1) The document outlines a 5-step method for designing a simple stormwater drainage system: analyzing the catchment area, assessing surface type, determining rainfall intensity, calculating stormwater production, and sizing drains.
2) An example calculates the time of concentration, design peak runoff rate, and discharge capacity of a proposed drain for a 12 hectare residential catchment area.
3) The method allows estimating stormwater flows and sizing drains using common terrain data and standard formulas involving runoff coefficients, rainfall intensities, and hydraulic properties.
Hydrology means science of water.
It is the science that deals with the occurance, circulation and distribution of water on the earth.
Hydrology is a broad subject of an inter-disciplinary nature drawing support from allied sciences.
This presentation includes the estimation of storm sewage generated as a result of storm/rainfall events. It includes the detailed usage of rational formula for quantity estimation with solved examples.
Hydrology means science of water.
It is the science that deals with the occurance, circulation and distribution of water on the earth.
Hydrology is a broad subject of an inter-disciplinary nature drawing support from allied sciences.
This presentation includes the estimation of storm sewage generated as a result of storm/rainfall events. It includes the detailed usage of rational formula for quantity estimation with solved examples.
TYPES OF RIVER, PERENNIAL & NON PERENNIAL, PERENIAL V/S NON PERENIAL, STAGES OF RIVERS, RIVER STAGES COVERED, MEANDERING, CUT OFF, RIVER TRAINING WORKS, OBJECTIVE OF RIVER TRAINING, CLASSIFICATION OF RIVER TRAINING WORKS, TYPES OF RIVER TRAINING WORK, PICTURES
Topics:
1. Causes of Failures of Weirs on Permeable Foundations
2. Bligh’s Creep Theory
3. Lane’s Weighted Creep Theory
4. Khosla’s Theory
5. Application of Correction Factors
6. Launching Apron
Topics:
1. Types of Diversion Head Works
2. Weirs and Barrages
3. Layout Diversion Head Works
4. Causes of Failures of Weirs and Barrages on Permeable Foundations
5. Silt Ejectors and Silt Excluders
Canal irrigation- (topics covered)
Types of Impounding structures: Gravity dam – Diversion Head works - Canal drop –
Cross drainage works – Canarl egulations – Canal outlets – Cana ll ining - Kennady s
and Lacey s Regim et heory
TYPES OF RIVER, PERENNIAL & NON PERENNIAL, PERENIAL V/S NON PERENIAL, STAGES OF RIVERS, RIVER STAGES COVERED, MEANDERING, CUT OFF, RIVER TRAINING WORKS, OBJECTIVE OF RIVER TRAINING, CLASSIFICATION OF RIVER TRAINING WORKS, TYPES OF RIVER TRAINING WORK, PICTURES
Topics:
1. Causes of Failures of Weirs on Permeable Foundations
2. Bligh’s Creep Theory
3. Lane’s Weighted Creep Theory
4. Khosla’s Theory
5. Application of Correction Factors
6. Launching Apron
Topics:
1. Types of Diversion Head Works
2. Weirs and Barrages
3. Layout Diversion Head Works
4. Causes of Failures of Weirs and Barrages on Permeable Foundations
5. Silt Ejectors and Silt Excluders
Canal irrigation- (topics covered)
Types of Impounding structures: Gravity dam – Diversion Head works - Canal drop –
Cross drainage works – Canarl egulations – Canal outlets – Cana ll ining - Kennady s
and Lacey s Regim et heory
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All of this illustrated with link prediction over knowledge graphs, but the argument is general.
