Analysis Slope Stability dengan Plaxis 8.x

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ANALYSIS SLOPE STABILITY Site ID : Site Name : I. Data Boring LOG

Analysis Slope Stability dengan Plaxis 8.x

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II. Nilai- Nilai Parameter Tanah

Parameter Humus Berpasir Lempung Material Model Mohr-coulomb Mohr-coulomb Type of Material Undrained drained Dry soil weight γd 16 16 Wet soil weight γs 18 20 Permeability in hor. direction Kx 1 1 Permeability in ver. direction Ky 1 1 Young’s modulus E 9000 15000 Poisson’s ratio v 0.3 0.3 Cohesion (constant) C 1 10 Friction Angel Φ 30 30 Dilatancy angel ψ 0 0

III. Analisis Pembebanan

Tower Beban Tower = 50 kN

IV. Analisis Kelongsoran dengan Aplikasi Plaxis v.8.2

A. Plaxis Input

Gambar 1. Geometri Lereng

Analysis Slope Stability dengan Plaxis 8.x

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IV.1. Tahap Gravity Loading Tahap awal dari analysis digunakan untuk menghitung tegangan-tegangan awal akibat berat sendiri massa tanah dan tegangan horosontal.

Fase 1: Gravity Loading Calculation type: plascic

Start from phase: 0 – initial phase Parameter:

- Additional step = 100 - Ignore undrained behaviour - Delete intermediate steps - Loading input: total multipliers Multipliers:

Σ Mweight_= 1 (maksudnya tegangan tanah terjadi dari berat sendiri tanah sendiri sehingga factor pengali beratnya = 1).

IV.2. Tahap Safety Factor akibat Gravity Loading

Untuk mencari factor aman sebelum ada beban pondasi.

Fase 2: SF gravity loading Calculation type: Phi-c reduction

Start from phase: 1 – Gravity Loading Parameter:

- Additional step = 100 - Loading input: increment multipliers Multipliers:

Σ MSF_= 0.1 IV.3. Tahap Beban Pondasi

Fase 3: beban pondasi Calculation type: Plastic

Start from phase: 2 – Safety Factor akibat Gravity Loading Parameter:

- Additional step = 100 - Loading input: staged construction - Reset displacement to Zero - Delete intermediate steps

IV.4. Tahap Beban Luar Fase 4: beban luar Calculation type: Plastic

Start from phase: 3 – beban pondasi Parameter:

- Additional step = 100 - Delete intermediate steps - Loading input: total multipliers

Multipliers: Σ Mload A_= 50 kN

Analysis Slope Stability dengan Plaxis 8.x

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IV.5. Tahap SF Pondasi dan Beban Tower Fase 5: SF Pondasi dan Beban Tower Calculation type: Phi-c reduction

Start from phase: 4 – beban luar Parameter:

- Additional step = 100 - Loading input: increment multipliers

Multipliers: Σ MSF_= 0.1

Analysis Slope Stability dengan Plaxis 8.x

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B. Plaxis Input 1. Tahap Gravity Loading

Pada tahap ini menunjukkan hasil bahwa dengan berat sendiri tanah, pada lereng mengalami pergerakan sebesar 165.07E10-3 m.

Gambar 2. Lereng terdeformasi akibat Gravity Loading

Gambar 3. arah gerakan tanah dan penurunan akibat gravity Loading

Analysis Slope Stability dengan Plaxis 8.x

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2. Tahap Vertical Loading

Pada tahap ini tanah menerima beban yang dimodelkan sebagai beban merata (tractions). Tanah mengalami deformasi yaitu sebesar 285.57E10-3m.

Gambar 4. Lereng terdeformasi akibat Vertical Loading

Gambar 5. arah gerakan tanah dan penurunan akibat Vertical Loading

Analysis Slope Stability dengan Plaxis 8.x

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Gambar 6. arah gerakan tanah dan penurunan akibat Vertical Loading (shading model)

Analysis Slope Stability dengan Plaxis 8.x

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PLAXIS CURVE V.8 Angka keamanan akibat Beban Pondasi dan Tower: Dari Kurva diketahui bahwa SF akibat gravity loading dan beban Pondasi dan tower adalah1.352. Angka ini lebih kecil dibandingkan dengan SF minimal untuk keruntuhan yaitu 1.5 Sehingga disimpulkan bahwa lereng tidak aman jika gravity dan Beban pondasi dan tower bekerja maksimal. V. Kesimpulan

Lereng tidak aman dan dibutuhkan retaining wall untuk stabilitas lereng.

