Engineering Hydrology Course Overview and Great Salt Lake Evaporation Analysis

 
CEE 3430, Engineering Hydrology
David Tarboton
(Richard Peralta today)
 
Overview
 
Handouts
Syllabus
Schedule
Student Information Sheet
Homework 1
Outline for today
Review Syllabus and Schedule
Introduce the Hydrologic Cycle and Water Balance Concepts
 
Texts
 
Ground and Surface Water Hydrology, by
Mays, 2011 (Chapters 1-4 and 7-9)
Either full text or Custom book with just
these chapters
Full textbook ISBN 9780470169872
Custom book
Print version ISBN 9781119920403
(order through bookstore)
Electronic version ISBN
9781119920403 (order at
http://store.vitalsource.com/
)
 
HEC-HMS Manual (last part of class only)
http://www.hec.usace.army.mil/software
/hec-hms/documentation.aspx
 
Course Learning Objective
 
U
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Please indicate your level of
knowledge of
 
E
x
c
e
l
 
A – Never heard of
B – Know of but have not used
C – Used a little
D – Comfortable using
E - Expert
 
Please indicate your level of
knowledge of
 
M
A
T
L
A
B
 
A – Never heard of
B – Know of but have not used
C – Used a little
D – Comfortable using
E - Expert
 
 
 
 
Please indicate your level of
knowledge of
 
R
A – Never heard of
B – Know of but have not used
C – Used a little
D – Comfortable using
E - Expert
 
http://www.r-project.org/
 
Please indicate your level of
knowledge of
 
HEC-HMS
A – Never heard of
B – Know of but have not used
C – Used a little
D – Comfortable using
E - Expert
 
http://www.hec.usace.army.mil/software/hec-hms/
 
Please indicate your level of
knowledge of
 
CANVAS
A – Never heard of
B – Know of but have not used
C – Used a little
D – Comfortable using
E - Expert
 
https://online.usu.edu/
 
Great Salt Lake Evaporation
 
The Great Salt Lake has an average inflow from
streamflow of 2,316,220 acre ft / year
The area is about 1 million acres
Average annual precipitation on the lake is about 10
inches/year
It is a closed basin with no outflows other than
evaporation
Assuming the level is not changing what is the
average annual evaporation ?
 
Area, A
 
Level
 
Inflows I
 
E x A
 
Evaporation depth E
Evaporation volume  E x A
 
Assumed Great Salt Lake Volume Balance
 
Average inflow from streamflow = 2,316,220 acre ft/yr
Area = 1 million acres
Average annual precipitation on lake = 10 inches/yr
Total outflow = evaporation
Lake level is steady. What is the average annual Evaporation?
--------------
Ks lake level is steady, lake area and volume are unchanging.
Δvolume =0 = Inflows – Outflows
Inflows = Streamflow + Precipitation + Groundwater (small) +
Wastewater discharges (even smaller)
Volume = Depth x Area
Precipitation = 1 x 10
6
 (acres) x 10/12 (ft) = 8.33 x 10
5
 acre ft/yr
Inflow = 2.316 x 10
6
 acre ft/yr + 0.833 x 10
6
 acre ft/yr
               = 3.149 x 10
6
 acre ft/yr   =   Outflow = Evaporation
 
Alternative Evaporation Expression
 
How a closed basin (e.g. GSL works)
 
Level
 
Level
 
Inflows I
 
I
 
E x A
 
If I > E x A level rises
If I < E x A level falls
Level adjusts to fluctuating
inputs so that on average
I = E x A
 
I includes inflows from
streams and precipitation
on the lake
     I = Q + P x A
Subject to climate
variability.
 
E is less variable, but also
depends on climate and
salinity, C.
 