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Participants will gain insights into the responsibilities, challenges, and best practices associated with test management in SAP projects. Additionally, the webinar delves into the significance of heatmaps as a visual aid for identifying testing priorities, areas of risk, and resource allocation within SAP landscapes. Through this session, attendees can expect to enhance their understanding of test management principles while learning practical approaches to optimize testing processes in SAP environments using heatmap visualization techniques
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1. Insights into SAP testing best practices
2. Heatmap utilization for testing
3. Optimization of testing processes
4. Demo
Topics covered:
Execution from the test manager
Orchestrator execution result
Defect reporting
SAP heatmap example with demo
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Deepak Rai, Automation Practice Lead, Boundaryless Group and UiPath MVP
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Paper presented at SYNERGY workshop at AVI 2024, Genoa, Italy. 3rd June 2024
https://alandix.com/academic/papers/synergy2024-epistemic/
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designing simple drainage system.pptx
1. 6th June, 2022
Designing a simple stormwater
drainage system
By
Engr Muhammad Asif
CEWRI, NARC
0333-5743704
asifbukhari1@gmail.com
…
2. Preamble
In this technical session, I will present a
method
• How much stormwater a catchment area will
produce?
• How a drain can be sized to remove this
water?
3. Materials needed:
i. A map of the catchment area with gradient lines, or a study of the catchment
ii. area from which it is possible to calculate its gradients and boundaries
iii. Ruler
iv. Paper with gridlines
v. A calculator with the option ‘y to the power x’ (yx)
vi. Preferably the IDF-curves (intensity-duration-frequency curves) of the zone studied
4. Step-1:Analysis of the catchment area
• First the catchment area with its boundaries
will have to be identified on the map.
• A catchment area is the entire surface that will
discharge its stormwater to one point (the
discharge point).
• As water always flows from high to low, it is
possible to identify the catchment area on a
map with the aid of the gradient lines.
• Once the catchment area is identified, its
surface must be estimated. This can be done
by transferring the contours of a catchment
area on paper with gridlines, and counting the
grids.
• Now the average gradient in the catchment
area has to be identified. This can be done on
the map with the aid of the gradient lines and
the horizontal distances.
• Figure 1 shows how to determine the gradient
in a terrain. Usually the average gradient of the
terrain can be taken.
Fig 1: The gradient of terrain
5. Step 2: To assess the surface of the terrain.
• This information is needed to determine the runoff
coefficient of the area
• The runoff coefficient is that part of the rainwater which
becomes stormwater
• A runoff coefficient of 0.8 means that 80% of the rainfall
will turn into stormwater
• The runoff coefficient depends on the type of terrain, and
its slope
• Future changes in the terrain must be anticipated in the
design of the drainage system to avoid problems at a later
date
• If no other values are available, the values from table 1 can
be used
Table 1: Runoff coefficients of different types of terrain (these
values are approximate figures assuming a low soil permeability)
Terrain type Runoff coefficient
Gradient < 0.05
(flat terrain)
Gradient > 0.05
(steep terrain)
Forest and pastures 0.4 0.6
Cultivated land 0.6 0.8
Residential areas and
light industry
0.7 0.8
Dense construction and
heavy industry
1.0 1.0
6. Step 3: Determining the rainfall intensity for which
the system is designed
• We will require local IDF-curves (intensity-duration-frequency curve)
• IDF curves show the rainfall intensity (in mm per hour) against the duration of the
rains (in
• minutes) for specific return periods
• Several curves from different return periods may be presented in one graph. A curve
with a return period of 1 year will show the worst storm that will on average occur
every year, a curve with a return period of 2 years is the worst storm that can be
expected in a 2 year period, and so on.
• To know which value to take from the IDF curve, the time of concentration has to be
calculated. The time of concentration is the time the water needs to flow from the
furthest point in the catchment area to the point where it will leave the area (the
discharge point). The time of concentration is determined with the formula
Tcon = 0.02 x ( Lmax )0.77 x ( Sav )-0.383
o Tcon : the time of concentration (in minutes)
o Lmax : the maximum length of flow in the catchment (in metres)
o Sav: the average gradient of the catchment area
7. Cal Example:
If the furthest point of our catchment area is at a distance of 500 meters from the discharge point, and the difference in
altitude between this point and the discharge points 10 meters, than the time of concentration would be around?
Solution:
The maximum length of flow in the catchment (in metres), Lmax= 500 m
The average gradient of the catchment area, Sav= difference in altitude / length of flow in the catchment
The time of concentration (in minutes), Tcon ?
