'highest levels'

Aerospace Titanium Specifications (AMS 49) AMS 4900 Plate, Sheet & Strip – Annealed –55,000 psi Yield AMS 4901 Sheet, Strip & Plate – Annealed – 70,000 psi Yield AMS 4902 Plate, Sheet & Strip – Annealed – 40,000 psi Yield AMS 4905 Plate, Damage Tolerant Grade – 6AI 4V, Beta Annealed AMS 4907 Plate, Sheet & Strip – 6Al-4V, Extra Low Interstitial, Annealed AMS 4908 Sheet & Strip – 8Mn Annealed - 110,000 psi Yield AMS 4909 Plate, Sheet & Strip – 5Al-2.5Sn, Extra Low Interstitial, Annealed AMS 4910 Plate, Sheet & Strip – 5Al-2.5Sn, Annealed AMS 4911 Sheet, Strip & Plate – 6Al-4V, Annealed AMS 4914 Sheet & Strip – 15V 3Cr 3Sn #AI – Solution Heat Treated AMS 4915 Plate, Sheet & Strip – 8Al-1Mo-1V – Single Annealed AMS 4916 Plate, Sheet & Strip – 8Al-1Mo-1V – Duplex Annealed AMS 4917 Plate, Sheet & Strip – 13.5V 11Cr 3Al – Solution Treated AMS 4918 Plate, Sheet & Strip –6Al-6V-2Sn – Annealed AMS 4919 Sheet, Strip & Plate – 6Al 2Sn 4Zr-2Mo – Annealed AMS 4920 Forgings – 6Al-4V – Alpha Beta or Beta Processed – Annealed AMS 4921 Bars, Forgings & Rings – Annealed – 70,000 psi Yield AMS 4924 Bars, Forgings & Rings – 5Al-2.5Sn – Extra Low Interstitial, Annealed – 90,000 psi Yield AMS 4926 Bars & Rings – 5Al-2.5Sn – Annealed – 110,000 psi Yield AMS 4928 Bars & Forgings – 6Al-4V – Annealed – 120,000 psi Yield AMS 4930 Bars, Forgings & Rings – 6Al-4V – Extra Low Interstitial, Annealed AMS 4931 Bars, Forgings & Rings – 6Al-4V ELI, Duplex Annealed, Fractured Toughness AMS 4933 Extrusions & Flash Welded Rings – 8AI 1Mo 1V – Solution Heat Treated & Stabilized AMS 4934 Extrusions & Flash Welded Rings - 6Al-4V – Solution Heat Treated & Aged AMS 4935 Extrusions & Flash Welded Rings – 6Al-4V – Annealed, Beta Processed AMS 4936 Extrusions & Flash Welded Rings – 6Al-4V – Beta Processed AMS 4941 Tubing, Welded – Annealed – 40,000psi Yield AMS 4942 Tubing, Seamless – Annealed – 40,000 psi Yield AMS 4943 Tubing, Seamless – Annealed – 3.0Al 2.5V AMS 4944 Tubing, Seamless – hydraulic – 3.0Al 2.5V – Cold Worked, Stress Relieved AMS 4951 Wire, Welding – Commercially Pure AMS 4953 Wire, Welding – 5Al 2.5Sn AMS 4954 Wire, Welding –6Al 4V AMS 4955 Wire, Welding – 8Al 1Mo 1V AMS 4956 Wire, Welding – 6Al 4V – Extra Low Interstitial, Environment Controlled AMS 4957 Bars & Wire, 3Al-8V-6Cr-4Mo-4Zr, Consumable Electrode Melted, Cold Drawn AMS 4958 Bars & Rod – 3Al-8V-6Cr-4Mo-4Zr, Consumable Electrode Melted, Solution Heat Treated & Centerless Ground AMS 4959 Wire – 13.5V 11Cr 3Al – Spring Temper AMS 4965 Bars, Forgings & Rings – 6Al-4V – Solution & Precipitation Heat Treated AMS 4966 Forgings – 5Al-2.5Sn – Annealed – 110,000 psi Yield AMS 4967 Rings & Forgings – 6Al-4V – Annealed, Heat Treatable AMS 4970 Bars & Forgings – 7Al 4Mo – Solution & Precipitation Heat Treated AMS 4971 Bars, Forgings & Rings – 