Piping Expansion Loop Design - Hand Calculation

PipingStress

3 Apr 202406:17

Summary

TLDRThis video guide provides an in-depth look at piping expansion loops, focusing on their design and optimization for high-temperature fluid systems. It highlights the importance of performing flexibility checks, especially for long pipe racks, and discusses how to manage excessive expansion through line stops or expansion loops. The video also explains how to calculate the size of an expansion loop and provides practical tips to ensure efficient and cost-effective designs. With considerations for branch connections and seismic loads, the guide offers valuable industry insights for engineers.

Takeaways

🛠️ Expansion loops are critical for managing thermal expansion in piping systems, especially for pipes on long racks transporting high-temperature fluids.
📏 A line stop should be placed at the center (zero expansion point) of the pipe to control expansion effectively.
🔍 Inspect the expansion distance at the end of the pipe racks to ensure the pipe shoes can handle thermal growth.
🔄 If expansion is excessive, consider designing an expansion loop to accommodate it.
🌿 Flexibility of branch connections should be evaluated, especially if the main line has significant expansion.
💰 Multiple branch connections can be costly, so using an expansion loop on the main line is often preferable.
🌍 Expansion loops can also account for occasional forces, including seismic loads, by distributing them along the rack.
📐 The largest expansion loop should be positioned outside the smaller loops to ensure optimal performance.
🧮 An equation is provided to calculate expansion loop dimensions based on factors like pipe diameter, length, and temperature differences.
🏗️ When space constraints exist, consider adding multiple expansion loops to reduce the overall height, which can be costly in terms of construction.

Q & A

What is the purpose of an expansion loop in a piping system?
-The purpose of an expansion loop is to accommodate thermal expansion in piping systems, especially for long pipes that transport high-temperature fluids. This prevents excessive stress and deformation in the pipes.
Why is it important to perform a flexibility check on long pipe racks?
-Flexibility checks are essential for long pipe racks to ensure that the pipes can accommodate thermal expansion without causing damage or excessive strain. This is particularly important for high-temperature fluid transport.
Where should a line stop be positioned in the piping system, and why?
-A line stop should be positioned at the center or the 'native zero point' of the line where the expansion is zero. This helps to control and prevent excessive expansion at the ends of the pipe racks.
How can you manage excessive expansion at the far end of a pipe rack?
-If the expansion at the far end of a pipe rack is excessive, you can either lengthen the pipe shoe to accommodate the expansion or design an expansion loop to handle the thermal growth effectively.
What should be considered when designing branch connections at the far end of the pipe rack?
-The flexibility of branch connections should be considered, especially if the main line's expansion is high. If needed, you may need to redesign the branch connections for better flexibility or add an expansion loop.
Why is it preferable to use an expansion loop on the main line instead of multiple branch connection loops?
-It is more cost-effective to use a single expansion loop on the main line, rather than installing multiple loops on each branch connection, which could be expensive.
How can seismic loads affect the design of an expansion loop?
-In cases where seismic loads are high on the stopper support, using an expansion loop can help divide the load and reduce stress on the piping system during seismic events.
Where should the largest expansion loop be located in relation to other loops in the system?
-The largest expansion loop should be located outside the other loops with less thermal growth to ensure optimal performance and load distribution.
What formula is used to calculate the size of an expansion loop, and what factors are considered?
-The formula for calculating the expansion loop size considers factors such as the pipe diameter, line length, operating temperature, and ambient temperature. These variables help determine the height and width of the expansion loop.
How can the height and width of an expansion loop be adjusted if the initial dimensions are impractical?
-If the calculated height or width of an expansion loop is too large, additional expansion loops can be added to reduce the height or width, ensuring that the loop fits within the available space and remains cost-effective.