As C increases E decreases
 
Evaporation depth E
Evaporation volume  E x A
 
Volume, V
Salt Load L
Salt Concentration C=L/V
 
Predicting Effect of Management Change
 
More Effects of Management Change
 
A lower level has implications for
Brine shrimp
Bird habitat
Boating and other users
A more comprehensive analysis has to consider additional
factors
Climate variability and lake fluctuations
Salinity.  A lower lake has smaller volume, but the amount of salt is the
same (apart from what the mineral co. is taking), so the salinity is more.
This reduced evaporation
Evaporation ponds actually occupy part of the lake
The railway causeway splits the lake into two water bodies with different
levels
 
Concepts Discussed
 
Fundamental equation in hydrology - mass
balance (eqn 1.5.1)
Expressing quantities in units that are easier to
interpret, such as depth for evaporation rather
than volume
Equilibrium or steady-state assumption
 
 
 
Water Balance
 
Watershed delineated on a topographic map
 
Watershed water balance
 
P
 
E+T
 
Q
 
G
 
S
 
The Hydrologic Cycle
 
P
 
Runoff
 
Runoff
 
Evap
 
ET
 
Evap
 
Streams
 
Lake
 
Reservoir
 
GW
 
Atmospheric Moisture
 
Snow
 
melt
 
Figure 1-1 from Bedient: http://hydrology.rice.edu/bedient/
 
Hydrologic Science in the hierarchy from basic
sciences to water resources management
 
Basic Sciences
Mathematics
Statistics
Physics
Chemistry
Biology
Geosciences
Geology
Soil Science
Atmospheric
Science
Ocean Science
Glaciology
Geochemistry
 
Fluid Mechanics
Hydraulic
Engineering
Meteorology
Hydrologic
Science
 
Economics
Law
Sociology
Political
Science
Engineering
Hydrology
Agriculture
Forestry
 
Water
Resources
Management
 
Modified From: National Research Council Committee on Opportunities in
the Hydrologic Sciences (COHS), (1991), 
Opportunities in the Hydrologic
Sciences
, Editor, P. S. Eagleson, National Academy Press, Washington, D.C.
 
Summary
 
The engineering hydrologist must be able to calculate
or estimate various components of the hydrologic
cycle to solve hydrologic problems
Drainage design, flood protection, water supply
The concept of the water balance is fundamental to
much hydrologic analysis
Become comfortable converting units and working
with “incompatible” units, it is an unfortunate fact of
life
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Engineering Hydrology course led by David Tarboton covers principles of hydrology, water balance concepts, and hydrologic modeling. The analysis of Great Salt Lake evaporation explores factors such as inflow, area, and precipitation to determine the average annual evaporation rate.


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  1. CEE 3430, Engineering Hydrology David Tarboton (Richard Peralta today)

  2. Overview Handouts Syllabus Schedule Student Information Sheet Homework 1 Web: http://www.engineering.usu.edu/dtarb/cee3430 Outline for today Review Syllabus and Schedule Introduce the Hydrologic Cycle and Water Balance Concepts

  3. Texts Ground and Surface Water Hydrology, by Mays, 2011 (Chapters 1-4 and 7-9) Either full text or Custom book with just these chapters Full textbook ISBN 9780470169872 Custom book Print version ISBN 9781119920403 (order through bookstore) Electronic version ISBN 9781119920403 (order at http://store.vitalsource.com/) HEC-HMS Manual (last part of class only) http://www.hec.usace.army.mil/software /hec-hms/documentation.aspx

  4. Course Learning Objective Upon successful completion of the course you should be able to apply the principles of hydrology to solve engineering hydrology design problems involving hydrologic modeling and analysis.

  5. Great Salt Lake Evaporation The Great Salt Lake has an average inflow from streamflow of 2,316,220 acre ft / year The area is about 1 million acres Average annual precipitation on the lake is about 10 inches/year It is a closed basin with no outflows other than evaporation Assuming the level is not changing what is the average annual evaporation ?

  6. Evaporation depth E Evaporation volume E x A Inflows I E x A Level Area, A

  7. Assumed Great Salt Lake Volume Balance Average inflow from streamflow = 2,316,220 acre ft/yr Area = 1 million acres Average annual precipitation on lake = 10 inches/yr Total outflow = evaporation Lake level is steady. What is the average annual Evaporation? -------------- Ks lake level is steady, lake area and volume are unchanging. volume =0 = Inflows Outflows Inflows = Streamflow + Precipitation + Groundwater (small) + Wastewater discharges (even smaller) Volume = Depth x Area Precipitation = 1 x 106 (acres) x 10/12 (ft) = 8.33 x 105 acre ft/yr Inflow = 2.316 x 106 acre ft/yr + 0.833 x 106 acre ft/yr = 3.149 x 106 acre ft/yr = Outflow = Evaporation

  8. Alternative Evaporation Expression 3.149 x 106 acre ft/yr of evaporation is not an easy number to visualize. Express evaporation as a depth by dividing by area E A = Outflow =3.149 106 ???? ?? 106 ????? 37.8 ??? ?? ? =??????? = 3.149 ?? = ?

