Pure Tungsten Sheets/Plates are flat, solid pieces of pure tungsten metal, typically produced in various thicknesses and sizes to meet specific industrial needs. Tungsten, with its exceptional properties, is highly valued in industries where extreme conditions of temperature, pressure, or corrosion resistance are prevalent. Key Characteristics of Pure Tungsten Sheets/Plates: Material Composition: 99.95% Pure Tungsten (W): These sheets or plates are composed entirely of tungsten, with minimal or no impurities, ensuring the full range of tungsten's beneficial properties. High Density:Tungsten has a very high density of around 19.25 g/cm³, making it one of the heaviest metals. This density is beneficial for applications requiring mass and weight in compact forms. Extremely High Melting Point:With a melting point of 3,422°C (6,192°F), tungsten is the highest-melting metal, making it ideal for applications in extreme temperatures such as aerospace and high-temperature manufacturing. Strength and Durability:Pure tungsten is incredibly strong and durable, with tensile strength that can reach up to 1510 MPa. It is highly resistant to wear, deformation, and damage under stress, even in extreme conditions. Corrosion and Oxidation Resistance:Tungsten exhibits excellent resistance to corrosion, oxidation, and other forms of environmental degradation, even at high temperatures, which makes it ideal for long-lasting, reliable use in harsh conditions. Applications of Pure Tungsten Sheets/Plates: Aerospace and Defense: Tungsten plates are used in aerospace components such as rocket nozzles, satellite shielding, and spacecraft parts, due to their ability to withstand extreme heat and pressure.Armor-piercing projectiles and military-grade materials also benefit from tungsten's high density and strength. High-Temperature Applications: Tungsten sheets are commonly used in high-temperature furnaces and other industrial heating equipment where temperatures may exceed normal metal capabilities, such as in hot zones of steel manufacturing or semiconductor production.

A tungsten-copper disc is a circular, flat-shaped component made from a composite material that blends the high density and strength of tungsten (W) with the excellent thermal and electrical conductivity of copper (Cu). This alloy is designed to provide a combination of the properties required in high-performance applications, especially where both heat resistance and conductivity are essential. Tungsten-copper discs are commonly used in industries like aerospace, electronics, manufacturing, and medical technologies. Properties: · Density: Tungsten-copper discs have a high density, which lies between the densities of pure tungsten and pure copper. This makes the material suitable for applications requiring high mass or weight, such as counterweights or radiation shielding. · Color and Appearance: Tungsten-copper discs typically have a metallic gray or brownish color, which reflects the tungsten content, while the copper content may give a reddish hue to the surface. The surface can be smooth or finished depending on the manufacturing and machining processes. · Thickness and Diameter: Tungsten-copper discs can be manufactured in a wide range of diameters and thicknesses. Custom sizes can be created to meet specific design and performance requirements. Applications of Tungsten-Copper Disc: · Electrical Contacts: Tungsten-copper discs are used in electrical contacts for high-voltage circuits, commutators, and other components that need to handle high current while effectively managing heat. · Heat Sinks: The high thermal conductivity of tungsten-copper alloys makes these discs ideal for heat dissipation in electronic devices and power electronics that generate large amounts of heat. · Radiation Shielding: Tungsten-copper discs are often used in radiation shielding applications, such as in X-ray machines or CT scanners, where both the high density (for radiation shielding) and heat dissipation properties are essential. · Heat Shields and Components: The high density and heat resistance make tungsten-copper discs ideal for aerospace applications, such as rocket nozzles, heat shields, and re-entry vehicle components.