6Al-6V-2Sn – Annealed, Heat Treatable AMS 4972 Bars & Rings – 8Al-1Mo-1V – Solution Heat Treated & Stabilize AMS 4973 Forgings – 8Al 1Mo 1V - Solution Heat Treated & Stabilized AMS 4974 Bars & Forgings – 11Sn 5.0Zr 2.3Al 1.0Mo 0.21Si - Solution & Precipitation Heat Treated AMS 4975 Bars & Rings – 6Al-2Sn-4Zr-2Mo - Solution & Precipitation Heat Treated AMS 4976 Forgings - 6Al-2Sn-4Zr-2Mo - Solution & Precipitation Heat Treated AMS 4979 Bars, Forgings & Rings – 6Al-6V-2Sn - Solution & Precipitation Heat Treated AMS 4981 Bars & Forgings 6Al 2Sn 4Zr 6Mo - Solution & Precipitation Heat Treated AMS 4983 Forgings – 10V 2Fe 3Al – Solution Heat Treated & Aged Military Titanium Specifications Mil-T-9046H Titanium & Titanium Alloy Sheet, Strip & Plate Type I – Commercially Pure: Composition A – CP GR 2 (40 KSI) Composition B – CP GR 4 (70 KSI) Composition C – CP GR 3 (55 KSI) Type II – Alpha Alloys: Composition A - 5Al-2.5Sn Composition B - 5Al-2.5Sn ELI Composition F – 8Al-1Mo-1V Composition G – 6Al-2Cb-1Ta-.8Mo Type III – Alpha-Beta Alloys: Composition C – 6Al-4V Composition D – 6Al-4V ELI Composition E – 6Al-6V-2Sn Composition G – 6Al-4Sn-4Zr-2Mo Composition H – 6Al-4V SPL Type IV – Beta Alloys Composition A – 13Al-11Cr-3Al Composition B – 11.5Mo-6Zr-4.5Sn (Beta III) Composition C – 3Al-8V-6Cr-4Mo-4Zr (Beta C™)(10) MIL-T-9046J Titanium & Titanium Alloy Sheet , Strip & Plate Commercially Pure (CP CP-1 – Grade 4 (70 KSI) CP-2 – Grade 3 (55 KSI) CP-3 – Grade 2 (40 KSI) CP-4 – Grade 1 (25 KSI) Alpha Alloys (A) A-1 – 5Al-2.5Sn A-2 – 5Al-2.5Sn (ELI) A-3 – 6Al-2Cb-1Ta-.8Mo A-4 – 8Al-1Mo-1V Alpha-Beta Alloys (AB) AB-1 – 6Al-4V AB-2 – 6Al-4V (ELI) AB-3 – 6Al-6V-2Sn AB-4 – 6Al-2Sn-4Zr-2Mo AB-5 – 3Al-2.5V AB-6 – 8Mn Beta Alloys (B) B-1 – 13V-11Cr-3Al B-2 – 11.5Mo-6Zr-4.5Sn (Beta III) B-3 – 3Al-8V-6Cr-$Mo-$zr (Beta C™)(10) B-4 – 8Mo-8V-2Fe-3Al MIL-T-9047E Titanium & Titanium Alloy Bars & Reforging Stock Alpha Alloys Composition 1 – Unalloyed Composition 2 – 5Al-2.5Sn Composition 3 – 5Al-2.5Sn ELI Composition 5 – 5Al-1Mo-1V Alpha-Beta Alloys Composition 6 – 6Al-4V Composition 7 – 6Al-4V ELI Composition 8 - 6Al-6V-2Sn Composition 9 – 7Al-4Mo Composition 10 – 11Sn-5Zr-2Al-1Mo Composition 11 – 6Al-2Sn-4Zr-2Mo Composition 14 – 6Al-2Sn-4Zr-6Mo Beta Alloys Composition 12 – 13V-11Cr-3Al Composition 13 – 11.5Mo-6Zr-4.5Sn (Beta III) MIL-T-9047G Titanium & Titanium Alloy Bars & Reforging Stock, Aircraft Quality Commercially Pure TI-CP-70 (Grade 4) Alpha Alloys Ti – 5Al-2.5Sn Ti – 5Al-2.5Sn (ELI) 6Al-2Cb-1Ta-.8Mo 8Al-1Mo-1V Alpha-Beta Alloys Ti – 3Al-2.5V Ti – 6Al-4V Ti – 6Al-4V (ELI) Ti – 6Al-6V-2Sn Ti – 6Al-2Sn-4Zr-2Mo Ti – 6Al-2Sn-4Zr-6Mo Ti –7Al-4Mo Beta Alloys Ti – 8Mo-8V-2Fe-3Al Ti – 11.5Mo-6Zr-4.5Sn (Beta III) Ti – 3Al-8V-6Cr-4Mo-4Zr (Beta C™)(10) Ti – 13V-11Cr-3Al Imperial and Metric sizes available upon request.

