Solution to the Breach of the Dike of Keur Bara KAIRE, Located in the Commune of Notto Diobasse in the Department of Thiès, Senegal ()
1. Introduction
The frequency and intensity of floods have increased in recent decades, largely due to climate change and increasing urbanization [1]. According to the World Food Program (WFP), devastating floods in West and Central Africa have affected five million people in 19 countries in the region. These floods displaced tens of thousands of people from their homes and decimated more than a million hectares of cultivated land [2]. Senegal is not left out since the country has experienced recurrent floods since 1989. This can be explained by rapid urbanization. The urbanization rate increased from 23% in 1960 to 38.40% in 1988, 40.6% in 2000 and 45.2% in 2013, thus leading to the creation and proliferation of irregular neighborhoods which represent nearly 40% of the total habitat in Senegal, more than 2/3 of which is located in flood zones [3]. Regions like Thiès are particularly affected due to the lawless occupation and topography. It is crucial to understand that flooding varies by region, season and local conditions, and flood responses must be tailored to the specific needs of each region [4]. However, huge investments have been made to build community resilience and build infrastructure. Among these infrastructures, there are protective dikes designed to meet specific needs. In Senegal, after the drought cycle of the 1970s, the Senegalese government invested in the construction of dikes which were used to retain water for agriculture and livestock such as the Allou Kagne 2 dam but also dykes which have the role of protecting populations against flooding such as the Keur Bara KAIRE dike which is the subject of this article. Indeed, this village is crossed by a stream which collects rainwater coming from the West to the East, following a natural slope. The passage of these waters caused serious flooding, literally cutting the road and isolating the population, which resulted in two losses of human life. In response to this situation, in 2004, the Senegalese government undertook the construction of the Keur Bara KAIRE dike, a structure intended to control the water level, prevent flooding, and protect agricultural and urban land from overflows. However, this dike failed in 2017, restoring previous problems. A dike rupture can cause a wave of submersion that is much more dangerous than the flood from which it was supposed to protect populations and its causes can be technical, natural or human. The general objective of this article is to contribute to the protection of populations against flooding by trying to propose a solution to make the dike functional [5].
2. Materials and Methods
2.1. Data Acquisition
The study area is located in the department of Notto Diobass, in the Thiès Region of Senegal. Figure 1 shows the location of the area.
Figure 1. Geographical location of the study area on Qgis.
Figure 2 provides an overview of the study area.
Figure 2. Delimitation of the study area on Google Earth.
Figure 3 shows the evolution of the demographics of the municipality.
Figure 3. The evolution of the demographics of the municipality (number of inhabitants).
Figure 4 gives a representation of the evolution of humidity in 2021.
Figure 4. Variation of humidity in the Thiès region [3].
Figure 5 shows the temperature variation.
Figure 5. Variation of monthly temperature in the Thies region in 2018 [5].
The winds are moderate and their speeds vary from 2 to 14 m/s. [6] Rainfall follows a sawtooth pattern (Figure 6) with an average of around 471 mm per year.
Figure 6. Variation in the average annual rainfall of Thiès (in mm of rain) from 1989 to 2019 [1].
Figure 7. Geological section of Thiès [6].
The morphology of the department causes most of the runoff water to converge towards the lowlands. In other words, the waters leave the highest points (altitude 112 m) towards the lowest (altitude 49 m). This makes the study area, located at an altitude of 82 m, a runoff zone [7].
To characterize the geological structure of Thiès, a section of the different layers was made from the logs of several boreholes as illustrated in Figure 7 [6].
Figures 8-11 illustrate the current state of the Keur Bara KAIRE dike.
Thus, the data obtained makes it possible to follow the procedures and approaches to deal with this specific problem of the dike.
Figure 8. Sandbags stored on the track ditch.
Figure 9. Rows of rocks to reduce wave pressure.
Figure 10. Rupture at the down stream slop.
Figure 11. Rupture at the spillway.
