Diagnosis Study of the Louga-Ouarack-Ndoyene R31 Regional Road (Senegal) ()
1. Introduction
As part of the mission of regular follow-up of the Senegalese’ network of “classified roads’ system”, the SENELABO-BTP laboratory conducted a diagnostic study of the R31 regional road, on behalf of AGEROUTE- Senegal (Agence des Travaux et de Gestion des Routes du Sénégal). The goal was to identify renovation/reha- bilitation works required in order to maintain the level of service after the projected lifetime of over 10 years.
For this study, three complementary indicators to provide assessment on the road edifice were analyzed: 1) its structural behavior (viz., the deformability of the road under the effect of a rolling load); 2) the appearance of the road surface characteristic (apparent pavement damages); and 3) the geotechnical properties of the constituent materials of the various layers of the road. The focus of this paper is to present the methodological approach and the investigations results, the outcome of which can be of advantage to the Senegalese Road Administration as new tools in road diagnosis techniques.
2. Materials and Methods
2.1. Materials
Site description and road structure: Figure 1 is a lay-out plan showing the study road R31. Out of a length of about 53.500 km, the R31 regional road supports a T2 traffic type (viz., a traffic type with up to 1000 vehicles/ day). It was built in 1998 with the key mission of serving the traffic of people and goods, and for the transport of merchandises from the rural economy within the regional administration of Louga; a district that accounts for approximately 678,000 inhabitants and covers an area of about 29,200 km2.
In terms of geomorphology, this area is characterized by the extension of relatively flat and open landscapes of sand dune systems (quaternary ergs). The climatic conditions are typically Sahelian, with nearly 70% of the
Figure 1. Location map of the study road.
annual precipitation occurring between the months of July and September. The average annual rainfall places the region between the isohyets 300 - 400 mm, which implies a savanna vegetation system. The land use is mainly for the cultivation of groundnuts and millet; but truck and cattle ranching are also important in the area.
The studied road comprises of a 5 cm thick layer of asphalt (bituminous pavement), a base layer of 20 cm lateritic gravel stabilized with cement, a 35 cm thick foundation (sub-base) layer (clayey sands) and a 40 cm thick subgrade of sand resting on the sandy original grounds (Table 1).
2.2. Methods
The data bank available for the investigations comprised of measurements of the deformability of the pavement structure using the type 02 Lacroix deflectograph (LD) (Figure 2(a)). These data were complemented with other available information such as data from auger holes drilling by hand and mechanical shovel at different PKs, and from the retrieved samples, and data from the VIZIR campaign conducted in May 2012 by the APAVE Sahel company in order to assess the severity of pavement degradations.
The campaign of deflectometric measurements was carried out by SENELABO-BTP Company in December 2012 immediately after the rainy season, which corresponds to the period of the year when water content in the subgrade is high. The bearing capacity of the road layers is minimal at this time period, as compared to the relatively higher values during the dry period. At the moment there are no experimental data in Senegal to be employed for possible seasonal data corrections in relation to the period of measurement. In addition, geotechnical surveys were also conducted in October 2012 by the company SENELABO-BTP. A series of samples were collected at 10 km interval, beginning from PK 0 (Louga town). The identification tests on sampled materials were performed in the laboratory based on standard tests such as grain size distribution [1] ; soils classification [2] ; oedometer methods [3] ; methylene blue test [4] ; CBR test [5] ; modified proctor test [6] ; water content determination [7] .
Data processing was performed based on the standards and technical specifications developed from the results of methodological research in recent years ( [8] - [13] ) and used as recommendations and decision tools in terms of diagnosis and estimation of the refection’ works to keep safety. This enabled us to achieve a good description of the structural conditions of the road, and establish the section to be repaired, as well as the nature of the most realistic rehabilitation measures to be undertaken.