Price: 0 | Payment Type: | Available: False | COD Available: False | KYC Status: FAILED

DIN 2569 Titanium Flanges PN 100 are precision-engineered welding neck flanges manufactured from premium-grade titanium, designed for exceptional performance in high-pressure and corrosive industrial applications. Built to DIN 2569 standards, these flanges offer outstanding corrosion resistance, high strength-to-weight ratio, and excellent thermal stability, making them suitable for critical systems across industries such as chemical processing, offshore engineering, aerospace, pharmaceuticals, marine, and power generation. Ladhani Metal Corporation is a trusted manufacturer and exporter of titanium flanges, delivering high-quality products that comply with rigorous international standards. The welding neck design ensures secure, leak-proof connections, ideal for high-stress environments and systems requiring permanent joints that withstand both pressure and temperature extremes. Pressure Rating: • PN 100 (100 bar / 1450 psi): Specifically designed for high-pressure systems requiring superior corrosion resistance, structural reliability, and long-term sealing performance in aggressive environments. Flange Types: • Welding Neck Flanges Ensure high-strength, welded connections ideal for systems with continuous pressure and thermal cycling. • Raised Face (RF) Flanges Enhances sealing capability in elevated pressure and temperature conditions. • Flat Face (FF) Flanges Used in systems with flat mating surfaces, particularly where non-metallic or brittle materials are involved. • Forged Welding Neck Flanges Provide enhanced strength, impact resistance, and dimensional precision. • Custom-Machined Flanges Available in a range of sizes, pressure classes, and titanium grades tailored to customer requirements. Titanium Grades and Composition: 1. Grade 2 (Commercially Pure Titanium) Composition: • Titanium (Ti): ≥ 98.9% • Iron (Fe): ≤ 0.30% • Oxygen (O): ≤ 0.25% • Carbon (C): ≤ 0.08% • Nitrogen (N): ≤ 0.03% • Hydrogen (H): ≤ 0.015% Applications: Widely used in chemical processing, desalination plants, and marine environments due to its excellent corrosion resistance and formability. 2. Grade 5 (Ti-6Al-4V, Titanium Alloy) Composition: • Titanium (Ti): Balance • Aluminum (Al): 5.5 – 6.75% • Vanadium (V): 3.5 – 4.5% Applications: Ideal for aerospace, offshore, and high-performance applications due to its high strength, low density, and corrosion resistance. Applications of DIN 2569 Titanium Flanges: • Chemical and Petrochemical Plants: Used in highly corrosive processes involving acids, chlorides, and oxidizing agents. • Marine and Offshore Engineering: Ideal for submerged and saltwater applications due to excellent resistance to seawater corrosion. • Aerospace and Defense: Employed in lightweight, high-strength components that require resistance to fatigue and corrosion. • Pharmaceutical and Medical Equipment: Used in ultra-clean and biocompatible systems where corrosion and contamination must be minimized. • Power Generation and Desalination: Applied in condenser systems, heat exchangers, and evaporators handling brine and other corrosive fluids. Key Features: • Manufactured to DIN 2569 standard • Available in PN 100 pressure rating • Exceptional corrosion resistance, including seawater and chemical environments • Lightweight, high-strength construction for improved efficiency and durability • Strong welded neck design for secure, permanent pipe connections • Supplied with test certificates, quality documents, and full traceability • Compatible with custom surface treatments including pickling, polishing, and passivation Conclusion: DIN 2569 Titanium Flanges PN 100 from Ladhani Metal Corporation are engineered for the highest levels of corrosion resistance, strength, and performance under pressure. Designed for extreme environments and demanding applications, these titanium flanges offer reliable, long-lasting service and are available in customized sizes and titanium grades. For project-specific requirements, technical support, or detailed specifications, contact Ladhani Metal Corporation today.

