Pipe Anchor Force Analysis – Liquid

Introduction

The following analysis determines stresses and deflections in pipelines at the transition from below ground (restrained) to above ground (unrestrained) to determine if an anchor is required for above ground pig traps or other piping facilities.

Internal pressure, temperature change, flexibility of to absorb a degree of lateral anchor movement is not considered in this calculation.

Tensile stress due to Poisson effect:

S_{poisson}=\vartheta S_H[psi]\,\,\,\,\,S_H=\frac{Pd}{2t}[psi]

S_{poisson}=\vartheta S_H[psi]\,\,\,\,\,S_H=\frac{Pd}{2t}[psi]

Where:
𝜗 − Poisson′s Ratio = 0.3
𝑃 − Design Pressure (psig)
𝑑 − Inside pipe diameter (in)
𝑡 − Pipe wall thickness (in)

Compressive stress due to temperature change:

S_{Temp}=E\alpha\triangle T\,[psi]

S_{Temp}=E\alpha\triangle T\,[psi]

Where:
𝐸 − Young′s Mosulus of Elasticity 𝐸 = 29×10⁶
𝛼 − Coefficient of Thermal Expansion for steel α = 6.5×10⁻⁶ (in/in℉)
Δ𝑇 = 𝑇_𝑜 − 𝑇_𝑖
𝑇_𝑜 − Operating Temperature (℉)
𝑇_𝑖 − Installation Temperature (℉)

Net longitudinal stress at beginning point (A) of the transition:

S_A=S_{Poisson}-S_{Temp} [psi]\,The\,strain\,will\,be\,\varepsilon=0,\,fully\,restrained

S_A=S_{Poisson}-S_{Temp} [psi]\,The\,strain\,will\,be\,\varepsilon=0,\,fully\,restrained

Net longitudinal stress at end point (B) of the transition:

S_B=\frac{S_H}{2}\,[psi]

S_B=\frac{S_H}{2}\,[psi]

Net strain at point (B), will be:

\varepsilon_B=\alpha\triangle T+\frac{S_H}{E}(\frac{1}{2}-\vartheta).[in/in]

\varepsilon_B=\alpha\triangle T+\frac{S_H}{E}(\frac{1}{2}-\vartheta)\.[in/in]

Soil resistance force based on Wilbur’s formula for average soil:

F_S=80(\frac{D}{12})\,[lbf/ft],\,where

F_S=80(\frac{D}{12})\,[lbf/ft],\,where

𝐷 − Outside pipe diameter (in)

Length of transition zone:

L=\frac{A(S_B-S_A)}{F_S}\,[ft].\,where \~\A=\pi(D-t)t

L=\frac{A(S_B-S_A)}{F_S}\,[ft].\,where \\~\\A=\pi(D-t)t

𝐴 − Pipe metal area (in²)

Total pipe movement at point (B) will be:

\delta=\frac{\varepsilon_B}{2}12L\,[in]

\delta=\frac{\varepsilon_B}{2}12L\,[in]

Anchor force:

F=(S_B-S_A)A\,\,\,[lbf]

F=(S_B-S_A)A\,\,\,[lbf]

Case Guide

Part 1: Create Case

Input Parameters

• Nominal Pipe Size (in):(0.625” – 48”)
• Wall Thickness (in):(0.068”- >2”)
• Pipe grade: (24000psi-80000psi) (if unknown use Grade A 24000)
• Design Pressure (psig)
• Operating Temperature: (-70°F – 160°F)
• Young’s Modulus of Elasticity: (29000000psi – 30000000psi)
• Poisson’s Ratio: (0.0 – 0.5)
• Thermal Expansion Coefficient (1/°F) : (0.0000022in/inF – 0.000012in/inF)
• Installation Temperature: (-70°F – 160°F)

Part 2: Outputs/Reports

Results

• Hoop Stress (psi)
• Compressive Stress Due to Temperature Change (psi)
• Net Longitudinal Stress at Point A (psi)
• Net Longitudinal Stress at Point B (psi)
• Net Longitudinal Stress at Point B (in/in)
• Soil Resistance (lbf/ft)
• Length of the Transition Zone A-B (ft)
• Total Pipe Moment at Point B (in)
• Anchor Force (lbs)

References

• ASME B31.8 – Gas Transmission and Distribution Piping Systems
• API 5L, API 5LS and API 5LX – Specification of Pipe Grade
• ASTM – Various – Weld Joint Factor
• CFR Code Part 192
• MMS Regulations
• USDA-SCS Modified (Permissible Velocity of Water and Soil Erodibility)
• FHWA-HEC
• Pipeline Rules of Thumb Handbook

FAQ