USE OF CONE PENETRATION TEST IN PILE DESIGN



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PERIODICA POLYTECHNICA SER. CIV. ENG. VOL. 47, NO. 2, PP. 189 197 (23) USE OF CONE PENETRATION TEST IN PILE DESIGN András MAHLER Department of Geotechnics Budapest University of Technology and Economics H 1521 Budapest, Hungary Received: December 1, 24 Abstract Modern methods of pile design often make extensive use of in situ test data. Different pile capacity prediction methods were used to evaluate the axial capacity of 13 full-scale test piles. The pile load tests were performed on CFA piles in various soil conditions. The predicted behaviours of the piles are discussed and compared with the results of the pile load tests. Keywords: cone penetration test, piezocone, pile capacity. 1. Introduction The prediction of pile capacity is complicated by the large variety of soil types and installation procedures. Many methods have been proposed to predict the axial capacity of single piles. These methods can be divided in three main groups: 1. Full scale pile load test: This test exactly describes the piles behaviour with a load-settlement curve. At the moment this is the best method to predict the capacity of a single pile. The disadvantages of this method are: the costs of such a test are high, and it is rarely feasible in the stage of planning. 2. Calculation methods based on results of laboratory tests: The low accuracy of these methods makes their economical use difficult. 3. Calculation methods based on results of in-situ tests: Among the numerous in-situ devices, the cone penetration test (CPT) and the piezocone (CPTu) represent the most versatile tools for geotechnical design. One of the earliest applications of this device was to predict a pile s axial capacity. As a model pile it is pushed into the ground and measurements are made of the resistance to penetration of the cone. Using this test the pile capacity can be predicted time- and cost-efficiently even in the stage of planning. Nevertheless the accuracy of this method will not achieve that of full scale tests, but the reliability of predictions based on CPT is improving.

19 A. MAHLER 2. Test Site Most of the tests were performed at the construction of highway M3 in Hungary, but other tests were also performed at different sites in Hungary. The tested piles were CFA (continuous flight auger) piles. The length of the piles ranged from 6.2 m to 22. m, the diameter ranged from.6 m to 1. m. The pile load tests were performed in different soil conditions. 3. Interpretation of Pile Load Tests The ultimate bearing capacity of the tested piles, determined by the method described in the Hungarian Code (MI-4-19), ranged from 83 kn to 39 kn. The pile axial capacity consists of two components: end bearing load (base resistance) and side friction load (shaft resistance). At the pile load tests only total capacity of the piles is measured, so it was necessary to calculate the base resistance and the shaft resistance of the piles separately, based on the results of the performed tests. These values were determined based on detailed analysis of the test results and soil conditions. 4. Prediction of Pile Capacity Using CPT Data The maximum bearing resistance of each single pile was predicted using the following methods: DIN 414 (German Standard) method Bustamante and Giasenelli (1982) method (LCPC method) EUROCODE 7-3 method (process recommended by EC 7-3) ERTC3 method (De Cock, F. Legrand C., 1997) In all cases the pile capacity is derived from the known formula: F max = F max, base + F max, shaft, where: F max is the maximum bearing resistance of the pile; F max, base is the maximum base resistance; is the maximum shaft resistance; F max, shaft DIN 414 Method The German Standard provides different methods for cohesive and non-cohesive soils. In case of non-cohesive soils the unit base and shaft resistance of a bored pile can be calculated using the following tables (Table 1, Table 2):

