'flat solid piece'

DIN 2576 Stainless Steel Flanges PN 10 are high-quality, slip-on flanges manufactured from corrosion-resistant stainless steel, designed for use in low to medium-pressure piping systems. Produced according to the DIN 2576 standard, these flanges offer reliable sealing, ease of installation, and long-term durability in environments involving water, steam, air, oil, and chemical fluids. The slip-on design allows the flange to slide over the pipe and be welded into place, ensuring accurate alignment and structural integrity in a wide range of industrial applications. Ladhani Metal Corporation is a recognized manufacturer and global exporter of stainless steel flanges, delivering products that meet international quality, dimensional, and performance standards. DIN 2576 flanges provide excellent mechanical strength and corrosion resistance, making them ideal for use in chemical plants, water treatment systems, and general process industries. Pressure Rating: • PN 10 (10 bar / 145 psi): Designed for systems operating under low to moderate pressure, offering dependable performance in industrial fluid and gas transport. Flange Types: • Slip-On Flanges Designed to slip over the pipe and be welded on both the inside and outside, these flanges provide easy installation and solid structural support. • Flat Face (FF) Flanges Used with flat gaskets and flat mating surfaces to ensure even gasket compression and proper load distribution, especially when joining with non-metallic components or cast iron. Stainless Steel Grades and Composition: Stainless Steel 304 (UNS S30400) Composition: • Chromium (Cr): 18.0 – 20.0% • Nickel (Ni): 8.0 – 10.5% • Carbon (C): ≤ 0.08% • Manganese (Mn), Silicon (Si), Phosphorus (P), Sulfur (S): Trace amounts • Iron (Fe): Balance Applications: 304 stainless steel offers good corrosion resistance, formability, and weldability, making it suitable for applications in food processing, water piping, and light chemical handling. Stainless Steel 316 (UNS S31600) Composition: • Chromium (Cr): 16.0 – 18.0% • Nickel (Ni): 10.0 – 14.0% • Molybdenum (Mo): 2.0 – 3.0% • Carbon (C): ≤ 0.08% • Iron (Fe): Balance Applications: 316 stainless steel is ideal for more aggressive environments, offering superior resistance to chlorides, acids, and marine exposure. Common applications include chemical plants, pharmaceutical systems, and marine piping. Stainless Steel 321 (UNS S32100) Composition: • Chromium (Cr): 17.0 – 19.0% • Nickel (Ni): 9.0 – 12.0% • Titanium (Ti): ≥ 5x(C) minimum • Carbon (C): ≤ 0.08% • Iron (Fe): Balance Applications: 321 stainless steel is stabilized with titanium to resist intergranular corrosion after welding. It is commonly used in high-temperature applications such as exhaust systems, heat exchangers, furnace parts, and thermal fluid piping in the chemical and petrochemical industries. Applications of DIN 2576 Stainless Steel Flanges: • Chemical and Petrochemical Industries Used in piping systems that handle corrosive chemicals, acids, and solvents, ensuring safe and long-lasting operation. • Water Treatment and Distribution Widely used in pipelines for potable water, wastewater, and desalination plants due to their corrosion resistance and hygienic properties. • Food and Beverage Processing Ideal for sanitary fluid handling systems, where stainless steel ensures contamination-free and easy-to-clean connections. • Marine and Offshore Applications Suitable for piping exposed to seawater and atmospheric corrosion, especially in deck and ballast systems. • General Industrial Use Used in heating systems, compressed air lines, fire protection networks, and process piping. • High-Temperature Services Grade 321 stainless steel is preferred in applications involving thermal cycling and continuous elevated temperatures, such as refinery piping and power plant components. Key Features: • Manufactured according to DIN 2576 standard • PN 10 pressure rating for low to medium-pressure systems • Excellent corrosion resistance and mechanical strength • Available in stainless steel 304, 316, 321, and other grades • Slip-on design ensures easy welding and alignment • Flat face options available for specific gasket and joint requirements • Suitable for chemical, marine, thermal, and general industrial applications • Available in customized sizes, face types, and surface finishes Conclusion: DIN 2576 Stainless Steel Flanges PN 10 from Ladhani Metal Corporation provide reliable, corrosion-resistant performance for a wide range of industrial systems operating under moderate pressure. For technical support, material selection, or custom orders, contact Ladhani Metal Corporation today. 📞 Contact Ladhani Metal Corporation Website: https://www.ladhanimetal.in/ https://www.ladhanimetal.com/ Email: info@ladhanimetals.com Request a Quote: Custom dimensions, materials, and finishes available upon request.