Tcon = 0.02 x ( Lmax )0.77 x ( Sav )-0.383
Tcon= (0.02 x (500)0.77 x (10/500)-0.383 =) 11 minutes.
• Now We need to look for the rainfall intensity on the chosen curve, at the duration of a storm equal to the time of
concentration which we calculated.
8. Step 4: Calculating the amount of water the
catchment area will produce
The amount of stormwater the catchment will produce can be
determined with the formula
Qdes = 2.8 x C x i x A
here
• Qdes : the design peak runoff rate, or the maximum flow of
stormwater the system will be designed for (in litres per second)
• C : the runoff coefficient (see table1)
• i : the rainfall intensity at the time of concentration read from the
chosen IDF curve; if no IDF curves are available, a value of 100 mm/h
can be taken (in mm/h)
• A : the surface area of the catchment area (in ha (10,000 m2)
9. Cal Example
If catchment area be a residential area, with a surface area of 12 ha, a gradient of 0.02, and a rainfall intensity of
100 mm/h, than the design peak runoff rate would be?
solution;
‾ Catchment area, A= 12 ha
‾ Rainfall intensity, i= 100mm/hr
‾ Design peak flow rate, Qdes=?
‾ Gradient = 0.02 ( < 0.05 means, flat terrain)
‾ Coefficient of discharge, C = 0.7 for residential area
Qdes = 2.8 x C x i x A
Qdes = 2.8 x 0.7 x 100 x 12
= 2350 liters per second
10. STEP 5: Sizing a drain to cope with the design
peak runoff rate
• WHEN design peak runoff rate known, we will have to plan where the drains
will be installed
• DRAINS may be lined or unlined but Unlined drains are at risk of erosion
therefore should have a relatively low gradient to control the velocity of the
stormwater
• Gradients in unlined drains should probably not exceed 0.005 (1 meter drop
in 200 meters horizontal distance).
• The size of the drain can be calculated with the formula
𝑸 = 𝟏𝟎𝟎𝟎 𝒙
𝑨 𝒙 𝑹 𝟎. 𝟔𝟕 𝒙 𝑺 𝟎. 𝟓
𝑵
Q : the capacity of discharge of the drain (in l/s)
A : the cross section of the flow (in m2)
R : the hydraulic radius of the drain (see figure F 1, in m)
S : the gradient of the drain
N : Manning’s roughness coefficient: for earth drains, 0.025; brick drains,
the hydraulic radius is the surface area of the cross section of the flow/the
total length of the contact between water and drain;
Hydraulic radius = (a x b) / (a + b + c)
Figure 1: The hydraulic radius
11. Cal Example:
A completely filled, rectangular, smooth concrete drain of 1.5 m by 0.7 m, with a gradient of 0.005, can in ideal
circumstances discharge around
Sol:
Width, b= 1.5 m
Depth, a=c; 0.7 m
Gradient, S =0.005
Roughness coefficient, N=0.015
𝑸 = 𝟏𝟎𝟎𝟎 𝒙 𝑨 𝒙 [
𝑹𝟎.𝟔𝟕
𝒙 𝑺𝟎.𝟓
𝑵
]
Here;
A = bxd= 1.5x0.7= 1.05 m2,; P= a+b+c = 0.7+1.5+0.7=2.9m,
R = A/P = 1.05/2.9 = 0.36 m
𝑸 = 𝟏𝟎𝟎𝟎 𝒙 𝟏. 𝟎𝟓 𝒙 [
𝟎.𝟑𝟔𝟎.𝟔𝟕 𝒙 𝟎.𝟎𝟎𝟓𝟎.𝟓
𝟎.𝟎𝟏𝟓
]
Q = 2496 lps
This calculation will probably have to be repeated a number of times to find the adequate size of drain
Editor's Notes
The rainfall intensity–duration–frequency (IDF) curves are graphical representations of the probability that a given average rainfall intensity will occur within a given period of time