  9. How a closed basin (e.g. GSL works) If I > E x A level rises If I < E x A level falls Level adjusts to fluctuating inputs so that on average I = E x A Evaporation depth E Evaporation volume E x A Inflows I E x A I includes inflows from streams and precipitation on the lake I = Q + P x A Subject to climate variability. Level Area, A I E x A Level Area, A E is less variable, but also depends on climate and salinity, C. Volume, V Salt Load L Salt Concentration C=L/V As C increases E decreases

  10. Predicting Effect of Management Change Company proposes to expand mineral production by pumping 100,000 acre ft/yr into evaporation ponds. How affect lake? Volumetrically, pumping from lake is like decreasing inflow. Lake will shrink. How much will area decrease at equilibrium? New Evaporation volume = inflows minus loss due to pumping. New Evaporation volume = 3.149 x 106 0.1 x 106 acre ft/yr = 3.049 x 106 acre ft/yr Assume unchanged evaporation depth (mainly climate-related). At steady state, E A = Outflow , or =3.049 106 3.149 ?? ?? With A and the relationship between area and level {L=f(A), determinable from underwater topography (i.e. bathymetry) one can estimate the reduction in level}. When occur? ? =??????? ???? ?? ?? = 0.968 106 ????? ?

  11. More Effects of Management Change A lower level has implications for Brine shrimp Bird habitat Boating and other users A more comprehensive analysis has to consider additional factors Climate variability and lake fluctuations Salinity. A lower lake has smaller volume, but the amount of salt is the same (apart from what the mineral co. is taking), so the salinity is more. This reduced evaporation Evaporation ponds actually occupy part of the lake The railway causeway splits the lake into two water bodies with different levels

  12. Concepts Discussed Fundamental equation in hydrology - mass balance (eqn 1.5.1) Expressing quantities in units that are easier to interpret, such as depth for evaporation rather than volume Equilibrium or steady-state assumption

  13. Water Balance Atmospheric Water Soil Water Surface Water Groundwater Change of Storage dS Inflow Outflow = = I Q dt

  14. Watershed delineated on a topographic map

  15. Watershed water balance P = P Q G E T S E+T Q S G

  16. The Hydrologic Cycle Atmospheric Moisture 39 100 Moisture over land Precipitation on land 61 385 P Evaporation from land Precipitation on ocean Snow melt Runoff Evap ET Surface runoff Precipitation 424 Evap Evaporation from ocean Streams Infiltration Groundwater Recharge Runoff 38 Surface discharge Groundwater flow 1 Groundwater discharge GW Impervious Lake strata Reservoir Figure 1-1 from Bedient: http://hydrology.rice.edu/bedient/

  17. Hydrologic Science in the hierarchy from basic sciences to water resources management Basic Sciences Mathematics Statistics Physics Chemistry Biology Geosciences Geology Soil Science Atmospheric Science Ocean Science Glaciology Geochemistry Economics Law Sociology Political Science Engineering Hydrology Agriculture Forestry Fluid Mechanics Hydraulic Engineering Meteorology Hydrologic Science Water Resources Management Modified From: National Research Council Committee on Opportunities in the Hydrologic Sciences (COHS), (1991), Opportunities in the Hydrologic Sciences, Editor, P. S. Eagleson, National Academy Press, Washington, D.C.

  18. Summary The engineering hydrologist must be able to calculate or estimate various components of the hydrologic cycle to solve hydrologic problems Drainage design, flood protection, water supply The concept of the water balance is fundamental to much hydrologic analysis Become comfortable converting units and working with incompatible units, it is an unfortunate fact of life

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