[1]. Th Full Papers that I've been already read and make summary
[2].
[3].
[4].
[5].
[6].
http://continuousimprovement.blogsome.com
http://Life4aaK.blogspot.com
http://godoproduction.blogspot.com
Friday, March 30, 2007
Wednesday, March 28, 2007
messagefromAdvisor(s): About Thesis
19.03.2007:
[1]. Prepare Proposal. Examination will be held on May 2007 (before new semester or about end of Summer Semester)--> Send me your document as a progress for it!.
[2]. Help by Mr. B about MESH/ GRID problem:--> May be the S/W not ur program.
26.03.2007:
[1]. I send my progress reports: 2 file present in front of Ajarn, then his messages are:
[2]. Want to see velocity vectors from Velocity_Inlet[1] to Pressure_Outlet[1] by assume Boundary Condition look like Paper ELSEVIER...CFD Study Flow in Natural Rubber Smoking Room (2007)...
[3]. Then the simulate concentration PM in empty rooms: one by one I/O...
+
[4]. AjG: read Tutorial05 FLUENT 5/6
Assumptions:
not have radiation,
use Bousinessq,
temperature operation?,
heat flux=0[standard in fluent],
velocity inlet at the top of the chamber, only Vy...[AjPT:from Paper Mr. X===0.63m/s(already read it by 28.03.2007)],
simulate 1st: fluid AIR then PARTICLEs (use 0.1micron),
operationng=1,
temp.,
cp=constant or not,
...
[5]. Think: send doc. to AjPT text to correction by him, before 23April2007
http://continuousimprovement.blogsome.com
http://Life4aaK.blogspot.com
http://godoproduction.blogspot.com
[1]. Prepare Proposal. Examination will be held on May 2007 (before new semester or about end of Summer Semester)--> Send me your document as a progress for it!.
[2]. Help by Mr. B about MESH/ GRID problem:--> May be the S/W not ur program.
26.03.2007:
[1]. I send my progress reports: 2 file present in front of Ajarn, then his messages are:
[2]. Want to see velocity vectors from Velocity_Inlet[1] to Pressure_Outlet[1] by assume Boundary Condition look like Paper ELSEVIER...CFD Study Flow in Natural Rubber Smoking Room (2007)...
[3]. Then the simulate concentration PM in empty rooms: one by one I/O...
+
[4]. AjG: read Tutorial05 FLUENT 5/6
Assumptions:
not have radiation,
use Bousinessq,
temperature operation?,
heat flux=0[standard in fluent],
velocity inlet at the top of the chamber, only Vy...[AjPT:from Paper Mr. X===0.63m/s(already read it by 28.03.2007)],
simulate 1st: fluid AIR then PARTICLEs (use 0.1micron),
operationng=1,
temp.,
cp=constant or not,
...
[5]. Think: send doc. to AjPT text to correction by him, before 23April2007
http://continuousimprovement.blogsome.com
http://Life4aaK.blogspot.com
http://godoproduction.blogspot.com
Thursday, March 15, 2007
[gambit2.2]What does "geometry not C1 or G1" meant?
[1]. http://www.caddigest.com/subjects/solidworks/select/cadcamnet_proe_vs_solidworks.htm
Curvature continuity
To appreciate what enables CAD software to produce graceful flowing curves, it’s important to understand some concepts of continuous curvature. The curvature of a curve or surface is the inverse of the radius of the curve at each point along its length. An arc, circle, or cylinder has a constant curvature as does a straight line or plane whose curvature is zero. When a circular fillet is tangent to a straight-line segment, the curvature falls abruptly from a constant value to zero.
The human eye can perceive abrupt changes in the curvature of surfaces. A round fillet meeting a plane surface appears to have a ridge at its edge, even though none physically exists. Artfully designed products thus avoid discontinuities in the derivative (rate of change) of the curvature of curves and surfaces except where ridges and sharp edges are used for accent. Entities whose curvature derivative is continuous are said to be C2 (or sometimes G2) continuous. Curves and surfaces that are tangent are said to be C1 (or G1) continuous, while continuous curves or surfaces with sharp edges are said to be C0 (or G0) continuous.
Most CAD systems can produce curves and surfaces that are continuous (C0) or tangent (C1). However, only the best systems can produce surfaces that can be joined with C2 continuity under a wide range of conditions. Pro/Engineer Wildfire maintains C2 continuity between adjacent surfaces under more conditions than SolidWorks 2004.
[2].http://www.cs.stevens.edu/~quynh/courses/cs537-notes/lesson6-CurvesAndSurfaces.ppt#257,2,Curves and Surfaces
Joining Curve Segments Together
G0 geometric continuity: Two curve segments join together
G1 geometric continuity: The direction of the two segments’ tangent vectors are equal at the join point
C1 (parametric) continuity: Tangent vectors of the two segments are equal in magnitude and direction
(C1 Þ G1 unless tangent vector = [0, 0, 0])
Cn (parametric) continuity: Direction and magnitude through the nth derivative are equal at the join point
http://continuousimprovement.blogsome.com
http://Life4aaK.blogspot.com
http://godoproduction.blogspot.com
Curvature continuity
To appreciate what enables CAD software to produce graceful flowing curves, it’s important to understand some concepts of continuous curvature. The curvature of a curve or surface is the inverse of the radius of the curve at each point along its length. An arc, circle, or cylinder has a constant curvature as does a straight line or plane whose curvature is zero. When a circular fillet is tangent to a straight-line segment, the curvature falls abruptly from a constant value to zero.
The human eye can perceive abrupt changes in the curvature of surfaces. A round fillet meeting a plane surface appears to have a ridge at its edge, even though none physically exists. Artfully designed products thus avoid discontinuities in the derivative (rate of change) of the curvature of curves and surfaces except where ridges and sharp edges are used for accent. Entities whose curvature derivative is continuous are said to be C2 (or sometimes G2) continuous. Curves and surfaces that are tangent are said to be C1 (or G1) continuous, while continuous curves or surfaces with sharp edges are said to be C0 (or G0) continuous.
Most CAD systems can produce curves and surfaces that are continuous (C0) or tangent (C1). However, only the best systems can produce surfaces that can be joined with C2 continuity under a wide range of conditions. Pro/Engineer Wildfire maintains C2 continuity between adjacent surfaces under more conditions than SolidWorks 2004.
[2].http://www.cs.stevens.edu/~quynh/courses/cs537-notes/lesson6-CurvesAndSurfaces.ppt#257,2,Curves and Surfaces
Joining Curve Segments Together
G0 geometric continuity: Two curve segments join together
G1 geometric continuity: The direction of the two segments’ tangent vectors are equal at the join point
C1 (parametric) continuity: Tangent vectors of the two segments are equal in magnitude and direction
(C1 Þ G1 unless tangent vector = [0, 0, 0])
Cn (parametric) continuity: Direction and magnitude through the nth derivative are equal at the join point
http://continuousimprovement.blogsome.com
http://Life4aaK.blogspot.com
http://godoproduction.blogspot.com
Wednesday, March 14, 2007
[CFDPackages] For CFD Code Learner in the World
Good for Learner about CFD Code Packages in the world:
http://nenes.eas.gatech.edu/CFD/
http://continuousimprovement.blogsome.com
http://Life4aaK.blogspot.com
http://godoproduction.blogspot.com
http://nenes.eas.gatech.edu/CFD/
http://continuousimprovement.blogsome.com
http://Life4aaK.blogspot.com
http://godoproduction.blogspot.com
Friday, March 02, 2007
[indoorairindonesia]BAQ2006.org
http://pciaonline.org/2007IndiaForum/index.cfm?/c=callForAbstracts
http://www.pciaonline.org/references.cfm
http://www.pciaonline.org/events_viewer.cfm?id=76
The following websites are particularly relevant to household energy, indoor air pollution and health, and contain (in most cases) annotated and searchable bibliographies.