A tungsten alloy block is a solid piece of tungsten metal alloy, typically made by combining tungsten with other metals like nickel, iron, or copper to enhance its properties. These blocks are known for their exceptional density, strength, and high resistance to heat, corrosion, and wear. Due to these characteristics, tungsten alloy blocks are widely used in industries that require durable materials capable of withstanding extreme conditions. Tungsten alloy blocks are commonly used in aerospace, defense, medical, and manufacturing applications. They are often used for producing high-performance components such as counterweights, radiation shielding, military projectiles, and components for heavy machinery. The material's high density also makes it ideal for applications like ballast and vibration damping. Characteristics: High Density and Strength: Tungsten alloy blocks are notably dense, with densities ranging from 16 to 19 grams per cubic centimeter (g/cm³), making them among the heaviest materials available. This makes them ideal for applications requiring heavy, compact materials. High Melting Point: Tungsten has one of the highest melting points of any metal, around 3422°C (6192°F), which ensures that tungsten alloy blocks maintain their structural integrity even under extreme temperatures. This property makes them highly suitable for applications in aerospace and defense sectors where high heat resistance is critical. Excellent Wear and Corrosion Resistance: The tungsten alloy's resistance to wear, corrosion, and abrasion is enhanced by the alloying elements, especially when the blocks are used in harsh environments or for high-wear applications. This makes them ideal for parts exposed to friction or high-stress conditions. Machinability: While tungsten itself is quite hard and brittle, alloying it with materials like nickel and iron improves its machinability. Tungsten alloy blocks are typically produced in a variety of forms, including standard sizes and custom shapes, making them suitable for a range of industrial applications.

A pure tungsten tube is a hollow cylindrical shape made from 100% tungsten metal, known for its exceptional physical properties, including high strength, resistance to high temperatures, and high density. These tubes are produced for specific industrial, scientific, and technological applications where extreme conditions are involved. Key Characteristics of a Pure Tungsten Tube 99.95% Pure Tungsten (W): A tungsten tube is made from pure tungsten metal, meaning it contains no significant alloys or impurities, allowing it to retain the full range of tungsten's advantageous properties. High Density:Tungsten has one of the highest densities of any metal, at 19.25 g/cm³, making tungsten tubes compact and heavy, which is beneficial in applications that require high mass in a small volume. Extremely High Melting Point: Tungsten has the highest melting point of any metal, at 3,422°C (6,192°F), which makes it ideal for high-temperature applications, such as in aerospace or certain high-performance industrial processes. Strength and Durability: Pure tungsten tubes are incredibly strong, with a high tensile strength around 1510 MPa, meaning they can endure extreme mechanical stresses without deforming or failing. Tungsten also exhibits high wear resistance, which makes the tube durable in harsh, abrasive environments. Corrosion Resistance: Tungsten is highly resistant to corrosion, oxidation, and environmental degradation, even under extreme conditions, including at high temperatures, making tungsten tubes suitable for long-term, reliable use. Applications of Pure Tungsten Tubes: Aerospace and Defense: Rocket nozzles, satellite components, and spacecraft parts benefit from tungsten tubes due to their ability to withstand extreme temperatures and mechanical stresses. Armor-piercing projectiles and military components can also be made from tungsten due to its high density and strength. High-Temperature and High-Pressure Applications: Tungsten tubes are often used in high-temperature environments like furnaces, industrial heating elements, and thermal processing chambers where metals with high melting points are required. Gas turbines and jet engines can also incorporate tungsten tubing for high-temperature stability and strength.

