Help with Metal Plates and Plate Stock specifications:
Size / Dimensions
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Overall Thickness | This is the overall thickness of stock forms, tube walls, or other fabricated components. | ||
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Gauge Thickness | The numerical gauge thickness of the sheet, foil, or wire product. Different gauge systems are used for different stock forms and alloy types. | ||
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Overall Width / OD | This is the overall width or outer diameter (OD) of stock forms such as bars, plates, and tubes. Overall width is the average particulate diameter for raw materials such as powders, granules, and pellets. | ||
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Overall Length | This is the length of stock materials such as bars, rods, plates, and tubes. | ||
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Mechanical Properties
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Tensile Strength (UTS, Break) | Ultimate tensile strength (UTS) at break is the maximum amount of stress required to fail or break the material under tension-loading test conditions. | ||
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Yield Strength (YS) | Yield strength (YS) is the maximum amount of stress required to deform or impart permanent plastic deformation (typically of 0.2%) in the material under tension-loading test conditions. The yield point occurs when elastic or linear stress-strain behavior changes to plastic or non-linear behavior. Ductile materials typically deviate from Hooke's law or linear behavior at some higher stress level. | ||
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Elongation | Elongation is the percent amount of deformation that occurs during a tensile test or other mechanical test. | ||
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Tensile Modulus (E) | Tensile modulus, Young's modulus, or the modulus of elasticity (E) is a material constant that indicates the variation in strain produced under an applied tensile load. Materials with a higher modulus of elasticity have higher stiffness or rigidity. | ||
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Applications
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Applications: | |||
Your choices are... | |||
Aerospace / Aircraft (AQ) | Products are designed and rated for use in aerospace, aircraft, airport, space vehicle, satellite, rocket, interplanetary explorer, and space station applications. Aircraft quality (AQ) steels and alloys are manufactured to aerospace industry AMS 2301 standard specifications of cleanliness, chemistry, strength, and mill traceability as well as exacting steelmaking, rolling, and testing practices. Mission critical and highly stressed aircraft parts are fabricated from aircraft quality (AQ) steel alloys. Aircraft quality alloys are also used in non-aerospace applications for highly stressed, mission critical components involving additional stringent inspection requirements such as macro-etch limits, magnetic particle, or other NDT tests for inclusions or other defects. Certified aircraft quality steels have paperwork indicating the alloy is what it is supposed to be and what steel mill produced the product. | ||
Abrasive / Erosive Wear Protection | Materials resist damage by abrasion or erosion, and protect underlying surfaces from abrasive or erosive wear. | ||
Alternative / Renewable Energy | Evaluated for alternative or renewable energy production products such as photovoltaic (PV) cells, solar power systems, wind turbines, hydro turbines, and flywheel power systems. | ||
Automotive / Vehicular | Products are designed and rated for use in automobiles, trailer trucks, trailers, railcars, off-road trucks, and other vehicles. | ||
Armor / Ballistic Protection | Materials are used to protect equipment, vehicles, and/or personnel against damage from blasts, explosions, bullets, and other high-speed projectiles. | ||
Bearings (BQ) | Bearing quality steels and alloys are produced in accordance with ASTM A 534, A 295, and A 485. Bearing quality steels are produced under restricted melting and special teeming, heating, rolling, and conditioning methods to meet the rigid bearing quality steel requirements. Bearing quality standards typically apply to alloy steel bars and tubes intended for the manufacture of races and balls or rollers in anti-friction bearings, oil well perforating gun bullets, dies, punches, shear and cutting blades, and cam rollers. Bearing quality level steels are usually produced from standard alloy carburizing grades and high-carbon chromium grades such as 52100 alloy steel. | ||
Battery / Fuel Cell | Material is suitable for use in battery or fuel cell as a collector plate, proton exchange membrane, or catalyst. | ||
Biocompatible / Biomaterial | Biomaterials are specially formulated or designed to have suitable biocompatibility for biotechnology and medical applications. | ||
