Tube To Tubesheet Joint Types

2024-10-18 16:02:28

Tube to tubesheet joints are important components in equipment such as heat exchangers, pressure vessels and boilers. Different tube to tubesheet joint types are adapted to different working environments and technical requirements. This article will introduce three common tube to tubesheet joint types and their processes and technical characteristics in detail.

1. Expanded Tube To Tubesheet Joint

Expanded tube to tubesheet joint is a connection process that mechanically fixes the tube to the tubesheet. It relies on a special expansion tool to expand the tube in the tubesheet hole so that the tube fits tightly with the hole wall to form a mechanical lock.

Process characteristics:
Simple operation: The expansion process does not require complex equipment, only expansion tools are required for operation, and it is suitable for large-scale production.
No heat treatment: The expansion process does not generate high temperature, so it does not change the mechanical properties of the material, and is suitable for temperature-sensitive materials.
No welding skills required: The expansion process does not require a high level of welding technology, and the construction is simple, especially suitable for the installation of thick-walled tubes.

Technical characteristics:
Sealing depends on contact pressure: Since it is a mechanical connection, the sealing of the expansion depends on the tightness of the tube and the tubesheet hole. If the expansion joint is not sufficient or the tube wall thickness is uneven, it may lead to insufficient sealing.
Not suitable for high-pressure environment: The mechanical locking force of the expansion joint may not be stable enough under high pressure or high temperature environment, and it is easy to loosen or leak. Therefore, the expansion joint is mainly used in low-pressure and normal temperature application scenarios, such as air coolers, condensers, etc.

2. Strength Welded Tube To Tubesheet Joint

Strength welded tube to tubesheet joint is a high-strength connection method that melts the tube and tubesheet materials together. Welded joints can be divided into partial welding and full welding, which are selected according to different working conditions.

Process characteristics:
Heat treatment process: High temperature is generated during welding, and the tube and tubesheet form a strong bond through melting. Depending on the application requirements, the welding process may also include preheating or post-heat treatment to ensure the quality of the weld.
Welding form: Common welding forms include argon arc welding (TIG), arc welding (SMAW) and automated welding technology. The specific choice depends on the pipe material and operation requirements.

Technical features:
High strength and high sealing: The welded joint achieves high-strength bonding through metal fusion and can withstand extremely high pressure and temperature changes. Excellent sealing, suitable for high pressure and corrosive environments.
Strict welding quality control: The welding process has high requirements for materials, and welding defects such as cracks and pores may affect the strength and sealing of the joint. Therefore, non-destructive testing (such as ultrasonic and radiographic testing) after welding is essential.
Adapt to harsh environments: Welded joints are usually used in high-pressure, high-temperature or corrosive environments such as petrochemicals, nuclear power, and aerospace, and can ensure long-term stable operation.

3. Expansion Welding Combination Joint

The expansion welding combination joint is a connection method that combines expansion and welding processes. The pipe is first fixed by expansion, and then welding is performed to further enhance the strength and sealing of the joint. This dual process can maximize the advantages of both.

Process features:
Double locking: First use the expansion process to ensure the fixed position of the pipe, and then use the welding process to provide additional strength and sealing. Usually, expansion is performed first, and then argon arc welding or manual welding is performed to ensure a stable welding process.
High complexity: Compared with a single expansion or welding process, the operation of the expansion welding combination joint is more complicated and requires strict process control to ensure that the expansion and welding effects complement each other.

Technical features:
Suitable for high pressure and high temperature environment: The expansion welding combination joint can withstand extreme working conditions and performs well in high pressure and high temperature equipment. It is especially suitable for equipment with extremely high safety requirements such as nuclear power and chemical heat exchangers.
High cost and high reliability: Due to the need to combine two processes, the construction cost of the expansion welding combination joint is relatively high, but the double safety guarantee it provides makes it highly favored in high-demand equipment.
Avoid stress concentration: By expanding first and then welding, the thermal stress generated during the welding process can be avoided from being concentrated in a certain part, effectively improving the fatigue life of the joint.

Conclusion

The selection and application of tube to tubesheet joint types directly affect the performance and safety of the equipment. Expansion, welding, and expansion welding combination joints each have their own advantages and are suitable for different industrial needs. Expansion is suitable for low pressure and normal temperature equipment, welding is the first choice for high pressure and high temperature environments, and expansion welding combination joints provide double protection under extreme working conditions. In practical applications, selecting the appropriate joint type and performing strict process control will significantly improve the reliability and service life of the equipment.

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