2.2. Data Processing and Analysis [8]
Seven (7) boreholes were made with a depth of 1 m:
S1 upstream with coordinates 14˚43'51.1"N/17˚4'3.1"W with an altitude of 77 m;
S2 upstream with coordinates 14˚43'50.2"N/17˚4'2.4"W with an altitude of 76 m;
S3 upstream with coordinates 14˚43'49.6"N/17˚4'2.1"W with an altitude of 77 m.
S1 downstream with coordinates 14˚43'50"N/17˚4'4.7"W with an altitude of 77 m;
S2 downstream with coordinates 14˚43'49.2"N/17˚4'3.7"W with an altitude of 77 m;
S3 downstream with coordinates 14˚43'48.2"N/17˚4'2.9"W with an altitude of 77 m.
An in situ permeability test was carried out to determine the permeability of the soil.
Table 1 gives the permeability classes.
Table 1. Permeability classes depending on the permeability coefficient.
Permeability classes depending on the permeability coefficient |
K (m/s) |
Degree of permeability |
Medium to large gravels |
10−1 - 10−3 |
Very high |
Small Gravel, Sand |
10−3 - 10−5 |
Quite high |
Very fine sand, silt sand |
10−5 - 10−7 |
Weak |
Compact silt, clay, loam |
10−7 - 10−9 |
Very weak |
Frank clay |
10−9 - 10−12 |
Virtual waterproof |
GTR classification is a soil classification method used to evaluate soil properties. The GTR classification is made according to Table 2 and Table 3.
Table 2. GTR class A classification.
Classification according to nature |
Classification according to water status |
Nature parameters First level of classification |
Class |
Nature parameters Second level of classification |
Subclass function
of nature |
Status Settings |
State function subclass |
Dmax ≤ 50 mm and Sieve at
80 µm > 35% |
A Sols fins |
VBS ≤ 2.5 or
Ip ≤ 12 |
A1 Little plastic silts, loess, alluvial silts, little polluted fine sands, little plastic arenas |
IPL ≤ 3 or Wn ≥ 1.25WOPN |
A1 th |
3 < IPL ≤ 8 or 1.10 ≤ Wn < 1.25WOPN |
A1 h |
8 < IPL ≤ 25 or 0.9WOPN ≤ Wn < 1.1WOPN |
A1 m |
0.7WOPN ≤ Wn < 0.9WOPN |
A1 s |
Wn < 0.7WOPN |
A1 ts |
|
|
12 < Ip ≤ 25 or 2.5 < VBS ≤ 6 |
A2 Fine clay sands, clay silts and poorly plastic marls, arenas |
IPL ≤ 2 or Ic ≤ 0.9 or Wn ≥ 1.3WOPN |
A2 th |
2 < IPL ≤ 5 or 0.9 ≤ Ic < 1.05 or 1.1WOPN ≤ Wn < 1.3WOPN |
A2 h |
5 < IPL < 15 or 1.05 < Ic ≤ 1.2 or 0.9WOPN ≤ Wn < 1.1WOPN |
A2 m |
1.2 < Ic ≤ 1.4 or 0.7WOPN ≤ Wn < 0.9WOPN |
A2 s |
Ic > 1.3 or Wn < 0.7WOPN |
A2 ts |
25 < Ip ≤ 40 or 6 < VBS ≤ 8 |
A3 Clays and marly clays, very plastic silts |
IPL < 1 or Ic ≤ 0.8 or Wn ≥ 1.4WOPN |
A3 th |
1 < IPL < 3 or 0.8 ≤ Ic < 1 or 1.2WOPN ≤ Wn < 1.4WOPN |
A3 h |
3 < IPL < 10 or 1 < Ic ≤ 1.15 or 0.9WOPN ≤ Wn < 1.2WOPN |
A3 m |
1.15 < Ic ≤ 1.3 or 0.7 WOPN ≤ Wn < 0.9WOPN |
A3 s |
Ic > 1.3 or Wn < 0.7WOPN |
A3 ts |
Ip > 40 or VBS > 8 |
A4 Very plastic clays and marly clays |
Threshold values of state parameters, to be defined in support of a specific study |
A4 th |
A4 h |
A4 m |
A4 s |
Table 3. GTR class B classification.
