A Molybdenum Industrial Ring is a circular component made from molybdenum metal, designed for use in demanding industrial applications where high strength, thermal stability, and corrosion resistance are crucial. Molybdenum, known for its exceptional high-temperature properties and durability, makes these industrial rings highly suitable for environments that require reliable, long-lasting performance. Key Features of Molybdenum Industrial Rings: o High Melting Point: Molybdenum has a melting point of around 2,623°C (4,753°F), which enables it to withstand extremely high temperatures without degrading. This makes molybdenum industrial rings ideal for use in furnaces, reactors, and other high-temperature processes. o Strength and Durability: Molybdenum industrial rings are characterized by their excellent mechanical properties, including superior tensile strength and resistance to wear and deformation. This ensures that the rings maintain their shape and functionality under stress. o Corrosion and Oxidation Resistance: Molybdenum's resistance to corrosion, especially at high temperatures, makes these industrial rings suitable for use in harsh chemical environments, including petrochemical, nuclear, and other processing industries where exposure to aggressive substances is common. o Thermal and Electrical Conductivity: Molybdenum has good thermal and electrical conductivity, allowing it to be used effectively in applications where efficient heat transfer and electrical performance are required. This makes molybdenum industrial rings useful in electronics and energy industries. o Precision and Customization: Molybdenum industrial rings can be manufactured with precise dimensions, surface finishes, and tolerances to meet the specific requirements of each application. This makes them versatile and adaptable for a wide range of industrial needs. Common Applications: o Aerospace Industry: Molybdenum industrial rings are used in aerospace components such as turbine blades, rocket engine parts, and heat shields due to their ability to withstand high temperatures and mechanical stresses. o Chemical and Petrochemical Industries: Molybdenum rings are used in reactors, heat exchangers, and other chemical processing equipment where resistance to corrosion and high-temperature conditions is essential. o Electronics and Electrical Applications: Molybdenum industrial rings are employed in electronic devices, electrical contacts, and filaments, where their thermal and electrical conductivity properties are advantageous. o Steel Manufacturing and Metallurgy: Molybdenum rings are used in steel alloys to improve their strength, durability, and resistance to heat. They are also used in manufacturing molds and tools that require precision and high-temperature performance. o Energy Sector: In the nuclear and energy industries, molybdenum industrial rings are used in components that must endure high radiation and thermal conditions.

Tungsten-Copper Industrial Ring is a high-performance component made from an alloy of tungsten (W) and copper (Cu), combining the exceptional properties of both metals. This industrial ring is specifically designed for applications requiring both high strength and excellent thermal and electrical conductivity. The unique characteristics of tungsten-copper alloys make these rings suitable for use in industries such as aerospace, electronics, manufacturing, and energy, where they can withstand extreme conditions. Properties: · Density: Tungsten-copper industrial rings are very dense, with a specific gravity ranging between 17 g/cm³ and 19 g/cm³. The high density of the tungsten gives the ring its strength and mass, making it suitable for applications where weight or stability is important. · Color and Appearance: Tungsten-copper industrial rings generally have a metallic gray or brownish appearance due to the tungsten content, and the copper gives the ring a slightly reddish hue, depending on the specific ratio of the metals. · Size and Shape: These rings are typically available in various diameters and thicknesses depending on the application. Custom dimensions and designs can be produced to meet specific performance or size requirements. The rings can be precisely machined or cast to the desired specifications. · Strength: Tungsten provides the ring with high tensile strength, making it resistant to wear, deformation, and mechanical stress. The copper content improves overall impact resistance, reducing the risk of cracking under extreme conditions. · Hardness: Tungsten has a high level of hardness, which allows the industrial ring to resist abrasions, indentations, and general wear. However, copper improves the machinability of the alloy, enabling more complex shapes and designs. Applications of Tungsten-Copper Industrial Ring: · Heat Shields: Due to their high thermal conductivity and strength, tungsten-copper industrial rings are used in aerospace applications like heat shields and rocket nozzles, which must withstand extreme temperatures during flight. · Counterweights: Tungsten's high density makes it ideal for use in counterweights for aerospace structures or systems where weight distribution is critical. · Electrical Contacts: Tungsten-copper industrial rings are used in high-voltage electrical contacts due to their electrical conductivity and ability to manage heat dissipation. They are found in commutators, switches, and connectors where both conductivity and wear resistance are essential. · Heat Sinks: The thermal conductivity of tungsten-copper alloys makes these rings ideal for heat dissipation in power electronics or LED lights, where managing heat is crucial for performance. · Welding Electrodes: Tungsten-copper industrial rings can also be used in welding electrodes, particularly for arc welding applications where the material must endure extreme temperatures and provide stable electrical conduction.