CONE PENETRATION TEST 191 Table 1. Calculation of unit base resistance (DIN 414 Non-cohesive soils) Average cone tip resistance (q c ) [MPa] Unit base resistance [MPa] 1 2. 15 3. 2 3.5 25 4. Table 2. Calculation of unit shaft resistance (DIN 414 Non-cohesive soils) Average cone tip resistance (q c ) [MPa] Unit shaft resistance [MPa]. 5.4 1.8 15.12 For the calculation of unit base resistance the average cone tip resistance is determined between the pile tip and depth of three times the pile diameter under the tip. In case of cohesive soils the unit base resistance and the unit skin friction can be determined with an indirect method, using the following tables (Table 3, Table 4): Table 3. Calculation of unit base resistance (DIN 414 Non-cohesive soils) Average undrained shear strength (c u ) [MPa] Unit base resistance [MPa].1.8.2 1.5 Similarly to the non-cohesive case average c u is determined between the pile tip and depth of three times the pile diameter under the tip. So the unit base and shaft resistance are calculated using the undrained shear strength (c u ) of cohesive soils. There are numerous methods to predict c u based on CPT values, but the method used for this purpose has a great influence on the estimated pile capacity. So the final predicted pile capacity may be different using different methods for undrained shear strength prediction.

192 A. MAHLER Table 4. Calculation of unit shaft resistance (DIN 414 Non-cohesive soils) Average undrained shear strength (c u ) [MPa] Unit shaft resistance [MPa].25.25.1.4.2.6 Bustamante and Giasenelli (1982) Method In this case the unit base and shaft resistances of a pile are calculated directly from the cone resistance (q c ) using the following equation: p max, base = k c q c,avg p max, shaft = q c,z α, where: q c,avg q c,z k c, α is the average value of q c,z between the depth of 1.5 D above and 1.5 D below the pile tip. is q c at depth z factors depending on pile- and soil type and measured cone tip resistance (q c ) (see in Table 5.) Table 5. k c and α factors (Bustamante and Giasenelli; 1982) q c [kpa] k c α max p shaft [kpa] soft clay q c < 1.4 3 15 moderately compact clay 1 < q c < 5.35 4 8 compact to stiff clay, compact silt q c > 5.45 6 8 silt and loose sand q c < 5.4 6 35 moderately compact sand and gravel 5 < q c < 12.4 1 12 compact to very compact sand and gravel q c > 12.3 15 15

CONE PENETRATION TEST 193 EUROCODE-7-3 method In this method the maximum unit base and shaft resistance can be derived form the following equations: ( ) qc,i, mean + q c,ii, mean p max, base = α p.5 + q c,iii, mean 2 p max, shaft = α s q c,z where: q c,i, mean is the mean of the q c,i values over the depth running from the pile base level to a level (critical depth) which is at least.7 times and at most 4 times the pile base diameter deeper. (Critical depth: where the calculated value of p max, base becomes a minimum) q c,i, mean = 1 dcrit q c,i dz d crit.7 D d crit 4 D q c,ii, mean is the mean of the lowest q c,ii values over the depth going upwards from the critical depth to the pile base q c,ii, mean = 1 q c,ii dz d crit d crit q c,iii, mean is the mean value of the q c,iii values over a depth interval running from the pile base level to a level of 8 times the pile base diameter higher. This procedure starts with the lowest q c,ii value used for computation of q c,ii, mean. q c,iii, mean = 1 8D 8 D q c,iii dz q c,z α p α s is q c at depth z is the pile class factor is a factor depending on the pile class and soil conditions (Table6). ERTC3 Method This method has the same process for calculation of unit base resistance as the EC 7-3 method, but the determination of the shaft resistance is modified. It can be calculated with the same process, but α s values are different (Table 7).

194 A. MAHLER Table 6. Friction coefficient, α s (EUROCODE 7-3) Soil type relative depth z/d α s fine to coarse sand.6 very coarse sand.45 gravel.3 clay/silt (q c 1MPa) 5< z/d < 2.25 clay/silt (q c 1MPa) z/d 2.55 clay/silt (q c > 1 MPa) not applicable.35 Peat not applicable Table 7. Friction coefficient, α s (ERTC 3) Non-cohesive Cohesive Gravel.3 Sandy gravel.45 Fine sand.6 Sandy silt.8 Silt.1 q c > 25 kpa.15 15 kpa <q c < 25 kpa.25 1 kpa <q c < 15 kpa.35 5 kpa <q c < 1 kpa.45 q c < 5 kpa.55 Predicted pile capacity [kn] 8 6 4 2 1 2 3 4 Measured pile capacity [kn] Fig. 1. DIN 414 method