Chemical / Materials Processing | Materials provide high temperature and/or corrosion resistance, making them suitable for chemical processing applications. | ||
Construction & Building / Architectural | Materials are designed or suitable for use in architectural, building, and construction applications. | ||
Electrical / HV Parts | Materials are used to fabricate electrical parts for high voltage or power applications. | ||
Electronics / RF-Microwave | Materials are suitable for electronics applications, including RF and microwave circuits, antennas, RMI and EFI shielding, and microelectronics interconnects. | ||
Marine | Products are designed for use in marine applications aboard ships or in offshore settings. Uses include fishing, mooring, docks, jetties, platforms, piers, and ship construction such as hull and deck plates. | ||
Mining | Alloys engineered for use in very corrosive and abrasive applications around mines and mining operations. Mining industry operations include excavation, water and slurry pumping, earth moving, and drilling under conditions where abrasive, corrosive, and erosive minerals, rocks, and soils are handled. | ||
MRO (Repair / Resurfacing) | Metals and alloys are suitable for repair, hole or gap filling, patching, refinishing, resurfacing, and other maintenance and repair (MRO) applications. | ||
Nuclear | Metals and alloys engineered for parts, products, capital equipment, or facilities used in the nuclear or utility industries. Nuclear grade stainless steels are manufactured to higher chemistry and cleanliness standards. Zirconium alloys such as Zircalloy are an excellent tube material choice for containment of uranium dioxide pellets because zirconium has a low neutron capture cross section. Inversely, hafnium has a high neutron capture cross section (neutron absorber) and is commonly used as a control rod alloy in nuclear reactors. | ||
Oil and Gas | Metals and alloys suitable for applications that can handle exposure to corrosive sour gases, erosive drilling and mining fluids, and abrasive minerals. Oil and gas industry applications entail extracting, synthesizing or processing oils, gases, or fuels such as well drilling, well maintenance, pumping, oil refining, re-refining, recovery, and recycling. Alloy products are designed and rated for use in oil wells and platforms, natural gas wells, refineries, and in other energy exploration and extraction applications. | ||
Pressure Vessel (PVQ) | Steels and stainless steels suitable for steam boiler, pressure vessel, and process reactor applications. Pressure vessel quality (PVQ) steels are manufactured to ASTM/ASME standards concerning chemical composition, mechanical properties, toughness, weldability, and hydrogen induced crack resistance. Pressure vessel quality steels are manufactured to higher cleanliness and quality standards compared to commercial grade steels. | ||
Resistance Alloy / Heating | Metals and alloys engineered to have properties suitable for resistance heating element application. These metals and alloys are known as resistance alloys. Nichrome and Kanthal are common nickel based resistance alloys. Resistance alloys must have sufficient internal electrical resistance, high melting point, and sufficient elevated temperature strength. Resistance can vary with temperature and ideally the resistance is uniform in alloys to minimize variations with temperature or provide a linear change. In non-reducing, oxygen rich oven, furnace, and resistance heating applications, the resistance alloy must have high temperature oxidation resistance. In very high temperature vacuum and inert atmosphere furnaces, tungsten and molybdenum are commonly used. | ||
Structural | Structural applications require ceramic components with a suitable strength, elastic modulus, toughness, and other mechanical properties. These can have much higher ductility and toughness compared to other metals. | ||
Wear Parts / Tooling | Wear-resistant metals are used in industrial products such as dies, molds, tooling, automotive rings, pump parts, valve seals/seats, stops, brake parts, clutch parts, and machining guides. | ||
Other | Other unlisted, specialized, or proprietary applications. | ||
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Metal / Alloy
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Metal / Alloy Types: | |||
Your choices are... | |||
Zirconium / Zirconium Alloy | Zirconium and zirconium alloys are used in chemical process equipment applications because of the metal's excellent corrosion resistance in alkaline, acidic, salt water, and some molten salt environments. Zirconium metal has high affinity to oxygen, i.e. a zirconium oxide has a high energy or heat of formation. Zirconium falls into the group of metals known as refractory metals because the metal has a high melting point above 1750º C. Zr melts at 1855º C. Refractory metals are used to make components for high temperature applications. Some refractory alloys require coatings to resist rapid oxidation or scaling at high temperatures. In space or vacuum furnace applications, oxygen may not be a concern. Zirconium's high reactivity toward oxygen has led to the metal's use as a getter (oxygen absorber in vacuum chambers and thin film coating systems) and as a pyrophoric component in explosive munitions and primers. Hafnium has properties very similar to zirconium, except in nuclear application where they are opposites. Zirconium alloys such as Zircalloy are an excellent tube material choice for containment of uranium dioxide pellets because zirconium has a low neutron capture cross section. Inversely, hafnium has a high neutron capture cross section (neutron absorber) and is commonly used a control rod alloy in nuclear reactors. | ||