Asian Regional Cookstove Program (ARECOP)http://www.arecop.org/The ARECOP network is made up of organizations and individuals involved in improved cookstove programs and household energy issues. The network includes 14 countries in the Asia Region. It also acts as a forum for discussions on Improved Cookstove Programs in the region. ARECOP organizes regular workshops on issues such as commercialization; kitchen improvements; and household energy and health. Key themes include improved stoves, household energy, indoor air pollution etc. The website also features: Proceedings of ARECOP regional workshops; household energy activity and contact information on member countries; issues of GLOW magazine and monthly Letters from the Secretariat; links to relevant organizations and publications for household energy and health. Contact Information:
ARECOP SecretariatPO. Box 19, BulaksumurYogyakarta55281 Indonesia.Phone: 62-274-885247,Fax: 62-21-885423E-mail: secretariat@arecop.org, arecop@yogya.wasantara.net.id
September 13-15, Yogyakarta, Indonesia
The 5th Better Air Quality (BAQ) workshop will be held 13-15 September 2006 in the historic city of Yogyakarta in Central Java, Indonesia. The theme of BAQ 2006 is called a "Celebration of Efforts" to highlight the success stories that Asian countries, cities and communities have achieved over the last years in addressing air pollution while at the same time highlighting the efforts that are still ahead in improving air quality in Asia. The submission deadline for abstracts is 30 March 2006. For more information, please visit http://www.baq2006.org.
http://continuousimprovement.blogsome.com
http://Life4aaK.blogspot.com
http://godoproduction.blogspot.com
http://www.pciaonline.org/references.cfm
http://www.pciaonline.org/events_viewer.cfm?id=76
The following websites are particularly relevant to household energy, indoor air pollution and health, and contain (in most cases) annotated and searchable bibliographies.
Asian Regional Cookstove Program (ARECOP)http://www.arecop.org/The ARECOP network is made up of organizations and individuals involved in improved cookstove programs and household energy issues. The network includes 14 countries in the Asia Region. It also acts as a forum for discussions on Improved Cookstove Programs in the region. ARECOP organizes regular workshops on issues such as commercialization; kitchen improvements; and household energy and health. Key themes include improved stoves, household energy, indoor air pollution etc. The website also features: Proceedings of ARECOP regional workshops; household energy activity and contact information on member countries; issues of GLOW magazine and monthly Letters from the Secretariat; links to relevant organizations and publications for household energy and health. Contact Information:
ARECOP SecretariatPO. Box 19, BulaksumurYogyakarta55281 Indonesia.Phone: 62-274-885247,Fax: 62-21-885423E-mail: secretariat@arecop.org, arecop@yogya.wasantara.net.id
September 13-15, Yogyakarta, Indonesia
The 5th Better Air Quality (BAQ) workshop will be held 13-15 September 2006 in the historic city of Yogyakarta in Central Java, Indonesia. The theme of BAQ 2006 is called a "Celebration of Efforts" to highlight the success stories that Asian countries, cities and communities have achieved over the last years in addressing air pollution while at the same time highlighting the efforts that are still ahead in improving air quality in Asia. The submission deadline for abstracts is 30 March 2006. For more information, please visit http://www.baq2006.org.
http://continuousimprovement.blogsome.com
http://Life4aaK.blogspot.com
http://godoproduction.blogspot.com
Thursday, March 01, 2007
risktech2007_fullpaper
Fundamental concept of risk
A typical dictionary defines risk as the possibility of loss or injury. It implies that risk has two main components: the probability of some event occurring and the negative consequence if it occurs. Thus, to analyze risk we should be able to estimate these two factors. Boehm [1] translated this defnition into the
fundamental concept of risk management: the risk exposure, sometimes called risk impact.
Fundamental concept of risk (Cairo., et al., 1999)
A typical dictionary defines risk as the possibility of loss or injury. It implies that risk has two main components: the probability of some event occurring and the negative consequence if it occurs. Thus, to analyze risk we should be able to estimate these two factors. Boehm (1989) translated this definition into the fundamental concept of risk management: the risk exposure, sometimes called risk impact.
Where RE means risk exposure, P(UO) expresses the probability of an unsatisfactory outcome, and L(UO) means the loss to the parties affected if the outcome is unsatisfactory.
Usually the perception of risk is higher for those items over which one have little or no control. However, the importance of the risk factors might be considered as some combination of risk frequency (that is, how likely it is that the risk will occur) and risk impact (such as, how serious a threat the risk represents if it does occur). In considering risks you must also consider their perceived level of control. This represents the degree to which the project manager perceived that their actions could prevent the risk from occurring. Most of the probable risks or threats to projects can be reduced or avoided using an appropriate methodology. It can also be complemented with approximative methods, which can provide enough information to support risk management decisions.
Risk-reduction is a fundamental part of project management in software and knowledge engineering. Software risk management is important because it helps people to avoid disasters, rework, and overkill, it also stimulates win-win situations on software projects (Boehm, 1989).
We should be aware that by avoiding or reducing the most significant risks, managers make more informed decisions, we obtain better outcomes, and hence the project will have a higher probability of success.
Boehm (1988) suggests to use a software risk management plan, which consists of five steps:
• Identify the project's top risk items.
• Present a plan for resolving each risk item.
• Update list of top risk items, plan, and results monthly.
• Highlight risk-item status in monthly project reviews.
• Initiate appropriate corrective actions.
Successful management of a project leads to control. Control leads to quality. Quality leads to satisfied customers. And we know customers are the final arbiters of a product or service.
The main factors affecting contaminants OK
Characteristics of indoor air flows:
Gant., et al.; 2006 state a number of parameters which can be used to characterize the dispersion of a contaminant inside a room, i. e.:
1. Fresh Air/ Contaminant Distribution:
Contaminant Concentration, Local Mean Age of Air, Purging Effectiveness of Inlets, Local Specific Contaminant-Accumulating Index, Air Change Efficiency, Ventilation Effectiveness Factor, Relative Ventilation Efficiency.
2. Stability and Bouyancy of the Room Air:
Reynold Number, Rayleigh Number, Grashof Number, Froude Number, Richardson Number, Flux Richardson Number, Bouyancy Flux.
3. Temperature Distribution:
Air Diffusion Performance Index, Effective Draft Temperature.
4. Supply Air Conditions:
Purging Effectiveness of Inlet, Reynold Number, Froude Number, Archimedes Number.
Due to overlap between these subjects, some parameters appear more than once. Some parameters characterize directly the observed pattern of contaminant distribution whilst others characterize flow features, such as stability. Flow parameters such as the ‘mean age of air’ are difficult but not impossible to calculate experimentally. They are used mainly as a tool to help interpret data from numerical simulations of contaminant dispersion. For discussions on how these parameters are used to assess compliance with standards on room air quality, see Peng & Davidson (1999) or the ASHRAE Guides (2003).
Clearly the simplest indicator of contaminant distribution in a room is the contaminant concentration, i.e. the mass of contaminant per unit volume of air (measured in kg/m3). Contaminant concentration is sometimes expressed in terms of parts per million (ppm), or parts per billion, trillion etc. This can be based on either the mass fraction or the volume fraction.
Local Mean Age of Air is commonly used to evaluate the performance of a ventilation system and indoor air quality. The precise meaning of the local mean age is defined in Di Tommaso et al.; (1999) as follows: “the average time it takes for air to travel from the inlet to any point P in the room”.
The purging effectiveness of an inlet is a quantity that can be used to identify the relative performance of each inlet in a room where there are multiple inlets.
Peng et al.; (1999) classify the various measures used to characterize ventilation performance into three groups: measures of ventilation air-diffusing efficiency which indicate the ability to provide fresh air to occupants, ventilation effectiveness which indicate the ability to remove contaminants from a ventilated space and specific ventilation effectiveness which deals with specific situations.
Air Change Efficiency is a measure of how effectively the air present in a room is replaced by fresh air from the ventilation system (Di Tommaso et al.; 1999). It is the ratio of the room mean age that would exist if the air in the room were completely mixed to the average time of replacement of the room.
The Ventilation Effectiveness Faction (VEF) appears to be ASHRAE’s preferred method for characterizing indoor air quality and is based on the work of Zhang et al. (2001).
