At Ladhani Metal Corporation, we rely on advanced, durable, and highly resistant Titanium Tanks and Vessels in our state-of-the-art gold and silver refining processes to meet the highest industry standards of efficiency and quality. Titanium, known for its exceptional strength, lightweight nature, and superior corrosion resistance, is the perfect material for handling the challenging and chemically aggressive processes involved in precious metal refining. Titanium Tanks and Vessels are critical components in ensuring the refined metals remain pure and free from contaminants, which is a paramount concern in the production of high-quality gold and silver. These tanks and vessels are custom-designed to withstand the demanding conditions of refining, where harsh chemicals, high temperatures, and reactive agents are frequently used. Key Features and Advantages of Titanium Tanks and Vessels: Unmatched Corrosion Resistance: Titanium's resistance to corrosion in both oxidizing and reducing environments makes it ideal for gold and silver refining operations. High Strength and Durability: Titanium exhibits extraordinary strength even at high temperatures, allowing our refining plant to maintain operational efficiency without concerns about material failure. Precision and Purity Assurance: Titanium's non-reactive nature ensures that it does not introduce any impurities into the refining solution, which is critical when producing high-purity gold and silver. As precious metals are refined, any contaminant introduced through the process can significantly reduce the quality of the final product. Titanium's inert properties prevent such risks, allowing for the highest-quality output. Optimal Design for Efficient Operations: The Titanium Tanks and Vessels are designed with precision to optimize chemical mixing, temperature regulation, and overall process control, contributing to the efficiency of the refining operations. Their advanced engineering ensures minimal energy loss and greater process consistency, which translates to better yields and faster turnaround times in the refining cycle. Applications in Gold and Silver Refining: Electrolytic Refining: Titanium vessels are used to hold the electrolyte solutions during electrorefining processes, which are crucial for separating pure gold and silver from impurities. The non-reactive properties of titanium ensure that the refining chemicals do not degrade the container or contaminate the solution. Aqua Regia Processing: When gold is dissolved in aqua regia for further separation and purification, the highly corrosive nature of this acid mixture makes titanium an ideal material for containing the solution without causing any damage to the vessel. Conclusion: The Titanium Tanks and Vessels at Ladhani Metal Corporation are integral to the efficiency, safety, and success of our precious metal refining operations. By leveraging the unique properties of titanium, we ensure that our gold and silver refining processes produce the highest purity metals while maintaining cost-effectiveness, operational longevity, and minimal maintenance requirements. Our commitment to using the best materials in the industry translates to superior results and a refined product that meets the exacting standards of our clients.

A tungsten alloy bar is a dense, strong, and high-melting-point metal product made primarily from tungsten combined with other metals like nickel, iron, or copper. These rods are known for their exceptional durability, resistance to heat and wear, and high density, making them ideal for applications in aerospace, defense, medical devices, and manufacturing processes. Tungsten alloy rods are commonly used for radiation shielding, electrical contacts, counterweights, and as tooling components in high-stress environments. It is produced by pressing and sintering into billets, which are worked by rolling or swaging into rod. Specific length can be supplied upon request. Key Features of Tungsten Bars: High Density: Tungsten bars are extremely dense, making them ideal for applications that require weight and mass, such as counterweights and ballast. Superior Strength: Tungsten exhibits one of the