multiple systems lid development - scdhec
TRANSCRIPT
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LID Development
Conservation Conservation Minimization Minimization Soil Management Soil Management Open Drainage Open Drainage Rain Gardens Rain Gardens Rain Barrels Rain Barrels Pollution Pollution Prevention Prevention
Disconnected Disconnected Decentralized Decentralized Distributed Distributed MultiMulti--functional functional
Multiple SystemsMultiple Systems
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McCuen, 1999
Natural Hydrologic Cycle
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RECHARGE
HYDROLOGIC CYCLE:P+R+E+T
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McCuen, 1999
Developed Hydrologic Cycle
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Wetlands Recharge
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Washington, DC - Reagan National
2001 Daily RainfallFrequency (inches)
90%
4%4% 2%
0.250.51> 1
Volume/Frequency
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How Does LID Maintain or Restore How Does LID Maintain or Restore The Hydrologic Regime?The Hydrologic Regime?
•• Creative ways to:Creative ways to:–– Maintain / Restore Storage Volume Maintain / Restore Storage Volume
•• interception, depression, channel interception, depression, channel –– Maintain / Restore Infiltration Volume Maintain / Restore Infiltration Volume –– Maintain / Restore Evaporation VolumeMaintain / Restore Evaporation Volume–– Maintain / Restore Runoff Volume Maintain / Restore Runoff Volume –– Maintain Flow PathsMaintain Flow Paths
• Engineer a site to mimic the natural water cycle functions / relationships
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Key LID PrinciplesKey LID Principles“Volume” “Volume” “Hydrology as the Organizing Principle ”“Hydrology as the Organizing Principle ”
• Unique Watershed Design– Match Initial Abstraction Volume– Mimic Water Balance
• Uniform Distribution of Small-scale Controls• Cumulative Impacts of Multiple Systems
– filter / detain / retain / use / recharge / evaporate • Decentralized / Disconnection• Multifunctional Multipurpose Landscaping & Architecture • Prevention
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Defining LID Technology Defining LID Technology Major Components 1. Conservation (Watershed and Site Level ) 2. Minimization (Site Level) 3. Strategic Timing (Watershed and Site Level) 4. Integrated Management Practices (Site Level)
Retain / Detain / Filter / Recharge / Use5. Pollution Prevention
Traditional Approaches
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LID Practices (No Limit!)LID Practices (No Limit!)
• Bioretention / Rain Gardens• Strategic Grading • Site Finger Printing• Resource Conservation • Flatter Wider Swales • Flatter Slopes• Long Flow Paths• Tree / Shrub Depression • Turf Depression• Landscape Island Storage • Rooftop Detention /Retention • Roof Leader Disconnection• Parking Lot / Street Storage • Smaller Culverts, Pipes & Inlets
• Alternative Surfaces• Reduce Impervious Surface• Surface Roughness Technology • Rain Barrels / Cisterns / Water Use• Catch Basins / Seepage Pits• Sidewalk Storage• Vegetative Swales, Buffers &
Strips • Infiltration Swales & Trenches• Eliminate Curb and Gutter• Shoulder Vegetation • Maximize Sheet flow • Maintain Drainage Patterns• Reforestation……………….. • Pollution Prevention…………..
“Creative Techniques to Treat,Use, Store, Retain, Detain and Rec“Creative Techniques to Treat,Use, Store, Retain, Detain and Recharge” harge”
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LID Hydrologic Analysis Dr. Mow-Soung Cheng
Compensate for the loss of rainfall abstractionInfiltration
EvapotranspirationSurface storageTime of travel
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LID Design Procedure Highlights
• Site Analysis• Determine Unique Design Storm• Maintain Flow Patterns and Tc• Conservation and Prevention• Develop LID CN• Compensatory Techniques. Stress
Volume Control then Detention or Hybrid for Peak
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Low-Impact Development Hydrologic Analysis and
Design
Low-Impact Development Hydrologic Analysis and
Design• Based on NRCS technology, can be
applied nationally• Analysis components use same
methods as NRCS• Designed to meet both storm water
quality and quantity requirements
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• TR-55 used as a basic design tool for local government use. COMMON PRACTICAL PLATFORM
• Still an ungaged and uncalibrated model!!• Other more sophisticated, data and time
intensive models exist for calibration/verification
• Continuous simulation recognized as the most rigorous
Other Models Acceptable!!!
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LID Manual
H and H Process
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Q
T
Developed Condition, Conventional CN(Higher Peak, More Volume, and Earlier Peak Time)
Existing Condition
Hydrograpgh Pre/ Post Development
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Q
T
Developed Condition, with Conventional CN and Controls
Existing
Additional Runoff Volume
Developed
Existing Peak Runoff Rate
Detention Peak Shaving
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Q
T
Developed Condition, with LID- CNno Controls.
Existing
Reduced Runoff Volume
Developed- No Controls
Reduced Qp
Minimize Change in Curve Number
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Q
T
Developed, LID- CN no controlssame Tc as existing condition.
