WEAP Demand Management Overview
A Simple System
An Infrastructure Constraint
A Regulatory Constraint
Different Priorities
Different Priorities For example, the demands of large farmers (70 units) might be Priority 1 in one scenario while the demands of smallholders (40 units) may be Priority 1 in another. We will touch upon this further in the “Refining Supply” tutorial module
Different Preferences
Different Preferences For example, a center pivot operator may prefer to take water from a tributary because of lower pumping costs.
How much water will the site with 70 units of demand receive? Example How much water will the site with 70 units of demand receive?
Example How much water will be flowing in the reach between the Priority 2 diversion and the Priority 1 Return Flow?
What could we do in order to insure that this reach does not go dry? Example What could we do in order to insure that this reach does not go dry?
WEAP Hydrology Module-2 Bucket Method Overview
What could we do in order to insure that this reach does not go dry? Example What could we do in order to insure that this reach does not go dry?
What are we assuming?
What are we assuming? That we know how much water is flowing at the top of each river.
What are we assuming? That we know how much water is flowing at the top of each river. That no water is naturally flowing into or out of the river as it moves downstream.
What are we assuming? That we know how much water is flowing at the top of each river. That no water is naturally flowing into or out of the river as it moves downstream. That we know what the water demands are with certainty.
What are we assuming? That we know how much water is flowing at the top of each river. That no water is naturally flowing into or out of the river as it moves downstream. That we know what the water demands are with certainty. Basicly, that this system has been removed from it HYDROLOGIC context.
What do we do now?
ADD HYDROLOGY!
Types of Models A Context for the WEAP approach… Hydrology, Rainfall/Runoff Models Hydraulic, Biophysical Process Models Planning, Water Resource Systems Models
Hydrology Model
Hydrology Model Critical questions: How does rainfall on a catchment translate into flow in a river?
Hydrology Model Critical questions: What pathways does water follow as it moves through a catchment?
Hydrology Model Critical questions: How does movement along these pathways impact the magnitude, timing, duration and frequency of river flows?
Hydraulic Model
Hydraulic Model Critical questions: How will the velocity, depth and horizontal extent of water flowing in a river channel, and the associated services provided by the river, change if flows are adjusted or the channel is modified?
Hydraulic Model Critical questions: How fast, how deep and what is the horizontal extent of water flowing in a particular section of river?
Hydraulic Model Critical questions: What is the interaction between the velocity, depth and horizontal extent of water flowing in a river and important services provided by the river (e.g. fish habitat, sediment transport, etc.)?
Planning Model
Planning Model Critical questions: How should water be allocated to various uses in time of shortage?
Planning Model Critical questions: How should infrastructure in the system (e.g. dams, diversion works, etc) be operated to achieve maximum benefit?
Planning Model Critical questions: How can these operations be constrained to protect the services provided by the river?
Planning Model Critical questions: How will allocation, operations and operating constraints change if new management strategies are introduced into the system?
The WEAP Hydrology Molude provides a framework for answering these sets of questions.
The WEAP 2-Bucket Hydrology Module (Handout) Smax Rd z 1(%) Interflow = f( 1 ,k s , 1 - f ) Percolation = , Baseflow = 2 ,drainage_rate Et= f( k c ? PET P e = f(P, Snow Accum, Melt rate) Plant Canopy 2(%) L u Surface Runoff = f(Pe,z1,1/LAI) Irrigation Rootzone Water Capacity (mm) Deep Water Capacity (mm)
One 2-Bucket Model Per Land Class
WEAP Hydrology
Some Comments The number of parameters in the model are fairly limited and are at least related to biophysical characteristics of the catchment. The irrigation routine includes an implicit notion of irrigation efficiency.
Groundwater representation Seepage can only pass from the lower bucket to the river, not the other way Groundwater representation
Some Comments The geometry of the aquifers in question are representative, not absolute. Stream stage fluctuations are assumed to represent average conditions. While the ‘water table’ can fluctuate, it ignores all local fluctuations.
Hydrology Data Input: Building Expressions Time series wizard Expression Builder-Similar to EXCEL Demand projections can be made through users establishing their own expressions. WEAP provides a number of ways of editing expressions. The most common are: x Typing directly into the expression field in one of the data entry table's in WEAP's Data View. x Selecting one of the most commonly used functions (Interpolation, Growth, Remainder) using the pop-up selection box attached to each expression field. x Using the Yearly Time-Series Wizard: a tool for easily entering time-series functions (Interpolation, Step, and Smooth Curve functions) x Using the Expression Builder tool: a tool for creating expressions by dragging-and-dropping functions and WEAP variables.
Hydrology Data Input: Water-Year Method Demand projections can be made through users establishing their own expressions. WEAP provides a number of ways of editing expressions. The most common are: x Typing directly into the expression field in one of the data entry table's in WEAP's Data View. x Selecting one of the most commonly used functions (Interpolation, Growth, Remainder) using the pop-up selection box attached to each expression field. x Using the Yearly Time-Series Wizard: a tool for easily entering time-series functions (Interpolation, Step, and Smooth Curve functions) x Using the Expression Builder tool: a tool for creating expressions by dragging-and-dropping functions and WEAP variables. Describe a series of water year types from very dry to very wet Enter the water year sequence
Hydrology Data Input: Read from File Historical or synthetic data Import from ASCII files Demand projections can be made through users establishing their own expressions. WEAP provides a number of ways of editing expressions. The most common are: x Typing directly into the expression field in one of the data entry table's in WEAP's Data View. x Selecting one of the most commonly used functions (Interpolation, Growth, Remainder) using the pop-up selection box attached to each expression field. x Using the Yearly Time-Series Wizard: a tool for easily entering time-series functions (Interpolation, Step, and Smooth Curve functions) x Using the Expression Builder tool: a tool for creating expressions by dragging-and-dropping functions and WEAP variables.
Conclusions Hydrology The hydrology module is a powerful tool for considering changing catchment dynamics. Hydrology is essential for conducting rigorous analysis of climate change impacts. Hydrology could be very interesting for livelihoods analysis because it considers several resources in a catchment, rainfed and irrigated agriculture, forest and range management, fish appropriate flows. The critical question is whether it is as simple as possible, and no simpler.
Hydrology Tutorial Updates (Pg. 175) Replaces Figure on Pg. 175 of tutorial
Hydrology Tutorial Additional Figure Flow to River Full Irrigation, Exhibiting rather constant soil moisture in first bucket throughout the year (at 45-50%)
Hydrology Tutorial Updates (Pg. 180) Replaces Figured on Pg. 180 of tutorial
Hydrology Tutorial Updates (Pg. 181) Replaces Figured on Pg. 181 of tutorial