highest melting points and tensile strengths of any metal, making the bars suitable for high-stress environments. Wear and Corrosion Resistance: Tungsten's resistance to corrosion and wear ensures long-lasting performance, even in harsh industrial conditions. Heat Resistance: With its high melting point, tungsten is capable of maintaining its integrity in extreme temperature environments. We also manufacture in following grades: Type Density (g/cm³) 85W-10.5Ni-4.5Fe 15.8-16.0 90W-7NI-3FE 16.9-17.1 90W-6Ni-4Fe 16.7-17.0 91W-6Ni-3FE 17.1-17.3 92W-5Ni-3FE 17.3-17.5 92.5W-5Ni-2.5Fe 17.4-17.6 93W-4 NI-3FE 17.5-17.6 93W-4.9Ni-2.1Fe 17.5-17.6 93W-5Ni-2Fe 17.5-17.6 95W-3Ni-2Fe 17.9-18.1 95W-3.5Ni-1.5Fe 17.9-18.1 96W-3Ni-1FE 18.2-18.3 97W-2Ni-1FE 18.4-18.5 98W-1Ni-1FE 18.4-18.6 90W-6Ni-4CU 17.0-17.2 93W-5Ni-2CU 17.5-17.6

Ladhani Metal Corporation offers premium DIN 94 Aluminium Alloy products, meticulously manufactured to meet the highest industry standards. In compliance with DIN 94, a globally recognized standard for aluminium alloys, these materials provide superior strength, light weight, and corrosion resistance. Ideal for a wide range of applications, including automotive, aerospace, construction, and industrial machinery. Key Features: Lightweight and Strong: Known for its excellent strength-to-weight ratio, aluminium alloy is significantly lighter than steel but provides comparable or superior strength in many applications. It offers exceptional mechanical properties, including tensile strength, yield strength, and hardness, while remaining much lighter than other metals, making it ideal for applications where weight reduction is crucial, such as in the aerospace and automotive industries. Corrosion Resistance: it is resistant to corrosion. The alloy naturally forms an oxide layer on its surface, providing a protective barrier that resists oxidation. This makes it highly suitable for use in marine, coastal, and other harsh environments where exposure to moisture and chemicals can be a concern. Excellent Machinability and Formability: It offers good weldability, along with the ability to be extruded, forged, and shaped into complex forms, making it a versatile material for manufacturers across various sectors. The alloy can be easily processed into sheets, plates, rods, and bars, enabling its use in numerous production techniques. Thermal and Electrical Conductivity: Aluminium alloys are known for their high thermal and electrical conductivity. It is ideal for applications that require effective heat dissipation or electrical conductivity, such as in electrical components, heat exchangers, and radiators. Applications: Automotive: Components such as engine parts, wheels, frames, and body panels where weight reduction is a priority without compromising strength. Aerospace: Structural components, wing sections, and fuselage parts, benefiting from the alloy's lightweight and high-strength properties. Marine: Used in boat hulls, ship parts, and offshore structures due to its excellent resistance to corrosion in saltwater environments. Construction and Engineering: Aluminium alloy is used for window frames, roofing, structural beams, and other architectural elements, benefiting from its strength and weather-resistant properties. Our Domestic reach is unlimited and we supply to this following cities Ahmedabad, Amritsar, Aurangabad, Bangalore, Bhopal, Chandigarh, Chennai, Coimbatore, Dhanbad, Faridabad, Ghaziabad, Guwahati, Gwalior, Howrah, Hyderabad, Indore, Jabalpur, Jaipur, Jodhpur, Kanpur, Kolkata, Kota, Lucknow, Ludhiana, Madurai, Meerut, Mumbai, Nagpur, Nashik, Navi Mumbai, New Delhi, Patna, Pune, Raipur, Rajkot, Ranchi, Solapur, Srinagar, Surat, Thane, Vadodara, Varanasi, Vijayawada, Visakhapatnam, Hubballi, Tiruchirappalli, Bareilly, Moradabad, Mysore, Gurgaon, Aligarh, Jalandhar, Bhubaneswar We export to following Countries: Russia, Canada, United States, China, Brazil, Australia, Argentina, Kazakhstan, Algeria, Denmark, Saudi Arabia, Mexico, Indonesia, Iran, Mongolia, Peru, South Africa, Colombia, Ethiopia, Bolivia, Egypt, Venezuela, Turkey, Chile, Myanmar, France, Ukraine, Madagascar, Botswana, Kenya, Thailand, Spain, Sweden, Uzbekistan, Morocco, Paraguay, Zimbabwe, Norway, Japan, Germany, Republic of the Congo, Finland, Vietnam, Malaysia, Poland, Oman, Italy, Philippines, Ecuador, New Zealand, United Kingdom, Guinea, Uganda, Nepal, Bangladesh