DIN 2545 is a German standard for stainless steel flanges, designed for use in piping systems requiring durability, corrosion resistance, and strong mechanical properties. These flanges are commonly used in industries like chemical, petrochemical, food processing, and more. They come in various sizes and configurations for secure and leak-proof connections. The PN 40 rating indicates that these flanges can withstand pressures up to 40 bar (approximately 580 psi) at normal temperatures (typically 20°C or 68°F). Types of DIN 2545 SS Flanges: · Slip-On Flange (SO): A flange that slides over the pipe and is welded inside and outside for a secure connection. · Weld Neck Flange (WN): A flange with a tapered neck that allows for a stronger weld, commonly used in high-pressure applications. · Blind Flange: A flange with no bore used to seal the end of a pipe or vessel. · Threaded Flange: A flange with internal threads that allows it to be screwed onto a pipe without welding. · Socket Weld Flange: Designed for pipes to fit into the socket of the flange, offering good pressure containment in high-temperature applications. · Lap Joint Flange: Used with a stub end and ideal for applications requiring frequent disassembly. Grades and Their Chemical Composition: · Grade 304 (AISI 304): This grade has a chemical composition consisting of 18-20% chromium, 8-10.5% nickel, with a carbon content of up to 0.08%. It also contains small amounts of manganese (2.00-2.50%), silicon (≤ 1.00%), phosphorus (≤ 0.045%), and sulfur (≤ 0.030%), while the rest is iron. It is widely used due to its good corrosion resistance, weldability, and formability. · Grade 316 (AISI 316): The chemical composition of 316 includes 16-18% chromium, 10-14% nickel, and 2-3% molybdenum. It also contains up to 0.08% carbon, 2.00-2.50% manganese, and ≤ 1.00% silicon, with iron making up the balance. The addition of molybdenum provides improved resistance to corrosion, particularly in chloride environments, making it suitable for marine and chemical industries · Grade 321 (AISI 321): This grade has a chemical composition with 17-19% chromium, 9-12% nickel, and a maximum carbon content of 0.08%. It also contains 2.00-2.50% manganese, ≤ 1.00% silicon, and small amounts of phosphorus (≤ 0.045%) and sulfur (≤ 0.030%). The remainder is iron. Grade 321 is stabilized with titanium to prevent sensitization and is highly resistant to intergranular corrosion, making it ideal for high-temperature applications like in the aerospace and chemical industries. Applications: DIN 2545 Stainless Steel Flanges (PN 40) are widely used in various industries due to their superior strength, corrosion resistance, and versatility. These flanges are specifically designed to handle higher pressure ratings (PN 40), making them ideal for demanding applications. Some of the key applications include: -Chemical Processing: Used in the manufacturing of chemicals, pharmaceuticals, and petrochemicals, where high resistance to corrosion is essential. -Oil and Gas Industry: For pipelines, pumps, and valves that transport oil, gas, and other fluids under high pressure. -Water Treatment Plants: Employed in water and wastewater management systems to connect piping and ensure leak-free connections under high pressure. -Food and Beverage Industry: In production systems where hygiene and corrosion resistance are critical, especially in food processing and dairy plants. -Power Generation: For use in power plants in systems such as steam lines and cooling circuits that operate under high-pressure conditions. -Marine and Offshore: Often used in ships, platforms, and offshore structures that are exposed to harsh environmental conditions. -HVAC Systems: In high-pressure heating, ventilation, and air conditioning applications. DIN 2545 Stainless Steel Flanges (PN 40) offer both durability and reliability in these high-pressure applications, ensuring safe and efficient performance in various industries. Conclusion: DIN 2545 SS flanges provide a reliable and robust solution for piping systems across various industries. These flanges are widely used in applications ranging from general industrial use to highly specialized sectors like aerospace, marine, and chemical processing, ensuring safe and efficient operation in demanding environments. The PN 40 rating guarantees they can withstand medium-to-high pressure systems.

