Ti and ti alloy foils

Titanium and titanium alloy foils

Specification:

Cold-rolled and annealed foil

Thickness (0.010.09mm)  width (30300mm) length ≥500mm  Strip thickness (0.12.0mm) width (50500mm) length ≥ 5002000mm 


price:

Titanium Foil: $30 to $80 per kilogram.

Titanium Alloy Foil: $40 to $100 per kilogram.



Titanium and titanium alloy foils have the following key characteristics:

Lightweight and high strength: Titanium foils possess exceptional strength and stiffness while being significantly lighter compared to other metals.

Excellent corrosion resistance: Titanium foils exhibit high resistance to various chemicals and corrosive environments. They can withstand common acids, alkalis, and oxidizing agents, making them suitable for applications even in seawater.

Good heat stability: Titanium foils maintain their mechanical properties and chemical stability at high temperatures, making them suitable for high-temperature applications such as aerospace engine components.

Excellent thermal conductivity: Although titanium itself is not the best thermal conductor, titanium foils have relatively good thermal conductivity.

Low magnetism: Titanium foils have low magnetic properties, making them useful in applications that are sensitive to magnetic fields, such as in laboratories or equipment.

Ease of processing: Titanium foils have good plasticity and processability, allowing them to be easily machined and manufactured through cutting, forming, and welding methods.


Applications of titanium and titanium alloy foils include:

Aerospace industry: Titanium foils are widely used in the aerospace field for manufacturing aircraft structural components, engine parts, combustion chambers, turbine blades, and guide vanes. Their lightweight, high strength, and excellent corrosion resistance make titanium foils crucial materials for aircraft and spacecraft.

Medical field: Titanium foils play a vital role in the manufacturing of medical instruments and implants. Due to their biocompatibility and corrosion resistance, titanium foils are commonly used for producing artificial joints, dental implants, bone plates, spinal fusion devices, and surgical instruments.

Chemical industry: The outstanding corrosion resistance of titanium foils makes them extensively used in chemical production and processing processes, such as chemical reactors, distillation equipment, storage tanks, and pipelines.

Electronics and electrical industry: Titanium foils are employed in the manufacturing of capacitors, integrated circuit substrates, wires, and connectors in the electronics and electrical field. Their low magnetism and good conductivity make titanium foils an ideal choice for electronic components.

Automotive industry: Titanium foils find applications in the automotive manufacturing sector, such as for producing high-temperature-resistant components in the automotive exhaust systems, automotive exterior embellishments, and lightweight designs to improve fuel efficiency.

Art and decoration: Titanium foils, with their metallic texture and aesthetic appearance, are used in art production, architectural decoration, jewelry design, and handicrafts.

The selection of titanium and titanium alloy foils depends on the specific performance required for different applications:

Grade 1 (Ti-CP): This commercial pure titanium grade offers excellent corrosion resistance, high ductility, and good formability. Grade 1 titanium foils are used in applications such as chemical processing equipment, construction, and marine components.

Grade 2 (Ti-CP): Similar to Grade 1, Grade 2 titanium foils are commercial pure titanium with excellent corrosion resistance. They find applications in industries such as chemical processing, power generation, and marine equipment.

Grade 5 (Ti-6Al-4V): This is one of the most widely used titanium alloy grades for foils. Grade 5 titanium foils provide a balance of high strength, corrosion resistance, and lightweight. They are commonly used in aerospace, automotive, marine industries, as well as medical implants and sports equipment.

Grade 9 (Ti-3Al-2.5V): This titanium alloy grade offers a combination of strength, formability, and weldability. Grade 9 titanium foils can be used in aerospace, marine, chemical processing, and automotive industries.

Grade 23 (Ti-6Al-4V ELI): This is a medical-grade titanium alloy with low interstitial elements (Extra Low Interstitials or ELI). Grade 23 titanium foils are typically used in medical implants, including orthopedic devices and dental components.

The specific grade chosen depends on the desired performance of the final product, such as strength, corrosion resistance, and biocompatibility


Common surface treatment methods for titanium foils include:

Acid etching: Removing the oxide layer and impurities from the surface of titanium foils using an acidic solution, such as hydrochloric acid. This can improve the surface smoothness, purity, and corrosion resistance of the titanium foil.

Electrochemical polishing: Electrochemical polishing is a method of electrolytically polishing the surface of titanium foils in an electrolyte. It can remove surface roughness, oxide layers, and impurities, resulting in a smoother and brighter surface.

Mechanical polishing: Mechanical polishing involves using mechanical means such as grinding, polishing, and buffing to treat the surface of titanium foils to achieve the desired surface smoothness and flatness.

Passivation treatment: Passivation is a surface treatment method that involves forming a passive film on the surface of titanium foils to enhance their corrosion resistance. Common passivating agents include nitric acid and sulfuric acid.

Coating: Sometimes, the surface of titanium foils is coated with a protective coating to increase corrosion resistance, friction performance, or fulfill specific functional requirements.

 

How to choose the appropriate surface treatment method:

Application and environment: Consider the specific application and environmental conditions for the titanium foils. If the foils will be used in highly corrosive environments or require higher corrosion resistance, acid etching and passivation treatment may be suitable choices. If the foils will be used in applications that demand higher surface smoothness and flatness, mechanical polishing and electrochemical polishing may be more appropriate.

