Linear Thermal Pipeline Expansion – Liquid

Contents

Introduction

Buried pipe must include pre-existing operational stresses. These includes hoop, longitudinal stress due to thermal expansion. Outside force stress must be added to these stresses before any evaluations can be performed as in PLTB.

The thermal stress is difficult to estimate because of unknown installation temperature. It can be estimated from local climatic data.

Thermal Expansion – Linear

E=CL(T_1-T_2)

E=CL(T_1-T_2)

Where:
𝐸 − Elongation (in)
𝐶 − Coefficient of Linear Expansion (in/℉)
𝐿 − Length of pipe (ft)
𝑇₁ − 𝑇₂ = Temperature change (℉)

Material Coefficient:

Longitudinal Stress Due to Temperature Changes

S=EC(T_1-T_2)

S=EC(T_1-T_2)

Where:
𝑆 − Stress (psi)
𝐶 − Coefficient of Linear Expansion (in/℉)
𝐸 − Modulus of Elasticity (psi)
𝑇₁ − 𝑇₂ = Temperature change (℉)

Case Guide

Part 1: Create Case

Select the Linear Thermal Pipeline Expansion application from the Design & Stress Analysis Module
To create a new case, click the “Add Case” button
Enter Case Name, Location, Date and any necessary notes.
Fill out all required Parameters.
Make sure the values you are inputting are in the correct units.
Click the CALCULATE button to overview results.

Input Parameters

Pipe Length (ft)
Youngs Modulus of Elasticity (psi)
Coefficient of Linear Expansion (in/in°F)
Temperature Change (°F)

Part 2: Outputs/Reports

If you need to modify an input parameter, click the CALCULATE button after the change.
To SAVE, fill out all required case details then click the SAVE button.
To rename an existing file, click the SAVE As button. Provide all case info then click SAVE.
To generate a REPORT, click the REPORT button.
The user may export the Case/Report by clicking the Export to Excel icon.
To delete a case, click the DELETE icon near the top of the widget.

Results

Pipe Linear Elongation (in)
Longitudinal Stress due to Temperature Change (psi)

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

Restrained versus Unrestrained Pipe (Difference in Gas vs. Liquid)?

ASME B31.4 liquid and B31.8 gas codes include calculations for the net longitudinal compressive stress that must be applied only for a restrained line that equates to a low (less than 2%) longitudinal strain. This stress status is characteristic to underground pipelines located some distance away from above ground piping facilities.
Unrestrained lines means those above ground sections of piping without axial restraint as with buried pipe with soil. In others words the soil exerts substantial axial restraint, but not fully restrained. Check Out
What is the Maximum Span Length of rev1?

Regarding span factors with and without water are based on bending stress and deflection. Larger diameter pipe spans require saddles for stability. Many standards that require pipes to be filled with water are based on bending and shear stresses not to exceed 1,500 psi and a deflection between supports not exceed 0.1 inches. Check Out
What is the model used for Thrust at Blow-Off?

HUBPL uses the equation from the DOT Inspectors Handbook:
TF = 0.5042 * G*Q^2/(P*D^2)
Check Out

Updated on December 15, 2023

Tagged: Calculations Design & Stress - Liquid

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