DIN 2543 Stainless Steel Flanges are flanges made from stainless steel that conform to the German industrial standard DIN 2543. These flanges are used to connect pipes, valves, pumps, and other equipment within a piping system. The DIN 2543 standard defines the specifications, dimensions, and materials for flanges used primarily in industrial applications where high strength, durability, and corrosion resistance are required. DIN 2543 refers to the "Flanges for pipes, slip-on flanges, welding neck flanges, and blind flanges." DIN 2543 flanges are PN 16, and they have specific dimensional standards for that pressure rating, ensuring compatibility and safety in pipeline applications. Here's a detailed description of DIN 2543 Stainless Steel Flanges: 1. Standard Overview (DIN 2543): • DIN 2543 refers to flanges that are used to connect pipes and related components in various industrial systems. It specifies welding neck flanges, slip-on flanges, and blind flanges among others. • The flanges covered by this standard are available in different pressure classes and materials, including stainless steel. • The main application of these flanges is in piping systems for industries such as chemical, oil and gas, water treatment, food processing, and HVAC. 2. Types of DIN 2543 Flanges: The standard covers different types of flanges, each with its own application: • Welding Neck Flanges (WN): o These flanges are designed to be welded to the pipe. They have a long tapered neck that provides better stress distribution and is suitable for high-pressure applications. o Application: Common in high-pressure and high-temperature systems. • Slip-On Flanges (SO): o These flanges fit over the pipe and are welded at both the inside and outside edges. They are easier to install compared to welding neck flanges. o Application: Suitable for low- and medium-pressure systems. • Blind Flanges (BL): o These flanges are used to seal the end of a pipe. They have no central hole and are typically used to close off piping systems or for future extensions. o Application: Used when a permanent or temporary closure is needed in a piping system. 3. Materials for Stainless Steel Flanges: DIN 2543 Stainless Steel flanges are typically manufactured from the following grades of stainless steel, which are selected based on the specific requirements of the application: • Grade 304 Stainless Steel (AISI 304): o The most common type of stainless steel, offering good corrosion resistance and forming ability. It is suitable for general-purpose applications in environments not subject to severe corrosion. o Applications: Food and beverage processing, chemical industries, and general industrial applications. • Grade 316 Stainless Steel (AISI 316): o Contains molybdenum (2–3%), which significantly enhances its resistance to pitting and crevice corrosion in chloride environments. It is widely used in more corrosive environments such as marine or chemical processing applications. o Applications: Marine environments, chemical industries, pharmaceuticals, and offshore applications. • Grade 321 Stainless Steel (AISI 321): o Similar to 304 but with added titanium to prevent carbide precipitation during welding. It is ideal for high-temperature environments and offers good oxidation resistance. o Applications: High-temperature systems, aerospace applications, and heat exchangers. 4. Gasket Surface Types: The gasket surface of DIN 2543 stainless steel flanges is crucial for creating a proper seal when two flanges are joined. The most common gasket surface types include: • Raised Face (RF): o A flange with a raised area where the gasket is placed. This is the most common type and provides a reliable seal. • Flat Face (FF): o The flange surface is flat and typically used in lower-pressure systems. • Ring Type Joint (RTJ): o This type has a groove for the insertion of a metal ring gasket, used in high-pressure or high-temperature applications. DIN 2543 SS flanges are designed to provide strong, durable, and leak-proof connections for pipes in various industries, with precise dimensions, materials, and pressure ratings tailored to different operational needs. The different types of flanges (Slip-on, Welding Neck, and Blind) allow for versatile use in a variety of applications.

