1 / 24

Groundwater Pollution Remediation (NOTE 2)

Groundwater Pollution Remediation (NOTE 2). Joonhong Park Yonsei CEE Department 2015. 10. 05. Darcy’s Experiment (1856). Flow of water in homogeneous sand filter under steady conditions. A: cross area. Sand Porous Medium. h 2. L. h 1. Datum. Q = - K * A * (h 2 -h 1 )/L

jgold
Download Presentation

Groundwater Pollution Remediation (NOTE 2)

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript


  1. Groundwater Pollution Remediation (NOTE 2) Joonhong Park Yonsei CEE Department 2015. 10. 05. CEE3330 Y2013 WEEK3

  2. Darcy’s Experiment (1856) Flow of water in homogeneous sand filter under steady conditions A: cross area Sand Porous Medium h2 L h1 Datum Q = - K * A * (h2-h1)/L K= hydraulic conductivity CEE3330-01 May 8, 2007 Joonhong Park Copy Right

  3. Darcy’s Law Q = - K * A * (Φ2 - Φ1)/L Φ piezometric head In a 1-D differential form, Darcy’s law may be: Darcy’s velocity: q = Q/A = dV/[A*dt] = - K * [dΦ/dL] Hydraulic Conductivity, K (L/T) KΞk * ρ * g / μ Here, k = intrinsic permeability (L2) ρ: fluid density (M L-3); g: gravity (LT-2) μ: fluid dynamic viscosity (M L-1 T-1) CEE3330-01 May 8, 2007 Joonhong Park Copy Right

  4. Modeling of Water Flow in Porous Media • Micro-scale modeling: the Navier-Stokes equation (flow through the void spaces in aquifers; fluid elements are described by differential equations ) • Macro-scale modeling: the Darcy’s equation (Darcy’s velocity: a volume flux defined as the volume of discharge per unit of bulk area) (What is seepage velocity? Velocity of a fluid element [v] vs Average v [q/n]) • Discussion (Differences? Advantages/Disadvantages?)

  5. Forces on Fluids in Porous Media (I) Driving forces: pressure (p) and a body force due to gravity Resistance forces (F) are involved in fluid motion in porous media (p+dl*dp/dl)*n*dA z dz dl F ρ:density of fluid g:gravity constant n:porosity p:pressure p*n*dA dA ρ*g*n*dA*dl l ρ*g*n*dA*dl * (dz/dl) + F (at Equilibrium) (p+dl*dp/dl)*n*dA = p*n*dA - Macro-scale F/(n*dA*dl) = - (dp/dl + ρ*g*dz/dl)

  6. Forces on Fluids in Porous Media (II) Meanwhile, from Exact Solution of N-S Equation 1) 8*μ*ave. v/R^2 = - (dp/dl + ρ*g*dz/dl) for a cylindrical tube of small radius R 2) 3*μ*ave v/d^2 = - (dp/dl + ρ*g*dz/dl) for a thin film of thickness d 3) 12*μ*ave v/b^2 = - (dp/dl + ρ*g*dz/dl) for between two plates spaced a distance b apart Micro-scale Resistance forces per unit volume (F/[dA*dl])

  7. Forces on Fluids in Porous Media (III) F/(n*dA*dl) = (C*μ/[characteristic length^2])*q Here: q= ave v/n The effects of the tortuous path traversed by fluid elements in a porous medium are Included in the parameters of characteristic length and a dimensionless number (C). WHY? q = - (characteristic length^2/ [C*μ]) * (dp/dl + ρ*g*dz/dl) = - (k/μ)*(dp/dl + ρ*g*dz/dl) = - (k ρ g/μ)*(dФ/dl) Fundamental Background for the1-D Darcy’s Law

  8. Effect of turbulence q = - (k/μ)*(dp/dl + ρ*g*dz/dl) QUESTION: When can the linearity maintain or when cannot? (1) F/(n*dA*dl) = (μ/k)*q + ρ*q^2/([k/C]^0.5) = - (dФ/dl) (The Forchheimer’s equation) (q^2 is the inertial forces) (2) -([k/C]^0.5/[ρ*q^2])*(dФ/dl) = μ/(ρ*q*([k*C]^0.5) + 1 (3) f = 1/Re + 1 (f=the friction factor) when Re < 0.02 [<0.1], Darcy’s law is extremely exact [probably acceptable]

  9. Effects of change in fluid density • q = - (k/μ)*(dp/dl + ρ*g*dz/dl) (Eq.3.10) • A rather general form of Darcy’s Law which applies for fluids with either constant or variable density contained in porous media whose intrinsic permeability may depend upon both direction and location. • Density of water is fairly constant. Therefore, the Eq.3.10 can be rewritten into the following equation. • q = - (k*ρ*g/μ)*d(p/ρ*g + z)/dl = - (k ρ g/μ)*(dh/dl) (Eq.3.15). • Here (p/ρ*g + z) is a scalar force potential or piezometric head (h).