As a distributor of titanium plate we stock widths from 36" to 72, lengths up to 240" and thicknesses up to 7". Available grades: CP Grade 1 CP Grade 2 Grade 7 Grade 19 Grade 5 (6Al-4V) Grade 6 (5Al-2.5Sn) Grade 6Al-2Sn-4Zr-2Mo (6-2-4-2) Grade 6Al-4V ELI (Formerly Grade 23) Grade 6Al-6V-2Sn (6-62) Grade 8Al-1Mo-1V (8-1-1) Grade 9 (3Al-2.5V) Titanium plate grade bellow Ti CP Grade 1 Ti CP Grade 2 TI CP GRADE 3 Lower Strength, softest, unalloyed Ti grade with highest ductility, cold formability, and impact tou ghness, with excellent resistance to mildly reducing to highly oxidixing media with or without chlorides and high weldability. Moderate strength unalloyed Ti with excellent weldability, cold formability, and fabricability; Excellent resistance to midly reducing to highly oxidizing media with or without chlorides. Approved for sour service use under the NACE MR-01-75 Standard Slightly stronger version of Ti CP Grade 2 with similar corrosion resistance with good weldability and reasonable cold formability/ductibility. Ingot/Bloom, Bar, Billet, Plate, Strip, Welded Pipe/Tubing, Wire. Ingot/Bloom, Bar, Billet, Plate, Strip, Welded Tubing/Pipe, Seamless Tubing, Wire, Foil Ingot/Bloom, Bar, Billet, Plate, Strip, Welded Tubing/Pipe Ti Grade 16 Ti Grade 17 Ti Grade 26 Lower cost, leaner Pd version of Ti Grade 7 with equivalent physical/mechanical properties, and similar corrosion resistance. Tubing Welded Pipe. Lower cost, leaner Pd version of Ti. Grade 11 with equivalent physical, mechanical properties and fabricability (soft grade) and similar corrosion resistance. Tubing Welded Pipe. Lower cost, Ru-containin g alternative for Ti Grade 7 with equivalent physical/mechanical properties and fabricability and similar corrosion resistance. Tubing, welded pipe. Ingot/Bloom, Bar, Billet, Plate, Strip, Welded Tubing/Pipe, Wire Ingot/Bloom, Bar, Billet, Plate, Strip, Welded Tubing/Pipe, Wire Ingot/Bloom, Bar, Billet, Plate, Strip, Welded Tubing/Pipe, Wire Ti Grade 18 Ti Grade 28 Ti Grade 6 Pd-enhanced version of Ti-3Al-2.5V with equivalent physical and mechanical properties and fabricability, offering elevated resistance to dilute reducing acids and crevice corrosion in hot halide (brine) media. Ru-enhanced version of Ti-3Al-2.5V with equivalent physical and mechanical properties and fabricability, offering elevated resistance to dilute reducing acids and crevice corrosion in hot halide (brine) media. Approved for sour service use under the NACE MR-01-75 Standard. Weldable, non-ageable, high-strength alloy offering good high temperature stability, strength, oxidation and creep resistance. Ingot/Bloom, Billet, Welded Pipe, Plate, Strip, Welded Tubing, Seamless Pipe Ingot/Bloom, Billet, Welded Pipe, Plate, Strip, Welded Tubing, Seamless Pipe, Wire Ingot/Bloom, Bar, Billet, Sheet Ti 6Al-4V [Ti-6-4] (Grade 5) Ti-6Al-4V ELI [Ti-6-4-ELI] (Grade 23) Ti-6Al-4V-0.1Ru (Grade 29) [Ti-6- 4-Ru] Heat treatable, high-strength, most commercially available Ti alloy ("workhorse" alloy for aerospace applications), for use up to 400C offerin g an excellent combination of hi gh strength, toughness, and ductility along with good weldability and fabricability. Extra low interstitial version of Ti-6Al-4V offerin g improved ductility and fracture toughness in air and saltwater environments, along with excellent toughness, strength, and ductility in cryogenic service as low as -255C. Typically used in a non-aged condition for maximum toughness. Extra low interstitial, Ru-containing version of Ti-6Al-4V offering improved fracture toughness in air, seawater, and brines, along with resistance to localized corrosion in sweet and sour acidic brines as high as 330 C. Approved for sour service use under the NACE MR-01-75 Standard. Ingot/Bloom, Bar, Billet, Plate, Sheet, Seamless Pipe/Tubing, Wire, Foil Ingot/Bloom, Bar, Billet, Plate, Sheet, Wire, Seamless Tubing, Foil Ingot/Bloom, Bar, Billet, Plate, Sheet, Seamless Pipe, Wire