Presentation is loading. Please wait.

Presentation is loading. Please wait.

Analytical and Numerical Solutions are affected by: Differences in conceptual model (confined vs unconfined) Dimensionality (1D vs 2D) Numerical Solutions.

Published by Modified over 8 years ago

Similar presentations

Presentation on theme: "Analytical and Numerical Solutions are affected by: Differences in conceptual model (confined vs unconfined) Dimensionality (1D vs 2D) Numerical Solutions."— Presentation transcript:

1 Analytical and Numerical Solutions are affected by: Differences in conceptual model (confined vs unconfined) Dimensionality (1D vs 2D) Numerical Solutions also affected by: Grid Spacing (4000 ft vs 1000 ft) Island Recharge Problem

2 Well Bottom 4 rows

3 R  x  y yy xx b Recharge goes in over an area (  x  y) and comes out through an area (b  y) or rate out is R  x / b. 1D flow

4 R  x  y yy xx b Recharge goes in over an area (  x  y) and comes out through an area (b  y). 1D flow 2D flow Recharge goes in over an area (  y  x) and comes out through areas (b  y) and (b  x) or through a total area of b(  x+  y). yy xx R  x  y

5 unconfined h(x) = R (L 2 – x 2 ) / 2T “confined” h (x) =  [R (L 2 - x 2 )/K] + (h L ) 2 h = h o at x = 0h o = R L 2 / 2T at x = 0; h = b + h o R = 2 Kb h o / L 2 R = (2 Kb h o / L 2 ) + (h o 2 K / L 2 ) h L = b  (b + h o ) 2 = [R L 2 /K] + b 2 &  To maintain the same head (h o ) at the groundwater divide as in the confined system, the 1D unconfined system requires that recharge rate, R, be augmented by the term shown in blue. b L 0 Manipulating analytical solutions

6 Well Bottom 4 rows -R = Q well / {(  x  y)/4} = Q well / (a 2 /4) = 4 Q well / a 2 Pumping treated as a diffuse sink.

7 R  x  y Q Distributed source (L 3 /T) Point source (L 3 /T) yy xx Finite difference models simulate all sources/sinks as distributed sources/sinks; finite element models simulate all sources/sinks as point sources/sinks.

8 r = a rere Using the Thiem eqn., we find that r e = 0.208a Use eqn. 5.1 or 5.7 in A&W to correct the head at sink nodes. Sink node (i, j) (i+1, j) r e is the radial distance from the node where head is equal to the average head in the cell, h i,j h i,j is the average head in the cell.

9 (Gauss-Seidel Formula for Laplace Equation) SOR Formula Relaxation factor = 1 Gauss-Seidel < 1 under-relaxation >1 over-relaxation SOR where, for example,

10 SOR solution for confined Island Recharge Problem The Gauss-Seidel formula for the confined Poisson equation where

11 Inflow = Outflow +  S Recharge Discharge Transient Water Balance Eqn.

12 General governing equation for transient, heterogeneous, and anisotropic conditions Specific Storage S s =  V / (  x  y  z  h)

13 Figures taken from Hornberger et al. (1998) Unconfined aquifer Specific yield Confined aquifer Storativity S = V / A  h S = S s b b hh hh

14 Law of Mass Balance + Darcy’s Law = Governing Equation for Groundwater Flow --------------------------------------------------------------- div q = - S s (  h  t) (Law of Mass Balance) q = - K grad h (Darcy’s Law) div (K grad h) = S s (  h  t) (S s = S /  z)

15 Figures in slide 13 are taken from: Hornberger et al., 1998. Elements of Physical Hydrology, The Johns Hopkins Press, Baltimore, 302 p.

Download ppt "Analytical and Numerical Solutions are affected by: Differences in conceptual model (confined vs unconfined) Dimensionality (1D vs 2D) Numerical Solutions."

Similar presentations

Groundwater Flow Equations

Groundwater Flow Equations
Groundwater Modeling - 1

Groundwater Modeling - 1
Yhd Soil and Groundwater Hydrology

Yhd Soil and Groundwater Hydrology
ESS 454 Hydrogeology Module 4 Flow to Wells Preliminaries, Radial Flow and Well Function Non-dimensional Variables, Theis “Type” curve, and Cooper-Jacob.

ESS 454 Hydrogeology Module 4 Flow to Wells Preliminaries, Radial Flow and Well Function Non-dimensional Variables, Theis “Type” curve, and Cooper-Jacob.
Boundaries and Superposition

Boundaries and Superposition
Midterm Review. Calculus Derivative relationships d(sin x)/dx = cos x d(cos x)/dx = -sin x.

Midterm Review. Calculus Derivative relationships d(sin x)/dx = cos x d(cos x)/dx = -sin x.
Ground-Water Flow and Solute Transport for the PHAST Simulator Ken Kipp and David Parkhurst.

Ground-Water Flow and Solute Transport for the PHAST Simulator Ken Kipp and David Parkhurst.
Continuum Equation and Basic Equation of Water Flow in Soils January 28, 2002.

Continuum Equation and Basic Equation of Water Flow in Soils January 28, 2002.
(e.g., the Toth Problem) z x z x h = c x + z o Profile Models.

(e.g., the Toth Problem) z x z x h = c x + z o Profile Models.
General governing equation for transient, heterogeneous, and anisotropic conditions Specific Storage S s =  V / (  x  y  z  h)

General governing equation for transient, heterogeneous, and anisotropic conditions Specific Storage S s =  V / (  x  y  z  h)
Lecture 7 & 8 Refraction of q Equivalent K for fractured media.

Lecture 7 & 8 Refraction of q Equivalent K for fractured media.
K = K xx K xy K xz K yx K yy K yz K zx K zy K zz K xx, K yy, K zz are the principal components of K K is a tensor with 9 components.

K = K xx K xy K xz K yx K yy K yz K zx K zy K zz K xx, K yy, K zz are the principal components of K K is a tensor with 9 components.
1D, transient, homogeneous, isotropic, confined, no sink/source term Explicit solution Implicit solution Governing Eqn. for Reservoir Problem.

1D, transient, homogeneous, isotropic, confined, no sink/source term Explicit solution Implicit solution Governing Eqn. for Reservoir Problem.
Source Terms Constant Concentration Injection Well Recharge May be introduced at the boundary or in the interior of the model.

Source Terms Constant Concentration Injection Well Recharge May be introduced at the boundary or in the interior of the model.
Subsurface Hydrology Unsaturated Zone Hydrology Groundwater Hydrology (Hydrogeology )

Subsurface Hydrology Unsaturated Zone Hydrology Groundwater Hydrology (Hydrogeology )
Today’s Lecture: Grid design/boundary conditions and parameter selection. Thursday’s Lecture: Uncertainty analysis and Model Validation.

Today’s Lecture: Grid design/boundary conditions and parameter selection. Thursday’s Lecture: Uncertainty analysis and Model Validation.
X y ocean 2L L Island Recharge Problem ocean well R= 0.00305 ft/d T= 10,000 ft 2 /day.

X y ocean 2L L Island Recharge Problem ocean well R= ft/d T= 10,000 ft 2 /day.
Conceptual Model A descriptive representation of a groundwater system that incorporates an interpretation of the geological & hydrological conditions.

Conceptual Model A descriptive representation of a groundwater system that incorporates an interpretation of the geological & hydrological conditions.
A set of equations that describes the physical and/or chemical processes occurring in a system. Mathematical Model.

A set of equations that describes the physical and/or chemical processes occurring in a system. Mathematical Model.
Theory of Groundwater Flow

Theory of Groundwater Flow

Similar presentations

Ads by Google