Ta10 Nickel Titanium Alloy Pipe Per Kg Gr9 Seamless Tube

Titanium Alloy Tube Properties
Titanium Alloy Tube Performance: Our cutting-edge titanium alloy tubes are composed of this revolutionary metal with impurity levels of carbon, nitrogen, hydrogen, and oxygen meticulously controlled. The purest titanium iodide contains impurities of no more than 0.1%, offering lower strength but high plasticity. The specifications of 99.5% industrial pure titanium include a density of ρ=4.5g/ cubic cm, a melting point of 1725ºC, thermal conductivity of λ=15.24W/(m.K), tensile strength of σb=539MPa, elongation of δ=25%, section shrinkage ψ=25%, an elastic modulus of E=1.078×105MPa, and a hardness of HB195.
Advantages of Titanium Alloy

Compared with other metal materials, titanium alloy offers unparalleled advantages:
Exceptional Strength-to-Density Ratio: Titanium alloy exhibits a superior strength-to-density ratio, boasting tensile strengths between 100 ~ 140kgf/mm2 while maintaining only 60% the density of steel.
Outstanding Medium Temperature Performance: Unlike aluminum alloys, titanium alloy retains its required strength at medium temperatures, suitable for prolonged use at 450 ~ 500°C.
Superior Corrosion Resistance: Titanium instantly forms a uniform and dense oxide film in the atmosphere, enhancing its resistance to erosion by various media. It excels in oxidizing and neutral environments and shows exceptional resistance in seawater, wet chlorine gas, and chloride solutions, although it does not perform as well in reducing media like hydrochloric acid.
Excellent Low-Temperature Performance: Certain titanium alloys, such as TA7, maintain substantial plasticity even at temperatures as low as -253°C.
Low Elastic Modulus and Thermal Conductivity: Titanium alloy features a low elastic modulus, minimal thermal conductivity, and is non-ferromagnetic.
High Hardness: The inherent hardness of titanium alloy makes it a robust choice for various applications.
Poor Stamping and Good Thermoplasticity: While titanium alloy demonstrates limited stamping capabilities, it excels in thermoplasticity.
Versatile Heat Treatment: By fine-tuning the heat treatment process, various phase compositions and microstructures can be achieved in titanium alloys. Fine equiaxial structures offer great plasticity, thermal stability, and fatigue strength, while acicular structures provide high lasting strength, creep strength, and fracture toughness. A combination of equiaxed and acicular structures ensures well-rounded properties.
Common heat treatment methods include annealing, solution treatment, and aging treatment. Annealing helps eliminate internal stress, improve plasticity, and enhance structural stability for superior comprehensive properties. Typically, the annealing temperature for α alloy and (α+β) alloy is set 120 ~ 200ºC below the (α+β) -→ β phase transition point. The solution and aging treatment involve fast cooling from high-temperature regions to achieve martensitic α 'phase and metastable β phase. This is followed by heat preservation in the middle temperature range to decompose these metastable phases, forming α phase or compounds and other finely dispersed second-phase particles, thus strengthening the alloy. For (alpha + beta) alloys, quenching happens 40 ~ 100 ºC below the alpha + beta) -- - > beta phase transition point, while for metastable beta alloys, quenching occurs 40 ~ 80 ºC above this point. The aging treatment temperature is typically 450 ~ 550ºC. Additionally, to meet specific workpiece requirements, the industry employs various metal heat treatment processes, including double annealing, isothermal annealing, β heat treatment, and deformation heat treatment.

Product parameter

Technical specification

Titanium alloys are primarily utilized in manufacturing aircraft engine compressor components, followed by applications in rockets, missiles, and high-speed aircraft structural parts. By the mid-1960s, titanium and its alloys had extended their usage to general industries, contributing to the production of electrolytic industry electrodes, power station condensers, oil refining, seawater desalination heaters, and environmental pollution control devices. These materials are now recognized for their corrosion-resistant structural properties. Furthermore, titanium alloys are instrumental in producing hydrogen storage materials and shape memory alloys.

Our Advantages

Qualitative Materials:

We utilize premium, top-grade raw materials to ensure our products deliver superior strength, resilience, and longevity.

Advanced Technology:

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

Customized Service:

We offer bespoke design and manufacturing services to meet the unique needs and requirements of our customers.

FAQ

Q1: Why choose your company?

A: With over 16 years of unparalleled industry expertise and the advantage of having our own state-of-the-art factory, we deliver exceptional services that are further enhanced by our professional and dedicated sales team.

Q2: What are your terms of payment?

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

Q3: What are your delivery terms?

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

Q4: What is your delivery time?

A: Our standard lead time ranges from 7 to 15 days after receiving the deposit.

Q5: Can you provide samples?

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