Ti-6Al-2Sn-2Zr-2Mo-2Cr-0.15Si [Ti-6- 22-22] Ti-4.5V-3V-2Mo-2Fe [SP-700] Ti-5Al-4Cr-4Mo-2Sn-2Zr [Ti-17] Heat treatable, high strength forging alloy with good strength and creep resistance to temperature as high as 400 C. Heat treatable, high strength Ti alloy with strength and fracture toughness-to-strength properties superior to those of Ti-6Al-4V, with excellent superplastic formability and thermal stability. Heat treatable, high strength Ti alloy with superior strength and exceptional hot and superplastic formability compared to Ti-6Al4V, combined with good ductility and fatigue resistance. Ingot/Bloom, Bar, Billet, Plate, Sheet, Wire Ingot/Bloom, Bar, Billet, Plate, Sheet Ingot/Bloom, Bar, Billet Ti-3Al-8V-6Cr-4Zr-4Mo-0.05Pd [Ti Beta-C/Pd] (Grade 20) A Pd-containing version of the Ti-38644 alloy (Beta-C/Pd) possessing equivalent physical/mechanical properties, but with significantly enhanced resistance to stress and localized corrosion in high temperature brines. Ingot/Bloom, Bar, Billet, Seamless Pipe TI CP GRADE 4 TI GRADE 7 TI GRADE 11 Much Stronger, high interstitial version of Grades 2 and 3 Ti with reasonable weldability, and reduced ductility and cold-formability. Most resistant Ti alloy to corrosion in reducing acids and localized attack in hot halide media, with physical/mechanical properties equivalent to Grade 2 and excellent weldability/fabricability. Most resistant Ti alloy to corrosion in reducin g acids and localized attack in hot halide media, with physical, mechanical, formability properties equivalent to Gr.1 Ti (soft grade) and excellent weldability. Ingot, Bloom, Bar, Billet, Plate, Strip Ingot/Bloom, Bar, Billet, Plate, Strip, Welded Tubing/Pipe, Wire Ingot/Bloom, Bar, Billet, Plate, Strip, Welded Tubing/Pipe, Wire Ti Grade 27 Ti Grade 12 Ti Grade 9 Lower cost, Ru-containing alternative for Ti Grade 11 with equivalent physical/mechanical properties (soft grade) and fabricability and similar corrosion resistance Highly weldable and fabricable Ti alloy offering improved strength and pressure code design allowables, hot brine crevice corrosion, and reducing acid resistance compared to Ti Grade 1, 2, and 3. Approved for sour sergice use under the NACE MR-01-75 Standard. Medium strength, non-ageable Ti alloy offering highest strength and design allowables under the pressure vessel code, with good weldability and cold fabricability for mildly reducing to mildly oxidizing media. Ingot/Bloom, Bar, Billet, Plate, Strip, Welded Tubing/Pipe Ingot/Bloom, Billet, Welded Pipe, Plate, Strip, Welded Tubing, Seamless Pipe, Wire Ingot/Bloom, Billet, Welded Pipe, Plate, Strip, Welded Tubing, Foil, Seamless Pipe, Wire Ti 5Al-2.5Sn ELI [Ti-5-2.5 ELI] Ti-8Al-1Mo-1V [Ti-8-1-1] Ti-6Al-2Sn-4Zr-2Mo-0.1Si [Ti-6-2-4-2S] Extra low interstitial version of Ti5Al-2.5Sn exhibiting an excellent combination of toughness and stren gth at cryo genic temperatures; suited for cryogenic vessels for service as low as -255C. Highly creep-resistant, non-ageable, weldable, high-strength Ti alloy for use up to 455C; exhibiting the lowest density and highest modulus of all commercial Ti alloys. Weldable, high strength Ti alloy offering excellent strength, stability, and creep resistance to temperatures as high as 550C. Ingot/Bloom, Bar, Billet Ingot/Bloom, Bar, Billet, Sheet Ingot/Bloom, Bar, Billet, Sheet Ti-6Al-7Nb Ti-6Al-6V-2Sn [Ti-6-6-2] Ti-6Al-2Sn-4Zr-6Mo [Ti-6-2-4-6] High strength Ti alloy with good toughness and ductility, used primarily for medical implants stemming from its excellent biocompatibility. Heat treatable, high strength Ti alloy with higher strength and section hardenability than Ti-6Al-4V, but with lower toughness and ductility, and limited weldability. Can be used in mill annealed or in the aged (very high strength) condition. Heat-treatable, deep hardenable, very hi gh stren gth Ti alloy with improved strength to temperatures as hi gh as 450C, with limited weldability. Approved for sour service under the NACE MR-01-75 Standard. Ingot/Bloom, Bar, Billet, Wire Ingot/Bloom, Bar, Billet, Plate, Sheet Ingot/Bloom, Bar, Billet Ti-10V-2Fe-3Al [Ti-10-2-3] Ti-3Al-8V-6Cr-4Zr-4Mo [Ti Beta-C] (Grade 19) Ti-3Al-8V-6Cr-4Zr-4Mo [Ti Beta-C] (Grade 