Presentation is loading. Please wait.

Presentation is loading. Please wait.

X y ocean 2L L Island Recharge Problem ocean well R= 0.00305 ft/d T= 10,000 ft 2 /day.

Published by Modified over 9 years ago

Similar presentations

Presentation on theme: "X y ocean 2L L Island Recharge Problem ocean well R= 0.00305 ft/d T= 10,000 ft 2 /day."— Presentation transcript:

1 x y ocean 2L L Island Recharge Problem ocean well R= 0.00305 ft/d T= 10,000 ft 2 /day

2 ocean R x = 0x = Lx = - L 1D approximation used by C.E. Jacob h(L) = 0 at x =0

3 h(x) = R (L 2 – x 2 ) / 2T Analytical solution for 1D “confined” version of the problem C.E. Jacob’s Model h(L) = 0 at x =0 Governing Eqn. Boundary conditions R = (2 T) h(x) / ( L 2 – x 2 ) Forward solution Inverse solution for R

4 R = (2 T) h(x) / ( L 2 – x 2 ) Inverse solution for R Solve for R with h(x) = h(0) = 20 ft. Re-arrange eqn to solve for T, given value for R and h(0) = 20 ft. Inverse solution for T L You will find that R  0.00305 ft/d

5 Head measured in an observation well is known as a target. Targets used in Model Calibration The simulated head at the node representing the observation well is compared with the measured head. During model calibration, parameter values (e.g., R and T) are adjusted until the simulated head matches the observed value. Model calibration solves the inverse problem.

6 x y ocean Solve the forward problem: R= 0.00305 ft/d T= 10,000 ft 2 /day 2L L = 12,000 ft Island Recharge Problem ocean well

7 Water Balance IN = Out IN = R x AREA Out = outflow to the ocean

8 Top 4 rows Red dots represent specified head cells, which are treated as inactive nodes. Note that the well node (not shown in this figure) is an active node. Head at a node is the average head in the area surrounding the node.

9 Top 4 rows IN =R x Area = R (L-  x/2) (2L -  y/2) 2L L Also: IN = R (2.5)(5.5)(a 2 )

10  x/2 Top 4 rows OUT =  Qy +  Qx Qy = K (  x b) (  h/  y) or Qy = T  h Qx = K (  y b)(  h/  x) or Qx = T  h Qx Qy

11 Well  y/2 Bottom 4 rows

12

13 b h ocean groundwater divide R x = 0x = Lx = - L datum Unconfined version of the Island Recharge Problem Let b = 100 ft & K = 100 ft/d so that at x=L, Kb= 10,000 ft 2 /day

14 Let v = h 2

Download ppt "X y ocean 2L L Island Recharge Problem ocean well R= 0.00305 ft/d T= 10,000 ft 2 /day."

Similar presentations

Simulation of groundwater response to development: CENTRAL PASSAIC RIVER BASIN, NJ Fatoumata Barry 1,2, Duke Ophori 1, Jeffrey L. Hoffman 2 and Robert.

Simulation of groundwater response to development: CENTRAL PASSAIC RIVER BASIN, NJ Fatoumata Barry 1,2, Duke Ophori 1, Jeffrey L. Hoffman 2 and Robert.
Groundwater Modeling - 1

Groundwater Modeling - 1
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.
Groundwater Modeling Conversion to Transient Particle Tracking.

Groundwater Modeling Conversion to Transient Particle Tracking.
(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.
Final Project I. Calibration II.Drawdown Prediction III.Particle Tracking IV.Presentation of Results.

Final Project I. Calibration II.Drawdown Prediction III.Particle Tracking IV.Presentation of Results.
3D Simulations-- the vertical dimension. Representation of hydrogeologic units in MODFLOW88.

3D Simulations-- the vertical dimension. Representation of hydrogeologic units in MODFLOW88.
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)
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 )
Final Project From USGS Hydrologic Atlas online.

Final Project From USGS Hydrologic Atlas online.
Analytical and Numerical Solutions are affected by: Differences in conceptual model (confined vs unconfined) Dimensionality (1D vs 2D) Numerical Solutions.

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

Theory of Groundwater Flow
Island Recharge Problem

Island Recharge Problem
Subsurface Hydrology Unsaturated Zone Hydrology Groundwater Hydrology (Hydrogeology )

Subsurface Hydrology Unsaturated Zone Hydrology Groundwater Hydrology (Hydrogeology )

Similar presentations

Ads by Google