Price: 0 | Payment Type: | Available: False | COD Available: False | KYC Status: FAILED

QUALITY STANDARD MATERIAL NO. DC07 DIN EN 10130 1.0873 The super deep drawing grade DC07 is specified according to the standard DIN EN 10130, which focuses on cold-rolled flat products made of soft steels for cold forming. This standard ensures that the technical requirements and test methods for cold-rolled products are met, which are of great importance in various industrial applications, especially where the highest demands are placed on formability and surface quality. DC07 is a particularly low-carbon steel characterized by exceptional cold formability. The chemical composition of DC07 is strictly controlled to ensure its excellent mechanical properties. The carbon content in DC07 is typically a maximum of 0.01 %, while the manganese content is a maximum of 0.20 %. The addition of micro-alloyed elements such as titanium and niobium can further improve formability and strength. The mechanical properties of DC07 are characterized by a very low maximum yield strength of 120 MPa and a tensile strength of between 270 and 350 MPa. A particularly outstanding property of DC07 is its high elongation at break of at least 40 %, which underlines the excellent formability of the material. These properties make DC07 ideal for the production of complex components that require extremely high precision and surface quality, such as deep-drawn body parts in the automotive industry or highly complex components in the electronics industry. The DIN EN 10130 standard also specifies precise tolerances for dimensions, shape and surface finish. These tolerances are crucial to ensuring consistently high product quality and meeting the requirements of end users. The surface of the cold-rolled flat products can be supplied in various qualities, from matt to high-gloss, to meet the specific requirements of different applications. The DIN EN 10152 standard specifies electrolytically galvanized, cold-rolled steel flat products for cold forming, including the super deep-drawing grade DC07. This standard defines the requirements for the zinc coating and the basic mechanical properties of the base material. DC07, when electrolytically galvanized in accordance with DIN EN 10152, is given an additional corrosion protection layer of zinc. This layer protects the material from oxidative influences and significantly increases the service life of the components made from it. The zinc coating can be applied in various thicknesses, depending on the specific requirements of the application. Typical coating thicknesses range from 5 to 20 µm. The chemical composition and mechanical properties of the base material DC07 remain unchanged after galvanizing and meet the requirements of DIN EN 10130. DC07 therefore retains its exceptional cold formability and mechanical performance. The yield strength, tensile strength and elongation at break also remain in the same range as for non-galvanized DC07. In addition to mechanical performance, the quality of the zinc coating is of central importance. The DIN EN 10152 standard specifies the requirements for the uniformity of the coating, the adhesive strength of the zinc and the surface quality. These requirements ensure that the galvanized products offer high corrosion resistance and an aesthetically pleasing surface. The use of DC07 in accordance with DIN EN 10152 is widespread in the automotive industry, the construction industry and in the manufacture of household appliances, where improved corrosion resistance is required in addition to high formability. Electrolytic galvanizing offers optimum protection here without impairing the excellent mechanical properties of the base material. In summary, it can be said that the DC07 super deep-drawing grade offers a wide range of applications in accordance with both DIN EN 10130 and DIN EN 10152. While DIN EN 10130 focuses on excellent formability and surface quality, DIN EN 10152 supplements these properties with improved corrosion resistance thanks to the zinc coating. Both standards ensure that DC07 is a reliable and high-quality material for numerous industrial applications.

Price: 0 | Payment Type: | Available: False | COD Available: False | KYC Status: FAILED

