Comparisons of rapid load test, dynamic load test and static load test on driven piles

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Comparisons of rapid load test, dynamic load test and static load test on driven piles Bamrungwong, C., Chaisukhang, J. & Janmonta, K. Department of Rural Roads, Thailand Kitiyodom, P. Geotechnical & Foundation Engineering Co., Ltd., Thailand Matsumoto, T. Kanazawa University, Japan Matsuzawa, K. International Association for Spring Hammer Rapid Load Test, Japan Youwai, S. King Mongkut s University of Technology Thonburi, Thailand Keywords: rapid load test, driven pile, load-displacement relation, case study ABSTRACT: Static load test (SLT) is usually used to obtain the bearing characteristics of a pile. However, it requires relatively high cost and testing period. In contrast, rapid load testing requires less cost and testing period. As one of rapid load test methods, Spring Hammer (SH, hereafter) rapid load test method has been developed in Japan. In this paper, validity of the SH test method with a simplified signal interpretation to estimate the static behaviour of a pile is discussed and demonstrated through comparison of the results from SLT and the SH test, as well as the results from dynamic load test (DLT). 1 INTRODUCTION In Thailand, static load test (SLT) or dynamic load test (DLT) is employed to obtain the bearing characteristics of a pile. Due to the lack of capable dynamic load test result interpreter, it is widely believed that static load test is the most reliable method to obtain the load-settlement behaviour of a pile. However, static load test requires high cost and testing period. Therefore, pile design has been mainly based on empirical equations and soil information from borehole investigation without any load test by adopting excessive design requirements, i.e. high factor of safety. In order to overcome the above situation, rapid load test methods have been proposed. As one of rapid load test methods, the Spring Hammer test (SH test) was developed in Japan (Matsumoto et al., ). Loading mechanism of the SH test is basically similar to Dynatest (Gonin & Leonard, 19) Statnamic test (Bermingham & Janes, 199) and Pseudo-static test (Schellingerhout & Revoort, 199). In the SH test method, the simple non-linear damping interpretation method (Matsumoto et al., 199) is usually used to derive static load-settlement curve. In this paper, in order to verify the applicability of the SH test in Thailand. SH tests were conducted on driven concrete piles at five DRR (Dept. of Rural Roads) bridge construction sites in Thailand. The validity of the SH test method to estimate the static behaviour of a pile is examined through comparison of the results from SLT, DLT and the SH test. SPRING HAMMER TEST METHOD Several SH test devices are available, although their loading mechanism and measuring system are the same in the devices. Figure 1 shows the loading system and the measurement system of the SH test. Figure shows a SH test device used in this work. A spring unit is mounted on the leader mast of pile driving rig to prevent deviations of the central axis of pile, spring unit and hammer. Maximum load capacity is 5 kn when using a hammer mass of 9.3 ton and a falling height of 1 m, which ensures confirmation of static pile capacity at least kn A load cell is placed on the pile top directly, on which the spring unit is placed. A hammer mass is dropped onto the spring unit to provide impact loading on the pile top. The acceleration at the pile top is measured using two accelerometers. The pile top displacement is measured by means of a laser or an optical displacement transducer. The dynamic signals are sampled at a sampling frequency greater than 1 khz. The output dynamic signals are recorded through a computerised data acquisition system. The recorded dynamic signals are promptly processed to derive static response of the pile using the Non-Linear Damping method. The spring unit consists of a number of coned disc springs. The total spring stiffness of the spring unit is easily controlled by changing arrangement of the coned disc springs. The maximum load and loading duration can be widely varied by changing combination of the spring stiffness, the hammer mass and the falling height of hammer. 795

F soil i F i M M i F rapid rapid i p M i s () where M is the sum of the pile mass and the additional soil mass, and (i) is the measured pile acceleration at time step i. The soil resistance, F soil, is the sum of the spring resistance (static resistance), F w, and the dashpot resistance, F v. F i F i F i F i C i v i soil w v w (3) Figure 1. Loading system and measurement system. Hammer where C(i) is the damping factor and v(i) is the pile velocity at time step i. At the first step (i = 1), the initial stiffness, K(1), is calculated by the initial static load, F w (1), divided by the initial displacement, w(1). K 1 Fw 1 w 1 Fstatic wstatic () Spring Unit Pile Figure. SH test device used in DRR construction sites. One of advantages of the rapid load test is that simplified interpretation methods, in which the pile is treated as a rigid mass neglecting wave propagation phenomena in the pile, could be used to derive a static load-displacement relation from the measured signals. Figure 3 shows the modelling of pile and soil during rapid pile load testing. The pile is assumed as a rigid mass having mass of M p, and the soil is modelled by a spring and a dashpot in parallel. This modelling has been advocated by Middendorp et al. (199) and Kusakabe & Matsumoto (1995). The additional soil mass beneath the end plate, M s, can be estimated as follows following Randolph & Deeks (199): At the next step (at step i+1), the soil spring, K(i+1) is assumed to be equal to K(i) as indicated by Eq. (5). Hence, the static resistance, F w (i+1), at step i+1 is calculated by Eq. (). The value of C(i+1) can be determined by means of Eq. (7). i K i i 1 Fw i K i 1 w i 1 i F i 1 F i 1 v i 1 K 1 (5) Fw w i () C (7) spring, K (F w ) 1 soil w F rapid Figure.3 Modelling of rapid load test. Pile mass, M p, with additional soil mass, M s dashpot, C (F v ) 3.1 M s D (1) s 1 where and s are Poisson's ratio and density of the soil, and D is the plate diameter. Figures and 5 show the notations used in the non-linear damping method. The applied load, F rapid, is equal to the sum of the soil resistance, F soil, and the inertias of the pile mass and the additional soil mass: Figure. Correction of inertia to obtain soil resistance. 79