DIN 2527 Titanium Grade 5 Blind Flanges are premium-quality sealing components designed to close off the open ends of pipes, vessels, or equipment in systems where no further connection is needed. Made from Titanium Grade 5 (Ti-6Al-4V), these flanges are known for their superior strength, excellent corrosion resistance, and lightweight properties. Titanium Grade 5 is an alloy composed of titanium, aluminum, and vanadium, making it stronger and more heat-resistant than commercially pure titanium (Grade 2). These flanges adhere to the DIN 2527 standard, ensuring that they meet the precise requirements for dimensional accuracy, pressure tolerance, and mechanical performance. Material Composition of Titanium Grade 5 (Ti-6Al-4V): Titanium Grade 5, also known as Ti-6Al-4V, is composed of the following elements: Titanium (Ti): 90.0% min Aluminum (Al): 6.0% - 7.0% Vanadium (V): 3.5% - 4.5% Iron (Fe): 0.25% max Oxygen (O): 0.20% max Carbon (C): 0.10% max Nitrogen (N): 0.05% max Hydrogen (H): 0.015% max Titanium Grade 5 is one of the most widely used titanium alloys due to its high strength, resistance to corrosion, and ability to withstand elevated temperatures, making it suitable for high-performance applications. Key Features of DIN 2527 Titanium Grade 5 Blind Flanges: Superior Strength: Titanium Grade 5 offers high strength (approximately 130 ksi tensile strength) while maintaining its light weight, making it suitable for demanding applications where both strength and low mass are important, such as in aerospace and military systems. Corrosion Resistance: Titanium Grade 5 exhibits exceptional corrosion resistance, particularly against chlorides, seawater, and acidic environments. It is highly resistant to pitting, crevice corrosion, and stress corrosion cracking. It performs well in the presence of strong acids like sulfuric and hydrochloric acids, making it suitable for chemical processing systems, offshore, and marine applications. Temperature Resistance: Titanium Grade 5 can withstand elevated temperatures, with a continuous operating temperature up to 400°C (752°F) and intermittent exposure to higher temperatures. This makes it suitable for high-temperature applications in aerospace, power generation, and chemical industries. Light Weight: Titanium alloys, including Grade 5, have a very low density, approximately 60% of that of steel, making them an excellent choice for applications where weight reduction is a priority, such as in the aerospace and automotive industries. Dimensional Accuracy & Pressure Ratings: DIN 2527 Titanium Grade 5 Blind Flanges are manufactured to exacting standards to ensure a tight, secure seal in piping systems. Available in various pressure classes such as PN6, PN10, and PN16, allowing compatibility with a range of piping systems depending on the pressure requirements. Design Options: Standard Blind Flange (Type A): A solid, circular flange used to seal the end of a pipe or vessel. Flat-Faced Blind Flange: Designed with a flat sealing surface for low-pressure systems. Raised Face Blind Flange: Features a raised area around the center for improved sealing in higher pressure applications. Ring-Type Joint (RTJ) Blind Flange: Designed for high-pressure applications with a groove for a ring-type joint gasket, commonly used in the oil and gas industries. Long Weld Neck Blind Flange: Includes an extended neck for welding, providing additional strength in high-pressure or stressed systems. Nominal Diameter: DIN 2527 Titanium Grade 5 Blind Flanges are available in a variety of nominal diameters (DN), ranging from DN10 (1/2 inch) up to DN600 (24 inches) or larger, depending on system requirements.

DIN 2527 Monel Blind Flanges are critical components used in piping systems to seal the open ends of pipes, vessels, or equipment when no further connection is needed. These blind flanges are made from Monel alloys, a group of nickel-copper-based alloys known for their exceptional corrosion resistance, especially in harsh marine and chemical environments. Monel flanges, manufactured to the DIN 2527 standard, ensure superior strength and reliability in demanding applications, making them ideal for industries such as chemical processing, marine, and power generation. Material Composition of Monel Alloys: Monel alloys are primarily composed of Nickel (Ni) and Copper (Cu), along with small amounts of other elements such as iron, manganese, and silicon. Two of the most commonly used Monel alloys in blind flange production are: Monel 400: Nickel (Ni): 63% Copper (Cu): 28-34% Iron (Fe): 2.5% max Manganese (Mn): 2.0% max Silicon (Si): 0.5% max Carbon (C): ≤ 0.30% Sulfur (S): ≤ 0.024% Monel K-500: Nickel (Ni): 63% Copper (Cu): 28% Aluminum (Al): 2.3-3.1% Titanium (Ti): 0.35-0.85% Iron (Fe): 2.5% max Manganese (Mn): 1.0% max Silicon (Si): 0.5% max Carbon (C): ≤ 0.30% Sulfur (S): ≤ 0.015% Key Features of DIN 2527 