Half Round Tube Shield Half Round Tube Shields by Ladhani Metal Corporation are designed to protect heat exchange surfaces such as boiler tubes, superheaters, and economizer coils from erosion, scaling, impact from ash particles, and flue gas corrosion. These shields are commonly applied in power plants, waste heat recovery boilers, and industrial heating systems to increase the service life of tubes and improve overall system reliability. Their semi-cylindrical shape ensures a snug fit over tube surfaces, especially in zones exposed to high-velocity gas flow or particulate matter. SS 410 Half Round Tube Shield for LTSH Tube The SS 410 Half Round Tube Shield is manufactured from martensitic stainless steel grade 410. This material offers high mechanical strength, moderate corrosion resistance, and excellent resistance to wear and oxidation in mildly corrosive and thermal environments. Specifically developed for Low Temperature Superheater (LTSH) applications, the SS 410 shield provides effective surface protection against soot, fly ash, and erosive gas streams where thermal and mechanical stresses are present. The Low Temperature Superheater (LTSH) is a section in a boiler where saturated steam from the steam drum is superheated to a moderately higher temperature before entering the high-temperature superheater stages. Positioned in areas with relatively lower flue gas temperatures, the LTSH helps improve thermal efficiency and reduces moisture content in steam. Due to constant exposure to abrasive flue gases and ash, LTSH tubes are prone to wear and require protective shielding, such as half round tube shields, to extend service life. Ladhani Metal Corporation is a trusted manufacturer, supplier, and exporter of SS 410 Half Round Tube Shields for LTSH applications, offering durable, cost-effective protection in thermal and industrial systems. Chemical Composition of SS 410 – Martensitic Stainless Steel • Carbon (C): 0.08 – 0.15% • Manganese (Mn): ≤ 1.00% • Phosphorus (P): ≤ 0.040% • Sulfur (S): ≤ 0.030% • Silicon (Si): ≤ 1.00% • Chromium (Cr): 11.5 – 13.5% • Nickel (Ni): ≤ 0.75% • Iron (Fe): Balance Applications: Suitable for low-temperature superheater zones exposed to fly ash erosion, oxidation, mechanical abrasion, and light corrosion. Uses • Installed on LTSH tube surfaces in power boilers to protect against particulate erosion and flue gas impact • Shields return bends and convection coils in HRSGs and WHRBs exposed to fluctuating gas temperatures • Used in process boilers and steam generators handling slightly corrosive or abrasive flue gases • Effective for dry ash and solid particulate protection in coal and biomass-fired units • Ideal for applications where wear resistance and moderate corrosion protection are critical Features • High mechanical strength – Withstands erosion, abrasion, and mechanical stress in high-flow zones • Moderate corrosion and oxidation resistance – Suitable for dry and mildly corrosive flue gas streams • Custom-fit – Fabricated to match the diameter, curvature, and layout of LTSH tubes • Easy installation – Compatible with weld-on, clamp-on, or banding installation methods • Cost-effective protection – Durable performance at an economical price point • Available in multiple lengths, thicknesses, and tube radii as per application needs Applications • thermal power plants – Protects LTSH tubes from fly ash impact and erosion in dry flue gas paths • waste heat recovery boilers – Applied in low-temperature return sections vulnerable to mechanical wear • steam generation systems – Shields superheater tubes operating in abrasive flue gas conditions • coal-fired boilers – Guards against slag and ash erosion in lower convection zones • process and utility boilers – Extends tube life in units operating with solid fuel combustion Conclusion The SS 410 Half Round Tube Shield for LTSH Tube by Ladhani Metal Corporation – manufacturer, supplier, and exporter – offers reliable, abrasion-resistant protection for superheater and boiler tubes in low-temperature flue gas environments. With its excellent wear resistance and mechanical durability, it is a practical choice for enhancing system performance and reducing downtime in power and industrial boilers. For custom sizing, technical guidance, or quotations, please contact Ladhani Metal Corporation.

