Skills Guide

Ingénierie géotechnique offshore

VérifiéSûr

Expertise en planification d'analyses géotechniques offshore : classification des sols (USCS, CPT), choix des méthodes de conception des fondations, calcul de capacité des pieux et ancres, stabilité au fond et prédiction d'affouillement. Aide les ingénieurs à sélectionner les méthodes et normes adaptées (API, DNV, ISO) pour le dimensionnement d'éléments géotechniques et la dérivation de paramètres à partir de données CPT ou de sondages.

Spar Skills Guide Bot
Data & IAIntermédiaire
6002/06/2026
Claude Code
#geotechnical#soil#foundation#pile#anchor

Recommandé pour

Claude CodeData scientistData & analyse

Notre avis

Fournit une expertise de domaine pour la planification d'analyses géotechniques offshore, incluant la classification des sols, la sélection de méthodes de conception de fondations et des tables de référence des paramètres.

Points forts

  • Tables de référence complètes pour la classification des sols USCS et CPT
  • Arbres de décision pour la capacité portante, la capacité des pieux et le choix du type d'ancre
  • Cartographie des normes reliant les sections des standards aux sujets

Limites

  • Couvre uniquement les applications offshore
  • N'inclut pas d'algorithmes de calcul détaillés
  • Peut simplifier à l'excès des conditions spécifiques au site
Quand l'utiliser

À utiliser lors de la planification de campagnes d'analyses géotechniques ou du choix de méthodes de conception de fondations pour des structures offshore.

Quand l'éviter

Ne pas utiliser pour des projets géotechniques terrestres ou lorsque une modélisation numérique détaillée spécifique au site est nécessaire.

Analyse de sécurité

Sûr
Score qualité92/100

This skill is purely informational, providing reference tables, decision trees, and standard mappings for geotechnical engineering. It contains no executable code, system calls, network requests, or instructions that could compromise security. There is no risk of destructive or exfiltrating actions.

Aucun point d'attention détecté

Exemples

Classify soil using CPT data
Using the Robertson CPT classification table, what soil type corresponds to an Ic value of 2.8?
Select anchor type for soft clay
For a soft clay seabed and vertical load direction, recommend an anchor type with standard reference.
Calculate pile shaft friction in clay
Using the alpha method from API RP 2GEO, calculate the unit shaft friction for a pile in clay with su=30 kPa and effective overburden stress of 50 kPa.

name: geotechnical-engineering version: "1.0.0" updated: 2026-02-26 category: engineering/marine-offshore description: | Domain expertise for offshore geotechnical analysis planning — soil classification, foundation design method selection, pile/anchor capacity, on-bottom stability, and scour prediction. tags: [geotechnical, soil, foundation, pile, anchor, scour, offshore] platforms: [linux, macos, windows] invocation: geotechnical-engineering depends_on: [] requires: [] see_also:

  • mooring-analysis
  • structural-analysis
  • marine-offshore-engineering

Geotechnical Engineering Skill

Offshore geotechnical analysis domain expertise for planning soil investigations, selecting foundation design methods, and sizing geotechnical elements (piles, anchors, mudmats, scour protection).

When to Use This Skill

  • Planning a geotechnical analysis campaign
  • Selecting bearing capacity or pile capacity methods
  • Choosing anchor type for given soil and loading conditions
  • Reviewing soil parameter derivation from CPT or borehole data
  • Mapping standards coverage for geotechnical calculations

Soil Classification Systems

USCS (Unified Soil Classification System)

| Symbol | Description | Typical su (kPa) | Typical φ' (°) | |--------|-------------|-------------------|-----------------| | CH | Fat clay | 20–200 | — | | CL | Lean clay | 10–100 | — | | ML | Silt | 5–50 | 25–30 | | SM | Silty sand | — | 28–34 | | SP | Poorly graded sand | — | 30–36 | | SW | Well graded sand | — | 33–40 | | GP | Poorly graded gravel | — | 35–42 |

