ASTM A213 TP316L Longitudinal Welding Finned Tube For Heat
Exchanger and Boiler
A Longitudinal Welding Finned Tube is a specialized type of heat
transfer tube designed to enhance heat exchange efficiency by
increasing the surface area available for heat transfer. These
tubes are constructed by welding fins longitudinally (along the
length) onto the outer surface of a base tube. The fins create
additional surface area, which improves the heat transfer
capabilities of the tube, making it ideal for applications where
efficient thermal exchange is critical.
Key Features of Longitudinal Welding Finned Tubes:
1. Construction:
Base Tube: Typically made from materials like carbon steel,
stainless steel, or alloys (e.g., ASTM A213 TP316L).
Fins: Made from strips of metal (often the same material as the
base tube) that are welded longitudinally along the tube's outer
surface.
Welding Method: The fins are welded using high-frequency welding or
other advanced techniques to ensure a strong bond between the fins
and the base tube.
2. Design:
The fins are aligned parallel to the tube's axis, running along its
length.
The height, thickness, and spacing of the fins can be customized
based on the application's heat transfer requirements.
3. Materials:
Common materials for the base tube and fins include:
Carbon steel
Stainless steel (e.g., 304, 316, 316L)
Copper-nickel alloys
Titanium
Other corrosion-resistant alloys.
4. Advantages:
- Increased Surface Area: The fins significantly increase the surface area of the tube,
improving heat transfer efficiency.
- High Strength: The welded fins provide mechanical strength and durability.
- Corrosion Resistance: When made from materials like stainless steel or alloys, these
tubes offer excellent resistance to corrosion.
- Customizability: The fin height, thickness, and spacing can be tailored to meet
specific thermal performance requirements.
ASTM A213 TP316L Longitudinal Welding Finned Tube is a specialized
type of heat transfer tube designed for applications requiring
enhanced surface area and superior corrosion resistance. It is made
from TP316L stainless steel, a low-carbon variant of 316 stainless
steel, and features longitudinal welding fins that increase the
tube's surface area, improving heat transfer efficiency. These
tubes are manufactured in accordance with the ASTM A213 standard,
which specifies seamless ferritic and austenitic alloy-steel tubes
for boilers, superheaters, and heat exchangers.
Material Composition of ASTM A213 TP316:
| Element | Composition (%) |
| Carbon (C) | 0.08% max |
| Manganese (Mn) | 2.00% max |
| Phosphorus (P) | 0.045% max |
| Sulfur (S) | 0.030% max |
| Silicon (Si) | 1.00% max |
| Chromium (Cr) | 16.0% - 18.0% |
| Nickel (Ni) | 10.0% - 14.0% |
| Molybdenum (Mo) | 2.00% - 3.00% |
| Nitrogen (N) | 0.10% max |
Mechanical Properties of ASTM A213 TP316:
| Property | Value |
| Tensile Strength | 515 MPa (75,000 psi) min |
| Yield Strength | 205 MPa (30,000 psi) min |
| Elongation (in 2 inches) | 40% min |
| Hardness (Typical) | 80 HRB max (Rockwell B scale) |
Additional Notes:
- Corrosion Resistance: TP316 stainless steel offers excellent resistance to pitting,
crevice corrosion, and stress corrosion cracking, especially in
chloride-containing environments.
- High-Temperature Performance: Retains mechanical properties and corrosion resistance at elevated
temperatures, making it suitable for high-temperature applications.
- Weldability: TP316 has good weldability, but post-weld heat treatment may be
required for certain applications to restore corrosion resistance.
Applications of ASTM A213 TP316L Longitudinal Welding Finned Tubes:
1. Heat Exchangers:
Used in shell-and-tube heat exchangers for industries such as
petrochemical, oil and gas, and power generation.
The finned design enhances heat transfer efficiency, making them
ideal for high-performance heat exchangers.
2. Boilers and Superheaters:
Suitable for boiler and superheater applications in power plants,
where high-temperature and high-pressure conditions are prevalent.
The corrosion resistance of TP316L ensures durability in these
demanding environments.
3. Chemical and Petrochemical Industries:
Used in heat exchangers and condensers that handle corrosive
chemicals, acids, and alkalis.
The finned tubes improve heat transfer efficiency while resisting
corrosion from aggressive media.
4. Refineries:
Applied in refinery processes, including crude oil distillation and
chemical processing, where heat transfer and corrosion resistance
are critical.
5. Food and Beverage Industry:
Used in heat exchangers for processes such as pasteurization,
sterilization, and cooling.
TP316L's corrosion resistance and hygienic properties make it
suitable for food-grade applications.
6. Pharmaceutical Industry:
Utilized in heat exchangers and condensers for pharmaceutical
manufacturing, where cleanliness and corrosion resistance are
essential.
7. Marine and Offshore Applications:
Suitable for heat exchangers and condensers in marine environments,
where resistance to seawater corrosion is required.
8. HVAC Systems:
Used in heating, ventilation, and air conditioning systems,
particularly in applications requiring efficient heat transfer and
corrosion resistance.
9. Waste Heat Recovery Systems:
Applied in waste heat recovery units to improve energy efficiency
by maximizing heat transfer from exhaust gases.