CLASSIFICATION TO USE FOR EMPLOYMENT |
CLASSIFICATION TO USE FOR SHAPE LAYERS |
CLASSIFICATION ACCORDING TO NATURE |
CLASSIFICATION ACCORDING TO WATER STATUS |
CLASSIFICATION BY BEHAVIOR |
Nature parameters first level of classification |
Class |
Nature parameters Second level of classification |
Subclass function of nature |
Status Settings |
State function subclass |
Behavior settings |
Subclass behavior function |
Dmax ≤ 50 mm and Sieve at
80 µm ≤ 35% |
B sandy and clay soil with fin |
Sieve at 80 µm ≤ 12% Sieve at 2 mm > 70%
0.1 ≤ VBS ≤ 0.2 |
B1 silica sands |
Materials generally
insensitive to water |
FS ≤ 60 FS > 60 |
B11 B12 |
Sieve at 80 µm ≤ 12% Sieve at 2 mm > 70% VBS > 0.2 |
B2 Clayey sands (lightly clayey) |
IPL ≤ 4 or Wn ≥ 1.25WOPN |
B2 th |
FS ≤ 60 |
B21 th |
FS > 60 |
B22 th |
4 < IPL ≤ 8 or 1.10 ≤ Wn < 1.25 WOPN |
B2 h |
FS ≤ 60 |
B21 h |
FS > 60 |
B22 h |
0.9WOPN ≤ Wn < 1, 10WOPN |
B2 m |
FS ≤ 60 |
B21 m |
FS > 60 |
B22 m |
0.5WOPN ≤ Wn < 0, 9WOPN |
B2 s |
FS ≤ 60 |
B21 s |
FS > 60 |
B22 s |
|
|
|
|
Wn < 0.5WOPN |
B2 ts |
FS ≤ 60 |
B21 ts |
FS > 60 |
B22 ts |
Sieve at 80 µm ≤ 12% Sieve at 2 mm > 70%
0.1 ≤ VBS ≤ 0.2 |
B3 Silty gravel |
Materials generally insensitive to water |
LA ≤ 45 et MIDE ≤ 45 |
B31 |
LA > 45 et MIDE > 45 |
B32 |
For watersheds, their characteristics can vary depending on different factors, such as geology, topography, vegetation, climate and land use [9]. Figure 12 represents the zoning done on Google Earth imported onto Global Mapper.
Figure 12. Zoning for watershed delimitation on Google Earth Pro.
The design flood calculation is done using the Grésillon formula which allows you to go from the ten-year flood to the hundred-year flood as given in formula 1:
(1)
Q10: Centennial flow;
C: increase coefficient given by the Gradex method (formula 2):
(2)
P10: daily precipitation corresponding to a return period of 10 years;
P100: daily precipitation corresponding to a return period of 100 years;
Tb: basic time (in hours);
Kr10: runoff coefficient of the ten-year flood (expressed as a fraction).
For the ratio between centennial and ten-year frequency precipitation:
Losses occur through infiltration and evaporation. The methodology adopted for data analysis made it possible to know the shape of the dike, and the nature of the soil and to verify the stability of the dike [10].
3. Results and Discussions
The Keur Bara KAIRE watershed is delimited using Global Mapper software. Figure 13 gives the delimitation of the sub-watersheds.
Figure 13. Demarcation of the sub-watersheds of Keur Bara KAIRE on Global Mapper.
Figure 14 gives the hypsometric curve of the Keur Bara KAIRE watershed.
Figure 14. Hypsometric curve of the Keur Bara KAIRE watershed.