Ladhani Metal Corporation is a manufacturer and stockist of a wide range of titanium valves, including: Titanium Full Bore and Flanged Valves, Titanium Needle Valves, Titanium Check Valves, Titanium Globe Valves, Titanium Gate Valves, Titanium Y Strainers, and other titanium forged fittings. Titanium valves are available in a variety of material grades, ranging from the most commonly used Grade 2 to alloyed titanium grades such as Gr. 5, Gr. 7, and Gr. 12. Titanium alloys are also known as R50400, R50550, and R56400 in UNS. Titanium valves are designed as per ANSI B16.34. Titanium valves are primarily made from ASTM B381 Grade F2 and F5. We manufacture our ball valves entirely from titanium, including: Titanium Ball Titanium Body Titanium Handle Titanium Fasteners Titanium Flange Ladhani Metal Corporation is a manufacturer, exporter, and supplier of titanium ball valves. Our Titanium Ball Valve Products: 1000 - 6000 PSI Two-Piece Full Bore Ball Valve 1000 - 6000 PSI Three-Piece Full Bore Ball Valve ANSI Class 150 – 900 Two-Piece Flanged Ball Valve ANSI Class 150 – 900 Two-Piece Flanged Ball Valve Design Features: Full Bar Machined Construction Valve Design as per ANSI B16.34 2-Piece Body Design, Full Bore Blow-Out-Proof Stem Design Flange Face to Face: ANSI B16.10 Class 150/300 RF Flange Dimension: ANSI B16.5 Class 150/300 End Type: Screwed & Welded End NACE MR0175 is available Ladhani Metal Corporation can also manufacture titanium ball valves in grades such as Titanium Grade 1, Titanium Grade 2, Titanium Grade 5, Titanium Grade 9, Titanium Grade 6, and Titanium Grade 23. Available at the following locations: Coimbatore, Rudrapur, Bhilai, Raigarh, Navi Mumbai, Aluva, Vijayawada, Firozabad, Panna, Panipat, Channapatna, Varanasi, Moradabad, Bareilly, Jamshedpur, Tiruppur, Rajahmundry, Bokaro Steel City, Kolkata, Durgapur, Kharagpur, Hosdurg, Haldia, Indore, Pithampur, Belagavi, Dibrugarh, Palakkad, Delhi, Noida, Kannur, Salem, Sivakasi, Kanpur, Rajkot, Kochi, Peenya, Surat, Rourkela, Visakhapatnam, Angul, Ahmedabad, Gandhinagar, Jamnagar, Vadodara, Bharuch-Ankleshwar, Ludhiana, Pimpri-Chinchwad, Mumbai, Bangalore, Thiruvananthapuram, Thrissur, Gajraula, Unnao, Sri City, Margao, Kunnamkulam, Darjeeling, Nashik, Chennai, Hosur, Haridwar, Faridabad, Mathura, Gurugram, Baddi, Calicut, Pune, Aurangabad, Nagpur, Mirzapur, Perambra, Muzaffarnagar, Meerut, Saharanpur, Bulandshahr, Ichalkaranji, Muvattupuzha, Aligarh, Anjar, Bardoli, Chittaranjan, Hyderabad, Jharia, Morbi, Nepanagar, Kollam, Tiruvalla, Kottayam, Idukki, Alappuzha, Cherthala, Alwaye, Ambattur, Ambarnath, Amritsar, Avadi, Ankleshwar, Bhadravati, Cochin, Dindigul, Ennore, Guntur, Kagithapuram, Kalpakkam, Kollegal, Kolar, Lucknow, Mysore, Nandambakkam, Nangal, Neyveli, Ooty, Perambur, Pinjore, Rupnarayanpur, Renukoot, Sindri, Singhbhum, Sirpur, Udhana, Urkunta, Worli, Zaina Kot. We are an exporter to the following countries: Russia, Canada, United States, China, Brazil, Australia, Argentina, Kazakhstan, Algeria, Democratic Republic of the Congo, Denmark, Saudi Arabia, Mexico, Indonesia, Sudan, Libya, Iran, Mongolia, Peru, Chad, Niger, Angola, Mali, South Africa, Colombia, Ethiopia, Bolivia, Mauritania, Egypt, Tanzania, Nigeria, Venezuela, Namibia, Mozambique, Pakistan, Turkey, Chile, Zambia, Myanmar, Afghanistan, South Sudan, France, Somalia, Central African Republic, Ukraine, Madagascar, Botswana, Kenya, Yemen, Thailand, Spain, Turkmenistan, Cameroon, Papua New Guinea, Sweden, Uzbekistan, Morocco, Iraq, Paraguay, Zimbabwe, Norway, Japan, Germany, Republic of the Congo, Finland, Vietnam, Malaysia, Côte d'Ivoire, Poland, Oman, Italy, Philippines, Ecuador, Burkina Faso, New Zealand, Gabon, United Kingdom, Guinea, Uganda, Ghana, Romania, Laos, Guyana, Belarus, Kyrgyzstan, Senegal, Syria, Cambodia, Uruguay, and Suriname.