Principle of the Lacroix deflectograph. Mounted on a truck, the Lacroix deflectograph (LD) allowed for quick survey of the pavement structure and coverage of more points per unit time compared to the famous Benkelman beam. Its technical characteristics are presented in Table 2. The LD allows the measurements of the deflection basin (deflection bowl) generated by a passing truck. The instrumental device includes an automatic pilot system of data acquisition, control and processing. The vehicle running at a constant speed (between about 2 - 4 km/h), thus simulates a passing heavy-weight-truck (axle load ~13.2 tons), traveling approximately at 70 km/h and records at the same time the deformation induced on the road structure (deflection basin; Figure 2(c)) using several sensors (two arrays of geophones distributed along a beam) that records transversal surface profiles. The goal is to measure in real magnitude the response/deformation of the road structure (viz., the bearing capacity of the subgrade and stiffness of the road pavement and thus evaluate its ability to withstand a heavy traffic load). The deflection/deformation is assumed to vary with the stiffness of the road.
Figure 2(b) schematizes the measurement principle of the LD. The operating procedure involved: first, placing of the measuring beam on the surface of the pavement, along the wheel paths between the wheel axles. The vehicle then drives at a steady speed. The measuring beam under the vehicle remains fixed until the rear axle exceeds 10 cm of the point of measurement. The stress related to the passage of the vehicle causes a deformation
Table 1. Structure cross section of the study road.
Figure 2. The Lacroix deflectograph: (a) Measurement frame; (b) Measurement principle; (c) Deflection basin and main parameters. (Dmax is the deflection under the rolling load; R is the radius of the deflection basin; evi is the vertical deformation in the subgrade; εt is the transversal deformation in the asphalt concrete (pavement) layer; SCI is the index of surface curvature and BCI represents the index of base curvature) (modified after [14] .)
Table 2. Main characteristics of the type 02 LD (modified after [14] ).
on the road floor which is recorded by the sensors (Figure 2(c)). The deflection basin thus created by the passage of the vehicle is subjected to 65 points of measurement before the system moves forwards over 4 - 6 meters to the next measuring station by pulling the measuring beam. Further details on the measurement principles and procedures are presented elsewhere in cited reference standards and literature (e.g., LPC No. 39 [4] ).
However, it should be noted that the resulting data from a LD measurement campaign can be used for various investigation activities and design of pavement structure ( [15] - [19] ), particularly in the analysis of deflections as indicators of performance (diagnosis and control) as well as in “back-calculations” of the ground E-modules to evaluate the residual modules of the road’s component layers and to optimize the prediction for the reinforcement of a pavement structure. There are formulae linking the value of the measured deflection to related “efforts” in the layers and thereby allowing the determination of the structural conditions and critical parameters responsible for the road degradation in terms of ageing and deformation of the pavement at the location of measurement (see Figure 2(c)).
3. Results and Discussion
3.1. Measure of the Road Deformability
Data from the measurements carried out with the LD road deflection tester were evaluated with the help of the WLFX 32 software (version 6.1.0). The procedure includes: 1) reading the charts records (deflection profiles); 2) conversion into numerical values, after calibration of the sensors, which will allowed for reading the measurements with a precision of 1/100th mm; 3) calculating the average value of the maximal deformations/deflecttions (Md) recorded within the deflection basin, and the standard deviation (σ) in order to highlight any (possible) heterogeneity within the deflection basin.
In this study, the deflection basin was referred to as a “homogeneous” deformation, if the value of σ is ≤15 × 1/100 mm; and “heterogeneous” when the value of σ is >15 × 1/100 mm. On the assumption of “homogenous” deformation within the basin, the so-called “characteristic deflection” (Cd) of the investigated zone can be defined using Equation (1), the numerical value of which provides guidance on the mechanical behavior of the floor structure and allows for appreciation or diagnosis of the state of the pavement structure at the measurement point (Table 3 and Table 4).