QUALITY STANDARD MATERIAL NO. DC07 DIN EN 10130 1.0873 The super deep drawing grade DC07 is specified according to the standard DIN EN 10130, which focuses on cold-rolled flat products made of soft steels for cold forming. This standard ensures that the technical requirements and test methods for cold-rolled products are met, which are of great importance in various industrial applications, especially where the highest demands are placed on formability and surface quality. DC07 is a particularly low-carbon steel characterized by exceptional cold formability. The chemical composition of DC07 is strictly controlled to ensure its excellent mechanical properties. The carbon content in DC07 is typically a maximum of 0.01 %, while the manganese content is a maximum of 0.20 %. The addition of micro-alloyed elements such as titanium and niobium can further improve formability and strength. The mechanical properties of DC07 are characterized by a very low maximum yield strength of 120 MPa and a tensile strength of between 270 and 350 MPa. A particularly outstanding property of DC07 is its high elongation at break of at least 40 %, which underlines the excellent formability of the material. These properties make DC07 ideal for the production of complex components that require extremely high precision and surface quality, such as deep-drawn body parts in the automotive industry or highly complex components in the electronics industry. The DIN EN 10130 standard also specifies precise tolerances for dimensions, shape and surface finish. These tolerances are crucial to ensuring consistently high product quality and meeting the requirements of end users. The surface of the cold-rolled flat products can be supplied in various qualities, from matt to high-gloss, to meet the specific requirements of different applications. The DIN EN 10152 standard specifies electrolytically galvanized, cold-rolled steel flat products for cold forming, including the super deep-drawing grade DC07. This standard defines the requirements for the zinc coating and the basic mechanical properties of the base material. DC07, when electrolytically galvanized in accordance with DIN EN 10152, is given an additional corrosion protection layer of zinc. This layer protects the material from oxidative influences and significantly increases the service life of the components made from it. The zinc coating can be applied in various thicknesses, depending on the specific requirements of the application. Typical coating thicknesses range from 5 to 20 µm. The chemical composition and mechanical properties of the base material DC07 remain unchanged after galvanizing and meet the requirements of DIN EN 10130. DC07 therefore retains its exceptional cold formability and mechanical performance. The yield strength, tensile strength and elongation at break also remain in the same range as for non-galvanized DC07. In addition to mechanical performance, the quality of the zinc coating is of central importance. The DIN EN 10152 standard specifies the requirements for the uniformity of the coating, the adhesive strength of the zinc and the surface quality. These requirements ensure that the galvanized products offer high corrosion resistance and an aesthetically pleasing surface. The use of DC07 in accordance with DIN EN 10152 is widespread in the automotive industry, the construction industry and in the manufacture of household appliances, where improved corrosion resistance is required in addition to high formability. Electrolytic galvanizing offers optimum protection here without impairing the excellent mechanical properties of the base material. In summary, it can be said that the DC07 super deep-drawing grade offers a wide range of applications in accordance with both DIN EN 10130 and DIN EN 10152. While DIN EN 10130 focuses on excellent formability and surface quality, DIN EN 10152 supplements these properties with improved corrosion resistance thanks to the zinc coating. Both standards ensure that DC07 is a reliable and high-quality material for numerous industrial applications.

Price: 0 | Payment Type: | Available: False | COD Available: False | KYC Status: FAILED

Price: 0 | Payment Type: | Available: False | COD Available: False | KYC Status: FAILED

Aka CAS No. 13463-67-7, Titanium (VI) oxide, Titania, Rutile, Anatase, Brookite Titanium Dioxide Chemical Titanium Dioxide, also referred to Titania, has a molecular formula of Ti02 and this mineral compound – a white colored, odorless solid – is available in three different forms. Rutile titanium dioxide is the most common naturally occurring form followed by the anatase form but titanium dioxide can also be produced synthetically. Titanium dioxide is produced from either ilmenite, rutile or titanium slag. The titanium pigment is extracted by using either sulphuric acid (sulphate process) or chlorine (chloride route). The sulphate process employs simpler technology while the chloride route produces a purer product. Titanium Dioxide – classified by CAS No. 13463-67-7 – is mined as a mineral in magmatic rocks. It is non-flammable, non-explosive and titanium dioxide is the most widely used pigment because of its brightness and refractive index. Bulk Chemicals Pallate Over 4 million tons of titanium dioxide are used worldwide every year for a wide array of common applications like paint, coatings, plastics, papers, ink, food (it’s often used to whiten skim milk and to enhance the flavor of nuts, seeds, soup and beer), medicine and toothpaste. Titanium Dioxide is also used in cosmetics and skin care products as a pigment, in sunscreen and sunblock as a thickener to protect the skin from ultraviolet light. Titanium Dioxide, believe it or not, is used to mark the white lines on the tennis courts at Wimbledon. Indeed, titanium dioxide accounts for 70% of the total production of pigments worldwide because “titanium white,” as it’s often called, is one of the whitest materials known to exist on Earth. In fact, titanium dioxide is even more reflective than diamonds!

Price: 0 | Payment Type: | Available: False | COD Available: False | KYC Status: FAILED