A Molybdenum Bar is a solid, rectangular or cylindrical piece of molybdenum metal, often used in industrial applications that require high strength, heat resistance, and durability. Molybdenum is a transition metal known for its excellent properties, including a high melting point, resistance to corrosion, and mechanical strength, which make it ideal for use in demanding environments. Key Features of Molybdenum Bar: o High Melting Point: Molybdenum bars can withstand extremely high temperatures (up to around 2,623°C or 4,753°F) without losing their structural integrity, making them perfect for high-temperature applications such as aerospace and industrial furnaces. o Strength and Durability: Molybdenum bars exhibit superior tensile strength and resistance to deformation, ensuring long-lasting performance under mechanical stress. o Corrosion Resistance: Molybdenum bars are highly resistant to oxidation and corrosion, even at high temperatures, which is crucial for use in harsh environments like chemical processing and high-temperature furnaces. o Electrical and Thermal Conductivity: Molybdenum has good electrical and thermal conductivity, making it suitable for specialized applications in electronics, including filaments, electrodes, and thermocouples. o Ductility and Workability: Although molybdenum is a hard and brittle metal at room temperature, it can be processed into various shapes and sizes, including bars, rods, and wires, through specialized manufacturing techniques. Common Applications: o Aerospace: Molybdenum bars are used in turbine blades, rocket nozzles, and heat shields for spacecraft due to their ability to perform under extreme heat. o Electronics and Electrical: Molybdenum bars are used in filaments, cathodes, and electrodes in electronic devices due to their excellent electrical conductivity and high melting point. o Metallurgy and Manufacturing: Molybdenum is a key component in high-strength steel alloys, making it useful in manufacturing tools, cutting equipment, and industrial machinery. o Chemical Processing: Due to its resistance to corrosive environments, molybdenum bars are used in the construction of reactors, heat exchangers, and other chemical processing equipment. Ladhani Metal Corporation's molybdenum bars are manufactured with strict quality controls and adhere to international standards to ensure optimal performance in demanding application

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 bar rod is a solid, cylindrical piece of tungsten metal, typically used in various high-performance industrial and scientific applications. Tungsten is renowned for its exceptional physical properties, which make it an ideal material for extreme conditions. Here's a more detailed description: Key Characteristics of a Pure Tungsten Bar Rod: Material Composition: 99.95% Tungsten (W): A pure tungsten rod is composed entirely of tungsten, without any alloys or significant impurities. This ensures the rod has the full range of tungsten's advantageous properties. Melting Point: Tungsten's melting point is extremely high at 3,422°C (6,192°F), which makes it ideal for high-temperature applications, such as aerospace and military uses. Strength and Durability: The tungsten rod is extremely strong and wear-resistant. It has a tensile strength of around 1510 MPa, making it suitable for heavy-duty, high-stress applications. Corrosion