Post on 22-May-2020
Decision SupportDecision Support Simulation for a Water
Basin
Purpose of DSSp
Based on systems modelingBased on systems modelingIncorporates all major processes within a
tsystemDemonstrates effects of seemingly isolated d i i th ti tdecisions on the entire systemMay show surprising or unanticipated results f t tiof management options
DSS in Education
Gives students a hands on tool to learn aboutGives students a hands-on tool to learn about water resourcesT h h i d i t l t dTeaches comprehensive and inter-related concepts while keeping complicated modeling hiddenmodeling hiddenAllows students to identify effective management strategies and developmanagement strategies and develop compromise plans
Typical DSS Elementsyp
Reservoir/LevelFlow Rate
Auxiliary VariableConstant Variable
ConnectorThis is the data that can bethat can be altered on user interfaces
Example of User InterfaceExample of User Interface
Water Basin DSS
Regional System approximately size of TucsonRegional System approximately size of TucsonLimited water supplyMultiple demand sectorsMultiple demand sectorsPopulation growth over 25 year simulationPresents various ways to make supply meetPresents various ways to make supply meet demandAllows observation of multiple options in a short timep pProvides opportunity for cost-benefit analysis
SupplyGroundwater
18.5 million acre-ft Imported Water
aquiferRenewable supply
Surface WaterAverage streamflow of 200 cfs
Tribal WaterMay be purchased
www.cap-az.com
200 cfsMinimum downstream flow
Reclaimed WaterCan only be used for certain demand
Reservoircertain demand
www.wwm.pima.gov
Demand
Residential TurfResidentialIndoor and Outdoor
Private golf coursesPublic golf courses and parks
AgricultureAlfalfa, Lettuce, Cotton,
parksSchools
Wheat
E i l
Industrial
EnvironmentalIn-stream flow requirementsrequirements
General Water System
INDUSTRIAL
RESERVOIR
Wastewater
INDUSTRIAL
Import/Tribal WATER
SUPPLYAGRICULTURE/
TURFtreatment plantSUPPLY
GWRESIDENTIAL
ENVIRONMENTAL/RECREATIONAL AREA
RIVER
Supply SubmodelsSupply Submodels
Residential SubmodelsResidential Submodels
front loader gal peruse% households w
frontloader
last year
h t Showerclotheswasher use
Households
use per day
current year
new houses topurchase
frontloaders
Shower per Day
Potential ShowerSavings
Shower
reg gallons per use
Shower Pre 89
p y
persons-house
Clotheswasher
Shower Low Flow
Shower Time
Shower Use
Households 1989
Households
Submodel Interface
Goals and Objectivesj
Today: Understand ConceptsToday: Understand ConceptsDemand by sectorConsumptive useConsumptive useReclaimed waterSurface Groundwater InteractionsSurface – Groundwater InteractionsEffects of population growthConservation optionsConservation optionsEnvironmental effects
Goals and Objectivesj
Next time: The Big PictureNext time: The Big PictureDifferent management alternatives and their effects on the systemeffects on the systemCombine and negotiate options to create the best possible outcomepEnhanced supply and treatment options
Big Pictureg
Day 1&2 – Explore basic model options:
Introductory Questions:
Day 3 – Try to simulate your city
D 4 C fli tQuestions:- Turf- Residential- PopulationA i lt
CustomizationChallenges
Day 4 – Conflict resolution exercise –role play with major water user stakeholders
- Agriculture- Water Budget
Control Case
Control case studies – Water supply- Climate variability
FarmerDeveloperCity Manager
Studies – if timeCity ManagerConservationist
Goal: Satisfy everyone's y ywater needs
Important Conceptsp p
Consumptive Use:Consumptive Use:Water that is not returned to the system through recharge or the WWTPrecharge or the WWTP=Total Demand – Recharge – Return to WWTPGenerally indoor use is non-consumptive andGenerally indoor use is non consumptive and outdoor use (irrigation) is highly consumptive.
Conservation Options:Conservation Options:Fixture retrofits, frontloaders, drip irrigation, rainwater harvesting
Streamflow ProcessesUpstream and Downstream Reach refer to location Upstream is streamflow before it gets to the city Downstream is streamflowstreamflow before it gets to the city. Downstream is streamflow in the river after the city has taken water from it and released effluent to it.Losing and Gaining Reach refer to relationship with the aquifer. os g a d Ga g eac e e to e at o s p t t e aqu eLosing streams are above the water table, so they lose water to the aquifer (instream recharge). Gaining streams are below the water table, so they gain water from the aquifer.
Losing ReachGaining Reach
Model Terms
Initial year means before pushing play andInitial year means before pushing play and final year means after pushing play.Default values are those present when theDefault values are those present when the simulation is reset, or before you change anything.New water is any water that is not reclaimed water.Safe Yield: net Extraction < net RechargeThis is the goal of Arizona’s AMA’s
Introduction to Powersim
InstructionsTo navigate, use the arrows, Home button, or hyperlinkshyperlinks. You can change inputs by using the slider bars or typing values in the boxes below the bars. On the
t l i l li k th di b ttcontrol pages, you simply click the radio buttons or enter inputs.You may find it useful to change variables without y grunning the simulation to see direct initial year differences between the results from default values and from the changed values.and from the changed values. The play button runs the simulation, the play/pause button progresses one year with each click, and the rewind button resets the simulation to the initial yearrewind button resets the simulation to the initial year. Each time you reset the simulation, the values return to default.
Inputs and Outputsp p
Basic input pages include Agriculture TurfBasic input pages include Agriculture, Turf, Residential, and Population. Outputs are found on each input page as wellOutputs are found on each input page as well as the main result page, the Water Budget.Advanced input pages are found within theAdvanced input pages are found within the Controls.Additional results can be found on Supply pp yCosts, Riparian Area, Environmental Economics.
Interpreting Resultsp g
This model displays results both numerically andThis model displays results both numerically and graphically. One way to see results is to look at a numerical value with the default inputs and compare it to the value with your inputs.However sometimes the most important results areHowever, sometimes the most important results are best explained through graphs.Each input page has two graphs on it; Streamflow and Aquifer Volume. There are also a few other graphs throughout the model. The following page shows you how to read some of these graphs.y g p
Reading GraphsDownstream flow will generally be lower than upstream flow, because the region removes water from the stream for use, and only a portion is returned from the WWTP and some water also recharges to the aquifer. If upstream Reading Graphsflow falls below downstream flow, this means that the reach has become ‘losing.’ A good goal is to maintain a healthy downstream flow.
The aquifer volume will decline throughout thethroughout the simulation in response to overdraft (extraction that exceeds totalexceeds total recharge). A good goal is to try to keep it level.
Trends
This graph shows demand trends influenced primarily p yby the population growth rate. Observe the slope of these trends, and compare it to th l f ll ithe slopes following a change in the growth rate. Generally the higher the growth rate the steeperrate, the steeper the trend, and thus the greater demand.
Safe Yield
An example of a region meeting g gsafe yield. Extraction does not exceed total recharge, also known as
blrenewable groundwater. The Aquifer Volume graph in this case would actually beactually be slowly rising.