19) Heat treatable, deep section hardenable, very high strength Ti alloy with superior strength and creep resistance over Ti-6Al-4V to temperatures as high as 400 C and limited weldability. Heat treatable, deep hardenable, very high strength Ti alloy possesing superior fatigue and strength/toughness combinations, with exceptional hot-die forgeability, but limited weldability. A heat-treatable, deep section hardenable, very high strength Ti alloy possessing good toughness/strength properties, low elastic modulus and elevated resistance to stress and localized corrosion in high temperature sweet and sour brines. Approved for sour service under the NACE MR-0175 Standard Ingot/Bloom, Bar, Billet Ingot/Bloom, Bar, Billet, Seamless Pipe, Wire Ingot/Bloom, Bar, Billet, Seamless Pipe

QUALITY STANDARD MATERIAL NO. OLD DESIGNATION DC03 DIN EN 10130 1.0347 St 13-03 The deep drawing grade DC03 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 defines the technical requirements and test methods for cold-rolled products used in various industrial applications, particularly where high demands are placed on surface quality and mechanical properties. DC03 is a low-carbon steel characterized by excellent cold formability. The chemical composition of DC03 is precisely defined to ensure that the material has the required mechanical properties. Typically, DC03 contains a maximum of 0.10% carbon, a maximum of 0.45% manganese and traces of phosphorus and sulphur. This small amount of alloying elements contributes to the good formability and weldability of the steel. The mechanical properties of DC03 are also clearly defined. The material has a yield strength of at least 140 MPa and a tensile strength of between 270 and 370 MPa. In addition, DC03 has an elongation at break of at least 34%, which underlines its excellent formability. These properties make DC03 particularly suitable for the production of complex components that require high precision and surface quality, such as body parts in the automotive industry or household appliances. The DIN EN 10130 standard also specifies the tolerances for dimensions, shape and surface finish. These tolerances are crucial to ensure consistently high product quality and to meet the requirements of end users. The surface of the cold-rolled flat products can be supplied in various qualities, from matt to glossy, to meet the specific requirements of different applications. The DIN EN 10152 standard specifies electrolytically galvanized, cold-rolled flat steel products for cold forming, including the deep-drawing grade DC03. This standard defines the requirements for the zinc coating and the basic mechanical properties of the base material. DC03, 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 DC03 remain unchanged after galvanizing and meet the requirements of DIN EN 10130. DC03 therefore retains its excellent cold formability and mechanical performance. The yield strength, tensile strength and elongation at break also remain in the same range as for ungalvanized DC03. 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 DC03 in accordance with DIN EN 10152 is widespread in the automotive industry, in 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 deep-drawing grade DC03 offers a wide range of applications in accordance with both DIN EN 10130 and DIN EN 10152. While DIN EN 10130 focuses on high formability and surface quality, DIN EN 10152 supplements these properties with improved corrosion resistance thanks to the zinc coating. Both standards ensure that DC03 is a reliable and high-quality material for numerous industrial applications. Cold-rolled flat steel DC03, produced in accordance with the DIN EN 10130 and DIN EN 10152 standards, offers a number of advantages for applications in the cold forming process. While DIN EN 10130 defines the basic requirements for chemical composition, mechanical properties and surface quality, DIN EN 10152 extends these specifications to include specific conditions for electrolytically galvanized products that offer additional corrosion protection. Both standards together ensure that DC03 is a versatile material with high quality and durability.