Robertson CPT Classification (1990/2009)

| Zone | Ic Range | Soil Behaviour Type | |------|----------|---------------------| | 1 | — | Sensitive fine grained | | 2 | > 3.60 | Organic soils / peat | | 3 | 2.95–3.60 | Clays (clay to silty clay) | | 4 | 2.60–2.95 | Silt mixtures | | 5 | 2.05–2.60 | Sand mixtures | | 6 | 1.31–2.05 | Sands (clean to silty) | | 7 | < 1.31 | Gravelly sand to dense sand |

Method Selection Decision Tree

Bearing Capacity

Undrained (clay)?
  ├── Yes → Brinch Hansen general formula (DNV-RP-C212 Sec 5)
  │         Nc = 5.14 for strip, shape/depth/inclination factors
  └── No (sand) → Terzaghi/Meyerhof drained bearing capacity
                   Nq, Nγ from friction angle

Pile Capacity

Soil type?
  ├── Clay → Alpha method (API RP 2GEO Sec 6.4)
  │          f = α × su; α from su/σ'v ratio
  ├── Sand → Beta method (API RP 2GEO Sec 6.5)
  │          f = K × σ'v × tan(δ); K from Table 6.5.3-1
  └── Layered → Sum unit shaft resistance per layer

Anchor Type Selection

| Soil Type | Load Direction | Recommended Anchor | Standard | |-----------|---------------|-------------------|----------| | Soft clay | Catenary | Drag (Stevpris/Vryhof) | DNVGL-RP-E301 | | Soft clay | Vertical/taut | Suction caisson | DNV-RP-E303 | | Stiff clay | Catenary | Drag (high capacity) | DNVGL-RP-E301 | | Sand | Catenary | Drag anchor | DNVGL-RP-E301 | | Any | Vertical (TLP) | Suction/driven pile | API RP 2GEO | | Deep water | Taut leg | Torpedo/SEPLA | project-specific |

Typical Parameter Ranges

| Parameter | Symbol | Soft Clay | Stiff Clay | Sand | |-----------|--------|-----------|------------|------| | Undrained shear strength | su | 5–25 kPa | 50–250 kPa | — | | Friction angle | φ' | — | — | 28–40° | | Submerged unit weight | γ' | 4–7 kN/m³ | 7–10 kN/m³ | 8–11 kN/m³ | | OCR | OCR | 1–3 | 3–20 | 1–5 | | CPT cone factor | Nkt | 10–18 | 15–25 | — | | su/σ'v (NC clay) | — | 0.20–0.30 | — | — |

Standard Reference Map

| Standard | Key Sections | Topic | |----------|-------------|-------| | API RP 2GEO | Sec 6 (piles), Sec 8 (foundations) | Pile + foundation design | | DNV-RP-C212 | Sec 5 (bearing), Sec 6 (piles) | Soil mechanics | | DNV-RP-E303 | Sec 4–7 | Suction anchor capacity | | DNVGL-RP-E301 | Sec 3–5 | Drag/fluke anchor design | | DNV-RP-F109 | Sec 3 | Pipeline on-bottom stability | | DNV-RP-F107 | Sec 5 | Scour assessment | | ISO 19901-4 | Sec 7–10 | Foundation design | | API RP 2SK | Sec 6 | Mooring anchor requirements |

Module Import Paths

from digitalmodel.geotechnical.soil_models import SoilProfile, SoilLayer
from digitalmodel.geotechnical.piles import PileCapacityAnalysis
from digitalmodel.geotechnical.foundations import ShallowFoundation
from digitalmodel.geotechnical.anchors import AnchorCapacity
from digitalmodel.geotechnical.on_bottom_stability import OnBottomStability
from digitalmodel.geotechnical.scour import ScourPrediction

Related Skills

  • mooring-analysis — mooring system design consuming anchor capacity
  • structural-analysis — structural loads feeding foundation design
  • marine-offshore-engineering — general offshore engineering context

Version History

| Version | Date | Changes | |---------|------|---------| | 1.0.0 | 2026-02-26 | Initial skill — method selection, parameter ranges, standards map |

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