusion Model.

CHAPTER 5 Concentration Models: Diffusion Model.

Similar presentations

Ads by Google