QUALITY STANDARD MATERIAL NO. DC07 DIN EN 10130 1.0873 The super deep drawing grade DC07 is specified according to the standard DIN EN 10130, which focuses on cold-rolled flat products made of soft steels for cold forming. This standard ensures that the technical requirements and test methods for cold-rolled products are met, which are of great importance in various industrial applications, especially where the highest demands are placed on formability and surface quality. DC07 is a particularly low-carbon steel characterized by exceptional cold formability. The chemical composition of DC07 is strictly controlled to ensure its excellent mechanical properties. The carbon content in DC07 is typically a maximum of 0.01 %, while the manganese content is a maximum of 0.20 %. The addition of micro-alloyed elements such as titanium and niobium can further improve formability and strength. The mechanical properties of DC07 are characterized by a very low maximum yield strength of 120 MPa and a tensile strength of between 270 and 350 MPa. A particularly outstanding property of DC07 is its high elongation at break of at least 40 %, which underlines the excellent formability of the material. These properties make DC07 ideal for the production of complex components that require extremely high precision and surface quality, such as deep-drawn body parts in the automotive industry or highly complex components in the electronics industry. The DIN EN 10130 standard also specifies precise tolerances for dimensions, shape and surface finish. These tolerances are crucial to ensuring consistently high product quality and meeting the requirements of end users. The surface of the cold-rolled flat products can be supplied in various qualities, from matt to high-gloss, to meet the specific requirements of different applications. The DIN EN 10152 standard specifies electrolytically galvanized, cold-rolled steel flat products for cold forming, including the super deep-drawing grade DC07. This standard defines the requirements for the zinc coating and the basic mechanical properties of the base material. DC07, when electrolytically galvanized in accordance with DIN EN 10152, is given an additional corrosion protection layer of zinc. This layer protects the material from oxidative influences and significantly increases the service life of the components made from it. The zinc coating can be applied in various thicknesses, depending on the specific requirements of the application. Typical coating thicknesses range from 5 to 20 µm. The chemical composition and mechanical properties of the base material DC07 remain unchanged after galvanizing and meet the requirements of DIN EN 10130. DC07 therefore retains its exceptional cold formability and mechanical performance. The yield strength, tensile strength and elongation at break also remain in the same range as for non-galvanized DC07. In addition to mechanical performance, the quality of the zinc coating is of central importance. The DIN EN 10152 standard specifies the requirements for the uniformity of the coating, the adhesive strength of the zinc and the surface quality. These requirements ensure that the galvanized products offer high corrosion resistance and an aesthetically pleasing surface. The use of DC07 in accordance with DIN EN 10152 is widespread in the automotive industry, the construction industry and in the manufacture of household appliances, where improved corrosion resistance is required in addition to high formability. Electrolytic galvanizing offers optimum protection here without impairing the excellent mechanical properties of the base material. In summary, it can be said that the DC07 super deep-drawing grade offers a wide range of applications in accordance with both DIN EN 10130 and DIN EN 10152. While DIN EN 10130 focuses on excellent formability and surface quality, DIN EN 10152 supplements these properties with improved corrosion resistance thanks to the zinc coating. Both standards ensure that DC07 is a reliable and high-quality material for numerous industrial applications.

Price: 0 | Payment Type: | Available: False | COD Available: False | KYC Status: FAILED