Analysis Slope Stability dengan Plaxis 8.x

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displacement vector (¦u¦) ΣMstage the ΣMstage parameter is associated with the Staged construction option in PLAXIS (see Staged construction). This total multiplier gives the proportion of a construction stage that has been completed. Without input from the user, the value of ΣMstage is always zero at the start of a staged construction analysis and at the end it will generally be 1.0. It is possible to specify a lower ultimate level of ΣMstage using the Advanced option of the Parameters tab sheet. However, care should be taken with this option. In calculations where the loading input is not specified as Staged construction, the value of ΣMstage remains zero. ΣMarea The ΣMarea parameter is also associated with the Staged construction option. This parameter gives the proportion of the total volume of soil clusters in the geometry model that is currently active. If all soil clusters are active then ΣMarea has a value of 1.0. Stiffness As a structure is loaded and plasticity develops then the overall stiffness of the structure will decrease. The Stiffness parameter gives an indication of the loss of stiffness that occurs due to material plasticity. The parameter is a single number that is 1.0 when the structure is fully elastic and reduces in magnitude as plasticity develops. At failure the value is approximately zero. It is possible for this parameter to have negative values if softening occurs. Pmax The Pmax parameter is associated with undrained material behaviour and represents the maximum absolute excess pore pressure in the mesh, expressed in the unit of stress. During undrained loading in a plastic calculation Pmax generally increases, whereas Pmax generally decreases during a consolidation analysis. Stresses σ'xx effective horizontal stress (x-direction) σ 'yy effective vertical stress (y-direction) σ 'zz effective stress in the out-of-plane direction (z-direction) σ xy shear stress σ '1 in absolute sense the largest effective principal stress σ '2 the intermediate effective principal stress σ '3 in absolute sense the smallest effective principal stress p' isotropic effective stress (mean effective stress) q deviatoric stress (equivalent shear stress) p excess excess pore pressure See the Scientific Manual for a definition of the stress and strain components. The phrase 'in absolute sense' in the description of the principal components is added because, in general, the normal stress and strain components are negative (compression is negative). Note that the deviatoric stress and strain components are always positive. Stress components are expressed in the units of stress; strains are dimensionless.

Analysis Slope Stability dengan Plaxis 8.x

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Memulai Plaxis 8.x Program > Plaxis 8.x > 1. Plaxis Input

Pilih New Project > OK

Analysis Slope Stability dengan Plaxis 8.x

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General Setting Isi Title, Contoh: Slope Stability

Setting Units, Geometry Dimensions atau ukuran lembar kerja dan Grid, Pilih OK

Analysis Slope Stability dengan Plaxis 8.x

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Pemodelan Pilih Geometry line, (tool yang diberi kotak)

Gambarkan Geometrynya sesuai dengan kondisi lapangan.

Analysis Slope Stability dengan Plaxis 8.x

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Jika lereng masih dalam kondisi existing. Setelah pemodelan, Pilih Loads > Standard Fixities

Maka akan seperti gambar dibawah ini:

Kemudian Pilih Material Sets

Analysis Slope Stability dengan Plaxis 8.x

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Isi Data Tanah sesuai dengan data hasil pengujian tanah.

Pilih Contoh tanah yang mendekati keadaan sebenarnya Pindahkan Kekotak sebelah kiri

Pilih Edit

Analysis Slope Stability dengan Plaxis 8.x

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Analysis Slope Stability dengan Plaxis 8.x

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Setelah selesai Klik sambil ditahan lalu pindahkan ke gambar tempat tanah tersebut,

Klik sambil ditahan

Lepas disini

Analysis Slope Stability dengan Plaxis 8.x

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Langkah selanjutnya adalah Pilih Generete Mest seperti gambar dibawah ini:

Hasilnya akan seperti gambar dibawah ini:

Pilih Update

Pilih Initial condition

Isi berat jenis air > OK

Analysis Slope Stability dengan Plaxis 8.x

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Langkah selanjutnya adalah: Pilih Calculate

Analysis Slope Stability dengan Plaxis 8.x

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Tahap Gravity Loading Tahap awal dari analysis digunakan untuk menghitung tegangan-tegangan awal akibat berat sendiri massa tanah dan tegangan horosontal.

Fase 1: Gravity Loading Calculation type: plascic

Start from phase: 0 – initial phase Parameter:

- Additional step = 100 - Ignore undrained behaviour - Delete intermediate steps - Loading input: total multipliers Multipliers:

Σ Mweight_= 1 (maksudnya tegangan tanah terjadi dari berat sendiri tanah sendiri sehingga factor pengali beratnya = 1).

Analysis Slope Stability dengan Plaxis 8.x

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Analysis Slope Stability dengan Plaxis 8.x

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Tahap Safety Factor akibat Gravity Loading Untuk mencari factor aman sebelum ada beban pondasi.

Fase 2: SF gravity loading Calculation type: Phi-c reduction

Start from phase: 1 – Gravity Loading Parameter:

- Additional step = 100 - Loading input: increment multipliers Multipliers:

Σ MSF_= 0.1

Analysis Slope Stability dengan Plaxis 8.x

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Analysis Slope Stability dengan Plaxis 8.x

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Pilih Project yang akan dibuka, *.DTA > Open

Hasilnya adalah sebagai berikut:

Analysis Slope Stability dengan Plaxis 8.x

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Untuk melihat model tampilannya. Pilih Deformations > Total displacements Atau yang lainnya.