Aula Teórica 1
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Transcript of Aula Teórica 1
Teachers
• Ramiro Neves, ext. 1397, 917224732• [email protected]• www.mohid.com
• Guillaume Riflet, (Visual Basic)• [email protected]
• Offices: Pavilhão de Mecânica I, 1º floor.
Dia mundial da água, Cascais, 2007
2D Overland flow
2/3. /hAR H xQ
n
PrecipitationVariable in Time
& Space
3D Porous Media
( )i i
h zK h
t x x
1D Drainage network
2 2 2
2 4/30
h
Q Q H Q ngA
t x A x A R
Integrated Basin Modelling
Integrated Basin Modeling
Rain Intensity
Flow Production
• 2 Different Soils
• Infiltration
• Overland Flow
Dia mundial da água, Cascais, 2007
Integrated Basin Modeling
Rain Intensity
Sediment Transport
• 2 Catchments
• 1 Reservoir
Difficulties are apparent because:
• Fluid Mechanics requires a FEW physical concepts.
• Mathematical operators are mostly derivatives, gradients and divergences.
• This course is an excellent opportunity to consolidate basic concepts of Engineering Sciences.
Set of courses downstream MFA
• Transferência de Energia e Massa. • Hidráulica Ambiental,• Hidrologia Ambiental e Recursos Hídricos,• Física da Atmosfera e do Oceano,• Ecologia....• Modelação Ambiental,• Planeamento Biofísico,• Gestão Integrada de Bacias Hidrográficas.
Requirements
• Physics: Forces, Newton law and acceleration, kinetic energy, momentum, fluxes.
• Mathematics: derivative, integral, divergence, gradient, vector internal and external products.
Conhecimentos a aquirir
• Compreensão das equações da mecânica dos fluidos e dos processos que determinam o movimento do fluido.
• Domínio dos conceitos de advecção e de difusão e do conceito de equação de evolução essenciais para as disciplinas a jusante.
MFA practical part
• A computational component is added to the classical exercises with 3 objectives:1. To show that Fluid Mechanics goes much beyond simple
analytical solutions;2. To help students to enhance their programing skills.3. To replace the classical laboratory lectures (laboratories were
essential before computational methods were available). • This component will be consolidated with a group home
work programmed using – preferentially - VBA. It is part of the MS Office is object oriented and useful for a wide range of engineering issues (database, internet...).
Bibliography
• Fluid Mechanics, Frank White, McGraw-Hill, (or any other Fluid Mechanics Introduction book de introdução).
• Apontamentos de Mecânica dos Fluidos I (Mecânica).
• Texts about specific subjects,• Lectures’ PPT.
What is a fluid?• Is formed by molecules...
– That move, as in any other type of matter above 0 K. ,– The difference between a fluid and a solid is that in the fluid
the molecules can change their relative positions allowing them to get the shape of the containers.
– Fluids can be liquids or gases• In gases molecules have free relative movement.• In liquids molecules form groups with relative free
movement (allowing them to get the shape of the container) which dimension depends on temperature (influencing their viscosity).
Why is Fluid Mechanics distinct from Solid Mechanics?
• In a fluid each molecule (or group of molecules) have relative movement freedom and not in solids. The consequence is that tangential stress deforms the fluids. Or in other words, if there is tangential stress there is movement.
• Normal stress compress the fluid, that can remain in rest. Tangential shear moves the fluid in layers creating velocity gradients.
Shear is proportional to the rate of deformation.
Continuum Hypothesis
• Necessary because we cannot assess the movement of individual molecules (too many and the Heisenberg principle) .
• But they move individually.... – The unknown molecule movement will be dealt as
diffusion in the equations.• When do we have velocity in a fluid?
– When there is net mass transport across a surface. • What is velocity?
What is the velocity?• Velocity is the flux of volume per unit of area. • The Velocity is defined in a point and thus is the flow per unit of
area, when the area tends to zero.
• A surface can have 3 orientations in a tridimensional space and thus velocity can have up to 3 components.
• The velocity component in one direction is the internal product of the velocity vector by the unitary vector along that direction. Using the surface normal one can write :
nudA
dQ
dA
dQun
.
dA
dQun
n
Discharge / Advective Flux
A
jj
A
dAnuQdAnuQdAnudQdt
dVol ..
Knowing the 3 Velocity components and knowing that the velocity is the discharge per unit of area when the area tends to zero ( The velocity is definided in a point) we can compute the discharge integrating the velocity along the whole area:
Defining a specific property as its value per unit of volume, (when the volume tends to zero)
dVol
dMc
And the flux of M across a surface is:
A
dAnucm
dAnuccdQdt
dVol
dVol
dM
dt
dMmd
.
.
We can say that the flux of M across na elementary surface is:
Summary
• We know what is fluid Mechanics and what for.• We know what is a fluid,• We know what is velocity and the advective flux.• We know that Fluid Mechanics aims to study flows
and thus to know the velocity distributions.• To compute fluxes we also need to know specific
properties distributions….