Titanium Sheet Plate

Titanium is a lightweight and high-strength metal known for its exceptional corrosion resistance, biocompatibility, and high melting point. It finds applications in aerospace, medical implants, chemical processing, marine structures, and various high-performance industries due to its unique combination of properties such as low density, strength, and resistance to corrosion. Additionally, titanium is ductile, exhibits fatigue resistance, and has an aesthetically appealing metallic surface.

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Your Premier Titanium Plate Sheet Manufacturer

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SAKY ALLOY CO., LTD

Our Titanium 6Al-4V round bar stock is available in many finishes and a large diameter range. All products are 100% inspected with guaranteed quality and quick turnarounds.

Titanium Plate

Titanium Grade 12 Sheet Plate

F.A.Q.

Titanium plates, known for their lightweight, high strength, and corrosion resistance, offer a range of advantages. These include their suitability for aerospace and aviation due to their lightweight design, excellent corrosion resistance in harsh environments, and biocompatibility for medical implants. Titanium plates also exhibit good formability, high-temperature stability, and reasonable weldability, making them versatile in manufacturing processes. Moreover, their environmental sustainability further enhances their appeal in various industries. Overall, the unique characteristics of titanium plates make them an optimal choice for applications demanding a combination of strength, lightness, and resistance to corrosion.

Titanium is a lightweight and high-strength metal known for its exceptional corrosion resistance, biocompatibility, and high melting point. It finds applications in aerospace, medical implants, chemical processing, marine structures, and various high-performance industries due to its unique combination of properties such as low density, strength, and resistance to corrosion. Additionally, titanium is ductile, exhibits fatigue resistance, and has an aesthetically appealing metallic surface.

1.Titanium Ore Extraction: Titanium is extracted from minerals like ilmenite or rutile.
2.Conversion to Titanium Tetrachloride (TiCl4): Titanium dioxide is converted into TiCl4 and then purified.
3.Reduction to Metallic Titanium: TiCl4 is reduced to metallic sponge titanium using processes like the Kroll process.
4.Melting and Forming: Sponge titanium is melted to form titanium ingots, which can be further processed into sheets or plates through hot rolling.
5.Hot Rolling: Ingots are hot-rolled to achieve the desired thickness.
6.Cold Rolling (Optional): Further reduction of thickness may occur through cold rolling.
7.Annealing: Rolled sheets or plates may undergo annealing for stress relief and property enhancement.
8.Cutting and Shaping: Sheets or plates are cut into desired sizes and shapes.
9.Surface Treatment (Optional): Surface treatments may be applied for corrosion resistance or improved appearance.
10.Quality Control: Stringent quality control ensures the final titanium plates meet specified standards.

Titanium plates are versatile and find applications in aerospace (aircraft components), medical field (implants), chemical processing (vessels, heat exchangers), marine engineering (ship components), power generation (condensers), oil and gas industry (offshore structures), automotive sector (performance vehicles), sporting goods (bike frames, golf clubs), electronics (heat sinks), and architecture/construction (cladding, roofing). Their lightweight nature, high strength, and corrosion resistance make them crucial in various industries.

 

 
 
 

1.Alloy Design: Choosing appropriate alloying elements and alloy compositions significantly influences titanium alloy performance. For example, adding small amounts of aluminum, vanadium, magnesium, etc., can enhance strength.

2.Thermo-Mechanical Processing: Controlling the treatment of the alloy at specific temperatures and deformation conditions can optimize crystal structures and improve strength.

3.Surface Treatments: Surface treatments like shot peening, nitriding, oxidation, etc., can increase surface hardness and corrosion resistance.

4.Controlled Cooling Rates: Controlling cooling rates can affect the alloy’s microstructure, influencing hardness and strength.

5.Optimization of Heat Treatment Parameters: Precisely controlling heat treatment parameters, including temperature, time, and cooling rate, ensures optimal performance.

What are the advantages and characteristics of titanium plates?

Titanium plates, known for their lightweight, high strength, and corrosion resistance, offer a range of advantages. These include their suitability for aerospace and aviation due to their lightweight design, excellent corrosion resistance in harsh environments, and biocompatibility for medical implants. Titanium plates also exhibit good formability, high-temperature stability, and reasonable weldability, making them versatile in manufacturing processes. Moreover, their environmental sustainability further enhances their appeal in various industries. Overall, the unique characteristics of titanium plates make them an optimal choice for applications demanding a combination of strength, lightness, and resistance to corrosion.

What are the characteristics of titanium?

Titanium is a lightweight and high-strength metal known for its exceptional corrosion resistance, biocompatibility, and high melting point. It finds applications in aerospace, medical implants, chemical processing, marine structures, and various high-performance industries due to its unique combination of properties such as low density, strength, and resistance to corrosion. Additionally, titanium is ductile, exhibits fatigue resistance, and has an aesthetically appealing metallic surface.

What is the manufacturing process of titanium plates?

1.Titanium Ore Extraction: Titanium is extracted from minerals like ilmenite or rutile.
2.Conversion to Titanium Tetrachloride (TiCl4): Titanium dioxide is converted into TiCl4 and then purified.
3.Reduction to Metallic Titanium: TiCl4 is reduced to metallic sponge titanium using processes like the Kroll process.
4.Melting and Forming: Sponge titanium is melted to form titanium ingots, which can be further processed into sheets or plates through hot rolling.
5.Hot Rolling: Ingots are hot-rolled to achieve the desired thickness.
6.Cold Rolling (Optional): Further reduction of thickness may occur through cold rolling.
7.Annealing: Rolled sheets or plates may undergo annealing for stress relief and property enhancement.
8.Cutting and Shaping: Sheets or plates are cut into desired sizes and shapes.
9.Surface Treatment (Optional): Surface treatments may be applied for corrosion resistance or improved appearance.
10.Quality Control: Stringent quality control ensures the final titanium plates meet specified standards.

What are the applications of titanium plates?

Titanium plates are versatile and find applications in aerospace (aircraft components), medical field (implants), chemical processing (vessels, heat exchangers), marine engineering (ship components), power generation (condensers), oil and gas industry (offshore structures), automotive sector (performance vehicles), sporting goods (bike frames, golf clubs), electronics (heat sinks), and architecture/construction (cladding, roofing). Their lightweight nature, high strength, and corrosion resistance make them crucial in various industries.

 

How to Enhance Strength and Other Properties?

1.Alloy Design: Choosing appropriate alloying elements and alloy compositions significantly influences titanium alloy performance. For example, adding small amounts of aluminum, vanadium, magnesium, etc., can enhance strength.
2.Thermo-Mechanical Processing: Controlling the treatment of the alloy at specific temperatures and deformation conditions can optimize crystal structures and improve strength.
3.Surface Treatments: Surface treatments like shot peening, nitriding, oxidation, etc., can increase surface hardness and corrosion resistance.
4.Controlled Cooling Rates: Controlling cooling rates can affect the alloy’s microstructure, influencing hardness and strength.
5.Optimization of Heat Treatment Parameters: Precisely controlling heat treatment parameters, including temperature, time, and cooling rate, ensures optimal performance.