High Quality Gr. 23 Class 60e Titanium Alloy

Properties of Nickel Titanium Alloy Tube
Titanium Alloy Tube Performance: This state-of-the-art metal is defined by its purity and minimal impurities (carbon, nitrogen, hydrogen, oxygen), with the purest titanium iodide containing less than 0.1% impurities. Despite its low strength, it exhibits high plasticity. The properties of 99.5% industrial pure titanium include: density ρ=4.5g/cm³, melting point 1725ºC, thermal conductivity λ=15.24W/(m·K), tensile strength σb=539MPa, elongation δ=25%, section shrinkage ψ=25%, elastic modulus E=1.078×10MPa, and hardness HB195.
Unmatched Advantages of Titanium Alloy

Titanium Alloy: The Superior Choice Among Metals
High Strength-to-Density Ratio: With tensile strength ranging from 100 to 140 kgf/mm², titanium alloy's density is only 60% that of steel, offering unmatched structural efficiency.
Outstanding Medium Temperature Strength: Our titanium alloy maintains robust mechanical properties at temperatures significantly higher than aluminum alloys, functioning efficiently between 450°C and 500°C.
Superior Corrosion Resistance: Titanium instantly forms a uniform and dense oxide film in the atmosphere, providing extraordinary resistance against various media. It excels in oxidizing and neutral environments and demonstrates exceptional durability in seawater, wet chlorine gas, and chloride solutions. However, its resistance in reducing environments like hydrochloric acid is limited.
Impressive Low-Temperature Performance: Titanium alloys like TA7 maintain excellent plasticity even at frigid temperatures as low as -253°C.
Unique Physical Properties: Titanium boasts a low elastic modulus, minimal thermal conductivity, and is non-ferromagnetic, making it suitable for specialized applications.
Remarkable Hardness: Titanium's superior hardness ensures durability and extended service life.
Thermoplasticity and Stamping: While titanium alloys excel in thermoplasticity, their stamping capabilities are relatively limited.
Versatile Heat Treatment Outcomes: By adjusting the heat treatment process, titanium alloys can be tailored to exhibit a variety of phase compositions and microstructures. Fine equiaxial structures provide good plasticity, thermal stability, and fatigue strength, while acicular structures offer high lasting strength, creep strength, and fracture toughness. Combined, these structures deliver excellent overall performance.
Common heat treatment methods include annealing, solution treatment, and aging. Annealing is used to alleviate internal stress, enhance plasticity, and stabilize the structure, thereby achieving superior comprehensive properties. For α alloy and (α+β) alloy, annealing temperatures are typically set 120 ~ 200ºC below the (α+β) → β phase transition point. Solution and aging treatments involve rapid cooling from high temperatures to form martensitic α' phase and metastable β phase, followed by medium temperature preservation to decompose these metastable phases into α phase or compounds and other finely dispersed second-phase particles, thus strengthening the alloy. Usually, (alpha+beta) alloys are quenched 40 ~ 100ºC below the alpha+beta → beta phase transition point, while metastable beta alloys are quenched 40 ~ 80ºC above this point. Aging temperatures generally range between 450 ~ 550ºC. Additionally, to meet specific workpiece requirements, the industry employs double annealing, isothermal annealing, β heat treatment, deformation heat treatment, and other specialized metal heat treatment processes.

Titanium alloy finds its primary use in aircraft engine compressor components and is also extensively applied in rockets, missiles, and high-speed aircraft structural parts. Since the mid-1960s, titanium and its alloys have been adopted in general industry for producing electrolytic industry electrodes, power station condensers, oil refining and seawater desalination heaters, and environmental pollution control devices. Recognized as corrosion-resistant structural materials, titanium and its alloys are also utilized in the production of hydrogen storage materials and shape memory alloys.

Our Advantages

Qualitative Materials:

We utilize only premium, top-grade raw materials to ensure that our products exhibit unparalleled strength, resilience, and longevity.

Advanced Technology:

Our manufacturing processes are enhanced by cutting-edge technologies, including advanced smelting, continuous casting, and rolling techniques.

Customized Service:

We provide bespoke design and manufacturing services tailored to meet the distinct needs and specifications of our customers.

FAQ

Q1: Why choose your company?

A: With over 16 years of unmatched industry expertise and our own state-of-the-art factory, we deliver exceptional services bolstered by a professional and dedicated sales team.

Q2: What are your terms of payment?

A: We require a 30% T/T deposit in advance, with the remaining 70% due before delivery.

Q3: What are your delivery terms?

A: Our delivery terms include FOB, CFR, CIF, and EXW.

Q4: What is your delivery time?

A: Our standard lead time is between 7 to 15 days after receiving the deposit.

Q5: Can you provide samples?

A: Yes, we provide complimentary samples if they are available in stock. However, the transportation fees must be covered by the buyer.
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