CONE PENETRATION TEST 195 Predicted pile capacity[kn] 8 6 4 2 1 2 3 4 Measured pile capacity [kn] Fig. 2. LCPC method 5. Reliability of the Prediction Methods In the following figures the results of the pile capacity predictions are shown. In each figure the predicted pile capacity values are plotted against the results of pile load tests (measured pile capacity). The continuous lines represent the perfect prediction zone. Fig. 1 shows the results of the DIN 414 method. As it was mentioned earlier it is an indirect method in case of cohesive soils, so the prediction method of undrained shear strength (c u ) has a serious effect on the calculated pile capacity. So it is obvious that the reliability of this method is varying with various c u prediction methods. LCPC (BUSTAMANTE and GIASENELLI, 1982) method provides a direct calculation process using solely the measured cone tip resistance (q c ) values. The results of this method are shown in Fig. 2. By comparing the two figures we can say that this process gives similarly accurate pile capacity values. Fig. 3 shows the results of the EUROCODE 7-3 method. Among the investigated methods this one has the most complicated process for estimation of unit base resistance of a pile. This calculation process results in very accurate results, but the prediction of unit skin friction is less accurate in some cases. As it can be seen in Fig. 3 in these particular cases the pile capacities are extremely overestimated. These piles were of large diameter, long piles in stiff clays of high plasticity and in each case the skin friction of the piles were overestimated. The ERTC 3 method has the same process for determination of unit base resistance, but the calculation process of unit skin friction is modified. In Fig. 4 the results of this prediction method are shown. We can see that this method gives reliable results even in cases in which the pile capacities were extremely overestimated by EUROCODE 7-3 method.

196 A. MAHLER Predicted pile capacity [kn] 8 6 4 2 1 2 3 4 Measured pile capacity [kn] Fig. 3. EUROCODE 7-3 method Predicted pile capacity [kn] 8 6 4 2 1 2 3 4 Measured pile capacity [kn] Fig. 4. ERTC 3 method 6. Summary and Conclusion Four pile capacity methods were evaluated using CPT data for thirteen full scale axial pile load tests. The test piles were CFA piles with various geometry and were measured in various soil conditions. DIN 414, LCPC, EUROCODE 7-3 and ERTC 3 methods were used for pile capacity predictions. Although the number of performed tests is not enough for statistical analysis, the results of performed tests are summarized in the following table (Table8): In case of the EUROCODE 7-3 method the standard deviation and average estimated value are higher than the respective values of other methods. Nevertheless these differences are caused by the overestimation of pile capacities of some piles. Without these results the EUROCODE 7-3 method gives similarly reliable results for pile capacity.

CONE PENETRATION TEST 197 Table 8. Results of performed tests DIN 414 LCPC EC 7-3 ERTC 3 avg. value 116. % 119.1 % 142.3 % 12.1 % std. deviation 29.3 % 36.5 % 51.7 % 35.3 % It is necessary to note that the pile capacities were generally overestimated. To decide whether it is caused by the differing soil conditions or by differences in the pile installation process requires further studies. Nevertheless it is clear that these methods represent a useful tool in geotechnical design. References [1] BUSTAMANTE, M. GIANESELLI, L., Pile Bearing Capacity Prediction by Means of Static Penetrometer CPT. Proceedings of the 2nd European Symposium on Penetration Testing, ESOPT- II, Amsterdam, 2 (1982), pp. 493 5. [2] DE COCK, F. LEGRAND, C. ed. Design of Axially Loaded Piles, European Practice, 1997. [3] DE COCK, F. LEGRAND, C. LEHANE,B.ed.Survey Report on Design Methods for Axially Loaded Piles, European Practice, 1999. [4] EUROCODE 7: Geotechnical Design Part 3: Design Assisted by Fieldtesting; European Committee for Standardization, 1999. [5] DIN 414 Bohrpfähle Herstellung, Bemessung und Tragverhalten; Deutsche Institut für Normen, 199.

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