Monel Blind Flanges: Corrosion Resistance: Monel alloys are highly resistant to a wide variety of corrosive agents, including seawater, sulfuric acid, hydrochloric acid, and alkaline environments. Monel 400, in particular, is known for its excellent resistance to chloride-induced stress corrosion cracking, making it ideal for marine applications. Monel K-500 offers enhanced strength and resistance to corrosion fatigue, commonly used in more challenging environments. Temperature Resistance: Monel 400 can withstand temperatures up to 1000°F (538°C) continuously and up to 1200°F (649°C) intermittently. Monel K-500 offers high strength and resistance to oxidation and scaling in environments up to 1000°F (538°C). Mechanical Strength: Monel 400 is known for its strength and durability, especially in environments that require resistance to both high pressure and corrosion. Monel K-500 exhibits additional strength due to the presence of aluminum and titanium, making it suitable for applications under higher stresses. Dimensional Accuracy and Pressure Class: DIN 2527 Monel Blind Flanges are manufactured to precise dimensions, ensuring a secure seal in the piping system. These flanges are available in various pressure classes, such as PN6, PN10, PN16, and others, providing flexibility for different pressure ratings. Design Options: Standard Blind Flange (Type A): A solid, flat disc used to seal the end of a pipe or vessel. Flat-Faced Blind Flange: Designed with a flat sealing surface, ideal for low-pressure systems. Raised Face Blind Flange: Features a raised surface around the center to improve sealing in high-pressure systems. Ring-Type Joint (RTJ) Blind Flange: Includes a groove for an RTJ gasket, used for high-pressure applications, often in the oil and gas industry. Long Weld Neck Blind Flange: Features an extended neck for welding, offering additional strength and used in high-pressure or stressed systems. Nominal Diameter: DIN 2527 Monel Blind Flanges are available in a wide range of sizes, typically from DN10 (1/2 inch) up to DN600 (24 inches) or more, depending on system requirements.

Titanium pipe fittings, including tees, elbows, and reducers, are essential components in the construction and maintenance of piping systems. Known for their superior strength, corrosion resistance, and lightweight properties, titanium fittings are ideal for industries such as aerospace, chemical processing, marine, and power generation. Titanium Tee Fittings Titanium tees are used to connect three sections of piping in a T-shaped configuration. This fitting allows for the branching of pipelines in a single direction, offering excellent durability and resistance to harsh environments. With titanium’s high strength-to-weight ratio and resistance to corrosion, these tees ensure reliable flow management in challenging applications. Titanium Elbow Fittings Titanium elbows are used to change the direction of fluid flow in a piping system. These fittings come in various angles, including 45°, 90°, and 180°, providing flexibility in routing pipes around obstacles or to specific angles. The lightweight nature of titanium and its high resistance to oxidation and chemical degradation make titanium elbows an optimal choice for systems that operate in high-pressure and corrosive environments. Titanium Reducer Fittings Titanium reducers are designed to connect pipes of different diameters, reducing or increasing the flow capacity between sections. Available in concentric or eccentric designs, titanium reducers help in optimizing flow rates while maintaining system integrity. The corrosion-resistant properties of titanium ensure that these reducers maintain their performance even in extreme temperature and pressure conditions. Advantages of Titanium Pipe Fittings Corrosion Resistance: Titanium resists a wide range of aggressive chemicals and environmental conditions, including seawater, chlorine, and acidic or alkaline substances. High Strength-to-Weight Ratio: Titanium fittings offer exceptional strength while remaining lighter than many alternative materials, leading to easier handling and lower transportation costs. Durability: These fittings are designed for long-lasting performance, even in demanding conditions where other materials might fail. Biocompatibility: In industries such as medical and aerospace, titanium’s biocompatibility ensures it is safe for specialized applications. Titanium pipe fittings – tee, elbow, and reducer – provide a combination of strength, flexibility, and durability that enhances the performance of your piping systems.