The hypsometric curve made it possible to determine the altitudes at 5% and 95% of cumulative surfaces which are respectively equal to 99.2 m and 84 m. These altitudes made it possible to calculate the overall slope index. Table 4 presents the characteristics of the Keur Bara KAIRE watershed.
These results show that the basin is very small with an elongated shape and low relief.
Table 4. Characteristics of the Keur Bara KAIRE watershed [8].
Watershed characteristics |
Results obtained |
Area S in km2 |
3.72 |
Perimeter P in km |
10.43 |
Maximum altitude in m |
104 |
Minimum altitude in m |
82 |
Hydraulic length in km |
2.54 |
Average slope |
0.63 |
Shape index KG |
1.52 |
Length of the equivalent rectangle L in km |
4.37 |
Overall slope index Ig in m/km |
5.98 |
Specific height difference Ds in m |
11.54 |
Basin typology |
Very small watershed |
Relief typology |
Weak |
The average permeability coefficient (km) is equal to 3.66731 × 10−6, so the permeability of the soil is low.
The particle size curves in Figure 15 represent the results of the particle size test carried out on the seven (7) samples.
Figure 15. Particle size curves on the seven (7) samples (percentage of aggregates).
The particle size curves do not allow a good classification of the soil due to the absence of the parameters D10, D30 and D60. It was, therefore, necessary to carry out the particle size test by sedimentometry. The results of the Cc and Cu calculations are presented in Table 5.
The uniformity coefficients of all samples are greater than 2, so the grain size of the soil is spread out. The curvature coefficients of the upstream and downstream samples are not between 1 and 3, so the soil is poorly graded upstream and downstream of the dike. On the other hand, the coefficient of curvature of the dike backfill sample is between 1 and 2, so the grain size of the dike backfill is well graded.
Table 5. Curvature and uniformity coefficients.
Samples |
Curvature coefficient (Cc) |
Uniformity coefficient (Cu) |
Upstream S1 |
4.20 |
6.20 |
Upstream S2 |
6.30 |
10.17 |
Upstream S3 |
4.65 |
8.33 |
Downstream S1 |
0.39 |
4.62 |
Downstream S2 |
0.55 |
4.88 |
Downstream S3 |
0.39 |
4.62 |
Embankment of the dike |
1.15 |
4.62 |
The results of the tests on the specific weight are given in Table 6.
Table 6. Results of specific weights of solid grains.
Samples |
γs moyen (g/ml) |
Upstream S3 |
2.649 |
Downstream S1 |
2.622 |
Downstream S2 |
2.927 |
Downstream S3 |
2.653 |
Embankment of the dike |
2.613 |
Average γs is greater than 2.6 g/ml, so the soil contains heavy particles. The results of the methylene blue tests are presented in Table 7.
Table 7. Results of the methylene blue test.
Samples |
VBS |
Upstream S3 |
1.12 |
Downstream S1 |
0.71 |
Downstream S2 |
0.71 |
Downstream S3 |
0.56 |
Embankment of the dike |
0.81 |
The VBS values are in the interval [0.2; 1.5] therefore the soil is sandy-loamy.
The results of the sand equivalent test carried out on samples S3 upstream, S1, S2 and S3 downstream as well as on the support soil of the dike are recorded in Table 8.
Table 8. Sand equivalent results.
Samples |
Sand equivalent |
Upstream S3 |
27.07 |
Downstream S1 |
27.06 |
Downstream S2 |
42.27 |
Downstream S3 |
42.21 |
Embankment of the dike |
53.45 |
The sand equivalents are less than 60, so the soil is clayey sand. The Atterberg limits test is carried out on the upstream samples S1 and S2. Figure 16 and Figure 17 represent the curves for determining the liquidity limit.
Figure 16. Curve of the liquidity limit (%) of the upstream S1 sample.
Figure 17. Curve of the liquidity limit (%) of the upstream S2 sample.
Figure 16 and Figure 17 give the values of the liquidity limit of upstream S1 and upstream S2 which are respectively 43.5% and 41.6%. The results of the compactness index (Ic) and the plasticity index (Ip) are presented in Table 9.
