Titanium Alloy Customization 

AikerlyTi  Alloy Customization 

Custom Titanium Profiles

 

Shapes: Includes angles, channels, U-profiles, T-profiles, square tubes, round tubes, etc.

Dimensions: Customized according to specific requirements, including profile dimensions, wall thickness, length, etc.

Surface Treatment: Options include anodizing, painting, electrophoretic coating, etc.

Special Requirements: Such as corrosion resistance, high temperature resistance, compressive strength, etc.

Custom Titanium Sheets

 

Thickness: From thin sheets to thick plates, typically ranging from 0.5mm to 100mm.

Dimensions: Width and length can be customized and cut to order.

Surface Treatment: Includes anodizing, painting, polishing, etc.

Custom Titanium Tubes

 

Diameter and Wall Thickness: Customized according to requirements, including inner diameter, outer diameter, and wall thickness.

Shapes: Includes round tubes, square tubes, rectangular tubes, etc.

Surface Treatment: Options include anodizing, painting, electrophoretic coating, etc.

Custom Titanium Castings

 

Shapes: Customizable for various complex shapes.

Dimensions: Can be customized based on drawings or specifications.

Surface Treatment: Includes cleaning, painting, anodizing, etc.

Titanium Welding and Assembly

 

Welding: Provides welding services to meet specific structural requirements.

Assembly: Assembly or processing of titanium components according to customer needs.

Custom Titanium Components

 

Applications: Custom parts for specific applications, such as mechanical parts, aerospace components, medical devices, etc.

Processing Methods: Includes CNC machining, laser cutting, stamping, etc.

Titanium Surface Treatment

 

Anodizing: Enhances corrosion resistance and aesthetics.

Painting: Offers various colors and protective layers.

Polishing: Improves gloss and appearance.


AikerlyTitanium alloy forming technology

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AikerlyTitanium alloy hot forming

Titanium alloy is a high strength, low density, corrosion resistant metal material commonly used in aerospace, medical equipment, chemical industry and other fields. Titanium alloy has good plasticity and ductility and can be subjected to various hot forming processes under high temperature conditions.

AikerlyTitanium alloy superplastic forming

Titanium alloy superplastic forming refers to the use of titanium alloy's superplasticity characteristics at high temperature conditions to achieve complex shape plastic deformation through very small stresses. Superplasticity is a special type of creep, meaning that materials can undergo significant plastic deformation with very low stresses.


AikerlyTitanium alloy creep forming

Titanium alloy creep forming is a process of plastic deformation using titanium alloy's creep properties under high temperature conditions. Creep refers to the continuous plastic deformation of materials under high temperature and stress, with time-dependent and increment-dependent characteristics.

There are also some specialized titanium alloy forming methods.

AikerlyExplosive forming

Explosive forming is a process that uses the impact force of an explosion wave on titanium alloy materials to achieve plastic deformation. This method is suitable for manufacturing small parts such as missile structural parts, vehicle components, etc. Explosive forming does not require equipment investment and has advantages such as low cost and high efficiency.

AikerlyElectromagnetic forming

Electromagnetic forming is a process that uses the force of a magnetic field to process titanium alloy materials. By applying an alternating electromagnetic field on the surface of the titanium alloy material, the material undergoes plastic deformation due to the electromagnetic force. Electromagnetic forming can achieve advantages such as high speed forming, no need for molds, and simple processing technology, and is suitable for manufacturing small parts and complex shaped materials.

AikerlyLaser forming

Laser forming is a process that uses laser beams to directly melt and solidify titanium alloy materials, thereby achieving plastic forming. Laser forming can achieve advantages such as high precision processing, no need for molds, and reduced material waste, and is suitable for manufacturing precision parts and complex structures.

AikerlyPowder metallurgy forming

Powder metallurgy forming is a process that uses titanium alloy powder under certain conditions to compress, sinter or melt into a desired shape. This method is suitable for manufacturing complex parts and large components. Powder metallurgy forming can achieve advantages such as uniform material properties, weight reduction, and improved hardness.