Product Name: Gr5 titanium bar for medical Standard: ASTM F136/ ISO 5832-3 Material: Grade 5/Gr23 Unit Price: $25.5usd/kg- $55.5usd/kg Shape: Round Diameter: 3-350mm Length: Max 6000mm Surface: Bright

Product Name: Titanium Bar Standard: ASTM B348 Material: GR1, GR2, GR5, GR7, GR12 Unit Price: $15usd/kg- $30usd/kg Shape: Round, Square, Flat, Hex Diameter: 6-350mm Length: Max 6000mm Surface: Bright

Product Name: Medical Titanium Bars Standard: ASTM F136/ ISO 5832-3 Material: Grade 5/Gr23 Unit Price: $25.5usd/kg- $55.5usd/kg Shape: Round Diameter: 3-350mm Length: Max 6000mm Surface: Bright Condition: Annealed Application:Medical,surgical implant(Bone nail implant, dentistry etc.) Medical titanium material has excellent corrosion resistance, elastic modulus close to natural bone, and good biocompatibility. Medical pure titanium is a single-phase structure, which can not be strengthened by heat treatment. It can be used as internal bone plate, bone screw, dental implant, etc. it can also be used as artificial skull, artificial heart valve, pacemaker and titanium alloy for radiother.

Product name:Titanium Elliptical Dished Head Standard: ASME VIII-I, DIN28013 Material: Titanium GR1, GR2 Size: Customized Titanium Hemispherical Dish Head Brand name LHTi Product name Titanium Hemispherical Dish Head Material Titanium & titanium alloy (Grade 1 Grade 2 Grade 7 Grade 12 etc.) Size DN - 100mm : 6000mm (customized size avaliable) Wall Thickness 3mm ~ 300mm (customized thickness available) Process Type Hot pressing, cold pressing, cold spinning Connection Type Butt-welded or threaded Edge Type Bevel, Plain or as required Process of depression Once the plate is cut into a circle (using a circular cutter, laser, plasma or other methods), the resulting plate is formed under the press and will be crowned with the plate by multiple impacts on the whole surface. In order to make different types and diameters of disc ends, a disc press must be equipped with a set of molds with different radii. The serving process is quite slow. Depending on the size and material of the plate, it usually takes several hours. This process can be automated by using a CNC manipulator. It is possible to find a press with CNC, which can handle more than 10 shafts and can run automatically for several hours. In addition to automation, another important factor in the disk making process is speed. The two speed press can greatly increase the output. The punch presses the workpiece continuously. This means that the structure of disc press is easily affected by material fatigue; Therefore, the life of the press designed to save cost may be very short, showing the first crack of the structure in a very short time. The press designed with HPT has better fatigue resistance. This design consists of four main parts: upper beam, lower beam and two columns. The two beams are connected with the column through the hydraulic preload pull rod. Compared with seam welding or bolts, these tie rods can better resist continuous stress, so as to provide more elasticity to the structure. Dished multi center end A special dished end is widely used in truck can body manufacturers: multi center dished end. These disc-shaped ends are usually made of aluminum or stainless steel and are usually made of thin plates up to 6 mm. This thickness allows the formation of multi center dished ends using a technique called hydroforming.