  10. 3-D Differential Form of Darcy’s Equation • q = - (k ρ g/μ) * ∇h (Eq.3.17) • ∇ = ∂/∂x * i + ∂/∂y * j + ∂/∂z * k (the gradient operator) • i, j, and k are the unit vectors in the x, y, and z coordinate directions, respectively. • Piezometric head is a scalar. Its negative gradient is a vector representing the force per unit weight acting on the fluid. (force potential) • q = - (k ρ g/μ) * ∇h = -K * ∇h (Eq.3.20) • Barotropic fluids (ρ = function of p). However, constant density of water in most of groundwater is a good assumption. Of course, there are often exceptions. • Suppose K is constant (homogeneous). Then it is permissible to define Ф = K*h • q = -∇ Ф (Eq.3.21)

  11. Laboratory Determination of K • The Fair-Hatch formula Eq.3-25 at p.81. • k = 1/{A*[(1-n)^2/n^3]*[(B/100)* ∑(F/dm)]^2} • n:porosity • A: a dimensionless packing factor (~5) • B: a particle shape factor (ex. 6 for spherical particles and 7.7 for highly angular ones) • F: the percent by weight of the sample between two arbitrary particle sizes • dm:the geometric mean of the particle sizes corresponding to F. • Harleman et al.’ formula: k = (6.54 x 0.0001) * d^2 • d:characteristic grain size • The formula is nearly valid for materials of very uniform particle size and shape.

  12. Carman-Kozeny Equation • k = Co * [n3/(1-n)2] * (1/SS2) n: porosity SS: specific surface area or empirically, • k = [n3/(1-n)2] * (dM2/180) dM: grain size for 50 percentile

  13. Reading assignments Please read Darcy’s Law and the Equations of Groundwater Motion, p.65-82 including Example 3-1 Example 3-2 Example 3-3 Example 3-4 Example 3-5 Example 3-6 Example 3-7

  14. Non-Homogeneity Homogeneous: K is a scalar Heterotrophic: K is a function of positions at x, y, and z. See p. 84-87 K-a/K-b = tan (α-a) / tan (α-b) q-a α-a ∇ dl K-a ∇ q-b α-b K-b

  15. Anisotropy -∇h q-x q q-y

  16. Reading assignments • Please read Darcy’s Law and the Equations of Groundwater Motion, p.82-90 including • Flow parallel to the layers in a stratified aquifer • Flow through beds in series • Figure 3-12 and Eq.3.39 to 3.44 • See p. 70-71 in the reading material

  17. 3D Generalization of Darcy’s Law Heterotrophic Isotropic: q = - K (x,y,z) ∇ h For homogenous case, can rewrite as q = ~ ~ ∇ Φ - ∇ [K * h] = - ~ ~ ~ Anisotropic: q = - K ∇h ~ = ~ Kxx Kxy Kxz Kyx Kyy Kyz Kzx Kzy Kzz K = =

  18. General form of Darcy’s law Valid for multi-dimensions, all Newtonian fluids – incompressible or compressible.

  19. Flow in Aquifer Qz+dz A Differential Mass Balance Qy △Z Qx Qx+dx △X △Y (x,y,z) Qy+dy Qz

  20. Reading assignments • Please read p.58-63 in the reading material • Governing Equation for Confined Aquifers • Governing Equation for Unconfined Aquifers • Governing Equation for Aquitards • The Duipuit-Forchheimer Approximation • The Boussinesq Equation • Also read p. 72

  21. GW Flow Eq: Confined aquifer with leakage qz-t Assumptions: Horizontal flow Constant width into paper, W (a fixed y-value) Aquifer thinkness at a point: B(X) B(X) Z ΔX X qz-b

  22. GW Flow Eq: Confined aquifer with leakage ФA K’: hydraulic conductivity for aquitard b’: thickness of aquitard Aquitard K: hydraulic conductivity for aquifer b: the thickness of aquifer A Impermeable rock x Assumptions: Homogeneous formation Steady-state Constant thickness Φ = ΦA at left boundary, Φ = Φo in overlying formation Semi-infinite system

More Related