1. Landslide-Faisal Fathani UGM

Gadjah Mada University Faculty Fa culty of Engineering Department of Civil and Environmental Engineering

Pengembangan Sistem Pemantau dan Peringatan Dini Bencana Sedimen dan Pemberdayaan Masyarakat dalam Menghadapi Bencana Teuku Faisal Fathani, Ph.D. E-mail: [email protected]

Kuliah Tamu  – Prodi Teknik Geofisika FT Unsyiah: 2 November 2013

Disaster cycle Preparation

Mitigation

Prevention

Emergency response

Rehabilitation

Reconstruction

Strategy and Road Map: Disaster Risk Reduction Improvement of SOCIETY RESILIENCE EDUCATION and TRAINING (Public education, Training, Evacuation drills)

Provision of appropriate COUNTERMESURES COUNTERMESURES and TECHNOLOGY (Prevention works & Early warning)

Provision of appropriate INFORMATION (Investigation, (Inve stigation, Hazard Area & Risk map)

Type of Disaster  Volcanic disaster Debris flow (laharic flow) Landslide Flood Earthquake & Tsunami Drought Dam failure, Forrest fire, Abrasion etc.

Landslide Disaster Development of Landslide Monitoring and Early Warning System

Peta Risiko Tanah Longsor Indonesia

500

1,000,000    R    A900,000    P    A800,000    P    R700,000    E    T 600,000    A    W    I 500,000    J    H400,000    A    L 300,000    M    U200,000    J 100,000

450 400

   N    A    I 350    D    A300    J    E250    K    H200    A    L150    M    U100    J 50 0

   H    T    R    T    T    A    H    A    N    I    L    A    A    U    A    T    R    E    R    A    A    N    A    C    A    T    B    G    R    I    M    R    A    A    G    A    T    A    N    B    T    B    U    L    E    G    T    A    A    A    N    A    E    S    E    R    I    A    W   W   R    T    A    E    E    S    W   A    I    J    T    T    E    J    A    S    A    A    W    J    E    M    M    A    W    U    U    L    A    S    S    U    L    S    U    S

PROVINSI

0

   T    H    R    T    A    N    T    H    A    I    A    A    U    T    R    A    A    A    T    L    A    R    G    M    N    A    T    R    G    R    B    A    N    I    T    A    A    N    A    B    E    T    U    L    B    E    K    A    T    T    A    A    A    E    S    A    I    Y    R    R    I    W   A    W    G    E    S    E    S    A    W   A    E    J    O    T    T    J    A    E    Y    A    A    W    J    W  .    A    M    A    M    L    I  .    U    L    U    U    D    S    U    S    S    S

PROVINSI

Local mass movement

Rapid local movements with localized impact (less than 10 ha) Debris slide

Palu-Sulawesi,, Feb 2009 Palu-Sulawesi

Debris fall

Creep inducing structural damages Slow local movement but with relatively larger impact area (more than 10 ha)

Long distance mass movement

Debris flow induced by Rainfall after Padang Earthquake of September 30, 2009, in Nagari Tanjung anjungsani, sani, Agam Regency Regency,, West Sumatra

Two villages were buried and more than 100 people died/ missing

Landslide (earth flows) induced by the earthquake of Sept 30, 2009 in Tandikek, Pariaman Regency, West Sumatra

Landslide (long distance rock fall) induced by the Earthquake

The deposited area exceeding the distance up to 1 km from the toe of slope

Site : Cikangkareng, Cianjur Regency, September 2009.

EQ induced landslide at Desa Serempah, Kecamatan Ketol, Kab.  Aceh Tengah Tengah : 12 damaged hous and 11 people died July 2013

Landslides in Banjarnegara

Landslide occurred (2006)

Monitoring site (2007)

The symptoms (cracks) at the upper slope (2006)

No monitoring activity

Landslide at Sijeruk Village Banjarnegara (5 January 2006)

1 occu oc curr rred ed at 03 03.0 .00 0 am 2 - 3 occurred at 05.00 am Resulting in 74 people died

Landslide fatalities

Stage of Development of Landslide Monitoring and Early Warning System Survey and field investigation on the geological and geotechnical condition, landslide controlling factors, and social-economic condition Design most adaptive and appropriate EWS Socialization and training for capacity development Install the EWS and provide consultation on the maintenance followed by a test and calibration to ensure the function and sustainability

First version of community-based landslide early warning technology (2007-2008)

First stage (2007)

Second version of landslide monitoring : Raingage

Extensometer and Tiltmeter with data logger

Central server in UGM

Initial setup 2007-2008

Outdoor unit of real-time monitoring equipment

IP Camera

Raingauge

Extensometer  Pore pressure sensor 

Fieldserver 

Outdoor unit of real-time monitoring equipment

IP Camera

Raingauge

Extensometer  Pore pressure sensor 

Fieldserver 

Indoor Unit of real-time monitoring equipment Display Monitor 

GPRS modem

Local server LINUX box

UPS with external battery

Digital Photogrammetry Altitude: 150m  – 300 m Effective Ground Coverage: 120m – 250m Camera: Nikon 10Mpixel With Lens Calibration Parameter Remote camera

Tools for aerial photogrammetry Quadcopters

Kite

Aerial photo, topography map and real-time monitoring

7 November 2007: 2007: Manual extensometer warned the community 4 hours before the landslide occur

Data on the Website

The results of measurement by extensometers, raingauge and pore water pressure sensor Extensometer P2 –P3 Extensometer P1 –P2

Extensometer P4 –P5

Extensometer P5 –P6 Pore water pressure

Flow of warning information and evacuation command for simple landslide EWS at village level Evacuation

Rain gage Head of Village Task Force Team

      