Product name: 25mm Titanium Bar Material: Gr1 Gr2 Gr3 Gr4 Gr5 Gr7 Gr12 etc. Standard : ASTM B348,ASTM B381, ASTM F136, ASTM F67,AMS 4928 Size: Dia 5--200mm * Max L6000mm Applications :Industry, aviation, military etc. Supply status: Annealed Package: Carton or plywood case. Quality and Test : EN10204.3.1 certificate Surface:CNC machined polished MOQ : 10kgs Feature : low density, special strong strength, excellent corrosive resistance 25mm gr5 Titanium Bar Titanium bar has many advantages: 1.Titanium Bright Bar has a low thermal expansion, which puts it at 1/3rd that of aluminium. 2.Titanium Alloy Round Rod is light in weight, which would put the specific gravity of this metal at about 1.7 times that of aluminium. and about 60% of specific gravity of steel. 3.Titanium Alloy Hexagon Bars tend to be non-magnetic in nature. 4.The heat conductivity of Titanium Alloy Square Bar is low, and is nearly the same as grade 18-8 stainless steel. Similarly, the electric conductivity of the alloy is low and the electric conductivity of titanium Cold Finished Bar about 3% of copper. 5.Titanium Polished Bar has high flexibility i.e. its Longitudinal elastic modulus. Which means that the flexibility of ASTM B348 Ti Alloy Hex Bar is one half of iron or stainless steel and it is the same as copper. Product name 25mm Titanium Bar,grade 2 titanium bar , grade 5 titanium bar ,grade 7 titanium bar,titanium bar price per kg Material Titanium, pure titanium Standard ASTM B348, ASTM F136, ASTM F67, ASTM F136, ISO-5832-2(3), AMS4928 etc. Titanium Grade Round Bar Sizes Minimum diameter: 0.040 inch or 1.00 mm Maximum diameter: 14.000 inch or 400.00 mm Type Ti square bar, Ti round bar, Ti hexagonal bar, Ti flat bar, Titanium Alloy Bars, Ti Billets, Forgings, and Forging Stock Condition R/M /Y ASTM B348 Ti Alloy Hex Bar size 2-100mm A/F Titanium Alloy Flat bar size Thickness: 2 -100mm Width: 10 to 500mm Pure Titanium Square bar size 4 to 100mm AMS Specificaton of Titanium Round Bar ASTM B348 (Grade 5), ASTM B348 (Grade 2), ASTM B348 (Grade 4), ASTM B348 (Grade 23), ASTM F67 (Grade 2), ASTM F67 (Grade 4), ASTM F136, ASTM F1472, MIL-T-9047 (6AL-4V), MIL-T-9047 (6AL-4V ELI), MIL-T-9047 (6AL-6V-2SN), MIL-T-9047 (CP-70 GR.4), AMS 6935, AMS 6936, AMS-T-9047 (6AL-4V), AMS-T-9047 (6AL-4V ELI), AMS-T-9047 (6AL-6V-2SN), AMS-T-9047 (CP-70 GR.4), DMS 1570, DMS 1583, AMS 4971, AMS 4921, AMS 4928, AMS 4930, AMS 4965, AMS 4967, AMS 4978, AMS 4979, AMS 6930, AMS 6931 and More. Titanium Angle bar size (in mm) 3*20*20~12*100*100 ASTM B348 Titanium Section 3.0 to 12.0mm thickness Titanium ASTM B348 Channel Bar (in mm) 80 x 40 to 150 x 75 section; 5.0 to 6.0 thickness Pure Titanium Hollow Bar (in mm) 32 OD x 16 ID to 250 OD x 200 ID) Titanium Alloy Billet Size 1/2" to 495mm Diameter ASTM B348 Ti Alloy Rectangles Size 33 x 30mm to 295 x 1066mm ASTM B348 Ti Alloy Round Bar Finish Cold (bright) drawn, centreless ground, hot rolled, smooth turned, peeled, slit rolled edge, hot rolled annealed, Rough Turned, Bright, Polish, Grinding, Centreless Ground & Black ASTM B348 Ti Round Bar Surface Bright, Hot Rolled Pickled, Cold Drawn, Sand Blasting Finished, Polished, Hairline Titanium Round Bar Uses chemical industry, Industrial, medical industry, military industry etc Titanium round bar Condition Hardened & tempered, annealed ASTM B348 Ti Alloy Bar Technique Hot Rolled, Cold Drawn, Cold Rolled, Forged Round Bar, Rod Titanium Alloy Round Bar Tolerance H8, H9, H10, H11, H12, H13K9, K10, K11, K12 or as per clients’ requirements Alloy Titanium Bar Processing Bar cutting to 650mm Standard Specification : ASTM B348 / ASME SB348 UNS grade Products Grade 1 - UNS R50250Grade 2 - UNS R50400Grade 5 - UNS R56400 Grade 7 - UNS R52400 Grade 9 - UNS R56320 Grade 12 - UNS R53400 Titanium Round Bar Titanium Rod Titanium Hex Bar Titanium Flat Bar Titanium Rods Titanium Square Bar Type SIZES (mm) SIZES (Inches) ISO Tolerance Titanium Alloy Cold Drawn and Polish Round Bar 3.00 – 75.00 1/8" – 3.00" h8-h9-h10-h11 Titanium Cold Drawn and Ground Bar 10.00 – 75.00 5/6" – 2.50" h8-h9-h10-h11 ASTM B348 Ti Alloy Peeled and Polished Round Bar 40.00 – 150.00 1.50" – 6.00" h11, h11-DIN 1013 Titanium Alloy Peeled and Ground Bar 20.00 – 50.00 3/4″ – 2.00" h9-h10-h11 Titanium Alloy Bars Standard lengths of 2000 mm up to 6010 mm. Cut to size on request (tolerance +2/-0 mm).