Existing
More Runoff Volumethan the existing condition.
Developed,LID-CNno controls Reduced
Qp
Maintain Time of Concentration
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Q
T
Provide Retentionstorage so that the runoffvolume will be the same as Predevelopment
Retention storage needed to reducethe CN to the existing condition= A2 + A3
A3
A2
A1
Reducing Volume
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Q
T
Provide additional detention storage to reduce peak discharge to be equal to that of the existing condition.
Existing
Predevelopment Peak Discharge
Detention Storage
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Q
T
Comparison of Hydrographs
A2
A3
LID Concepts
Conventional Controls
Existing
Increased Volumew/ Conventional
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Q
T
2
3
4
1
5
6
7
Hydrograph Summary
2
3
4
1 Existing
Developed, conventional CN, no control.
Developed, conventional CN and control.
Developed, LID-CN, no control.
Developed, LID-CN, same Tc.
Developed, LID-CN, same Tc, same CN withretention.
Same as , with additional detention tomaintain Q.
6
5
6
7
Pre-developmentPeak Runoff Rate
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Comparison of Conventional and L I D Curve Numbers (CN)
for 1- Acre Residential Lots
Comparison of Conventional and L I D Curve Numbers (CN)
for 1- Acre Residential Lots
Conventional CN20 % Impervious80 % Grass
Low Impact Development CN15 % Impervious25 % Woods60 % Grass
Curve Number is reduced by using LID Land Uses.
DisconectivenessCNC=CNP+[PIMP] (98-CNP) (1-0.5R)
100CNC
C= Composit
CNP
= Pervious
R=Ratio Unconnected imp. to total imp
PIMP
= Percent of imp. site
Customize Curb Number to Maximize Land Cover and
Disconnectivity
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LI D to Maintain the Time of Concentration
“Uniformly Distributed Controls”
LI D to Maintain the Time of Concentration
“Uniformly Distributed Controls”
* Minimize Disturbance
* Flatten Grades
* Reduce Height of Slopes
* Increase Flow Path
* Increase Roughness “ n “
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Retention LID Storage Options
(On-Site)
Retention LID Storage Options
(On-Site)
* Infiltration* Retention* Roof Top Storage* Rain Barrels* Bioretention* Irrigation Pond
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8% BMP
Determining LID BMP Sizing
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Methods of Detaining Storage to Reduce Peak Runoff Rate
Methods of Detaining Storage to Reduce Peak Runoff Rate
* Larger Swales with less slope* Swales with check dams* Smaller or constricted drainage pipes* Rain barrels* Rooftop storage* Diversion structures
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Low Impact Development Objective
Flat
ten
Slop
e
Incr
ease
Flo
w P
ath
Incr
ease
She
et F
low
Incr
ease
Rou
ghne
ss
Min
imiz
e D
istu
rban
ce
Lar
ger
Swal
es
Flat
ten
Slop
es o
n Sw
ales
Infil
trat
ion
Swal
es
Veg
etat
ive
Filte
r St
rips
C
onst
rict
ed P
ipes
D
isco
nnec
ted
Impe
rvio
us A
reas
R
educ
e C
urb
and
Gut
ter
Rai
n B
arre
ls
Roo
ftop
Sto
rage
B
iore
tent
ion
Re-
Veg
etat
ion
Veg
etat
ion
Pre
serv
atio
n
Increase Time of Concentration X X X X X X X X X X X
Increase Detention Time X X X X
Increase Storage X X X X X X
Lower Post Development CN X X X X X
LID Techniques and ObjectivesLow-Impact Development Technique
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Maintain Time ofConcentration (Tc)Maintain Time of
Concentration (Tc)
Low Impact Developmentobjective to Maintain Time ofConcentration (Tc) B
alan
ce c
ut a
nd fi
ll on
lot.
Net
wor
k Sm
alle
r Sw
ales
Clu
ster
s of T
rees
and
Shru
bs in
Flo
w P
ath
Prov
ide
Tre
eC
onse
rvat
ion
on L
ots
Elim
inat
e St
orm
Dra
inPi
pes
Dis
conn
ect I
mpe
rvio
usA
reas
Save
Tre
es in
Sm
alle
rC
lust
ers
Ter
race
Yar
ds
Dra
in fr
om H
ouse
and
then
Red
uce
Gra
des
Minimize Disturbance X X X X X
Flatten Grades X X
Reduce Height of Slopes X X
Increase Flow Path (Divert andRedirect)
X X X X
Increase Roughness “n” X X X X X
X
X X
X
X
X X
Low-Impact Development Technique
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Summary of LID TechniquesSummary of LID Techniques(1) Recalculate Postdevelopment CN based on LID land use.
(2) Increase Travel Time (TT) using LID techniques to achievethe same Tc as Existing conditions.
(3) Retention: Provide permanent storage (Infiltration/Retention)using LID techniques to maintain the CN and runoff volumeof existing conditions.
(4) Detention: Provide additional detention storage to maintainthe same peak discharge as existing conditions.