The relative ventilation efficiency is the ratio of the local mean age that would exist if the air in the room were completely mixed to the local mean age that is actually measured at a point.
Air Diffusion Performance Index (ADPI) is primarily a measure of occupant comfort rather than an indicator of contaminant concentrations. It expresses the percentage of locations in an occupied zone that meet air movement and temperature specifications for comfort.
The temperature effectiveness is similar in concept to ventilation effectiveness and reflects the ability of a ventilation system to remove heat.
The effective draft temperature, θ, indicates the feeling of coolness due to air motion:
where Tx and Tc are the local air-stream and average room dry-bulb temperatures (in ºC or K), Vx is the local air-stream centre-line velocity (in m/s) and θ is measured in K.
The Reynolds number, Re, expresses the ratio of the inertial forces to viscous forces:
where U and L are characteristic velocity and length scales of the flow and ν is the kinematic
viscosity.
Natural convection flows are often characterized using the Rayleigh Number, Ra, given by:
where g is the acceleration due to gravity (g = 9.81 m/s2), β the coefficient of thermal expansion (where for an ideal gas, β = T 1 ), ∆T the temperature difference, L the length scale (e.g. the height of the heated surface), υ the kinematic viscosity and α the thermal diffusivity (α = k /ρCp).
The Grashof number, Gr, is equivalent to the Rayleigh number divided by the Prandtl number:
where g is the acceleration due to gravity, β the coefficient of thermal expansion ∆T temperature difference, L the length scale and υ the kinematic viscosity.
The following form of the Froude number is used by Linden [6] to characterize flow through corridors and doorways and in combined displacement and wind ventilation cases.
where U and L are characteristic velocity and length scales, respectively, and g the acceleration due to gravity.
The Richardson number, Ri, characterizes the importance of buoyancy. It is calculated from:
where ∆ ρ is the density difference that occurs over a typical (usually vertical) length scale, L, in a flow of velocity, U.
The flux Richardson number, Rif, is used to characterize the stabilizing effect of stratification on turbulence:
where Pkb and Pk are the turbulence production due to buoyancy and shear respectively
The buoyancy flux, B, is calculated from:
Linden (1999) uses this to characterize buoyancy driven flows, where W is the heat flux, β = 1/ T is the coefficient of expansion and cp is the specific heat capacity at constant pressure.
The conditions of the supplied air are often characterized by the discharge Archimedes number, Ar, which expresses the ratio of the buoyancy forces to momentum forces or the strength of natural convection to forced convection:
where T ∆ is the temperature difference between supply and exhaust, U is the initial velocity of the discharged air, g is the acceleration due to gravity and L is the length scale of the supply terminal (i.e. diffuser or grille).
Aerosol as one kind of Particulate Matter and contaminants,
From pre-proposal….
The respiratory system (http://www.sirinet.net/~jgjohnso/respiratory.html accesed 01st March 2007)
CHAPTER 46, SECTION 3
THE RESPIRATORY SYSTEM
You have read how the blood transports oxygen from the lungs to cells and carries carbon dioxide from the cells to the lungs. It is the function of the respiratory system to transport gases to and from the circulatory system. The respiratory system involves both External and Internal respiration.
External Respiration is the exchange of gases between the atmosphere and the blood. Internal Respiration is the exchange of gases between the blood and the cells of the body. Cellular Respiration or Aerobic Respiration involves the use of oxygen to break down glucose in the cell. We will examine the structures and mechanisms that carry oxygen to the cells for use in aerobic respiration and that eliminate the carbon dioxide that is produced by the same process.
OBJECTIVES:
1. Differentiate external respiration from internal respiration.
2. Trace the path of air from the atmosphere to the bloodstream.
3. Describe how gases are exchanged in the lungs and transported in the bloodstream.
4. Summarize the skeletal and muscular changes that occur during breathing.
5. Describe how the rate of breathing is controlled.
RESPIRATION
1. THE MAIN JOB OF THE RESPIRATORY SYSTEM IS TO GET OXYGEN INTO THE BODY AND WASTE GASES OUT OF THE BODY. IT IS THE FUNCTION OF THE RESPIRATORY SYSTEM TO TRANSPORT GASES TO AND FROM THE CIRCULATORY SYSTEM.
2. Respiration is a vital function of all living organisms.
3. Respiration occurs at TWO DIFFERENT LEVELS:
A. The level of the CELL. In the Mitochondria of Eukaryotic Cells, Aerobic Respiration requires OXYGEN to break down Glucose, releases CARBON DIOXIDE, and produces large amounts of ATP. THIS LEVEL OF RESPIRATION IS CALLED INTERNAL RESPIRATION OR CELLULAR RESPIRATION.
B. The level of the ORGANISM. An organism must get oxygen into its CELLS and CARBON DIOXIDE back out. THIS LEVEL OF RESPIRATION IS CALLED EXTERNAL RESPIRATION BECAUSE THE EXCHANGE OF GASES TAKES PLACE WITH THE EXTERNAL ENVIRONMENT. THE EXCHANGE OF GASES, OXYGEN (O2) AND CARBON DIOXIDE (CO2) BETWEEN AIR AND BLOOD.
4. EXTERNAL RESPIRATION INVOLVES THE RESPIRATORY SYSTEM.
5. A RESPIRATORY SYSTEM IS A GROUP OF ORGANS WORKING TOGETHER TO BRING ABOUT THE EXCHANGE OF OXYGEN AND CARBON DIOXIDE WITH THE ENVIRONMENT.
6. A single-celled organism living in water (DIFFUSION) gets its oxygen directly from its surroundings (the water). The oxygen easily diffuses across the Cell Membrane. Carbon dioxide also diffuses across the Cell Membrane; thus single-celled organisms do not need a Respiratory System.
7. In MULTICELLULAR ORGANISMS, Each Cell consumes Oxygen and produces Carbon dioxide. Large Multicellular organism must have a Respiratory System to ensure the effective exchange of gasses with the Atmosphere quickly and efficiently to survive.
8. THIS OCCURS EVERY TIME AN ORGANISM TAKES A BREATH.
9. The atmosphere of planet Earth is approximately 78% Nitrogen and 21% Oxygen. The remaining 1% is made up of Carbon Dioxide, Water Vapor, and other trace gases.
10. Humans are Air Breathers; our Respiratory System has adapted to these concentrations of gases in the Atmosphere. If the amount of Oxygen FALLS much below 15 %, our Respiratory System will be UNABLE to provide enough Oxygen to support cellular respiration.
THE PASSAGE OF AIR AND THE RESPIRATORY STRUCTURES (Figure 46-16)
1. THE HUMAN RESPIRATORY SYSTEM CONSIST OF THE NOSE, NASAL CAVITY, PHARYNX, LARYNX, TRACHEA, SMALLER CONDUCTING PASSAGEWAYS (BRONCHI AND BRONCHIOLES), AND LUNGS.
2. The Respiratory System may be divided into the UPPER RESPIRATORY TRACT AND THE LOWER RESPIRATORY TRACT.
3. THE UPPER RESPIRATORY TRACT CONSISTS OF THE PARTS OUTSIDE THE THORACIC (CHEST) CAVITY: THE AIR PASSAGES OF THE NOSE, NASAL CAVITIES, PHARYNX (WINDPIPE), LARYNX (VOICE BOX), AND UPPER TRACHEA.
4. THE LOWER RESPIRATORY TRACT CONSISTS OF THE PARTS FOUND IN THE THORACIC (CHEST) CAVITY: THE LOWER TRACHEA AND THE LUNGS THEMSELVES.
5. Air ENTERS the Respiratory System through the Mouth or Nose.
6. Air entering the Nose passes into the NASAL CAVITY. The Nasal Cavity is richly supplied with arteries, veins, and capillaries, which bring nutrients and water to its cells.
