Welding is a crucial process for connecting metal and non-metal materials, extensively used in various fields including machinery manufacturing, construction, shipbuilding, bridges, and pipelines. However, during the welding process, concentrated heat release can lead to uneven thermal expansion and contraction of the weld seam and base material, resulting in welding stresses and deformation. These welding stresses not only affect the mechanical properties and corrosion resistance of the weld seam but can also lead to serious failures such as cracks and fractures. Therefore, studying and applying effective methods to eliminate welding stresses is vital for improving welding quality and extending the service life of welded components.

I. Formation and Impact of Welding Stresses

Welding stresses primarily arise from the heat-affected zone during the welding process, where temperature gradients induce non-uniform contraction as the metal cools. Welding stresses can be categorized into residual stresses, which remain within the material after welding, and transient stresses, which occur due to rapid temperature changes during the welding process. The presence of welding stresses can result in numerous issues, including local cracking of the weld, overall deformation, and stress concentration. Consequently, welding engineers must implement effective measures to minimize the generation of welding stresses in order to enhance the overall performance of welded structures.

II. Methods for Eliminating Welding Stresses

Based on the principles and methods applied during the elimination of welding stresses, these methods can be classified into several categories:

1. Mechanical Methods

Mechanical methods involve applying external mechanical forces to counteract welding stresses. Key techniques include:

• Hammering: Post-welding, using a hammer to strike the weld seam and surrounding areas induces plastic deformation, thereby releasing internal stresses. This method is simple but typically limited to small structural components and thin plates.
  
  

• Forging: Heating the entire structure to its plastic temperature and then applying hammering or pressing to encourage overall deformation can eliminate internal stresses. This method is suitable for larger, thicker components but requires significant energy and equipment.
  

  
  

• Vibration: Utilizing vibrators to apply periodic vibrations on structural components induces micro-deformations, releasing internal stresses. This method is versatile across various shapes and sizes, offering significant effectiveness and ease of operation with energy-saving benefits.
  

  
  

• Pressing: Applying pressure using hydraulic presses or other equipment causes the component to undergo plastic or elastic deformation, reducing internal stresses. This method is ideal for closed containers such as cylindrical and spherical structures.

2. Heat Treatment Methods

Heat treatment relies on temperature control through heating or cooling materials, enabling welded components to experience uniform thermal expansion and contraction, thus reducing temperature gradients and thermal stresses. Common heat treatment methods include:

• Preheating: Local or overall heating of materials before welding decreases temperature differences and minimizes the heat-affected zone, particularly effective for high-strength steels, stainless steels, and cast iron, which are prone to welding stresses.
  

  
  

• Post-Weld Heat Treatment: Heating and slow cooling of the structure after welding promotes uniform deformation of the weld and base material, thereby eliminating internal stresses. This method includes processes like tempering, normalizing, and annealing.
  

  
  

• Controlling Cooling Rates: Adjusting cooling rates avoids dimensional changes and stress concentration caused by rapid or slow cooling, utilizing methods such as natural cooling, forced cooling, and thermal insulation.

3. Process Control Methods

Process control methods emphasize improving welding conditions through reasonable technical measures before and during welding to reduce welding stresses. Key aspects include:

• Choosing Appropriate Welding Methods: Select suitable welding techniques based on material characteristics and structural requirements, such as Gas Metal Arc Welding (GMAW) and Gas Tungsten Arc Welding (GTAW), to achieve optimal welding results.
  

• Optimizing Welding Parameters: Properly setting parameters such as electrode type, welding current, voltage, and polarity ensures stable welding processes and effective heat input control.
  

• Weld Seam Position and Orientation: Strategically arranging the position of weld seams and the sequence of welding can minimize thermal effects on the base material and reduce stress concentration.
  

• Symmetrical and Sectional Welding: Symmetrical welding methods apply uniform heat, minimizing deformation caused by asymmetrical cooling, while sectional welding divides the entire weld into smaller segments, reducing the overall thermal impact.
  

• Using Auxiliary Tools: Employing fixtures and tension rods to maintain the shape and position of welded components mitigates deformation caused by welding. Additionally, processing and corrective treatments on welded joints help control deformation.

III. Comprehensive Application of Methods to Eliminate Welding Stresses

The methods for eliminating welding stresses can be used individually or in combination, allowing for flexible application based on specific material characteristics, structural design, and process requirements. A comprehensive approach utilizing multiple methods can achieve optimal stress elimination, enhancing the overall performance of welded structures.

1. Importance of Eliminating Welding Stresses

Eliminating welding stresses significantly improves welding quality and reliability, reduces the occurrence of welding defects and decreases material waste and energy consumption, ultimately lowering production costs. Furthermore, addressing welding stresses contributes to ensuring the safety and stability of structures during their operational lifetime. As such, adequate emphasis must be placed on the elimination of welding stresses in welding engineering.

2. Further Study on Welding Stresses

In summary, various methods exist for eliminating welding stresses, each suitable for different materials, structural components, and processing conditions. Selecting the appropriate method or combining multiple strategies will yield the best results in reducing welding stresses. Understanding the causes, classifications, hazards, and remedies for welding deformation is crucial for effective intervention.

Through continuous practice and integration of theory, welding personnel can gain proficiency in stress elimination techniques, further contributing to advancements in the welding industry.

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