QUALITY STANDARD MATERIAL NO. OLD DESIGNATION DC03 DIN EN 10130 1.0347 St 13-03 The deep drawing grade DC03 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 defines the technical requirements and test methods for cold-rolled products used in various industrial applications, particularly where high demands are placed on surface quality and mechanical properties. DC03 is a low-carbon steel characterized by excellent cold formability. The chemical composition of DC03 is precisely defined to ensure that the material has the required mechanical properties. Typically, DC03 contains a maximum of 0.10% carbon, a maximum of 0.45% manganese and traces of phosphorus and sulphur. This small amount of alloying elements contributes to the good formability and weldability of the steel. The mechanical properties of DC03 are also clearly defined. The material has a yield strength of at least 140 MPa and a tensile strength of between 270 and 370 MPa. In addition, DC03 has an elongation at break of at least 34%, which underlines its excellent formability. These properties make DC03 particularly suitable for the production of complex components that require high precision and surface quality, such as body parts in the automotive industry or household appliances. The DIN EN 10130 standard also specifies the tolerances for dimensions, shape and surface finish. These tolerances are crucial to ensure consistently high product quality and to meet the requirements of end users. The surface of the cold-rolled flat products can be supplied in various qualities, from matt to glossy, to meet the specific requirements of different applications. The DIN EN 10152 standard specifies electrolytically galvanized, cold-rolled flat steel products for cold forming, including the deep-drawing grade DC03. This standard defines the requirements for the zinc coating and the basic mechanical properties of the base material. DC03, 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 DC03 remain unchanged after galvanizing and meet the requirements of DIN EN 10130. DC03 therefore retains its excellent cold formability and mechanical performance. The yield strength, tensile strength and elongation at break also remain in the same range as for ungalvanized DC03. 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 DC03 in accordance with DIN EN 10152 is widespread in the automotive industry, in 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 deep-drawing grade DC03 offers a wide range of applications in accordance with both DIN EN 10130 and DIN EN 10152. While DIN EN 10130 focuses on high formability and surface quality, DIN EN 10152 supplements these properties with improved corrosion resistance thanks to the zinc coating. Both standards ensure that DC03 is a reliable and high-quality material for numerous industrial applications. Cold-rolled flat steel DC03, produced in accordance with the DIN EN 10130 and DIN EN 10152 standards, offers a number of advantages for applications in the cold forming process. While DIN EN 10130 defines the basic requirements for chemical composition, mechanical properties and surface quality, DIN EN 10152 extends these specifications to include specific conditions for electrolytically galvanized products that offer additional corrosion protection. Both standards together ensure that DC03 is a versatile material with high quality and durability.