Molybdenum / Molybdenum Alloy | Molybdenum is a refractory metal with a very high melting point and a relatively high density. Molybdenum and molybdenum alloys are used to fabricate PVD evaporation crucibles, electrodes, electrical contacts, and other high temperature components. | ||
Niobium / Niobium Alloy | Niobium is used in niobium-titanium alloys to make the low temperature metallic superconductors required for the powerful magnets used in MRI units. Niobium and niobium alloys are used in nuclear and chemical process equipment applications because of the metal's excellent corrosion resistance in alkaline, acidic, salt water, and some molten salt environments. Niobium has corrosion resistance and properties similar to tantalum, which is the most corrosion resistant metal. Niobium falls into the group of metals known as refractory metals because the metal has a high melting point above 1750º C. Nb melts at 2477º C. Refractory metals are used to make components for high temperature applications. Some refractory alloys require coatings to resist rapid oxidation or scaling at high temperatures. In space or vacuum furnace applications, oxygen may not be a concern. In Europe, niobium is also known as columbium. | ||
Tungsten / Tungsten Alloy | Tungsten is a refractory metal with a very high melting point and high density. Tungsten and tungsten alloys are used to fabricate light bulb filaments, PVD evaporation crucibles, EDM electrodes, electrical contacts, and other high temperature components. The high density of tungsten alloys are put to use in penetrators and balancing weights. | ||
Tantalum / Tantalum Alloy | Tantalum is an extremely corrosion resistant refractory metal. Tantalum can be fabricated by conventional methods due to the metal's good ductility and weldability. The corrosion resistance exceeds that of titanium and nickel alloys in many environments. Tantalum has a dark bluish gray color and is almost completely immune to acid attacks. | ||
Beryllium / Beryllium Alloy | Beryllium has the second lowest density compared to the common structural light metal alloys (Al, Mg, and Ti). Magnesium has a density of 1.74 g/cc and aluminum has a density of 2.7 g/cc. Beryllium's unusually high Young's modulus (287 GPa) is a useful property in structural applications. The high modulus and low density make beryllium alloys useful for aerospace applications. Beryllium has superior specific heat dissipation (heat dissipation per unit mass) compared to other metals because of beryllium's high specific heat and thermal conductivity. Beryllium also has a low thermal expansion coefficient (CTE). Many heat sinks and other thermal management products are fabricated from beryllium, beryllium alloys, and beryllium oxide ceramics due to beryllium's excellent thermal properties. Beryllium is also used to fabricate x-ray detector windows because it is transparent to most x-rays and gamma rays. Only characteristic x-rays from elements with lower atomic weights compared to beryllium are stopped or absorbed by a Be window. | ||
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Ferrous / Iron Based: | |||
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Ferrous / Iron Based - Any Type | Ferrous metals and alloys are based on iron. This category includes carbon steels, alloy steels, stainless steels, cast iron, maraging steel, and other specialty iron-based alloys. | ||
Carbon Steel (UNS G) | Plain carbon steels are ferrous alloys based on iron, carbon, and small levels of other alloying elements such as manganese or aluminum. Carbon steels include soft, non-hardenable low carbon or mild steels such as 1020, as well as hardenable high carbon steels such as 1095. Steel alloys are used in a wide variety of applications in almost every industrial segment. Mild steels and low carbon steels can be fabricated easily by machining, forming, casting, and welding. | ||
Alloy Steel (UNS G) | Alloy steels are ferrous alloys based on iron, carbon, and high to low levels of alloying elements such as chromium, molybdenum, vanadium, and nickel. Alloy steels include hardenable high alloy steels, high strength low alloy steels, maraging steel, and other specialty steel alloys. Steel alloys are used in a wide variety of applications in almost every industrial segment. Low alloy steels can be fabricated easily by machining, forming, casting, and welding. | ||
