Titanium Sheet Ta22 Ta22-1 Titanium Plate Supplier Titanium Plate Various Sizes Can Be Customized

Titanium alloy, a robust material formed by adding various elements to titanium, exhibits unique properties with its dual homogeneous crystal structures: α titanium (close-packed hexagonal structure) below 882°C and β titanium (body-centered cubic) above 882°C. Technical requirements: 1. The chemical composition of titanium and titanium alloy sheets must align with GB/T 3620.1 standards, and any permissible deviations during reinspection should comply with GB/T 3620.2 standards. 2. The thickness deviation of the sheet should adhere to Table 1 specifications. 3. The width and length deviations should conform to Table 2 provisions. 4. The corners must be cut to right angles as much as possible, with inclines not exceeding the stipulated length and width deviations.

Titanium Alloy Plate Production Specifications
Thickness 0.5-1.0mm x Width 1000mm x Length 2000-3500mm

Thickness 1.0-5.0mm x Width 1000-1500mm x Length 2000-3500mm
Thickness 5.0-30mm x Width 1000-2500mm x Length 3000-6000mm
Thickness 30-80mm x Width 1000mm x Length 2000mm

Alloying

Titanium alloy is a composite material formed by adding different elements to titanium, featuring two homogeneous crystal structures: α titanium (close-packed hexagonal) below 882ºC and β titanium (body-centered cubic) above 882ºC.
Alloying elements are grouped into three categories based on their impact on phase transition temperatures:
1. Elements stabilizing the α phase and increasing phase transition temperatures are α-stable elements, including aluminum, carbon, oxygen, and nitrogen. Aluminum, a primary alloying element, significantly enhances the alloy's strength at both room and high temperatures, reduces specific gravity, and increases elastic modulus.
2. Elements stabilizing the β phase and reducing phase transition temperatures are β-stable elements, categorized into isomorphic and eutectoid types. Common examples include molybdenum, niobium, and vanadium for isomorphic, and chromium, manganese, copper, iron, and silicon for eutectoid types.
Common β-stable elements in titanium alloys include molybdenum, niobium, vanadium (isomorphic), and chromium, manganese, copper, iron, silicon (eutectoid).
3. Neutral elements, such as zirconium and tin, have a minimal effect on phase transition temperatures.
Impurities like oxygen, nitrogen, carbon, and hydrogen significantly affect titanium alloys. Oxygen and nitrogen, with high solubility in the α phase, enhance strength but reduce plasticity. Their content is typically limited to 0.15-0.2% for oxygen and 0.04-0.05% for nitrogen. Excess hydrogen can cause brittleness through hydride formation, keeping its content below 0.015%. Hydrogen content can be reduced via vacuum annealing.
Product Parameter

Application

Titanium plates are pivotal in shipbuilding due to their superior corrosion resistance, low density, shape memory, and non-magnetic properties. They are extensively used in nuclear submarines, deep submersibles, atomic icebreakers, hydrofoils, hovercrafts, minesweepers, propellers, whip antennas, seawater pipes, condensers, heat exchangers, acoustic devices, and firefighting equipment. Titanium alloys serve various purposes such as industrial pure titanium, titanium-zirconium alloys, and multiple titanium alloy variants.
(1) All Titanium Ships. Our practical experience in crafting titanium boats is extensive, with pioneering work dating back to the 1990s by Toho Titanium Co., LTD., Nikko Industrial Co., LTD., Fuji Shin Shipyard, and Eteng Shipyard. These vessels offer myriad advantages such as reduced weight, higher speeds, smaller engines, lower fuel costs, and minimal CO2 emissions. Additionally, they require no surface coating and facilitate easy maintenance. However, the high cost of materials and complex manufacturing processes pose challenges. Tests confirm excellent speed stability, reduced vibration, and noise, making these boats a viable, eco-friendly choice.
(2) Atomic Powered Ships. Leveraging titanium alloy in place of stainless steel revolutionizes ship components like steam engines, heat exchangers, and coolers, particularly in Russia. This innovation significantly mitigates corrosion risks, with titanium steam engines being a staple in Russian atomic icebreakers. The switch to titanium alloy boosts engine lifespan by tenfold, underscoring its durability and efficiency.
(3) Propellers. Propeller materials must exhibit high strength, exceptional fatigue performance, erosion, and cavitation resistance in seawater. Titanium alloys satisfy these stringent requirements. The U.S. Navy was the first to employ a 1,500 mm diameter, four-bladed detachable titanium alloy propeller on a hydrofoil, with similar advancements seen in China since 1972. Our current capabilities include producing propellers with diameters ranging from 450-1700mm and fixed propellers of 1200mm diameter, weighing 130kg. Empirical evidence indicates that titanium alloy propellers have a service life more than five times longer than their copper counterparts.
(4) Marine Pumps, Valves, and Pipes. Traditional materials like copper and stainless steel offer a limited service life of 2-5 years under harsh marine conditions. Titanium alloys, however, significantly extend this lifespan, making them ideal for large-flow mobile seawater pipelines. Russian standards mandate a first docking maintenance period of 8-9 years, a service life of at least 15 years, and an overall operational reliability of 25-30 years for all vessel types, demonstrating the unparalleled longevity and reliability of titanium solutions.

Our Advantages

Qualitative Materials:

We exclusively use premium, top-grade raw materials, ensuring our products deliver unmatched strength, durability, and longevity.

Advanced Technology:

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

Customized Service:

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

FAQ

Q1: Why choose your company?

A: With over 16 years of unparalleled industry expertise, our state-of-the-art factory, and a professional and dedicated sales team, we deliver exceptional services that stand out in the industry.

Q2: What are your terms of payment?

A: We require a 30% T/T deposit upfront, with the remaining 70% due before delivery to ensure seamless transactions and customer satisfaction.

Q3: What are your delivery terms?

A: Our flexible delivery terms include FOB, CFR, CIF, and EXW, catering to a variety of shipping preferences and logistical needs.

Q4: What is your delivery time?

A: Our standard lead time ranges from 7 to 15 days post deposit receipt, ensuring timely and efficient delivery of orders.

Q5: Can you provide samples?

A: Yes, we offer complimentary samples when available in stock, with transportation fees to be covered by the buyer, providing a risk-free opportunity to evaluate our products.
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