Ladhani Metal Corporation offers SS 410 Boiler Half Round Tube Shields designed to protect straight boiler and heat exchanger tubes from erosion, abrasion, and moderate corrosion in high-temperature service conditions. Manufactured from martensitic stainless steel grade SS 410, these shields provide good mechanical strength, wear resistance, and oxidation resistance, making them suitable for applications where tubes are exposed to flue gases, soot blower impact, and abrasive particles in thermal power plants, industrial boilers, and process heaters. The shields are precision-formed into a half-round profile to match standard tube diameters, ensuring secure coverage and consistent protection. SS 410 offers a cost-effective balance between heat resistance and mechanical durability, extending the operational life of boiler tubes while reducing maintenance downtime. Ladhani Metal Corporation manufactures, supplies, and exports SS 410 Boiler Half Round Tube Shields in a variety of lengths, diameters, and thicknesses to meet the needs of domestic and international projects. SS 410 Grade Chemical Composition – 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 utility boilers, waste heat recovery boilers, process heaters, and other high-temperature units requiring erosion and oxidation protection. Uses • Shields straight tubes in industrial and power boilers • Protection from soot blower erosion and particulate abrasion • Suitable for dry flue gas areas with moderate corrosion levels • Used in process heaters and industrial furnaces • Ideal for cost-effective tube protection in medium-duty environments Features • Good oxidation resistance – Performs well in dry, high-temperature service • High mechanical strength – Resists wear and deformation under impact • Cost-effective protection – Balances durability with material economy • Precision fit – Half-round profile ensures close tube contact • Easy installation – Clamped, tack welded, or banded as required • Export quality – Manufactured to international dimensional and quality standards Applications • Thermal power plants – Shields economizer and superheater tubes • Waste heat recovery units – Protects against ash and particulate wear • Petrochemical industry – Used in process heaters and heat recovery boilers • Cement plants – Guards boiler tubes from abrasive kiln dust Conclusion The SS 410 Boiler Half Round Tube Shield from Ladhani Metal Corporation provides reliable, cost-effective tube protection in high-temperature environments where moderate corrosion resistance, high strength, and wear resistance are required. Available in custom sizes and export-grade specifications, these shields are an ideal choice for industrial and utility boiler systems worldwide. For technical details, custom orders, or international supply inquiries, contact Ladhani Metal Corporation. #Mumbai #Pune #Ahmedabad #Vadodara #Surat #Rajkot #Jamnagar #Bharuch #Ankleshwar #Vapi #Delhi #Faridabad #Ghaziabad #Noida #Gurugram #Chennai #Coimbatore #Tiruchirappalli #Hyderabad #Visakhapatnam #Vijayawada #Bangalore #Mangalore #Mysore #Kolkata #Durgapur #Asansol #Bhubaneswar #Rourkela #Raipur #Bhilai #Bilaspur #Nagpur #Nashik #Aurangabad #Indore #Bhopal #Jabalpur #Kanpur #Lucknow #Varanasi #Jaipur #Kota #Udaipur #Jodhpur #Chandigarh #Ludhiana #Jalandhar #Haridwar #Dehradun #Agra #Meerut #Aligarh #Moradabad #Bareilly #Mathura #Gwalior #Rewa #Satna #Sagar #Ujjain #Ratlam #Solapur #Kolhapur #Amravati #Akola #Jalgaon #Latur #Sangli #Nanded #Gandhinagar #Bhavnagar #Mehsana #Surendranagar #Junagadh #Nadiad #Nizamabad #Karimnagar #Warangal #Kurnool #Nellore #Tirupati #Salem #Erode #Madurai #Tirunelveli #Thoothukudi #Belgaum #Hubli #Tumkur #Hassan #Cuttack #Sambalpur #Jamshedpur #Ranchi #Dhanbad #Patna #Gaya #Muzaffarpur#halftubeshield #utypehalftubeshield #tubeshieldexporter #TubeShield #HalfTubeShield #SSHalfRoundShield #BoilerTubeShield #BoilerShield #TubeProtection #Tubeshieldmanufacturer #BoilerTubeProtection #SSTubeShield #MetalIndustry #SteelFabrication #IndustrialShielding #SS304Shield #SS316Shield #StainlessSteelShield #WeldOnShield #WeldedTubeShield #TubeCladding #BoilerTubeSleeve #TubeSleeve #MetalFabrication #PowerPlantSupplies #RefineryEquipment #ProcessIndustry #MetalComponent #TubeShieldForBoilers #BoilerParts #SteelSolutions #TubeShieldManufacturer #TubeShieldSupplier #SSShielding #IndustrialTubeShield #BoilerTubeGuard #CustomMetalParts #SteelIndustryIndia #MetalEngineering #HeavyIndustrySupply #StainlessSteelIndia #SteelExporters #MetalComponentExport #FabricatedProducts #SteelDealer #IndustrialSupplyIndia #BoilerTubeFittings #TubeShieldingSolutions #HalfTubeCover #HeatExchangerShield

Price: 0 | Payment Type: | Available: False | COD Available: False | KYC Status: FAILED