Resistance: Pure tungsten rods exhibit strong resistance to corrosion, oxidation, and other forms of environmental degradation, even at elevated temperatures. Uses of Pure Tungsten Bar Rods: Aerospace & Defense: Tungsten rods are used in applications like rocket nozzles, spacecraft components, and military hardware. Their high density and ability to withstand extreme temperatures make them valuable in these fields. Medical Applications: Tungsten rods are employed in radiation shielding and in medical imaging devices like X-ray machines, where their high density helps to absorb harmful radiation. Machining & Manufacturing: Tungsten rods are used as tools or as part of tooling systems for machining metals, particularly in high-speed or high-precision operations. Specialty Manufacturing: Tungsten rods are often used in the production of custom components that need to operate in harsh environments, such as semiconductor manufacturing or nuclear reactors.

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: Titanium Elliptical Dish Tank Head Standard: ASME VIII-I, DIN28013 Material: GR1, GR2, GR7, GR12 Size: Customized Titanium Elliptical Dish Tank Head The Elliptical Dish Tank Head is the lid of the pressure vessel and the main bearing part of the pressure vessel. Its function is to seal. One is an upper and lower pressure vessel consisting of a tank, and the other end is a pipe, which does not extend forward, and is then welded to seal the pipe in the form of a header. The head of the product acts like a blind and a lid, but both can be removed. And the head can not be removed after welding. With support pressure vessels, pipes, flanges, elbows, tees, stone products. The quality of Elliptical Dish Tank Head /dish head is directly related to the long-term safe and reliable operation of pressure vessel. Diameter 300 mm to 2000 mm Shape Round Thickness 1 to 16 mm Process Industrial use Material grade CP4 - level; CP3 - secondary; Titanium contact international.like apply SSDS - level 3; CP1 - level 4; Seven; ; Grade 11 -CP ti-0.15pd; Grade 5 - Titanium 6Al-4V; Grade 6 -- Titanium 5Al-2.5Sn; Grade 9 - Titanium 3Al-2.5V; 12-0.8 Ni Ti - 0.3 - Mo -; Grade 19 - Titanium βC; Grade 23 - Titanium 6Al-4V ELI; 6, 6 v - 2 sn; 6 al zr - 2-2 sn - 4 mo; 6 al zr - 2 sn - 4-6 mo; Mo 8 al - 1-1 v. Fe 10 v - 2-3 al; 15 v - 3 cr - 3 sn - 3 al; Alpha alloy; Beta alloy; Alpha beta alloy Purpose Forging Features Solid construction Smooth Finish High quality Type of disk head/endcaps/head: Ellipsoidal head This is also known as a 2:1 oval head. This head shape is more economical because the height of the head is only a quarter of its diameter. Its radius varies between the major axis and the minor axis. Hemispherical head A sphere is the ideal shape for the head because the pressure in the container is evenly distributed over the surface of the head. The head radius (R) is equal to the radius of the cylindrical part of the container. Torispherical head These have a disc head with a fixed radius (CR), the size of which depends on the type of spherical head. The transition between the cylinder and the plate is called the knuckle. The steering knuckle is circular. Klopper head This is a spherical head. The radius of the plate is equal to the diameter of the cylinder to which it is attached. The radius of the knuckle is equal to one tenth of the diameter of the cylinder. Korbbogen head This is a hemispherical head, also known as a hemispherical head (DIN 28013). The radius of the disk is 80% of the diameter of the cylinder (CR=0.8 x D0.). The radius of the knuckle is (KR= 0.154x D0).