The degree of deformation with respect to passing load depends on the type of road surface (flexible or semi-rigid). For a fully flexible road it was established [20] , that there is a relation between the degree of structural damage, the measured Cd-value and the traffic load that have already passed on the road. Under certain conditions the ground modulus (Es) can be estimated based on the Cd-value and the equivalent thickness of the road structure [14] . Cd values can be used to assess the remaining service life of a road floor or to dimension it with respect to the allowable deflection. In this study, the Cd value of a monitored zone was estimated graphically from the Md-value (average deflection), using the following statistical relationship (Equation (1)). That is to say, by assuming a probability level of exceeding the Md value of 10%.
Table 3. Correlation between the parameters Cd, bearing capacity and quality level of a road structure (modified after [3] ).
Table 4. Interval class values for the characteristic deflection [18] .
(1)
Threshold for critical deflections. The procedure of data analysis required establishing “threshold” values as a qualitative basis for appreciating the measured values. Table 3 shows the parameters considered in the process of qualitative data analysis of the road structure in terms of threshold values for the characteristic deflections.
Due to lack of reference value or standard for the Senegalese road network system, the critical threshold values were defined with reference to the “Handbook for Building Flexible Pavements in Tropical Countries” [3] .
Thus the following values were adopted in this study (Table 3): Cd1 = 60 × 1/100th mm (threshold value below which the structure behaves satisfactorily) and Cd2 = 1/100 × 80 mm (threshold value above which the structure has bearing defects). These limits normally characterize the road structures for which constituent materials have been emplaced mechanically. The numerical values may vary in principle according to the geographical location and the local climatic conditions, and are normally derived from an experimental validation procedure based on a series of LD measurements’ campaigns in the area of interest.
It is worth noting at this stage of the discussion that the measurement campaigns resulted in a large data set. The data were then processed in a multistep procedure which allowed for division of the monitored road into some 170 separate sections or segments regarded as homogeneous zones. Each homogeneous zone is regarded as a zone where the maximal deflection does not vary significantly (standard deviation σ ≤ 15 × 1/100 mm); in other words, within a homogeneous zone the pavement responds in a similar way to the applied load. Consequently, the decision to take a particular action is based separately on the individual homogeneous zone. For convenience, however, the monitored road section need not be divided into relatively short zones [20] , so the minimum length can be set for the survey. In this study a minimum length of 50 m was arbitrarily adopted for the zones. The large number of the individual zones implied the use of the graphical dual axis mode of representation (Figure 3 and Figure 4) for the parameter values.
Classes of Cd values. These were defined based on Table 4. The distribution pattern (Figure 3) shows a high variability of the values, although suggesting a predominance of the low deflection levels (Cd ≤ 60 × 1/100th mm). Since the road has been initially designed to support a T2 traffic class and still exhibits a S3 bearing capacity platform class (15 ≤ CBR ≤ 30; see Table 6), the levels of deflection could be classified as week to moderate on the most part of the road section length. This would mean a road structure of good to doubtful quality on the road sections. Further discussion on this will be presented later in the subsequent section below.
Figure 3. Histogram of section lengths surveyed and their corresponding Cd values. Note the following features of the graph: range of Cd values < 60 mm × 1/100: low deflection (elevated residual bearing capacity, the road edifice is still good); values range 60 × 1/100 mm ≤ Cd ≤ 80 × 1/100 mm: medium deflection (poor residual bearing capacity, the structure of the road edifice is doubtful); Cd values > 80 × 1/100 mm: high deflection (low residual bearing capacity, the road edifice is bad).
3.2. Pavement Damages
The results of classifying the apparent pavement damages using the index values (Is) derived from the VIZIR study [21] are graphically presented in Figure 4, while the results were also categorized based on Table 5 [22] , after some corrections taking into account the recent cosmetic reparation works on the study road. The Is value was calculated by combining the cracking index (If) (i.e. degradation couple: cracking/crazing) with the deformation index (Id) (i.e. degradation couple: deformation/rutting). As shown by the graphic presentation, zones with degradation indices greater than 3 (Is > 3) occur more frequently suggesting that many zones of the road section exhibit large surface structural damages. Consequently, their degradation’s level can be characterized as medium to bad which ultimately require that rehabilitation works should be undertaken.