Material requirements: Consider the material requirements of the titanium foils, including hardness, roughness, and purity. Different surface treatment methods will have different effects on these properties. For example, mechanical polishing can improve the surface smoothness and flatness of titanium foils, while acid etching can remove oxide layers and impurities, enhancing purity.

Cost and efficiency: Consider the cost and efficiency of the surface treatment method.

Safety and environmental impact: Evaluate the impact of the surface treatment method on the environment and human health.


Methods for the preparation of titanium and titanium alloy foils include:

Hot Rolling Method: This method involves heating titanium or titanium alloy to high temperatures and then using mechanical rolling to compress it into thin sheets. Hot rolling improves the material's plastic deformation capability and mechanical properties.

Cold Rolling Method: Cold rolling is a method of preparing titanium and titanium alloy foils by rolling at room temperature. Compared to hot rolling, cold rolling can achieve higher surface smoothness and dimensional accuracy, but it requires higher plastic deformation capability of the material.

Multiple Pass Rolling Method: This method involves reducing the thickness of titanium and titanium alloy foils gradually through multiple rolling passes. It allows for maintaining high mechanical properties while achieving thinner foils.

Hot and Cold Rolling Combination Method: This method combines the advantages of hot rolling and cold rolling. It involves initially hot rolling titanium or titanium alloy at a specific temperature and then cold rolling it at room temperature to further reduce the foil thickness and improve surface quality.

Vacuum Hot Rolling Method: Vacuum hot rolling is performed under high vacuum conditions to prevent oxidation and contamination. This method enables the preparation of high-purity and high-quality titanium and titanium alloy foils.

 

Key points in the preparation process of titanium and titanium alloy foils include:

Temperature control: Accurate temperature control is essential during the preparation process. Hot rolling and vacuum hot rolling methods require precise control of heating temperature to ensure material plasticity and deformation capability. Cold rolling method requires maintaining appropriate hardness of the material at room temperature.

Pressure and rolling process: Pressure is a critical parameter in the preparation process. Its magnitude determines the degree of deformation and reduction in foil thickness. The rolling process should involve selecting suitable pressure and the number of rolling passes based on material characteristics and requirements.

Annealing treatment: After preparation, the foils usually undergo annealing treatment to eliminate internal stresses and improve the crystalline state of the material. Annealing enhances the mechanical properties and deformation capability of the foils while reducing hardening and brittleness.

Surface treatment: Surface quality of the foils is crucial for certain applications. During the preparation process, attention should be paid to protecting the foil surface from scratches, contamination, and oxidation. Appropriate surface treatment improves the appearance, smoothness, and corrosion resistance of the foils.

Material selection and purity control: The choice of titanium and titanium alloy is critical for the preparation process. Different titanium alloys have varying chemical compositions and crystal structures, requiring corresponding process parameters and treatment methods. Additionally, ensuring high purity and uniformity of the material is essential to obtain high-quality foils.

Process control and quality inspection: Strict process control and quality inspection are necessary during the preparation process. Monitoring parameters such as temperature, pressure, and rolling force, as well as conducting quality inspections, ensure the production of titanium and titanium alloy foils that meet the required specifications.

 

Various methods for the preparation of titanium and titanium alloy foils have advantages and disadvantages:

Hot Rolling Method:

Pros: Hot rolling at high temperatures enhances the material's plastic deformation capability and mechanical properties. It is suitable for preparing thicker titanium and titanium alloy foils.

Cons: The process requires high temperatures, which may lead to oxidation and decreased surface quality. It also involves relatively higher production costs.

Cold Rolling Method:

Pros: Cold rolling achieves higher surface smoothness and dimensional accuracy and is suitable for preparing thinner titanium and titanium alloy foils. It does not require high temperatures during the preparation process.

Cons: Cold rolling requires higher plastic deformation capability of the material, which may result in increased hardening and brittleness of the foils.

Multiple Pass Rolling Method:

Pros: Gradually reducing the foil thickness through multiple rolling passes allows for maintaining high mechanical properties while achieving thinner foils.

Cons: The preparation process takes longer, resulting in relatively lower production efficiency.

Hot and Cold Rolling Combination Method:

Pros: This method combines the advantages of hot rolling and cold rolling, allowing for achieving high mechanical properties and surface quality.

Cons: The preparation process is relatively complex, involving two stages of rolling operations.

Vacuum Hot Rolling Method:

Pros: Performing hot rolling under high vacuum conditions prevents oxidation and contamination, enabling the preparation of high-purity and high-quality titanium and titanium alloy foils.

Cons: The method requires advanced equipment and stringent process requirements, leading to higher production costs.

 

Selection of preparation methods:

Thickness requirement of the foils: Choose the appropriate preparation method based on the desired thickness of the foils. Hot rolling is suitable for thicker foils, while cold rolling is suitable for thinner foils.

Material performance requirements: Consider the mechanical properties, surface quality, purity, and other characteristics required for the foils' intended applications. Different preparation methods have varying effects on material properties, and the choice can be made based on specific requirements.

Process control and equipment requirements: Different preparation methods may require specific process control and equipment. Consider the availability of production equipment and the controllability of the production process when selecting the appropriate preparation method.

Production cost and efficiency: Different methods may have different costs and efficiencies. Take into account the production costs and efficiency factors to select an economically feasible preparation method.

By considering these factors holistically, the appropriate preparation method can be chosen to ensure the production of titanium and titanium alloy foils that meet the required specifications. Evaluation and selection should be based on specific circumstances.