7. As air pushes back from the Nasal Cavity, it enters the PHARYNX. The Pharynx is located in the back of the mouth and serves as a passageway for BOTH AIR AND FOOD. When food is swallowed, a Flap of Cartilage, called the EPIGLOTTIS, presses down and covers the opening to the air passage (ever have food go "Down the Wrong Way"?).
8. From the Pharynx, the air moves through the LARYNX, the upper end of the Trachea, and into the TRACHEA (WINDPIPE), WHICH LEADS DIRECTLY TO THE LUNGS.
9. These passageways provide a direct connection between the outside air and some of the most Delicate Tissue in the body.
10. These passageways must filter out dust, dirt, smoke, bacteria, and a variety of other contaminants found in air.
11. THE FIRST FILTERING IS DONE IN THE NOSE. THE NOSE WILL DO THREE THINGS TO THE AIR WE BREATHE IN:
A. FILTER THE AIR
B. WARM THE AIR
C. PROVIDE MOISTURE (WATER VAPOR OR HUMIDITY) TO THE AIR.
12. As air passes through the nasal cavities it is warmed and humidified, so that air that reaches the lungs is warmed and moist.
13. The Nasal Airways are lined with Cilia and kept moist by Mucous secretions. The combination of Cilia and Mucous helps to filter out solid particles from the air an Warm and Moisten the air, which prevents damage to the delicate tissues that form the Respiratory System.
14. The moisture in the nose helps to heat and humidify the air, Increasing the amount of Water Vapor the air entering the Lungs contains.
15. This helps to keep the air entering the nose from Drying out the Lungs and other parts of our Respiratory System.
16. When air enters the Respiratory System through the Mouth, much less filtering is done. It is generally better to take in air through the Nose.
17. At the top of the Trachea is the LARYNX (Voice Box or Adam's Apple). Inside, and stretched across the Larynx are two highly elastic folds of tissue (Ligaments) called the VOCAL CORDS. Air rushing through the voice box causes the vocal cords to vibrate producing sound waves.
18. From the Larynx, the Warmed, Filtered, and Moistened air passes downward into the Thoracic Cavity through the Trachea.
19. The Walls of the Trachea are made up of C-Shaped rings of tough flexible Cartilage. These rings of cartilage Protect the Trachea, make it Flexible, and keep it from Collapsing or over expanding.
20. The Cells that line the trachea produce Mucus; the mucus helps to capture things still in the air (Dust and Microorganisms), and is swept out of the air passageway by tiny Cilia into the Digestion System.
21. Within the Thoracic Cavity, the Trachea divides into TWO Branches, the Right and Left BRONCHI. Each BRONCHUS enters the LUNG on its respective side. The Lungs are the Site of Gas Exchange Between the Atmosphere and the Blood. The Right Lung has Three Divisions or Lobes, and is slightly larger than the Two Lobed Left Lung. The Lungs are inside the Thoracic Cavity, bounded by the Rib Cage and Diaphragm. Lining the entire cavity and encasing the Lungs are PLEURA MEMBRANES that secrete a Mucus that decreases friction from the movement of the Lungs during Breathing. (Figure 47-16)
22. The further branching of the BRONCHIAL TUBES is often called the BRONCHIAL TREE.
23. Imagine the Trachea as the trunk of an upside down tree with extensive branches that become smaller and smaller; these smaller branches are the BRONCHIOLES.
24. Both Bronchi and Bronchioles contain Smooth Muscle Tissue in their walls. This muscle tissue controls the SIZE of the Air Passage.
25. The Bronchioles continue to subdivide until they finally end in Clusters of Tiny Hallow AIR SACS called ALVEOLI. Groups of Alveoli look like bunches of grapes. ALL EXCHANGE OF GASES IN THE LUNGS OCCURS IN THE ALVEOLI. (Figure 46-16 AND 17)
26. The Alveoli consist of thin, flexible membranes that contain an extensive network of Capillaries. The Membranes separate a gas from liquid. The gas is the air we take in through our Respiratory System, and the liquid is BLOOD.
27. The Functional Unit of the LUNGS is the ALVEOLI; it is here that the Circulatory and Respiratory Systems come together, for the purpose of gas exchange. ALL EXCHANGE OF GASES IN THE LUNGS OCCURS IN THE ALVEOLI. Each Lung contains nearly 300 Million ALVEOLI and has a total surface area about 40 times the surface area of your skin.
MECHANISM OF BREATHING (Figure 46-18)
1. BREATHING IS THE ENTRANCE AND EXIT OF AIR INTO AND FROM THE LUNGS.
2. VENTILATION is the term for the movement of air to and from the Alveoli.
3. Every single time you take a breath, or move air in and out of your lungs, TWO major actions take place.
A. INHALATION - also called INSPIRATION, air is pulled into the LUNGS. (Figure 46-18 (a))
B. EXHALATION - also called EXPIRATION, air is pushed out of the Lungs. (Figure 46-18 (b))
4. These Two actions deliver oxygen to the Alveoli, and remove Carbon dioxide.
5. The Continuous Cycles of Inhalation and Exhalation are known as BREATHING. Most of us Breathe 10 to 15 times per minute.
6. The lungs are not directly attached to any Muscle, SO THEY CANNOT BE EXPANDED OR CONTRACTED.
7. Inhalation and Exhalation are actually produced by Movements of the LARGE FLAT MUSCLE CALLED THE DIAPHRAGM AND THE INTERCOSTAL (BETWEEN THE RIBS) MUSCLES.
8. The DIAPHRAGM is located along the BOTTOM of the RIB CAGE and SEPARATES THE THORACIC CAVITY FROM THE ABDOMINAL CAVITY.
9. Before Inhalation the Diaphragm is curved UPWARD into the chest. During Inhalation, the Diaphragm CONTRACTS and Moves DOWN, CAUSING THE VOLUME OF THE THORACIC CAVITY TO INCREASE.
10. When the Diaphragm moves Down, the Volume of the Thoracic Cavity INCREASES and the AIR PRESSURE INSIDE IT DECREASES.
11. The Air OUTSIDE is still at ATMOSPHERIC PRESSURE, TO EQUALIZE THE PRESSURE INSIDE AND OUT, THE AIR RUSHES THROUGH THE TRACHEA INTO THE LUNGS - INHALED. (Figure 46-18 (a))
12. When the Diaphragm relaxes, it returns to its curved position. THIS ACTION CAUSES THE VOLUME OF AIR IN THE THORACIC CAVITY TO DECREASE.
13. As the Volume Decreases, the pressure in the Thoracic Cavity outside the lungs increases. This INCREASE the Air pressure and causes the LUNGS to DECREASE IN SIZE.
14. The air inside the Lungs is Pushed Out or EXHALED. (Figure 46-18 (b))
15. We generally breathe with the Diaphragm and Intercostal Muscles (REST), under extreme conditions we can use other muscles in our Thoracic Cavity to breathe (ACTIVITY).
16. Since our Breathing is based on Atmospheric Pressure, the Lungs can only Work Properly if the space around them is SEALED.
17. When the Diaphragm contracts, the expanded volume in the Thoracic Cavity quickly fills as air rushes into the Lungs. If there is a small hole in the Thoracic Cavity, the Respiratory System will NOT Work.
18. Air will rush into the cavity through the hole, upset the pressure relationship, and possibly cause the collapse of a lung.
GAS EXCHANGE AND TRANSPORT (Figure 46-17)
1. Chemical Analysis of the gases that are inhaled and exhaled:
GAS INHALED -vs- EXHALED
O2 20.71% 14.6%
CO2 0.04% 4.0%
H2O 1.25% 5.9%
2. THREE IMPORTANT THINGS HAPPEN TO THE AIR WE INHALE:
A. OXYGEN IS REMOVED
B. CARBON DIOXIDE IS ADDED
C. WATER VAPOR IS ADDED.
3. This occurs in the ALVEOLI in the LUNGS; Our Lungs consist of nearly 300 million ALVEOLI where gas exchange occurs (THE EXCHANGE OF CARBON DIOXIDE AND OXYGEN).