3.3. Geotechnical Properties of the Road Layers’ Constituent Materials
The results of the laboratory investigations as presented in Table 6 revealed the following facts: 1) The plat- form (subgrade) is essentially a sand gravel, with a small non-swelling fine fraction of medium plasticity index; whereas materials of the foundation layer (sub-base) are made of clayey sands; 2) The bearing capacity of the subgrade is in the S3 class (15 ≤ CBR ≤ 30) over the entire road section, which means it is still suitable. In contrast, the bearing ratio of the sub-base materials (CBR » 18) appeared low, and far below the technical specifications of 30 ≤ CBR ≤ 60. In addition, with CBR indices in the order 55 to 60, the materials of the base layer (lateritic gravels improved with cement) show some severe bearing defects, compared to the requirements of the technical specifications of CBR range of ≥80 for raw materials and CBR of ≥160 for materials treated with cement.
In summary, the sub-base still kept a proper bearing capacity (CBR » 22) and can thus support the ancient pavement structure. However, both the base and the sub-base layers have lost their initial bearing capacity over time, thus causing a considerable structural defect in the road edifice. Based on the poor behavior of the residual surface layers, it is possible to imagine some best feasible rehabilitation solutions. Nonetheless, it should be noted that in general practice, a road edifice, although properly designed, deteriorates with time at the end of its projected useful life span of 10 - 15 years in Senegal. Hence, to maintain its level of service beyond that period,
Figure 4. Histogram of the section lengths for surface damages (apparent pavement damages) based on the Is index [21] . Note: A comparison with Figure 3 suggests a fairly close correspondance between road segments’ length with high Dc values and those with high Is values.
Table 5. Interval of definition for the index (Is) of surface deterioration on the pavement (VZIR method, [22] ).
it must be repaired, usually by constructing a new base layer of cement improved lateritic gravels and capping it with a bituminous pavement cover.
3.4. Summary of the Diagnosis Study
The frequency distribution of the Cd classes, as defined based on Table 4 and presented in Figure 5(a), revealed that the C1 and C2 class levels are largely dominant, as already shown in Figure 3. In addition a cumulative length of approximately 47,686 m (that is about 89.67% of the total length of the road section) has Cd values in the C1 and C2 class levels; thus exhibiting low deflections. This implies a good bearing capacity of the road structure and a relatively good to moderate road quality level. In contrast, a cumulated length of 3,212 m (corresponding to 6.04% of the total length of the road) has Cd values of medium C3 class level which implies a questionable (doubtful) road structure quality level, while a section of 2,279 m (about 4.29% of the road length) exhibited a road structure in the bad quality category (i.e. C4 and C5 class levels).
With reference to Table 7 [3] which orients the choice of possible solutions in tropical countries according to the profile of Cd values and the apparent surface deteriorations of a road, it can be seen in Figure 5(b) that most of the monitored road sections have quality level of the order ≥ Q3, which imply a doubtful road quality and the necessity for further investigations.
Table 6. Geotechnical properties of the road layers.
(Symbols: BL: base layer; FL: fundation layer; PF: plateforme layer).
(a) (b)
Figure 5. Frequency distribution of the road quality levels (a) and the Cd classes for the monitored road. (Note: The deflection classes Ci are defined in Table 3, while the quality indices Qi are given in Table 7).
4. Recommended Rehabilitation Works
Based on the statistics derived from the qualitative ranking (categorization) of the levels of degradation, individual segments’ length upon which corrective measures are required were recognized. Such corrective measures take into account the diagnostic results and type of traffic the road was supposed to carry (viz., one equivalent to the T2 traffic type). The recommended solutions to improve the quality of the study road edifice and thus maintain its level of service are: 1) performance of some maintenance works on road sections with quality levels of ≤Q2; and 2) undertaking of some reinforcement works for those sections with quality indices > Q2.