Satkorlak Satlak Satgas SAR Red cross Health center   Army-Police

Evacuation

  y    t    i   n     u   m   m   o   c    l   a   c   o    L

Other Monitoring Devices: - Incli Inclino nomet meter  er  - Tiltme iltmeter  ter  - Pore Porewa wate terr pres pressur sure e gage gage - Groundw Groundwater ater measurement measurement - GPS Monito Monitorin ring g

EM-1 : Manual Extensometer  EM-2 : Automatic Extensometer with paper recording EA-1 : Automatic Extensometer with data logger  EA-2 : Automatic underground underground Extensometer  EL-1 : Long-span Extensometer with data logger & telemetry

Network diagram of telemetric system for realtime monitoring and early warning of landslide

Newly developed devices for landslide monitoring on a network diagram of telemetric system

Installation of digital extensometer at a mining site

Web performance of Smart Grid showing the geographical position of the reported nodes

(2007-2013)

Myanmar  (2012)

South Kalimantan (2009) Palu (2012)

Pariaman (2012)

ICL (2007)

 Yogyakarta  Yogyakarta (2010)

South Sulawesi (2008)

Cianjur (2009) ICL (2009) Banjarnegara (2007) Karanganyar (2008)

Situbondo (2007)

UGM in cooperation with Ministry for the Development of Disadvantage Regions (KPDT) UGM in cooperation with National Agency for Disaster Management (BNPB) UGM in cooperation with Private Mining Company UGM in cooperation with Pertamina Geothermal Energy (2013)

Hydro-geotechnical Model Two cascading cascadi ng tank model reflecting geological feature and hydrological process in Banjarnegara Landslide

Result of Hidro-geotechnical Modeling

 

    o    B

 o

 Visco-plastic Model

ds dt 

1m

ds dt 

  B

  s   c  o    W

    α

 F v

 F 

W     s i  n  α  

W 

l 

shear zone  

W l  h z  α  P w F v 

h

 P w α σ 

 z 

: weight : depth of sliding mass : piezometric level : shear zone thickness  v = ηv    /z Viscous force : surface slope angle and shear zone slope : pore water pressure   − [c’  +  + (σ − pw ) tan φ’ ] –  v  = ma : viscous force

 

 l sin  cos    c'  l cos 2     p

t an '  m dv    v

Crack-3

Crack-2  

Crack-1

P4

11.7o

Wire 4-5

+

P5

-

Wire 5-6

Crack-2

+

-

P6  

16.6o

Crack-1

Block-1 Well

Crack-3

Result of Viscoplastic Modelling

Block-2

Block-3

350

0.25 Velocity

0.2    )    h    /   m0.15   m    (   y    t    i   c   o 0.1    l   e    V

300

Simulated Displacement

250    )   m

 Actual  Actual Displacement Displacement

200 150 100

0.05

50 0

0 1/1/08

4/1/08

7/1/08

10/1/08

1/1/09

  m    (    t   n   e   m   e   c   a    l   p   s    i    D

60

Early Warning Criteria

Scenario I

50

Scenario II

   )    h    /   m   m40    (   y    t    i   s   n 30   e    t   n    i    l    l   a 20    f   n    i   a   r

Scenario Scenar io III III Scenario IV C1 C2 C3

CL

10

0

 Y=-0.62X+31 0

10

20

30

40

SWI (mm)

Class 1 (C1) : <0.1 mm/hour Class 2 (C2) : 0.1 mm/hour < C2 < 0.4 mm/hour Class 3 (C2) : 0.4 mm/hour < C3

50

Numerical Model of Fast Landslide Movement 

Simulation for the motion of disrupted-type landslides



Sliding mass is assumed as an incompressible Newton’s viscous fluid



Governing equation of motion : Navier-Stokes equation



Resistance force along the sliding surface by Coulomb’s resistance criteria



The simulation was handled quasi-three-dimensionally for the problem of flow considering the distribution and thickness of sliding mass



It is possible to consider the seismic force input seismic waves (three components of sine wave, horizontal and vertical)

FUNDAMENTAL EQUATIONS Governing equation of motion of the incompressible viscous fluid by using Navier-Stokes equation :

 p     2u   F  x     Dt   x

(1)

 p        v   F  y  Dt   y

(2)

 p        2 w   F  z   z   Dt 

(3)

 Du

 Dv

 Dw

2

The equation of continuity of the incompressible fluid :

 u v w  div (  v )      0    x  y  z   

(4)

u, v >> w, u and v are uniform in a vertical direction direction and the inertial force of fluid particle is small, compared to t o the acceleration due to gravity.

 u u u     zx  p      u      g  x      x  z   t   x  y 

(5)

   zy  v v v   p 2       2 v      g  y     y  z   t   x  y 

(6)

2

2



 p     g z   0  z 

• As the resistance rule along the sliding surface: Coulomb’ Coulomb’s s criterion. • c  :  : cohesion at the sliding surface •   :  : angle of internal friction of the sliding surface u  M  (uM ) (v M )  H  2     g  z h  g  x h   2  M   g  z (hc  h t an ) t   x  y  x u 2  v 2  w2

 N  (uN ) (vN )  H  v 2     g  z h   g  y h   2  N   g  z  (hc  h t an ) t   x  y  y u 2  v 2  w2   M   N  h     t     x  y  

where

hc 

c   . g  z 

Bishamon Landslide 

Located in Hiyoshicho, Kagoshima Prefecture



Length : 350 m



Width : 150 m



Area : 6 ha



Volume : 1.0 x 10 5 m3



Resulting in 2 deaths, 3 injuries



Destruction of 2 residential houses, affecting 436 m of roadway and 2.3 ha of cultivated field



Primary cause of the sliding was a heavy rainfall.