Ladhani Metal Corporation offers SS 430 Outer Half Round 90 Degree Bend Tube Shields designed to protect the outer arc of U-bend and 90-degree curved tubes in boilers, heat exchangers, superheaters, and reheaters. Manufactured from ferritic stainless steel grade SS 430, these shields provide good corrosion resistance, excellent formability, and thermal stability in moderately aggressive service environments. SS 430 is particularly suitable for applications where resistance to oxidation and surface scaling is needed without exposure to highly corrosive agents. The semi-cylindrical profile is precision-formed to match the outer curvature of return tube bends, offering a physical barrier against soot-blower impact, flue gas erosion, and ash particle wear. SS 430 shields are commonly used in utility and industrial boilers operating under dry, mildly corrosive, and thermally demanding conditions. Ladhani Metal Corporation is a trusted manufacturer, supplier, and exporter of SS 430 Outer Half Round 90 Degree Bend Tube Shields, offering custom configurations to suit specific plant layouts and service requirements. SS 430 Grade Chemical Composition – Ferritic Stainless Steel • Carbon (C): ≤ 0.12% • Manganese (Mn): ≤ 1.00% • Phosphorus (P): ≤ 0.040% • Sulfur (S): ≤ 0.030% • Silicon (Si): ≤ 1.00% • Chromium (Cr): 16.0 – 18.0% • Nickel (Ni): ≤ 0.75% • Iron (Fe): Balance Applications: Ideal for power plants, WHRBs, HRSGs, and general industrial systems requiring protection for tube bends in dry heat and oxidizing environments. Uses • Shielding outer 90-degree bends in superheaters and reheaters • Applied in WHRBs and HRSG return coils exposed to dry flue gas • Protects against moderate erosion and oxidation in utility boilers • Suitable for curved tubes in industrial furnaces and heat recovery units Features • Cost-effective protection – Combines durability with economical material choice • Oxidation resistance – Performs well in clean flue gas and dry heat exposure • Thermal reliability – Withstands repeated heating cycles without deformation • Custom-fit geometry – Formed to match exact bend radius for tight coverage • Versatile installation – Can be clamped, banded, or tack welded as needed • Multiple sizes – Offered in a variety of thicknesses, lengths, and radii Applications • Thermal power stations – Shields steam lines and return bends from surface scaling • Waste heat boilers – Guards tube bends in clean gas recovery systems • Process heaters – Used in less corrosive gas heating environments • Cement and food processing industries – Protects tube curves from oxidation Conclusion The SS 430 Outer Half Round 90 Degree Bend Tube Shield by Ladhani Metal Corporation provides durable and cost-efficient protection for tube bends exposed to dry heat, oxidation, and moderate wear. With good formability and thermal performance, these shields are ideal for systems where corrosion levels are controlled but mechanical shielding is essential. For custom sizing, material selection, or technical specifications, contact Ladhani Metal Corporation. #Mumbai #Pune #Ahmedabad #Vadodara #Surat #Rajkot #Jamnagar #Bharuch #Ankleshwar #Vapi #Delhi #Faridabad #Ghaziabad #Noida #Gurugram #Chennai #Coimbatore #Tiruchirappalli #Hyderabad #Visakhapatnam #Vijayawada #Bangalore #Mangalore #Mysore #Kolkata #Durgapur #Asansol #Bhubaneswar #Rourkela #Raipur #Bhilai #Bilaspur #Nagpur #Nashik #Aurangabad #Indore #Bhopal #Jabalpur #Kanpur #Lucknow #Varanasi #Jaipur #Kota #Udaipur #Jodhpur #Chandigarh #Ludhiana #Jalandhar #Haridwar #Dehradun #Agra #Meerut #Aligarh #Moradabad #Bareilly #Mathura #Gwalior #Rewa #Satna #Sagar #Ujjain #Ratlam #Solapur #Kolhapur #Amravati #Akola #Jalgaon #Latur #Sangli #Nanded #Gandhinagar #Bhavnagar #Mehsana #Surendranagar #Junagadh #Nadiad #Nizamabad #Karimnagar #Warangal #Kurnool #Nellore #Tirupati #Salem #Erode #Madurai #Tirunelveli #Thoothukudi #Belgaum #Hubli #Tumkur #Hassan #Cuttack #Sambalpur #Jamshedpur #Ranchi #Dhanbad #Patna #Gaya #Muzaffarpur #TubeShield #HalfTubeShield #SSHalfRoundShield #BoilerTubeShield #BoilerShield #TubeProtection #Tubeshieldmanufacturer #BoilerTubeProtection #SSTubeShield #MetalIndustry #SteelFabrication #IndustrialShielding #SS304Shield #SS316Shield #StainlessSteelShield #WeldOnShield #WeldedTubeShield #TubeCladding #BoilerTubeSleeve #TubeSleeve #MetalFabrication #PowerPlantSupplies #RefineryEquipment #ProcessIndustry #MetalComponent #TubeShieldForBoilers #BoilerParts #SteelSolutions #TubeShieldManufacturer #TubeShieldSupplier #SSShielding #IndustrialTubeShield #BoilerTubeGuard #CustomMetalParts #SteelIndustryIndia #MetalEngineering #HeavyIndustrySupply #StainlessSteelIndia #SteelExporters #MetalComponentExport #FabricatedProducts #SteelDealer #IndustrialSupplyIndia #BoilerTubeFittings #TubeShieldingSolutions #HalfTubeCover #HeatExchangerShield #halftubeshield #utypehalftubeshield #tubeshieldexporter

Price: 0 | Payment Type: | Available: False | COD Available: False | KYC Status: FAILED