Being one of the leading organization in the market, highly involved in offering a broad range of Dished Ends as per DIN 28011 And DIN28013 to our esteemed customers. Our offered products are manufactured suing utmost quality raw material which is obtained from the authentic vendor if the supplier. Moreover, these products are accessible in different sizes and dimensions to suit the varied demands and needs of our customers.We Manufacture and Export Types Of Dishends / Endcaps / Heads ELLIPSOIDAL HEAD HEMISPHERICAL HEAD. TORISPHERICAL HEAD KLÖPPER HEAD KORBBOGEN HEAD Semi ellipsoidal head DIN28013 Flat dished heads Standard Flat dished heads Flat heads Convex Discs Plate Type Heads Diffuser Heads Cone , Bulk & Tank Vehicle Heads Weld Counstriction Special Pressed part Experienced In Making Grades Like Carbon steel,P265-GH, 16Mo3,15NiCuMoNb5, CrMo(V), Alloy steel, 10CrMo9-10,13CrMo4-5,ASME SA 387 Gr.11,Gr12,ASME SA 387 Gr.91,P355-Gh,-NH,-NL1,-NL2,ASME SA 516 Gr.60 , Gr.70,Stainless steel 1.4301,1.4307,1.4404,1.4541,1.4571,1.4539,1.4501,Stainless steel ASME SA240 304,304L,316,316l,321,321H,316Ti,904L,2205,Super Duplex 1.4462 , cr25,Nickel alloys Alloy 20,59,200,MONEL 400,INCONEL 600,601,625,INCOLOY 800,825, 825,Copper,Titanium Grade 2,Grade 5, Aluminium Test method: Impact -Test acc. to DIN EN 10045-2 Tensile test acc to DIN EN 10002-1 , ISO 6892-1 , ASTM A 370 Hot tensile test acc to DIN EN 10002-5 until 900°C Hardness Test acc. to Brinell and DIN EN ISO 6506-1 Testing of intercrystalline corrosion acc to ISO 3651-2 (A) , ASTM A 262 Pract. E X – Ray -Examination acc. to EN 1435 , ISO 5817 , ASME V Art.2 , VIII Div.1 § UW -51 UT - Ultrasonic testing acc. to EN 10160 , EN 10307 , ASME SA-578 , ASME SA-435 PT - Penetrant testing acc. to EN 571 , ASME V Art.6 , ASME VIII Div.1 App.8 MT- Magnetic particle testing acc. to EN 1291 , ASME V Art.7 , ASMEVIII Div.1 App.6 Certificate: Certificate acc. to EN 10204 - 3.1 and 3.2 from independent organization

Being one of the leading organization in the market, highly involved in offering a broad range of Dished Ends as per DIN 28011 And DIN28013 to our esteemed customers. Our offered products are manufactured suing utmost quality raw material which is obtained from the authentic vendor if the supplier. Moreover, these products are accessible in different sizes and dimensions to suit the varied demands and needs of our customers.We Manufacture and Export Types Of Dishends / Endcaps / Heads ELLIPSOIDAL HEAD HEMISPHERICAL HEAD. TORISPHERICAL HEAD KLÖPPER HEAD KORBBOGEN HEAD Semi ellipsoidal head DIN28013 Flat dished heads Standard Flat dished heads Flat heads Convex Discs Plate Type Heads Diffuser Heads Cone , Bulk & Tank Vehicle Heads Weld Counstriction Special Pressed part Experienced In Making Grades Like Carbon steel,P265-GH, 16Mo3,15NiCuMoNb5, CrMo(V), Alloy steel, 10CrMo9-10,13CrMo4-5,ASME SA 387 Gr.11,Gr12,ASME SA 387 Gr.91,P355-Gh,-NH,-NL1,-NL2,ASME SA 516 Gr.60 , Gr.70,Stainless steel 1.4301,1.4307,1.4404,1.4541,1.4571,1.4539,1.4501,Stainless steel ASME SA240 304,304L,316,316l,321,321H,316Ti,904L,2205,Super Duplex 1.4462 , cr25,Nickel alloys Alloy 20,59,200,MONEL 400,INCONEL 600,601,625,INCOLOY 800,825, 825,Copper,Titanium Grade 2,Grade 5, Aluminium Test method: Impact -Test acc. to DIN EN 10045-2 Tensile test acc to DIN EN 10002-1 , ISO 6892-1 , ASTM A 370 Hot tensile test acc to DIN EN 10002-5 until 900°C Hardness Test acc. to Brinell and DIN EN ISO 6506-1 Testing of intercrystalline corrosion acc to ISO 3651-2 (A) , ASTM A 262 Pract. E X – Ray -Examination acc. to EN 1435 , ISO 5817 , ASME V Art.2 , VIII Div.1 § UW -51 UT - Ultrasonic testing acc. to EN 10160 , EN 10307 , ASME SA-578 , ASME SA-435 PT - Penetrant testing acc. to EN 571 , ASME V Art.6 , ASME VIII Div.1 App.8 MT- Magnetic particle testing acc. to EN 1291 , ASME V Art.7 , ASMEVIII Div.1 App.6 Certificate: Certificate acc. to EN 10204 - 3.1 and 3.2 from independent organization