The Ip is the interval [15; 40] and the Ic > 1 therefore the soil is in a plastic and solid state.
Table 9. Atterberg limit results.
Samples |
Hint |
Upstream S1 |
Ip |
17.8 |
Ic |
2.21 |
Upstream S2 |
Ip |
25.6 |
Ic |
1.38 |
The GTR classification was made using the results obtained in the geotechnical tests.
Samples S3 upstream, S1, S2 and S3 downstream of the dike are class A1, so they are lightly polluted fine sand. On the other hand, samples S1, S3 upstream are respectively fine clayey sand and marly clay. This can be explained by the fact that runoff water carries materials with it. The embankment is class B2, so the soil is a slightly clayey sand.
To check the stability of the structure, it is necessary to know the cohesion and the internal friction angle of the dike backfill. Table 10 gives the normal and tangential stresses at the different loadings.
Table 10. Results of calculations of σn (kPa) and τ (kPa).
Overload (kg) |
σn (kPa) |
τ (kPa) |
4 |
237.819 |
87.582 |
8 |
514.370 |
305.999 |
16 |
1023.195 |
282.611 |
Figure 18 shows the shear stress-deformation curve plotted using Table 10.
Figure 18. Shear force-strain curve.
The cohesion and friction angle are given in Table 11.
The cohesion is zero, which confirms that the backfill is made with sand.
Table 11. Cohesion and angle of internal friction.
Cohesion |
C (kPa) |
0 |
Internal friction angle |
φ (˚) |
21.82 |
Figure 19 and Figure 20 respectively give the variation in the moving average of annual rainfall and the variation in the moving average of daily maximum rainfall.
Figure 19. Variation in the moving average of annual rainfall (in mm of rain).
Figure 20. Variation in the moving average of daily maximum rainfall.
The analysis of this data did not show any doubtful periods. Therefore, these data will be used to diagnose the dimensioning of the work.
The graphic adjustment of the daily maximum data by Gumbel’s law made it possible to obtain the graph in Figure 21.
The analysis of Figure 21 reveals that there is a distribution of the cloud of points around the adjustment line. Thus, the results of the parameters obtained by the graphical method will be used as input parameters for the design of the structure. Table 12 gives the values of Gumbel’s law (s and X0) obtained by the graphical method.
Figure 21. Graphical adjustment of daily maximum rainfall (in mm/d of rain).
Table 12. Gumbel Settings by graphical adjustment.
δ (standard deviation) |
a |
medium |
X0 |
s |
65.841 |
0.019 |
200.906 |
171.274 |
51.356 |
The results obtained by the moment method are reported in Table 13.
Table 13. Gumbel parameters by adjustment by the moment method.
δ (standard deviation) |
medium |
s |
X0 |
65.841 |
200.906 |
51.356 |
171.274 |
The scale factor and the amount of rainfall in the current state are the same in both methods.
For the estimation of the flow by the ORSTOM method, since the area of the catchment area is 3.72 km2 also the smallest height of precipitation is equal to 234.9 mm and the largest 664.4 mm, so all heights are in the interval [150; 1600]. The decadal flow calculations by the ORSTOM method are given in Table 14.
Table 14. Calculation of Qr10 by the ORSTOM method.
A |
0.91 |
P10 |
286.844 |
P100 |
407.521 |
Kr10 |
24 |
Pan |
441.24 |
S |
3.72 |
α10 |
2.6 |
Tb10 |
440 |
Qr10 (m3/s) |
23.17 |
For the ORSTOM method, the ten-year flood amounts to 23.17 m3/s.
For the estimation of the flow by the CIEH method, since the catchment area is 3.72 km2, it is in the range [0.07; 2500] also the smallest height is equal to 234.9 mm and the largest 664.4 mm, so all heights are in the interval [150; 1600]. The results of the calculations are recorded in Table 15.
Table 15. Calculation of Q10 by the CIEH method.