4. Blood flowing from the HEART enters Capillaries surrounding each Alveolus and spreads around the Alveolus. This Blood contains a LARGE AMOUNT of CO2 and Very Little O2.
5. The Concentration of the gases in the blood and the alveolus are not Equal (Concentration Gradient). This causes the DIFFUSION of CO2 from the Blood to the Alveolus and the DIFFUSION of O2 from the Alveolus into the Blood. (Figure 46-17)
6. The Blood leaving the alveolus has nearly tripled the total amount of oxygen it originally carried.
7. TWO SPECIAL MOLECULES HELP THIS PROCESS OF GAS EXCHANGE WORK EFFECTIVELY:
A. MACROMOLECULES - Soaplike, consisting of phospholipid and protein, they coat the inner surface of the Alveolus.
B. HEMOGLOBIN - An Oxygen Carrying Molecule that is a component of Blood. Hemoglobin is a red colored protein found in red blood cells. Each Hemoglobin molecule has FOUR SITES to which O2 atoms can bind. Thus, One Hemoglobin molecule can carry up to Four molecules of oxygen. Most of the oxygen - 97 percent - moves into the red blood cells, where it combines with Hemoglobin.
REGULATION OF BREATHING
1. Breathing is such an important function that your NERVOUS SYSTEM will NOT let you have complete control of it.
2. TEST IT! HOW LONG CAN YOU HOLD YOUR BREATH!
3. BREATHING IS AN INVOLUNTARY ACTION UNDER CONTROL OF THE MEDULLA OBLONGATA IN THE LOWER PART OF THE BRAIN. Sensory neurons in this region control MOTOR NEURONS IN THE SPINAL CORD.
4. Although YOU can consciously controlled breathing to a limited extent-such as holding your breath-it CANNOT BE CONSCIOUSLY SUPPRESSED. THE NEED TO SUPPLY OXYGEN TO OUR CELLS AND REMOVE CARBON DIOXIDE IS A POWERFUL ONE.
5. You can only hold your breath until you lose Consciousness - Then the Brain takes control and normal breathing resumes.
6. CARBON DIOXIDE AND HYDROGEN IONS (BLOOD ACIDITY) ARE THE PRIMARY STIMULI THAT CAUSES US TO BREATHE.
7. The Nervous System must have a way to determine whether enough O2 is getting into the Blood.
8. Two special sets of SENSORY NEURONS constantly check the levels of gases in the Blood. THESE SPECIAL SENSORY RECEPTORS ARE SENSITIVE TO THE LEVELS OF GASES IN THE BLOOD, ESPECIALLY THE LEVEL OF CARBON DIOXIDE.
9. One set is located IN the CAROTID ARTERIES in the NECK, which Carry Blood to the BRAIN.
10. The other set is located NEAR the AORTA, the large ARTERY that Carries Blood FROM THE HEART TO THE REST OF THE BODY.
11. When Carbon Dioxide Dissolves in the blood, it forms AN ACID KNOWN AS CARBONIC ACID. CARBONIC ACID IS SO UNSTABLE THAT IT IMMEDIATELY BREAKS DOWN INTO HYDROGEN ION (H+) AND A BICARBONATE IONS (HCO3-).
CO2 + H20 H2CO3
H2CO3 H+ + HCO3-
12. Most carbon dioxide travels in the blood as Bicarbonate Ions. When the Blood reaches the Lungs, the series of reactions is reversed. The Bicarbonate ions combine with a proton to form Carbonic Acid, which in turn forms Carbon Dioxide and Water. The carbon dioxide Diffuses out of the capillaries into the Alveoli and is exhaled into the atmosphere.
13. The Hydrogen Ions change the ACIDITY (pH) of the Blood, and it is this change in Acidity the special sensory cells respond to.
14. The Lungs of an average person have a total air capacity of about 6.0 liters. Only about 0.6 liter is exchange during Normal Breathing. This is all the air we need at rest.
15. During Exercise, deep breathing forces out much more of the total lung capacity. As much as 4.5 liters of air can be Inhaled or Exhaled with effort.
16. The MAXIMUM Amount of Air that can be moved into and out of the Respiratory System is Known AS THE VITAL CAPACITY OF THE LUNGS.
17. The Vital Capacity is ALWAYS 1 to 1.5 liters LESS than the Total Capacity because the Lungs Cannot be completely Deflated without serious damage.
18. The extra capacity allows us to exercise for long periods of time. Rather than Breathing 12 times a minute, as most of us do at REST, a Runner may Breath as often as 50 times a minute.
19. For rapid and deep breathing during vigorous exercise you use the muscles of the rib cage.
Type of indoor airflow & standard that related to Indoor air quality,
From doc….
Ending: more than 4 simulation …mapping
References
Boehm, B.: Software Risk Management. IEEE Computer Society Press. (1989)
Boehm, B.: A spiral model of software development and enhancement. IEEE Com-
puters. (1988) 61-62
Cairo, O., Barreiro, J., Solsona, F., Software Methodologies at Risky, WWW home page: http://cannes.divcom.itam.mx/Osvaldo, Instituto Tecnologico Autonomo de Mexico (ITAM), Universidad Nacional Autonoma de Mexico (UNAM), Mexico
Knowledge Acquisition, Modeling and Management: 11th European Workshop, EKAW '99, Dagstuhl Castle, Germany, May 1999. Proceedings
Peng, S.-H. and L. Davidson. Performance evaluation of a displacement ventilation
system for improving indoor air quality: a numerical study. in 8th International
Conference on Indoor Air Quality and Climate. 1999. Edinburgh, Scotland.
Di Tommaso, R.M., E. Nino, and G.V. Fracastoro, Influence of the boundary thermal
conditions on the air change efficiency indexes. Indoor Air, 1999. 9: p. 63-69.
Zhang, Y., X. Wang, G.L. Riskowski, and L.L. Christianson, Quantifying ventilation
effectiveness for air quality control. Transactions of the American Society of
Agricultural and Biological Engineers (ASABE), 2001. 44(2): p. 385-390.
Linden, P.F., The fluid mechanics of natural ventilation. Annu. Rev. Fluid Mech., 1999.
31: p. 201-238.
The main factors affecting contaminants
Characteristics of indoor air flows
Aerosol as one kind of Particulate Matter and contaminants,
The respiratory system
Type of indoor airflow & standard that related to Indoor air quality,
Ending: more than 4 simulation …
http://continuousimprovement.blogsome.com
http://Life4aaK.blogspot.com
http://godoproduction.blogspot.com
A typical dictionary defines risk as the possibility of loss or injury. It implies that risk has two main components: the probability of some event occurring and the negative consequence if it occurs. Thus, to analyze risk we should be able to estimate these two factors. Boehm [1] translated this defnition into the
fundamental concept of risk management: the risk exposure, sometimes called risk impact.
Fundamental concept of risk (Cairo., et al., 1999)
A typical dictionary defines risk as the possibility of loss or injury. It implies that risk has two main components: the probability of some event occurring and the negative consequence if it occurs. Thus, to analyze risk we should be able to estimate these two factors. Boehm (1989) translated this definition into the fundamental concept of risk management: the risk exposure, sometimes called risk impact.
Where RE means risk exposure, P(UO) expresses the probability of an unsatisfactory outcome, and L(UO) means the loss to the parties affected if the outcome is unsatisfactory.
Usually the perception of risk is higher for those items over which one have little or no control. However, the importance of the risk factors might be considered as some combination of risk frequency (that is, how likely it is that the risk will occur) and risk impact (such as, how serious a threat the risk represents if it does occur). In considering risks you must also consider their perceived level of control. This represents the degree to which the project manager perceived that their actions could prevent the risk from occurring. Most of the probable risks or threats to projects can be reduced or avoided using an appropriate methodology. It can also be complemented with approximative methods, which can provide enough information to support risk management decisions.
Risk-reduction is a fundamental part of project management in software and knowledge engineering. Software risk management is important because it helps people to avoid disasters, rework, and overkill, it also stimulates win-win situations on software projects (Boehm, 1989).