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VIEW OF LOT WITH STORAGE AND BIORETENTION
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Source Node
Gross Pollutant Trap
Buffer Strip
Vegetated Swale
Vegetated Swale
InfiltrationDry & Wet Detention Pond
Wetlands
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HSPF LAND SIMULATION
– Unit-Area Output by Landuse –
BMP Evaluation Method
Existing Flow & Pollutant Loads
Simulated Flow/Water Quality Improvement Cost/Benefit Assessment of LID design
0
50
100
150
200
250
2/20/99 6/20/99 10/20/99 2/20/00 6/20/00 10/20/00
Time
Flow
(cfs
)
0
1
2
3
4
5
6
7
8
9
10
Tota
l Rai
nfal
l (in
)
Total Rainfall (in) Modeled Flow
BMP DESIGN– Site Level Design –
SITE-LEVEL LAND/BMP ROUTINGSimulatedSurface Runoff
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Overflow Spillway
Bottom Orifice
Evapotranspiration
Infiltration
Outflow:Inflow:Modified Flow &
Water QualityFrom Land Surface
Storage
BMP Class A: Storage/Detention
Underdrain Outflow
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UMCP Bioretention
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The Interface
Landuse Menu
BMP Menu
click-and-drag1
edit attributes2
connect objects
3
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Storm Volume (in) 0.180 0.380 0.420 0.790 1.260 2.080 2.390Peak Flow Reduction 2_1 90.3% 94.7% 98.0% 90.9% 82.1% 69.3% 45.7%Peak Flow Reduction 6_2 89.7% 95.3% 98.3% 94.4% 91.1% 88.8% 64.0%
General Assessment of BMP Effectiveness
0%
20%
40%
60%
80%
100%
0.0 0.5 1.0 1.5 2.0 2.5
Storm Volume (in)
BM
P Pe
ak F
low
Red
uctio
n
BMP 2_1 BMP 2_1 in series with BMP 6_2
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Storm Volume (in) 0.180 0.380 0.420 0.790 1.260 2.080 2.390Peak Flow Reduction 2_1 96.6% 81.4% 78.8% 57.4% 42.1% 18.9% 13.7%Peak Flow Reduction 4_2 96.8% 94.6% 93.9% 78.4% 61.0% 53.2% 28.5%
General Assessment of BMP Effectiveness
0%
20%
40%
60%
80%
100%
0.0 0.5 1.0 1.5 2.0 2.5
Storm Volume (in)
BM
P Pe
ak F
low
Red
uctio
n
BMP 2_1 BMP 2_1 in series with BMP 4_2
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Storm Volume (in) 0.180 0.380 0.420 0.790 1.260 2.080 2.390Total Load from Site (lb): 0.142 0.269 0.303 0.287 0.489 1.379 0.628Total load after BMP 4_2 (lb): 0.025 0.104 0.168 0.197 0.370 1.264 0.552Lost or Trapped (lb): 0.117 0.165 0.135 0.090 0.119 0.114 0.075Total Nitrogen Removal (%) 82.14% 61.23% 44.50% 31.27% 24.40% 8.30% 12.00%
General Assessment of BMP Effectiveness
0.000.200.400.600.801.001.201.401.601.802.00
0.18 0.38 0.42 0.79 1.26 2.08 2.39
Storm Volume (in)
Nitr
ogen
Loa
d (lb
)
0%
10%
20%
30%
40%
50%
60%
70%
80%
90%
Perc
ent R
educ
tion
Total Load from Site (lb):Total load after BMP 4_2 (lb):% Removal after BMP 2_1% Removal after BMP 4_2
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Other Models
• PC SWMM/Permeable Pavers (Unilock)• PCSLAMM/(UAB)• SWMM for Microscale Practices (USEPA)
OPTIMIZATION!!• TR-20 Windows (NRCS)• EPA SWMM Optimization• Music (Monash University)• Delaware Conservation and LID Model (TR-
20)
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Lumped or Specific Issues?How do we evaluate/monitor/model/review/determine effectiveness
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Hoffman and Crawford, 2000
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Existing Problems and Future High Risks
Hoffman and Crawford, 2000
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Remove Large Impervious Areas
Oversize Pipes
Comparison of Conventional and LID Strategies
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An estimate of imperviousness can be derived directly from the satellite image for developed areas. (Water bodies from the USGS topographic maps are overlaid for orientation, and areas identified as undeveloped in the National Land Cover dataset are left white.)
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Soil moisture maps can be generated using the vegetation and surface temperature data with a surface climate model. The gray-scale image is dark for surfaces with a dried out top layer and bright or white for surfaces that are wet. This information can be used to locate areas with very moist surface layers near identified wetlands that can be easily converted to wetlands themselves.
woody wetlands classified by the National Land Cover Dataset (NLCD)
forested, non-tidal wetlands classified by the Army Corps of Engineers
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Ground Truthing Image
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( )( ) SIP
IPQa
a
+−−
=2
101000−=
CNS
( )( ) R
SIPIP
Qa
a −+−
−=
2