Titanium alloy screws are widely used in aerospace, precision machinery and other fields due to their "low density and high specific strength". However, in actual use, titanium alloy screws may break due to a variety of factors. This article objectively analyzes the common causes of titanium alloy screw breakage from the perspectives of material properties, usage methods and maintenance, and puts forward targeted suggestions.

 

1. Material properties and strength performance of titanium alloy screws 1. Specific strength advantage The "specific strength" (ratio of strength to density) of titanium alloy is higher than that of steel, but the absolute strength is not outstanding. Its original design intention is to take into account both lightweight and structural strength, and it is suitable for weight-sensitive and load-bearing scenes (such as aircraft structural parts). Comparative data: The tensile strength of titanium alloy screws is equivalent to that of steel screws (usually 800-1200 MPa), but the density is only 60% of that of steel, and the weight is lighter. 2. Source of fracture risk The fracture of titanium alloy is not due to insufficient material strength, but is closely related to the use environment, installation method and maintenance conditions.

 

2. Common causes of titanium alloy screw fracture 1. Improper installation method Insufficient torque control: Titanium alloy has a low elastic modulus (about half of that of steel), and it is easy to cause plastic deformation or stress concentration due to over-tightening when tightening, causing fracture. Thread bite problem: Failure to use matching thread lubricant or insufficient thread accuracy may cause excessive local stress. 2. The use environment affects temperature changes: The strength and toughness of titanium alloy may decrease in high temperature (>400℃) or low temperature (<-100℃) environments, increasing the risk of fracture. Corrosive media: Long-term exposure to strong acids, strong alkalis or chloride ion environments may cause hydrogen embrittlement or stress corrosion cracking. 3. Material defects and fatigue damage Internal defects: Titanium alloys may produce defects such as pores and inclusions during smelting or processing, reducing fatigue life. Dynamic load: When subjected to alternating loads (such as vibration and impact) for a long time, titanium alloy screws are prone to fatigue fracture. 4. Design and selection errors Specification mismatch: Selecting screws with insufficient diameter or length leads to insufficient load-bearing capacity. Alternative use: Using titanium alloy screws in non-designed working conditions (such as ultra-high strength demand scenarios) may cause fracture.

 

III. Measures to prevent titanium alloy screw fracture 1. Standardize installation operation torque control: Tighten strictly according to the torque value recommended by the manufacturer to avoid over-tightening or under-tightening. Thread lubrication: Use special thread lubricant to reduce friction and stress concentration. 2. Optimize the use environment temperature management: Avoid long-term operation of titanium alloy screws at extreme temperatures, and adopt heat insulation or cooling measures when necessary. Corrosion protection: Surface treatment (such as plating, coating) of screws in contact with corrosive media. 3. Regular maintenance and inspection fatigue inspection: Regular non-destructive testing (such as ultrasonic testing) is performed on screws that bear dynamic loads. Replacement cycle: Develop a reasonable replacement plan based on the use conditions to avoid over-service. 4. Reasonable selection and design condition matching: Select the appropriate titanium alloy grade (such as TC4, TC6) according to the actual load, temperature and medium conditions. Redundant design: Use double screws or reinforced structures in key parts to reduce the risk of fracture.

 

4. Conclusion The fracture of titanium alloy screws is not simply caused by insufficient material strength, but is closely related to the installation method, use environment, material defects and design selection. Through standardized operation, optimized environment, regular maintenance and reasonable selection, the risk of fracture can be significantly reduced and the service life of titanium alloy screws can be extended.