We should be aware that by avoiding or reducing the most significant risks, managers make more informed decisions, we obtain better outcomes, and hence the project will have a higher probability of success.
Boehm (1988) suggests to use a software risk management plan, which consists of five steps:
• Identify the project's top risk items.
• Present a plan for resolving each risk item.
• Update list of top risk items, plan, and results monthly.
• Highlight risk-item status in monthly project reviews.
• Initiate appropriate corrective actions.
Successful management of a project leads to control. Control leads to quality. Quality leads to satisfied customers. And we know customers are the final arbiters of a product or service.
The main factors affecting contaminants OK
Characteristics of indoor air flows:
Gant., et al.; 2006 state a number of parameters which can be used to characterize the dispersion of a contaminant inside a room, i. e.:
1. Fresh Air/ Contaminant Distribution:
Contaminant Concentration, Local Mean Age of Air, Purging Effectiveness of Inlets, Local Specific Contaminant-Accumulating Index, Air Change Efficiency, Ventilation Effectiveness Factor, Relative Ventilation Efficiency.
2. Stability and Bouyancy of the Room Air:
Reynold Number, Rayleigh Number, Grashof Number, Froude Number, Richardson Number, Flux Richardson Number, Bouyancy Flux.
3. Temperature Distribution:
Air Diffusion Performance Index, Effective Draft Temperature.
4. Supply Air Conditions:
Purging Effectiveness of Inlet, Reynold Number, Froude Number, Archimedes Number.
Due to overlap between these subjects, some parameters appear more than once. Some parameters characterize directly the observed pattern of contaminant distribution whilst others characterize flow features, such as stability. Flow parameters such as the ‘mean age of air’ are difficult but not impossible to calculate experimentally. They are used mainly as a tool to help interpret data from numerical simulations of contaminant dispersion. For discussions on how these parameters are used to assess compliance with standards on room air quality, see Peng & Davidson (1999) or the ASHRAE Guides (2003).
Clearly the simplest indicator of contaminant distribution in a room is the contaminant concentration, i.e. the mass of contaminant per unit volume of air (measured in kg/m3). Contaminant concentration is sometimes expressed in terms of parts per million (ppm), or parts per billion, trillion etc. This can be based on either the mass fraction or the volume fraction.
Local Mean Age of Air is commonly used to evaluate the performance of a ventilation system and indoor air quality. The precise meaning of the local mean age is defined in Di Tommaso et al.; (1999) as follows: “the average time it takes for air to travel from the inlet to any point P in the room”.
The purging effectiveness of an inlet is a quantity that can be used to identify the relative performance of each inlet in a room where there are multiple inlets.
Peng et al.; (1999) classify the various measures used to characterize ventilation performance into three groups: measures of ventilation air-diffusing efficiency which indicate the ability to provide fresh air to occupants, ventilation effectiveness which indicate the ability to remove contaminants from a ventilated space and specific ventilation effectiveness which deals with specific situations.
Air Change Efficiency is a measure of how effectively the air present in a room is replaced by fresh air from the ventilation system (Di Tommaso et al.; 1999). It is the ratio of the room mean age that would exist if the air in the room were completely mixed to the average time of replacement of the room.
The Ventilation Effectiveness Faction (VEF) appears to be ASHRAE’s preferred method for characterizing indoor air quality and is based on the work of Zhang et al. (2001).
The relative ventilation efficiency is the ratio of the local mean age that would exist if the air in the room were completely mixed to the local mean age that is actually measured at a point.
Air Diffusion Performance Index (ADPI) is primarily a measure of occupant comfort rather than an indicator of contaminant concentrations. It expresses the percentage of locations in an occupied zone that meet air movement and temperature specifications for comfort.
The temperature effectiveness is similar in concept to ventilation effectiveness and reflects the ability of a ventilation system to remove heat.
The effective draft temperature, θ, indicates the feeling of coolness due to air motion:
where Tx and Tc are the local air-stream and average room dry-bulb temperatures (in ºC or K), Vx is the local air-stream centre-line velocity (in m/s) and θ is measured in K.
The Reynolds number, Re, expresses the ratio of the inertial forces to viscous forces:
where U and L are characteristic velocity and length scales of the flow and ν is the kinematic
viscosity.
Natural convection flows are often characterized using the Rayleigh Number, Ra, given by:
where g is the acceleration due to gravity (g = 9.81 m/s2), β the coefficient of thermal expansion (where for an ideal gas, β = T 1 ), ∆T the temperature difference, L the length scale (e.g. the height of the heated surface), υ the kinematic viscosity and α the thermal diffusivity (α = k /ρCp).
The Grashof number, Gr, is equivalent to the Rayleigh number divided by the Prandtl number:
where g is the acceleration due to gravity, β the coefficient of thermal expansion ∆T temperature difference, L the length scale and υ the kinematic viscosity.
The following form of the Froude number is used by Linden [6] to characterize flow through corridors and doorways and in combined displacement and wind ventilation cases.
where U and L are characteristic velocity and length scales, respectively, and g the acceleration due to gravity.
The Richardson number, Ri, characterizes the importance of buoyancy. It is calculated from:
where ∆ ρ is the density difference that occurs over a typical (usually vertical) length scale, L, in a flow of velocity, U.
The flux Richardson number, Rif, is used to characterize the stabilizing effect of stratification on turbulence:
where Pkb and Pk are the turbulence production due to buoyancy and shear respectively
The buoyancy flux, B, is calculated from:
Linden (1999) uses this to characterize buoyancy driven flows, where W is the heat flux, β = 1/ T is the coefficient of expansion and cp is the specific heat capacity at constant pressure.
The conditions of the supplied air are often characterized by the discharge Archimedes number, Ar, which expresses the ratio of the buoyancy forces to momentum forces or the strength of natural convection to forced convection:
where T ∆ is the temperature difference between supply and exhaust, U is the initial velocity of the discharged air, g is the acceleration due to gravity and L is the length scale of the supply terminal (i.e. diffuser or grille).
Aerosol as one kind of Particulate Matter and contaminants,
From pre-proposal….
The respiratory system (http://www.sirinet.net/~jgjohnso/respiratory.html accesed 01st March 2007)
CHAPTER 46, SECTION 3
THE RESPIRATORY SYSTEM
You have read how the blood transports oxygen from the lungs to cells and carries carbon dioxide from the cells to the lungs. It is the function of the respiratory system to transport gases to and from the circulatory system. The respiratory system involves both External and Internal respiration.
External Respiration is the exchange of gases between the atmosphere and the blood. Internal Respiration is the exchange of gases between the blood and the cells of the body. Cellular Respiration or Aerobic Respiration involves the use of oxygen to break down glucose in the cell. We will examine the structures and mechanisms that carry oxygen to the cells for use in aerobic respiration and that eliminate the carbon dioxide that is produced by the same process.
OBJECTIVES:
1. Differentiate external respiration from internal respiration.
2. Trace the path of air from the atmosphere to the bloodstream.
3. Describe how gases are exchanged in the lungs and transported in the bloodstream.
4. Summarize the skeletal and muscular changes that occur during breathing.
5. Describe how the rate of breathing is controlled.
RESPIRATION
1. THE MAIN JOB OF THE RESPIRATORY SYSTEM IS TO GET OXYGEN INTO THE BODY AND WASTE GASES OUT OF THE BODY. IT IS THE FUNCTION OF THE RESPIRATORY SYSTEM TO TRANSPORT GASES TO AND FROM THE CIRCULATORY SYSTEM.
2. Respiration is a vital function of all living organisms.
3. Respiration occurs at TWO DIFFERENT LEVELS:
A. The level of the CELL. In the Mitochondria of Eukaryotic Cells, Aerobic Respiration requires OXYGEN to break down Glucose, releases CARBON DIOXIDE, and produces large amounts of ATP. THIS LEVEL OF RESPIRATION IS CALLED INTERNAL RESPIRATION OR CELLULAR RESPIRATION.