Table 8 shows the diagnosis results based on the categorization, and the nature of recommended rehabilitation works according to the recommendations presented in Table 9 [3] . For comparative purposes, the table also presents the results of the VIZIR study [21] based mainly on the apparent surface conditions of the monitored road (i.e., simply based on the Is index of apparent surface deterioration).
Based on the above analyses and discussion, this study recommends:
1) some “maintenance” works on road segments with quality levels < Q3; that is to say, a rehabilitation of the road pavement by installing a new asphalt layer coating for the degraded zones. The concerned road length is estimated to be about 16.250 km (equivalent to 30.56% of the monitored road section).
2) some “reinforcement or strengthening” works on a distance of 36.924 km (nearly some 69.44% of the road length) by providing a new base course of cement treated lateritic gravels (in the usual mixing level of 3% cement) to address the low bearing capacity of the road edifice, and then setting up a bituminous pavement.
However, the VIZIR study [21] finds that 30.650 km of study road (approximately 57.64% of the studied section length) requires some strengthening works, while a length of 22.524 km (~42.36% of the road length) are in suitable condition and would require only minor maintenance works. The discrepancy between the two estimation or evaluation methods is quite substantial; however, the estimates in this study which integrates more index parameters, seems to provide a better understand of the situation of things.
Funding: Further assessment of the cost calculations for the proposed rehabilitation works based on the prevailing market prices revealed a cost estimate in the order of 5,352,000,000 (five billion three hundred fifty-two million) CFA francs, as highlighted in Table 10. This cost assessment scenario, which takes into consideration the uncertainties related to the Q3 class level in some of the road sections, is deemed satisfactory based on the dedicated traffic type and desired quality objective.
The funding should be sources from the major financial institutions (e.g., African Bank for Development― ABD and the French Agency for International Development―FAID), which can assist the Senegalese Government in its policy of modernization of the transport infrastructures.
Table 7. Roast decision and parameters taken into account in the development of solutions (modified after [3] .
Note: The quality scores Q1 and Q2 indicate the need for maintenance works, while note Q3 indicate questionable road quality and requires further analysis for a final appreciation. The higher-order classes (Q4 and Q5) should receive reinforcement works.
Table 8. Results of the diagnosis study for the R31 regional road―quality of the degradations and consistency of recommendation works.
Table 9. Recommendations for the types of repairs according to the road quality index and the traffic class T [3] .
Abbreviations: UTG = untreated gravel; BP = bituminous pavement.
Table 10. Details of the proposed repairs and their cost allocations.
5. Summary and Conclusions
The structural performance of the R31 regional road was evaluated after more than 10 years of projected service life by means of the Lacroix deflectograph together with other standard methods, while following the French standards and technical specifications used as tools for decision support in road diagnosis and reinforcement.
The study highlights that the main problem lies in a bearing failure of the road structure at some places, following a loss (temporal degradation) of initial properties at the base course and foundation, which show the respective CBR ratios well below the technical specifications. In this particular case, a “reinforcement” aiming at lengthening the service life of the road is recommended, which consists of a layers’ replacement. Elsewhere, where the bearing capacity still remains in good condition, it is recommended that the corrective action should consist of some minor “maintenance”, by introduction of a new pavement coating for the degraded surfaces. A cost saving scenario for such works has been estimated.
As a form of recommendation, it is essential:
a) to pay a detailed attention to the hydraulic work operations for managing the natural flow and disposal of rain water, by limiting the infiltration on the roadway edges and through carefully executed road shoulders;
b) to carefully study the environment of the road, as well as the hydraulic regime, in order to better understand the origin of the degradations observed on the study road, the rehabilitation of which will allow for revitalization of the agriculture sector which is one of the principal activities in the area.