The Tugu Dam is one of the National Strategic Projects located in Trenggalek, East Java. Dam construction is an old practice, so history of dam shows great innovations in engineering. The innovations are not only for foundation design, but for foundation failure repairing. In the conduit of the Tugu dam, there is displacement as far as 20 mm - 60 mm. The alternative foundation failure repairing is grouting. The purpose of this study is to identify problems in the foundation failure of Conduit Tugu Dam and to evaluate the effectiveness of grouting based on the lugeon value and displacement value in the simulation by software. The results of the investigation that obtained a colovial layer as deep as 15-28 (m) in the displacement. The Lugeon Value area by testing the water pressure is 3,54 – 104,13. After the grouting work is done and the water pressure test is carried out, the Lugeon value on the Check Hole is 1,01 – 4,95 so that the grouting effectiveness is 75% (good category). The results using sigma/w show that displacement without using grout is -0,394 (m) alternative 1 is -0,027 (m), alternative 2 is -0,051(m), alternative 3 is -0,034 (m) and alternative 4 is -0,026 (m).

displacement, effectiveness, Lugeon value, grouting

Arsyad, M.S., 2017, Modul Pengaturan Dan Konsepsi Keamanan Bendungan, Bandung: Pusat Pendidikan Dan Pelatihan Sumber Daya Air Dan Konstruksi.

Bowles, J.E., 1997, Foundation Analysis and Design International Student Edition Third Edition, New York: Mc Graw-Hill.

Bryson, L.S., R. Ortiz, dan J. Leandre, 2014, “Effects of a Grout Curtain on Hydraulic and Electrical Conductivity in a Laboratory-Scale Seepage Model”, Geo-Congress 2014 Technical Papers 234(Geo-Characterization and Modeling for Sustainability): 3233–42.

BSN, 2000, Tata Cara Pengontrolan Sungai Bag-1 (SNI 03-6456. 1-2000), Indonesia: Badan Standardisasi Nasional.

BSN, 2008a, Cara Uji Kelulusan Air Bertekanan Di Lapangan (SNI 2411-2008), Indonesia: Badan Standarisasi Nasional.

BSN, 2008b, Tata cara pencatatan dan identifikasi hasil pengeboran inti (SNI 2436:2008), Indonesia: Badan Standarisasi Nasional.

Budiyanto, Kadar, 2010, Pelaksanaan Grouting Bendungan Sangiran, Ngawi: Tim Pelaksanaan Boring dan Grouting Bendungan Sangiran Ngawi.

Das, Braja M., dan Khaled Sobhan, 2014, Principles of Geotechnical Engineering, Eighth Edition,SI. Stamford: Cengage Learning.

Dwiyanto, J.S., 2005, Hand Out Geoteknik, Bandung : Dep Pekerjaan Umum.

Ewert, Friedrich-Karl, dan Ulrich Hungsbrg, 2018, Rock Grouting at Dam Sites, frankfurt: Springer.

Fan, G., D. Zhong, F. Yan, dan P. Yue., 2016, “A hybrid fuzzy evaluation method for curtain grouting efficiency assessment based on an AHP method extended by D numbers, Expert Systems with Applications”, Expert Systems with Applications 44:289–303.

Mulyono, Joko, 2017, “Konsepsi Keamanan Bendungan.” Junal Infrastruktur 3:62–69.

Nurnawaty, Suhardiman, dan Ihwan, 2018, “Analisis Rembesan Pada Bendungan Tipe Urugan (Uji Simulasi Lab).” Jurnal Teknik Hidro 11(1):12–22.

Pearson, R., dan S. Money, M., 1977, “Improvement in the Lugeon or Packertest Permeability test.” Q. Jl Eng Geology1 10:221–39.

PUPR, 2015, Peraturan Menteri PUPR nomor 27/PRT/M/2015. Jakarta: JDIH Kementerian

Wahana TEKNIK SIPIL Vol. 27 No. 1 Juni 2022 1 - 14

PUPR.

PUPR, 2016, Petunjuk Teknis Pengujian Tanah, Jakarta: Direktorat Jenderal Bina Marga.

SDA, 2005, Pedoman Grouting Untuk Bendungan, Jakarta: Direktorat Jenderal Sumber Daya Air.

Skempton, A., dan D. Macdonald, 1955, “A Survey of Comparisons between Calculated and Observed Settlement of Structures on Clay”, Correlation of Calculated and Observed Stresses and Displacemen 318–37.

Sosrodarsono, Suyono, dan Kansaku Takeda, 1977, Bendungan Type Urugan (Edisi ke-2), Jakarta: PT. Pradndya Paramita.

Sudaryanto, Eddi, 2020, Laporan Konsultan Bulan Maret, Trenggalek: Tim Konsultan Bendungan Tugu Trenggalek.