B. The level of the ORGANISM. An organism must get oxygen into its CELLS and CARBON DIOXIDE back out. THIS LEVEL OF RESPIRATION IS CALLED EXTERNAL RESPIRATION BECAUSE THE EXCHANGE OF GASES TAKES PLACE WITH THE EXTERNAL ENVIRONMENT. THE EXCHANGE OF GASES, OXYGEN (O2) AND CARBON DIOXIDE (CO2) BETWEEN AIR AND BLOOD.
4. EXTERNAL RESPIRATION INVOLVES THE RESPIRATORY SYSTEM.
5. A RESPIRATORY SYSTEM IS A GROUP OF ORGANS WORKING TOGETHER TO BRING ABOUT THE EXCHANGE OF OXYGEN AND CARBON DIOXIDE WITH THE ENVIRONMENT.
6. A single-celled organism living in water (DIFFUSION) gets its oxygen directly from its surroundings (the water). The oxygen easily diffuses across the Cell Membrane. Carbon dioxide also diffuses across the Cell Membrane; thus single-celled organisms do not need a Respiratory System.
7. In MULTICELLULAR ORGANISMS, Each Cell consumes Oxygen and produces Carbon dioxide. Large Multicellular organism must have a Respiratory System to ensure the effective exchange of gasses with the Atmosphere quickly and efficiently to survive.
8. THIS OCCURS EVERY TIME AN ORGANISM TAKES A BREATH.
9. The atmosphere of planet Earth is approximately 78% Nitrogen and 21% Oxygen. The remaining 1% is made up of Carbon Dioxide, Water Vapor, and other trace gases.
10. Humans are Air Breathers; our Respiratory System has adapted to these concentrations of gases in the Atmosphere. If the amount of Oxygen FALLS much below 15 %, our Respiratory System will be UNABLE to provide enough Oxygen to support cellular respiration.
THE PASSAGE OF AIR AND THE RESPIRATORY STRUCTURES (Figure 46-16)
1. THE HUMAN RESPIRATORY SYSTEM CONSIST OF THE NOSE, NASAL CAVITY, PHARYNX, LARYNX, TRACHEA, SMALLER CONDUCTING PASSAGEWAYS (BRONCHI AND BRONCHIOLES), AND LUNGS.
2. The Respiratory System may be divided into the UPPER RESPIRATORY TRACT AND THE LOWER RESPIRATORY TRACT.
3. THE UPPER RESPIRATORY TRACT CONSISTS OF THE PARTS OUTSIDE THE THORACIC (CHEST) CAVITY: THE AIR PASSAGES OF THE NOSE, NASAL CAVITIES, PHARYNX (WINDPIPE), LARYNX (VOICE BOX), AND UPPER TRACHEA.
4. THE LOWER RESPIRATORY TRACT CONSISTS OF THE PARTS FOUND IN THE THORACIC (CHEST) CAVITY: THE LOWER TRACHEA AND THE LUNGS THEMSELVES.
5. Air ENTERS the Respiratory System through the Mouth or Nose.
6. Air entering the Nose passes into the NASAL CAVITY. The Nasal Cavity is richly supplied with arteries, veins, and capillaries, which bring nutrients and water to its cells.
7. As air pushes back from the Nasal Cavity, it enters the PHARYNX. The Pharynx is located in the back of the mouth and serves as a passageway for BOTH AIR AND FOOD. When food is swallowed, a Flap of Cartilage, called the EPIGLOTTIS, presses down and covers the opening to the air passage (ever have food go "Down the Wrong Way"?).
8. From the Pharynx, the air moves through the LARYNX, the upper end of the Trachea, and into the TRACHEA (WINDPIPE), WHICH LEADS DIRECTLY TO THE LUNGS.
9. These passageways provide a direct connection between the outside air and some of the most Delicate Tissue in the body.
10. These passageways must filter out dust, dirt, smoke, bacteria, and a variety of other contaminants found in air.
11. THE FIRST FILTERING IS DONE IN THE NOSE. THE NOSE WILL DO THREE THINGS TO THE AIR WE BREATHE IN:
A. FILTER THE AIR
B. WARM THE AIR
C. PROVIDE MOISTURE (WATER VAPOR OR HUMIDITY) TO THE AIR.
12. As air passes through the nasal cavities it is warmed and humidified, so that air that reaches the lungs is warmed and moist.
13. The Nasal Airways are lined with Cilia and kept moist by Mucous secretions. The combination of Cilia and Mucous helps to filter out solid particles from the air an Warm and Moisten the air, which prevents damage to the delicate tissues that form the Respiratory System.
14. The moisture in the nose helps to heat and humidify the air, Increasing the amount of Water Vapor the air entering the Lungs contains.
15. This helps to keep the air entering the nose from Drying out the Lungs and other parts of our Respiratory System.
16. When air enters the Respiratory System through the Mouth, much less filtering is done. It is generally better to take in air through the Nose.
17. At the top of the Trachea is the LARYNX (Voice Box or Adam's Apple). Inside, and stretched across the Larynx are two highly elastic folds of tissue (Ligaments) called the VOCAL CORDS. Air rushing through the voice box causes the vocal cords to vibrate producing sound waves.
18. From the Larynx, the Warmed, Filtered, and Moistened air passes downward into the Thoracic Cavity through the Trachea.
19. The Walls of the Trachea are made up of C-Shaped rings of tough flexible Cartilage. These rings of cartilage Protect the Trachea, make it Flexible, and keep it from Collapsing or over expanding.
20. The Cells that line the trachea produce Mucus; the mucus helps to capture things still in the air (Dust and Microorganisms), and is swept out of the air passageway by tiny Cilia into the Digestion System.
21. Within the Thoracic Cavity, the Trachea divides into TWO Branches, the Right and Left BRONCHI. Each BRONCHUS enters the LUNG on its respective side. The Lungs are the Site of Gas Exchange Between the Atmosphere and the Blood. The Right Lung has Three Divisions or Lobes, and is slightly larger than the Two Lobed Left Lung. The Lungs are inside the Thoracic Cavity, bounded by the Rib Cage and Diaphragm. Lining the entire cavity and encasing the Lungs are PLEURA MEMBRANES that secrete a Mucus that decreases friction from the movement of the Lungs during Breathing. (Figure 47-16)
22. The further branching of the BRONCHIAL TUBES is often called the BRONCHIAL TREE.
23. Imagine the Trachea as the trunk of an upside down tree with extensive branches that become smaller and smaller; these smaller branches are the BRONCHIOLES.
24. Both Bronchi and Bronchioles contain Smooth Muscle Tissue in their walls. This muscle tissue controls the SIZE of the Air Passage.
25. The Bronchioles continue to subdivide until they finally end in Clusters of Tiny Hallow AIR SACS called ALVEOLI. Groups of Alveoli look like bunches of grapes. ALL EXCHANGE OF GASES IN THE LUNGS OCCURS IN THE ALVEOLI. (Figure 46-16 AND 17)
26. The Alveoli consist of thin, flexible membranes that contain an extensive network of Capillaries. The Membranes separate a gas from liquid. The gas is the air we take in through our Respiratory System, and the liquid is BLOOD.
27. The Functional Unit of the LUNGS is the ALVEOLI; it is here that the Circulatory and Respiratory Systems come together, for the purpose of gas exchange. ALL EXCHANGE OF GASES IN THE LUNGS OCCURS IN THE ALVEOLI. Each Lung contains nearly 300 Million ALVEOLI and has a total surface area about 40 times the surface area of your skin.
MECHANISM OF BREATHING (Figure 46-18)
1. BREATHING IS THE ENTRANCE AND EXIT OF AIR INTO AND FROM THE LUNGS.
2. VENTILATION is the term for the movement of air to and from the Alveoli.
3. Every single time you take a breath, or move air in and out of your lungs, TWO major actions take place.
A. INHALATION - also called INSPIRATION, air is pulled into the LUNGS. (Figure 46-18 (a))
B. EXHALATION - also called EXPIRATION, air is pushed out of the Lungs. (Figure 46-18 (b))
4. These Two actions deliver oxygen to the Alveoli, and remove Carbon dioxide.
5. The Continuous Cycles of Inhalation and Exhalation are known as BREATHING. Most of us Breathe 10 to 15 times per minute.
