MODFLOW – Introduction Organization & Main Packages

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Presentation transcript:

MODFLOW – Introduction Organization & Main Packages CE EN 547 – BRIGHAM YOUNG UNIVERSITY MODFLOW – Introduction Organization & Main Packages

Developed by McDonald & Harbaugh of the USGS, 1983 Public Domain Most widely used groundwater model Steady state or transient saturated flow Latest version is MODFLOW 2005 GMS uses MODFLOW 2000 version

Finite Difference Model 3D Cartesian Grid Cell-Centered

Grid Geometry Orthogonal in xy Thickness varies in z

Governing Equation where: Kxx, Kyy, Kzz = values of hyd. cond. along xyz axes h = total head W = Sources and sinks Ss = Specific storage t = time

Processes & Packages MODFLOW is divided into a series of processes & packages. Major tasks are organized as processes More specific tasks are performed by packages Each process may use one or more packages

Global Process Spatial discretization Temporal discretization Units # rows, cols, layers Top/bottom elevations Temporal discretization Stress periods Time steps Units Package Selection There is a layer discretization file and a global package file that are used by the Global Process.

Ground Water Flow Process Formulation and solution of the ground water flow equation by the FD method Main part of MODFLOW code Includes Flow package (BCF, LPF, or HUF) Source/sink packages Solvers

Other Processes Observation Process SEN Process PES Process Observed heads and flows Used for calibration SEN Process Sensitivity analysis Calibration PES Process Automated parameter estimation (calibration)

Packages Required Packages Array-Based Stress Packages Basic Global Output Control Flow Package (BCF, LPF, HUF) Solver (SIP, SSOR, PCG, GMG, etc.) List-Based Stress Packages River Stream-Aquifer Interaction Drain General Head Well Lake Changing Head Boundary Array-Based Stress Packages Recharge Evapotranspiration Other Horizontal Flow Barrier

Basic Package Starting Heads Array IBOUND Array Provides initial set of heads for iterative solver. Defines head values at specified head cells IBOUND Array Array of integers Three possible values zero = inactive negative = specified head positive = variable head http://va.water.usgs.gov/online_pubs/WRIR/98-4085/g-wfmcpasys_va.html

Active/Inactive Zones Cells outside problem domain are marked as inactive

Virginia Coastal Plain Model http://va.water.usgs.gov/online_pubs/WRIR/98-4085/g-wfmcpasys_va.html

Flow Packages Three options One of the three packages must be used Block-Centered Flow (BCF) Layer Property Flow (LPF) Hydrogeologic Unit Flow (HUF) One of the three packages must be used

BCF Package Original flow package Each layer is assigned a layer type Layer data are entered (depending on type) Horizontal K Bottom elevation Transmissivity Leakance etc.

Layer Property Flow (LPF) Package User enters Kh, Kv and storage terms for all layers, regardless of type Kv can be entered as directly or in terms of vertical anisotropy Horizontal anisotropy entered on a cell-by-cell basis Two layer types Confined Convertible

LPF Property Input Two options for inputting hydraulic properties: Array input one value per cell Material id approach Each cell is assigned a material id Properties are inherited from material

Hydrogeologic Unit Flow (HUF) Package Aquifer stratigraphy represented in a grid-independent fashion Equivalent Kh, Kv computed at runtime

HUF Arrays Top Thick 1 Thick 2 Thick 3 Thick 4 HUF data defined by a top array and multiple thickness arrays. In some cases, most entries in the thickness arrays are zero. Thick 4

Well Package Assigned to individual cells Q can be steady state or transient Extraction well (neg Q) Injection well (pos Q)

Drain Package Assigned to individual cells Used to simulate Agricultural drains Springs Creek beds Required parameters Elevation Conductance

Drains Hijk CD When the head is above the drain elevation: Delev When the head is above the drain elevation: Q = CD (Hijk - Delev) or Q = CD (Delev - Hijk) for proper sign on Q

Drains CD Delev Hijk When the head is below the drain elevation: Q = 0

Conductance Darcy’s Law: where q = flow rate k = hydraulic conductivity Dh = head difference L = flow length A = gross cross-sectional area

Conductance, Cont. Darcy’s law can be rewritten as: where The appropriate values for k, A, and L must be determined on a case-by-case basis

Recharge Package One value assigned to each vertical column Represents recharge due to precipitation Can be steady state or transient Infiltration rate must be assigned in correct units [L/T]

Factors Affecting Recharge Rate Rainfall Runoff Slope Soil type Land use Evapotranspiration Vegetation