Product name: Titanium alloy Tubes Standard:ASTM B338 ASTM B861 ASTM B862 Material:Titanium Gr7 Diameter:5-914mm Wall thickness:0.5-50mm Length:Max 16000mm Surface:Pickling surface/Polished Type:Seamless, welded Application:Heat Exchanger, chemical industry etc. Technique:Rolled Because stainless steel and other materials are inefficient in many cases, titanium tubes are increasingly used in various occasions. A common titanium grinding product is titanium tube. Because of its superior corrosion resistance and strength weight ratio, titanium tube is used in various products. The development of many different alloys has expanded the application of titanium in industry, chemical processing and power generation. Commodity Titanium Alloy Tube /Pipe/Tubing,titanium alloy seamless tube/pipe,titanium alloy welded tube pipe,ASTM B338 titanium tube,Titanium pipe price per kg Tube Shape Round Square Flat Coil Material Gr1,Gr2,Gr3,Gr4,Gr5(Ti-6Al-4V),Gr7,Gr9,Gr11,Gr12,Gr23(Ti-6Al-4V Eli) Standard ASTM B337 ASTM B338 ASTM B861 ASTM B862 Type Seamless Welded ERW Fabricated OD 5-914mm or as customized Wall Thickness 0.5-50mm or as customized Length Max 16000mm End Plain End, Beveled End, Threaded Certificate EN 10204/3.1B, Raw Materials Certificate 100% Radiography Test Report Third Party Inspection Report, etc Application Off-Shore Oil Drilling Companies Power Generation Petrochemicals Gas Processing Specialty Chemicals Pharmaceuticals Pharmaceutical Equipment Chemical Equipment Sea Water Equipment Heat Exchangers Condensers Pulp and Paper Industry Titanium alloy tubes can be divided into three categories according to phase composition: α Alloy（ α+β) Alloy and β alloy 1. α Stability of alloy containing a certain amount α The element of phase, in equilibrium, is mainly composed of α Phase composition. α The alloy has small specific gravity, good thermal strength, good weldability and excellent corrosion resistance. Its disadvantage is low strength at room temperature. It is usually used as heat-resistant and corrosion-resistant materials. α Alloys can usually be divided into complete alloys α Alloy (Gr7), near α Alloy (ti-8al-1mo-1v) and alloy with a small amount of compounds α Alloy (Ti-2.5Cu). 2. ( α+β) Stability of alloy containing a certain amount α Phase harmony β Phase elements, and the microstructure of the alloy in equilibrium is α Phase harmony β Phase. ( α+β) The alloy has medium strength and can be strengthened by heat treatment, but its weldability is poor. ( α+ β) Alloys are widely used, and the output of Ti-6Al-4V Alloy accounts for more than half of all titanium materials. 3. β The alloy contains a large amount of stable β Phase elements can be used at high temperature β All phases were retained to room temperature. β Alloys can usually be divided into heat treatable alloys β Alloy (metastable) β Alloy and near metastable β Alloy) and thermal stability β Alloy. Heat treatable β The alloy has excellent plasticity in quenched state, and the tensile strength can reach 130 ~ 140kgf / mm2 by aging treatment. β Alloys are usually used as high strength and high toughness materials. The disadvantages are large ratio, high cost, poor welding performance and difficult machining.