6. The lungs are not directly attached to any Muscle, SO THEY CANNOT BE EXPANDED OR CONTRACTED.
7. Inhalation and Exhalation are actually produced by Movements of the LARGE FLAT MUSCLE CALLED THE DIAPHRAGM AND THE INTERCOSTAL (BETWEEN THE RIBS) MUSCLES.
8. The DIAPHRAGM is located along the BOTTOM of the RIB CAGE and SEPARATES THE THORACIC CAVITY FROM THE ABDOMINAL CAVITY.
9. Before Inhalation the Diaphragm is curved UPWARD into the chest. During Inhalation, the Diaphragm CONTRACTS and Moves DOWN, CAUSING THE VOLUME OF THE THORACIC CAVITY TO INCREASE.
10. When the Diaphragm moves Down, the Volume of the Thoracic Cavity INCREASES and the AIR PRESSURE INSIDE IT DECREASES.
11. The Air OUTSIDE is still at ATMOSPHERIC PRESSURE, TO EQUALIZE THE PRESSURE INSIDE AND OUT, THE AIR RUSHES THROUGH THE TRACHEA INTO THE LUNGS - INHALED. (Figure 46-18 (a))
12. When the Diaphragm relaxes, it returns to its curved position. THIS ACTION CAUSES THE VOLUME OF AIR IN THE THORACIC CAVITY TO DECREASE.
13. As the Volume Decreases, the pressure in the Thoracic Cavity outside the lungs increases. This INCREASE the Air pressure and causes the LUNGS to DECREASE IN SIZE.
14. The air inside the Lungs is Pushed Out or EXHALED. (Figure 46-18 (b))
15. We generally breathe with the Diaphragm and Intercostal Muscles (REST), under extreme conditions we can use other muscles in our Thoracic Cavity to breathe (ACTIVITY).
16. Since our Breathing is based on Atmospheric Pressure, the Lungs can only Work Properly if the space around them is SEALED.
17. When the Diaphragm contracts, the expanded volume in the Thoracic Cavity quickly fills as air rushes into the Lungs. If there is a small hole in the Thoracic Cavity, the Respiratory System will NOT Work.
18. Air will rush into the cavity through the hole, upset the pressure relationship, and possibly cause the collapse of a lung.
GAS EXCHANGE AND TRANSPORT (Figure 46-17)
1. Chemical Analysis of the gases that are inhaled and exhaled:
GAS INHALED -vs- EXHALED
O2 20.71% 14.6%
CO2 0.04% 4.0%
H2O 1.25% 5.9%
2. THREE IMPORTANT THINGS HAPPEN TO THE AIR WE INHALE:
A. OXYGEN IS REMOVED
B. CARBON DIOXIDE IS ADDED
C. WATER VAPOR IS ADDED.
3. This occurs in the ALVEOLI in the LUNGS; Our Lungs consist of nearly 300 million ALVEOLI where gas exchange occurs (THE EXCHANGE OF CARBON DIOXIDE AND OXYGEN).
4. Blood flowing from the HEART enters Capillaries surrounding each Alveolus and spreads around the Alveolus. This Blood contains a LARGE AMOUNT of CO2 and Very Little O2.
5. The Concentration of the gases in the blood and the alveolus are not Equal (Concentration Gradient). This causes the DIFFUSION of CO2 from the Blood to the Alveolus and the DIFFUSION of O2 from the Alveolus into the Blood. (Figure 46-17)
6. The Blood leaving the alveolus has nearly tripled the total amount of oxygen it originally carried.
7. TWO SPECIAL MOLECULES HELP THIS PROCESS OF GAS EXCHANGE WORK EFFECTIVELY:
A. MACROMOLECULES - Soaplike, consisting of phospholipid and protein, they coat the inner surface of the Alveolus.
B. HEMOGLOBIN - An Oxygen Carrying Molecule that is a component of Blood. Hemoglobin is a red colored protein found in red blood cells. Each Hemoglobin molecule has FOUR SITES to which O2 atoms can bind. Thus, One Hemoglobin molecule can carry up to Four molecules of oxygen. Most of the oxygen - 97 percent - moves into the red blood cells, where it combines with Hemoglobin.
REGULATION OF BREATHING
1. Breathing is such an important function that your NERVOUS SYSTEM will NOT let you have complete control of it.
2. TEST IT! HOW LONG CAN YOU HOLD YOUR BREATH!
3. BREATHING IS AN INVOLUNTARY ACTION UNDER CONTROL OF THE MEDULLA OBLONGATA IN THE LOWER PART OF THE BRAIN. Sensory neurons in this region control MOTOR NEURONS IN THE SPINAL CORD.
4. Although YOU can consciously controlled breathing to a limited extent-such as holding your breath-it CANNOT BE CONSCIOUSLY SUPPRESSED. THE NEED TO SUPPLY OXYGEN TO OUR CELLS AND REMOVE CARBON DIOXIDE IS A POWERFUL ONE.
5. You can only hold your breath until you lose Consciousness - Then the Brain takes control and normal breathing resumes.
6. CARBON DIOXIDE AND HYDROGEN IONS (BLOOD ACIDITY) ARE THE PRIMARY STIMULI THAT CAUSES US TO BREATHE.
7. The Nervous System must have a way to determine whether enough O2 is getting into the Blood.
8. Two special sets of SENSORY NEURONS constantly check the levels of gases in the Blood. THESE SPECIAL SENSORY RECEPTORS ARE SENSITIVE TO THE LEVELS OF GASES IN THE BLOOD, ESPECIALLY THE LEVEL OF CARBON DIOXIDE.
9. One set is located IN the CAROTID ARTERIES in the NECK, which Carry Blood to the BRAIN.
10. The other set is located NEAR the AORTA, the large ARTERY that Carries Blood FROM THE HEART TO THE REST OF THE BODY.
11. When Carbon Dioxide Dissolves in the blood, it forms AN ACID KNOWN AS CARBONIC ACID. CARBONIC ACID IS SO UNSTABLE THAT IT IMMEDIATELY BREAKS DOWN INTO HYDROGEN ION (H+) AND A BICARBONATE IONS (HCO3-).
CO2 + H20 H2CO3
H2CO3 H+ + HCO3-
12. Most carbon dioxide travels in the blood as Bicarbonate Ions. When the Blood reaches the Lungs, the series of reactions is reversed. The Bicarbonate ions combine with a proton to form Carbonic Acid, which in turn forms Carbon Dioxide and Water. The carbon dioxide Diffuses out of the capillaries into the Alveoli and is exhaled into the atmosphere.
13. The Hydrogen Ions change the ACIDITY (pH) of the Blood, and it is this change in Acidity the special sensory cells respond to.
14. The Lungs of an average person have a total air capacity of about 6.0 liters. Only about 0.6 liter is exchange during Normal Breathing. This is all the air we need at rest.
15. During Exercise, deep breathing forces out much more of the total lung capacity. As much as 4.5 liters of air can be Inhaled or Exhaled with effort.
16. The MAXIMUM Amount of Air that can be moved into and out of the Respiratory System is Known AS THE VITAL CAPACITY OF THE LUNGS.
17. The Vital Capacity is ALWAYS 1 to 1.5 liters LESS than the Total Capacity because the Lungs Cannot be completely Deflated without serious damage.
18. The extra capacity allows us to exercise for long periods of time. Rather than Breathing 12 times a minute, as most of us do at REST, a Runner may Breath as often as 50 times a minute.
19. For rapid and deep breathing during vigorous exercise you use the muscles of the rib cage.
Type of indoor airflow & standard that related to Indoor air quality,
From doc….
Ending: more than 4 simulation …mapping
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The main factors affecting contaminants
Characteristics of indoor air flows
Aerosol as one kind of Particulate Matter and contaminants,
The respiratory system
Type of indoor airflow & standard that related to Indoor air quality,
Ending: more than 4 simulation …
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