Stainless Steel Tube Bundle For Heat Exchanger ASME SA213 / SA312 / SA249 /

Product Specification

A tube bundle is a critical component of a shell-and-tube heat exchanger, which is one of the most common types of heat exchangers used in industrial applications. The tube bundle consists of a series of tubes through which one fluid flows, while another fluid flows around the tubes (on the shell side) to facilitate heat transfer between the two fluids.

Components of a Tube Bundle:

Tubes:

The primary heat transfer surface.

Made from materials with high thermal conductivity, such as copper, stainless steel, titanium, or carbon steel, depending on the application.

Tubes can be straight or U-shaped, depending on the design.

Tube Sheets:

Flat plates that hold the tubes in place.

Tubes are either welded, expanded, or rolled into the tube sheets to create a leak-proof seal.

Tube sheets separate the shell-side and tube-side fluids.

Baffles:

Plates or rods that direct the flow of the shell-side fluid across the tube bundle.

Improve heat transfer efficiency by creating turbulence and preventing stagnant zones.

Common types include segmental, helical, and rod baffles.

Spacers or Support Plates:

Used to maintain the alignment and spacing of the tubes.

Prevent vibration and damage to the tubes during operation.

Tie Rods and Spacers:

Hold the baffles and tube bundle together.

Ensure structural integrity.

End Caps or Channels:

Located at the ends of the tube bundle.

Direct the tube-side fluid into and out of the tubes.

Design Considerations for Tube Bundles:

Tube Diameter and Thickness:

Smaller diameters increase heat transfer efficiency but may lead to higher pressure drops.

Thicker tubes are used for high-pressure applications.

Tube Layout:

Tubes can be arranged in triangular, square, or rotated square patterns.

Triangular layouts provide higher heat transfer efficiency, while square layouts are easier to clean.

Tube Length and Number:

Longer tubes increase the heat transfer area but may require more space.

The number of tubes depends on the required heat transfer rate and flow rates.

Material Selection:

Materials must be compatible with the fluids being processed to avoid corrosion or fouling.

Common materials include stainless steel, copper alloys, titanium, and nickel alloys.

Baffle Design:

Baffle spacing and type affect heat transfer efficiency and pressure drop.

Segmental baffles are the most common, but helical baffles can reduce pressure drop and vibration.

Thermal Expansion:

Differential thermal expansion between the tubes and the shell must be accounted for to avoid stress and failure.

U-tube or floating head designs are used to accommodate expansion.

Types of Tube Bundles:

Fixed Tube Sheet Bundle:

Tubes are fixed to the tube sheets at both ends.

Simple and cost-effective but cannot handle large temperature differences between the shell and tube sides.

U-Tube Bundle:

Tubes are bent into a U-shape, allowing for thermal expansion.

Suitable for applications with high temperature differences.

Floating Head Bundle:

One end of the tube bundle is free to move, accommodating thermal expansion.

Ideal for high-temperature and high-pressure applications.

Pull-Through Floating Head Bundle:

Similar to a floating head design but allows the entire tube bundle to be removed for maintenance.

Applications of Tube Bundles:

Power Plants: Condensing steam from turbines.

Oil and Gas: Heating or cooling hydrocarbons in refineries.

Chemical Processing: Heat exchange in reactors and distillation columns.

HVAC Systems: Chillers and condensers.

Food and Beverage: Pasteurization and sterilization processes.

Advantages of Tube Bundles:

High heat transfer efficiency.

Can handle high pressures and temperatures.

Durable and long-lasting with proper maintenance.

Suitable for a wide range of fluids and applications.

Disadvantages of Tube Bundles:

Large physical size and weight.

Higher initial cost compared to some other heat exchanger types.

Requires regular maintenance to prevent fouling and corrosion.

Maintenance and Troubleshooting:

Fouling:

Deposits on the tube surfaces reduce heat transfer efficiency.

Regular cleaning (mechanical or chemical) is required.

Corrosion:

Material selection and protective coatings can help prevent corrosion.

Inspect for pitting or cracking regularly.

Vibration:

Improper baffle spacing or flow rates can cause tube vibration and failure.

Ensure proper design and operation.