Ejecuta cualquier Skill en Manus
con un clic

Ejecuta cualquier Skill en Manus con un clic

structural-analysis

Perform real structural engineering calculations — beam deflection, stress analysis, buckling, safety factors. Uses numpy and scipy with built-in helper functions.

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Resumen

Perform real structural engineering calculations — beam deflection, stress analysis, buckling, safety factors. Uses numpy and scipy with built-in helper functions.

Comando de instalación

npx skills add https://github.com/00000star/AGI_engineering_forge --skill structural-analysis

Copia y pega este comando en Claude Code para instalar la habilidad

Fuente

00000star/AGI_engineering_forge

Estrellas0

Forks0

Actualizado26 de marzo de 2026, 19:32

SKILL.md

readonly

name	structural-analysis
description	Perform real structural engineering calculations — beam deflection, stress analysis, buckling, safety factors. Uses numpy and scipy with built-in helper functions.
metadata	{"openclaw":{"emoji":"🔩","requires":{"anyBins":["python3"]}}}

Structural Analysis Tool

Run structural engineering calculations with real physics.

Built-in Helper Functions

beam_deflection_simply_supported(F, L, E, I, x) — Point load deflection
beam_max_stress(M, c, I) — Maximum bending stress σ = Mc/I
safety_factor(strength, stress) — Factor of safety
euler_buckling(E, I, L, K) — Critical buckling load
moment_of_inertia_rect(b, h) — I = bh³/12
moment_of_inertia_circle(d) — I = πd⁴/64

Usage

python3 /workspace/bridge.py structural_analysis '
F = 5000  # 5kN load
L = 1.5   # 1.5m span
E = 200e9 # Steel
b, h = 0.04, 0.08  # 40x80mm beam
I = moment_of_inertia_rect(b, h)
delta = beam_deflection_simply_supported(F, L, E, I)
sigma = beam_max_stress(F*L/4, h/2, I)
sf = safety_factor(250e6, sigma)
print(f"Deflection: {delta*1000:.3f} mm")
print(f"Max stress: {sigma/1e6:.1f} MPa")
print(f"Safety factor: {sf:.2f}")
'

Always use SI units: meters, Newtons, Pascals. Always compute and report safety factors.

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Fuente

00000star

00000star/AGI_engineering_forge

Abrir repositorio de GitHub Ver repositorios del creador

Comando de instalación

Descarga

Ejecutar en Manus

Útil paraSOC

Ingenieros civilesArquitectura e ingeniería17-2051L4

name	structural-analysis
description	Perform real structural engineering calculations — beam deflection, stress analysis, buckling, safety factors. Uses numpy and scipy with built-in helper functions.
metadata	{"openclaw":{"emoji":"🔩","requires":{"anyBins":["python3"]}}}

Structural Analysis Tool

Run structural engineering calculations with real physics.

Built-in Helper Functions

beam_deflection_simply_supported(F, L, E, I, x) — Point load deflection
beam_max_stress(M, c, I) — Maximum bending stress σ = Mc/I
safety_factor(strength, stress) — Factor of safety
euler_buckling(E, I, L, K) — Critical buckling load
moment_of_inertia_rect(b, h) — I = bh³/12
moment_of_inertia_circle(d) — I = πd⁴/64

Usage

python3 /workspace/bridge.py structural_analysis '
F = 5000  # 5kN load
L = 1.5   # 1.5m span
E = 200e9 # Steel
b, h = 0.04, 0.08  # 40x80mm beam
I = moment_of_inertia_rect(b, h)
delta = beam_deflection_simply_supported(F, L, E, I)
sigma = beam_max_stress(F*L/4, h/2, I)
sf = safety_factor(250e6, sigma)
print(f"Deflection: {delta*1000:.3f} mm")
print(f"Max stress: {sigma/1e6:.1f} MPa")
print(f"Safety factor: {sf:.2f}")
'

Always use SI units: meters, Newtons, Pascals. Always compute and report safety factors.