QUALITY STANDARD MATERIAL NO. DC06 DIN EN 10130 1.0873 The special deep-drawing grade DC06 is specified in accordance with the standard DIN EN 10130, which focuses on cold-rolled flat products made of soft steels for cold forming. This standard defines the requirements and test methods for cold-rolled products used in various industrial applications, especially where high demands are placed on formability and surface quality. DC06 is an ultra-low carbon steel characterized by outstanding cold formability. The chemical composition of DC06 is precisely defined to ensure that the material has the required mechanical properties. Typically, DC06 contains a maximum of 0.01% carbon, a maximum of 0.20% manganese and only minimal traces of phosphorus and sulphur. This small amount of alloying elements contributes to the steel’s exceptional formability and weldability. The mechanical properties of DC06 are also clearly defined. The material has a maximum yield strength of 120 MPa and a tensile strength of between 270 and 350 MPa. In addition, DC06 has an elongation at break of at least 40%, which underlines its excellent formability. These properties make DC06 particularly suitable for the production of complex and precise components that require high formability, such as deep-drawn body parts in the automotive industry or sophisticated components in the household appliance industry. The DIN EN 10130 standard also specifies the tolerances for dimensions, shape and surface finish. These tolerances are crucial to ensure consistently high product quality and to meet the requirements of the end user. The surface of the cold-rolled flat products can be supplied in various qualities, from matt to glossy, to meet the specific requirements of different applications. The DIN EN 10152 standard specifies electrolytically galvanized, cold-rolled flat steel products for cold forming, including the special deep-drawing grade DC06. This standard defines the requirements for the zinc coating and the basic mechanical properties of the base material. DC06, 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 DC06 remain unchanged even after galvanizing and meet the requirements of DIN EN 10130. DC06 therefore retains its outstanding cold formability and mechanical performance. The yield strength, tensile strength and elongation at break also remain in the same range as for ungalvanized DC06. 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 DC06 in accordance with DIN EN 10152 is widespread in the automotive industry, in 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 special deep-drawing grade DC06 offers a wide range of applications in accordance with both DIN EN 10130 and DIN EN 10152. While DIN EN 10130 focuses on outstanding formability and surface quality, DIN EN 10152 supplements these properties with improved corrosion resistance thanks to the zinc coating. Both standards ensure that DC06 is a reliable and high-quality material for numerous industrial applications.

QUALITY STANDARD MATERIAL NO. DC06 DIN EN 10130 1.0873 The special deep-drawing grade DC06 is specified in accordance with the standard DIN EN 10130, which focuses on cold-rolled flat products made of soft steels for cold forming. This standard defines the requirements and test methods for cold-rolled products used in various industrial applications, especially where high demands are placed on formability and surface quality. DC06 is an ultra-low carbon steel characterized by outstanding cold formability. The chemical composition of DC06 is precisely defined to ensure that the material has the required mechanical properties. Typically, DC06 contains a maximum of 0.01% carbon, a maximum of 0.20% manganese and only minimal traces of phosphorus and sulphur. This small amount of alloying elements contributes to the steel’s exceptional formability and weldability. The mechanical properties of DC06 are also clearly defined. The material has a maximum yield strength of 120 MPa and a tensile strength of between 270 and 350 MPa. In addition, DC06 has an elongation at break of at least 40%, which underlines its excellent formability. These properties make DC06 particularly suitable for the production of complex and precise components that require high formability, such as deep-drawn body parts in the automotive industry or sophisticated components in the household appliance industry. The DIN EN 10130 standard also specifies the tolerances for dimensions, shape and surface finish. These tolerances are crucial to ensure consistently high product quality and to meet the requirements of the end user. The surface of the cold-rolled flat products can be supplied in various qualities, from matt to glossy, to meet the specific requirements of different applications. The DIN EN 10152 standard specifies electrolytically galvanized, cold-rolled flat steel products for cold forming, including the special deep-drawing grade DC06. This standard defines the requirements for the zinc coating and the basic mechanical properties of the base material. DC06, 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 DC06 remain unchanged even after galvanizing and meet the requirements of DIN EN 10130. DC06 therefore retains its outstanding cold formability and mechanical performance. The yield strength, tensile strength and elongation at break also remain in the same range as for ungalvanized DC06. 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 DC06 in accordance with DIN EN 10152 is widespread in the automotive industry, in 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 special deep-drawing grade DC06 offers a wide range of applications in accordance with both DIN EN 10130 and DIN EN 10152. While DIN EN 10130 focuses on outstanding formability and surface quality, DIN EN 10152 supplements these properties with improved corrosion resistance thanks to the zinc coating. Both standards ensure that DC06 is a reliable and high-quality material for numerous industrial applications.

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.