Stainless Steel (UNS S) | Stainless steels are highly corrosion resistant, ferrous alloys that contain chromium and/or nickel additions. There are three basic types of products: austenitic stainless steels, ferritic and martensitic stainless steels, and specialty stainless steels and iron superalloys. Austenitic stainless steels (AISI 300 / 200 Series) are highly corrosion resistant, ferrous alloys that contain chromium and nickel or manganese additions. Generally, austenitic stainless steels are more corrosion resistant than ferritic or martensitic stainless steels. Annealed austenitic stainless steels are non-magnetic. Cold working is used to harden austenitic stainless steels because these alloys do not respond to conventional quench and temper hardening processes. Ferritic and martensitic stainless steels are highly corrosion resistant, ferrous alloys that contain chromium and/or carbon additions. Ferritic stainless steels are soft, easy to form metal alloys. Cold working is used to harden ferritic stainless steels because these alloys do not respond to conventional quench and temper hardening processes. Ferritic stainless steels are formed to fabricate mufflers and other sheet metal components that require good corrosion resistance. Martensitic stainless steels can be hardened by a conventional quench and temper operation. Martensitic stainless steels are used for knife blades, tooling, or other applications that require good corrosion resistance combined with higher hardness and wear resistance. Specialty stainless steels and iron superalloys are highly corrosion resistant, ferrous alloys containing chromium, nickel, or other alloying additions to provide high strength or heat resistance. Duplex and precipitation hardening stainless steels belong in this category. | ||
Tool Steel (UNS T) | Tool steels are wear resistant, ferrous alloys based on iron and carbon with high levels of alloying (hardenability and property modifying) elements such as chromium, molybdenum, tungsten, and vanadium. Specific tool steel grades are available for die or cold work, hot work, high speed, and shock resistance applications. Tool steel alloys are used in a wide variety of applications that require wear resistance. They are difficult to fabricate in their hardened form and are usually EDM-machined or ground to achieve the tolerances required for tooling applications. EDM is an acronym for electrical discharge machining. This is a process that can cut small or odd-shaped angles, intricate contours, and cavities in extremely hard steels and exotic metals. | ||
Hardenability Specified / H-Steel (UNS H) | AISI-SAE H-steels are produced to specified hardenability bands. AISI is the American Iron and Steel Institute, a North American trade association. SAE is the Society of Automotive Engineers. | ||
Mechanical Property Specified (UNS D, Structural) | UNS D steels have specified mechanical properties. | ||
Specialty / Other Ferrous (UNS K) | Other miscellaneous ferrous alloys have specialized or proprietary compositions or properties. Examples include maraging steels, high strength low alloy (HSLA) steels, and iron-based superalloys. | ||
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Nonferrous Metals: | |||
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Non-ferrous - Any Type | Non-ferrous metals and alloys are not based on iron and include alloys of aluminum, copper, titanium, zinc, nickel, cobalt, magnesium, tungsten, molybdenum, precious metals, silver, gold, platinum, palladium, refractory metals, as well as many other metals and alloys. | ||
Aluminum / Aluminum Alloy (UNS A) | Aluminum and aluminum alloys are lightweight, non-ferrous metals with good corrosion resistance, ductility, and strength. Aluminum is relatively easy to fabricate by forming, machining, or welding. This metal is a good electrical and thermal conductor. Aluminum is also useful as an alloying element in steel and titanium alloys. Aluminum alloys are versatile metals with applications in almost every industrial and commercial segment. | ||
Cobalt / Cobalt Alloy | Cobalt and cobalt alloys are non-ferrous magnetic alloys with high strength and toughness, excellent corrosion and oxidation resistance, and high temperature strength. Cobalt can also be magnetized. Cobalt's properties result in the use of cobalt alloys in jet engine super-alloy components, prosthetic devices, magnets, and cutting tool binders. Cobalt is a useful alloying element in tool, maraging, and other alloy steels. | ||
Copper, Brass or Bronze Alloy (UNS C) | Copper and copper alloys are non-ferrous metals with excellent electrical and thermal conductivity as well as good corrosion resistance, ductility, and strength. Copper alloys are relatively easy to fabricate by forming, casting, or machining. Pure copper is more difficult to weld, cast, or machine. Brass, tin bronze, leaded brass, beryllium copper, and zirconium copper are examples of copper alloys. Copper is useful as an alloying element in aluminum alloys and powder metal based iron alloys. Copper is a versatile metal with applications in many industrial and commercial segments. