Falling Weight Deflectometer, FWD, is the most popular equipment used to measure the deflection of  flexible pavement in Indonesia. The loading used during application of the FWD equipment generally correlates directly with those of the loads of standard heavy vehicles. Therefore, the resulted pavement deflections obtained from the tests should be also suitable for highways traversed by standard normal vehicles only. This may not be the case for highways in Indonesia, where most trucks are highly overloaded, so much beyond the allowable standard loads. The existing method of FWD test may not be representative anymore to measure the actual pavement deflections under highly overloaded vehicles. In this paper, the authors describe their findings about deflections of flexible pavement when the pavements were subjected by heavily overloaded vehicles. The first step is to modify the FWD equipment with larger falling distances and heavier loads to simulate the highly overloaded vehicles in Indonesia. Based on the results and by using statistical approach, a new mathematical equation can be derived to reflect the functions of actual pavement deflections under much higher loads when compared to those of standard normal load. Therefore, using this new equation one can predict the actual pavement deflection under highly overloaded vehicles, by just performing standard FWD test of standard loads on the pavement, so that the design of overlay thickness can be modified accordingly to be applicable to overloaded traffic in Indonesia.

pavement deflection; falling weight deflectometer; FWD; pavement overlay; overloaded heavy vehicles

Departemen Pekerjaan Umum (2005), Indonesian Dept. of Public Work, Highway Division. “Pedoman Perencanaan Tebal Lapis Tambah Perkerasan Lentur Dengan Metode Lendutan (Pd T-05-2005-B)” (“Guidance of Designing of pavement Overlay Using Deflection Method”), Direktorat Jenderal Bina Marga.

AASHTO, (1993), AASHTO Guide for Design of Pavement Structures, American Association of State Highway and Transportation Officials, Washington, D.C.

Asphalt Institute (1981). Thickness Design, Asphalt Pavement Structure for Highway and Streets (MS-1): College Park, Maryland 20740,USA.

FHWA (U.S. Federal Highway Administration) (2003). Distress Identification Manual for the Long-Term Pavement Performance Program. Publication: No. FHWA-RD-03-031, Washington D.C.

Huang, Y.H. (2004). Pavement Analysis and Design. Pearson Prentice Hall, Upper Saddle River, NJ.

Kosasih, D. (2003). The Effects of Pavement Structure Modeling and Deflection Bowl Analysis on Calculated Layer Moduli. Journal of the Eastern Asie Society for Transportation Studies. Vol 5: 927-939.

Shell International Petroleum Company (1978). Shell Pavement Design Manual:Asphalt Pavements and Overlay for Road Traffic. Shell International Petroleum Co.: London.

Sutikno, Sentot dan Mochtar, IB, (1991), “Studi Lapangan Tentang Pengaruh Beban Gandar dan Temperatur Terhadap Lendutan Perkerasan Jalan Tol Surabaya-Gempol” (“Field Study on the Effects of Axle Loads and Temperature Against the Deflections of Pavement of the Surabaya-Gempol Toll Road”), Tugas Akhir S-1 ITS. Jurusan Teknik Sipil, FTSP-ITS, Surabaya. (Final Project Report, Dept. of Civil Engineering, ITS, Surabaya).

Prastyanto, C, A,. et. al. (2012), “Perencanaan Jalan Akses Pabrik Semen Tuban” (“Design of Access Road of Tuban Cement Factory”), Design Report, PT. Semen Gresik, Tuban, Jawa Timur.

Danida dan Pusat Litbang Jalan (1990). Study of Improved Bearing Capacity Evaluation and Strengthenen Design of Road. Technical Report No. 2. FWD Calibration, Bandung: Puslitbang P.U.

Dynatest FWD/HWD Test Systems, (2008), “Owner’s Manual Version 2.4.2”, Dynatest International A/S.