Table 1. Properties of the piles. Site Allowable Site name Dimension No. pile capacity 1 Petchaburi..m 5 kn Lampang..m 5 kn 3 Chaiyapum..m 5 kn Pangnga..m 5 kn 5 Rayong.5.5m kn RESULTS OF PILE LOAD TESTS Figure 5. Non-Linear Damping interpretation. At the following step i+, C(i+) is assumed to be equal to C(i+1) as indicated by Eq. (). Therefore, the values of F w (i+) and K(i+) can be determined by means of Eqs. (9) and (1), respectively. i C i 1 w i Fsoil i 1 C i v i Fw i Fw i 1 i w i w i 1 C () F (9) K (1) By repeating the procedure from Eq. (5) to Eq. (1), the values of K and C for following steps are alternately updated consecutively. Finally, the whole static load-displacement relation, F w vs w, is constructed as shown in Figure 5. 3 TEST DESCRIPTION Figure shows the profiles of soil layers and SPT N-values at the five DRR bridge construction sites in Petchaburi, Lampang, Chaiyapum, Pangnga and Rayong, together with driven concrete piles. The driven concrete piles were used for the foundations of the bridges. Properties of the piles are summarised in Table 1. Three piles at each construction site were subjected to the dynamic load tests and the SH rapid load tests. The tests were conducted after a curing period of 1 days from the end of the pile driving. Load tests were carried out to confirm proof load ( times of allowable load). In addition, static load tests were carried out on one of the three piles at each site approximately 1 to months after the DLT and SH tests. Note that due to the site condition at Rayong site, static load test was not conducted on the same pile as the DLT and SH tests, but a SLT was carried out on the pile located in the next bridge abutment foundation about 1 m away from the pile which the DLT and SH tests were carried out..1 Results of SH tests in Pangnga site Figure 7 shows examples of dynamic signals from rapid load test on pile No. in Pangnga Site: (a) pile head force, (b) acceleration, (c) velocity and (d) displacement. The pile head velocity was obtained by integration of the measured acceleration with respect to time. The pile head displacement was obtained by double time integration of the measured acceleration. The loading duration, t L, was ms that corresponded to the relative loading duration T r = t L /(L/c) = 1, where L and c are the pile length and the wave propagation speed (c = m/s) in the RC driven pile, respectively. In the Method for Rapid Load Test of Single Pile by Japanese Geotechnical Society (), load test with T r greater than 5 is regarded as rapid loading where wave propagation phenomena in the pile can be neglected. Figure shows the measured F rapid vs w from 5 different hammer dropping heights varied from. to. m. Figure 9 shows the derived static loaddisplacement F w vs w, together with the static load-displacement obtained from SLT and DLT with wave matching analysis. It can be seen that there is good agreement between load test results.. Results of Load Tests in Other Sites Figures 1 to 13 show comparisons of loaddisplacement relations from SLT, DLT and SH tests in Chaiyapum, Petchaburi, Rayong and Lampang sites, respectively. Good agreement between load test results of Chaiyapum and Petchaburi sites are seen in the figures. In Rayong site although the SLT was carried out on different pile which DLT and SH tests were conducted, there is good agreement between load test results as shown in Figure 1. Good agreement between DLT and SH tests results of Lampang site is shown in Figure 13. However, SLT result shows a different trend. This is thought to be due to that the pile tip of the test pile during the static load test penetrated into the silty sand layer that have lower SPT N-value than the above sand layer. 797