Pan |
441.24 |
S |
3.72 |
Ig |
5.98 |
Q10 (m3/s) |
13.86 |
For the CIEH method, the ten-year flood is equal to 13.86 m3/s.
Table 16 presents the results of the centennial flow calculation or project flood.
Table 16. Project flood calculation.
|
Q10 (m3/s) |
C |
Q100 (m3/s) |
ORSTOM |
23.17 |
2.37 |
54.99 |
CIEH |
13.86 |
32.89 |
For safety reasons, the maximum ten-year flood Q100 = 54.99 m3/s is used as the project flow.
To make the diagnosis of the dike, it is necessary to compare the dimensions found on site with the results of the resizing. Table 17 and Table 18 show the dimensions of the dike found at the site and the results of the dike resizing, respectively.
Table 17. Dimensions of the dike.
Ridge width Lc (m) |
7.02 |
Width of the base of the dike Lb (m) |
58.8 |
Height of the dike H (m) |
2.88 |
Water Slide h (m) |
0.7 |
Height of the reservoir Hr (m) |
2.27 |
Length of weir (m) |
30.00 |
Table 18. Resizing the dike.
Wind speed (u in km/h) |
15.24 |
TN Rating (m) |
75.06 |
Lengths of the (m) |
132 |
FETCH Length (Lf in m) |
0.12 |
Wave height (Hv in m) |
0.79 |
Wave propagation speed (v in m/s) |
3.09 |
Revenge (R in m) |
1.08 |
Height of the dike (Hd in m) |
3.00 |
Ridge width (Lc in m) |
2.86 |
Width of the base of the dike (Lb in m) |
14.86 |
Water Gap (h in m) |
0.70 |
Height of the reservoir (Hr in m) |
1.22 |
Flow coefficient (m) |
0.40 |
Project flood (Q in m3/s) |
54.99 |
Spillway length (L in m) |
52.99 |
The resizing showed that the dimensions of the dike are acceptable except for the length of the spillway. The calculation results for the LANE rule check are shown in Table 19.
Table 19. Checking for infiltration under the dike.
Lv (m) |
LH (m) |
C |
Hr (m) |
|
58.81 |
132 |
7 |
1.22 |
× |
The LANE rule is respected, so the risk of infiltration under the dike is eliminated.
The results for the protection of the upstream slope are given in Table 20.
Table 20. Calculation of the thickness of the upstream slope protection.
Y |
Pente |
C |
V (m/s) |
e (m) |
2.8 |
1/2 |
0.026 |
3.09 |
0.24 |
For good protection of the upstream slope, the thickness of the protective layer had to be equal to 24 cm, but the protective layer found on the site is 15 cm. So, the protection of the upstream slope is not good. The protection of the downstream embankment is made of stone with a thickness of 20 cm, which complies with the standard which requires a thickness of at least 16 cm, so it is acceptable. The ridge protection is made of laterite with a thickness of 16 cm, which is below the standard. The thickness of the laterite layer should be at least 20 cm. So, the protection of the ridge is not good.
The results of the slip stability calculations are given in Table 21.
Table 21. Calculation of slip stability.
W1 |
U |
Pa |
FSG |
179.69 |
205.8 |
2.45 |
1.84 |
Slip stability is checked.
The results of the rollover stability calculations are given in Table 22.
Table 22. Calculation of Rollover Stability.
∑M Stabilizers |
530.39 |
∑M Stunning |
4035.53 |
FSR |
0.13 |
Rollover stability is not checked.
In summary, the diagnosis of the dike failure according to the three hypotheses raised yielded:
3.1. Excess Flooding
Taking the average annual precipitation of 1989 (609.9 mm), which returns ten years later in 1999 (618.5 mm), as a reference point, the rupture may be due to an excess of flooding since in 2010, the average rainfall was well above the reference threshold, reaching 664.4 mm. So, the rupture may be due to an excess of flooding.
3.2. External Erosion
To minimize the risk of breakage, good slope protection is necessary. However, the protection of the upstream slope, which was supposed to be 24 cm thick, is 15 cm. Similarly, the thickness of the laterite layer of the ridge, which must have been 20 cm, is 16 cm. So, the protections at the crest and the upstream embankment are not good. If slope protection is not adequate, water can seep into the embankment, which can cause erosion. In this context, it is relevant to speak of external erosion, since the protection of the downstream slope is sufficient.
3.3. Undersizing
The sizing is acceptable except for the length of the spillway. Also, the overturning stability is not checked, which can be a cause of breakage.
4. Conclusions
There are many shortcomings in the design of the Keur Bara KAIRE dike. First, there is the excess flooding, then the poor protection of the embankments and finally, the undersizing. This confirms the hypotheses outlined above. Therefore, to solve the flooding problems caused by the failure of the dike, it is first proposed to redo the structure using a homogeneous earthen dike with zones with a slope of 1/2 upstream and downstream, clay sand for the backfill to prevent water infiltration, a protective layer of 24 cm for the upstream embankment, 20 cm for the crest and 15 cm for the downstream embankment and for more resistance, build 50 cm thick ramming walls with a length of 1 m for the anti-fox screen. Table 23 presents the results of the design of the flanking walls.
Table 23. Dimensioning of the flanking walls.
Peak Width (m) |
2.86 |
Height of the wall above the TN (m) |
3 |
Wall thickness (m) |
0.5 |
Length of the anti-fox screen (m) |
1 |
Slope of side walls |
1/2 (Upstream and downstream) |
It is essential to consider that this article is not limited to the simple rehabilitation of the dike.
In order to guarantee the sustainability of the structure, it would be wise for the stakeholders to work together to develop an organizational plan dedicated to monitoring, control and maintenance. This will establish a solid structure that will ensure the long-term preservation of the structure.
Abbreviations
˚C |
Degree Celsius |
ANACIM |
National agency for civil aviation and meteorology |
ANSD |
National Agency for Statics and Demography |
Cc |
Curvature coefficient |
CIEH |
Inter-African Committee for Hydraulic Studies |
cm |
Centimeter |
Cu |
Uniformity coefficient |
D10 |
Sieve diameter corresponding to 10% |
D30 |
Sieve diameter corresponding to 30% |
D60 |
Sieve diameter corresponding to 60% |
Dd |
Drainage density |
Ds |
Specific elevation |
ES |
Sand equivalent |
Fd |
Exceeding frequency |
Fnd |
Frequency of non-exceeding |
FSG |
Slip safety factor |
FSR |
Rollover safety factor |
GNSS |
Global navigation satellite systems |
GPS |
Global positioning system |
GTR |
Guide to road earthworks |
HD |
Height of the dike |
Hr |
Height of the reservoir |
Ic |
Consistency index |
Ig |
Overall slope index |
Ip |
Plasticity index |
k |
Permeability coefficient |
KG |
Shape index |
Km |
Kilometer |
km2 |
Square kilometer |
L |
Length of the equivalent rectangle |
Lb |
Base width of the dike |
Lc |
Ridge width |
m |
Meter |
DEM |
Digital terrain model |
MRUH |
Ministry of Urban Renewal and Housing |
NF |
French standard |
ORSTOM |
Overseas Scientific and Technical Research Office |
P |
Perimeter of the watershed |
P10 |
Ten-year daily rain |
P100 |
100-year daily rain |
PVC |
Polyvinyl chloride |
Q100 |
Centennial flow or design flood |
Qr10 |
Ten-year flow |
A |
Free revenge |
s |
Second |
S |
Watershed area |
T |
Return period |
TN |
Natural terrain |
U |
Reduced Gumbel variable |
UFR-SI |
Engineering sciences training and research unit |
VBS |
Methylene blue value |
w |
Water content |
WL |
Liquidity limit |
WP |
Plasticity limit |
Zd |
Setting dimension |