Petchaburi SPT N-value 1 3 5 Lampang SPT N-value 1 3 5 Chaiyapum SPT N-value 1 3 5 Clayey sand Sandy clay Clayey sand Sandy clay Silty clay Sandy clay Sand 1 1 1 Silty sand End of Borehole 1 1 1 P1 P P3 1 1 1 Silty sand Sand Silty sand 1 1 1 P1 P P3 1 1 1 Sandy clay Sand stone 1 1 1 P1 P P3 1 1 1 1 1 1 Pangnga SPT N-value 1 3 5 Rayong SPT N-value 1 3 5 Top soil 1 Silty sand Sand 1 P1 P P3 1 Silty sand Clayey sand Sand 1 1 1 1 Rock 1 1 1 1 1 1 Sandy clay Clay 1 1 1 P1 P P3 Figure. Profiles of soil layers and SPT N-values in DRR bridge construction sites, together with pile lengths. Force (kn) 15 1 5 3 9 1 Time (ms) (a) Pile head force Acceleration (m/s ) 1-1 - 3 9 1 Time (ms) (b) Acceleration Velocity (m/s) 1..5. -.5 3 9 1 Time (ms) (c) Velocity Figure 7. Examples of measured dynamic signals. Displacement (mm) 1 3 9 1 Time (ms) (d) Displacement 79

F rapid (kn) 3 9 1 F w (kn) 5 1 15 Displacement (mm) 1 h =. m h =. m 3 h = 1. m Pangnga Pile No.1 h = 1. m 5 h =. m Displacement (mm) 1 h =. m h =. m 3 h = 1. m h = 1. m Petchaburi Pile No.1 SLT DLT Figure. Measured rapid load-displacement. Displacement (mm) F w (kn) 3 9 1 1 h =. m h =. m 3 h = 1. m h = 1. m 5 h =. m Pangnga Pile No.1 SLT DLT Figure 9. Comparisons of load-displacement relations from SLT, DLT and SH tests of Pangnga site. Displacement (mm) 1 F w (kn) 5 1 15 1 h =. m h =. m 3 h =. m h =. m 5 h = 1.5 m SLT DLT Chaiyapum Pile No. Figure 1. Comparisons of load-displacement relations from SLT, DLT and SH tests of Chaiyapum site. Figure 11. Comparisons of load-displacement relations from SLT, DLT and SH tests of Petchaburi site. Displacement (mm) 1 5 1 15 Pile No. 1 Pile No. Pile No. 3 SLT on Different Pile DLT on Pile No. 1 Rayong Site F w (kn) Figure 1. Comparisons of load-displacement relations from SLT, DLT and SH tests of Rayong site. Displacement (mm) F w (kn) 5 1 15 1 h =.5 m h = 1. m Lampang Pile No. SLT DLT Figure 13. Comparisons of load-displacement relations from SLT, DLT and SH tests of Lampang site. 799

5 CONCLUDING REMARKS The validity of the SH rapid load test was examined through comparisons of static, dynamic and rapid load tests on the RC driven piles. The RC driven piles were used for foundations of bridges in five construction sites. It was confirmed that all the piles in the five sites have the pile capacity greater than the required values. The case studies presented in this paper encourage the use of rapid pile load testing for construction and quality controls of the constructed piles in Thailand. REFERENCES Bermingham, P. and Janes, M. (199). An innovative approach to load testing of high capacity piles, Proc. of Int. Conf. on Piling and Deep Foundations, Stresa, Italy, pp.9-13. Gonin, H.G.C. and Leonard, M.S.M. (19). Theory and performance of a new dynamic method of pile testing, Proc. of nd Int. Conf. of Application of Stress-Wave Theory to Piles, Stockholm, Sweden, pp.3-1. Japanese Geotechnical Society (). Method for Rapid Load Test of Single Piles, JGS 115-, Standards of Japanese Geotechnical Society for Vertical Load Tests of Piles,. Kusakabe, O. and Matsumoto, T. (1995). Statnamic tests of Shonan test program with review of signal interpretation, Proc. of 1st Int. Statnamic Seminar, Vancouver, Canada, pp.113-1. Matsumoto, T., Tsuzuki, M. and Michi, Y. (199). Comparative study of static loading test and statnamic on a steel pipe pile driven in a soft rock, Proc. of 5th Int. Conf. and Exhibition on Piling and Deep Foundations, Bruges, Belgium, pp.531-537. Matsumoto, T., Wakisaka, T., Wang, F.W., Takeda, K. and Yabuuchi, N. (). Development of a rapid pile load test method using a falling mass attached with spring and damper, Proc. of 7th Int. Conf. on the Appl. of Stress-Wave Theory to Piles, Selangor, Malaysia,pp. 351-35. Middendorp, P., Bermingham, P. and Kuiper, B. (199). Statnamic loading testing of foundation piles, Proc. of 3rd Int. Conf. on Application of Stress-Wave Theory to Piles, The Hague, The Netherlands, pp.51-5. Randolph, M.F. and Deeks, A.J. (199). Dynamic and static soil models for axial pile response, Proc. of th Int. Conf. on Appl. of Stress-Wave Theory to Piles, The Hague, The Netherlands, 3-1. Schellingerhout, A.J.G., Revoort, E. (199). Pseudo static pile load tester, Proc. of 5th Int. Conf. on Application of Stress-Wave Theory to Piles, Orland, USA, pp.131-137.

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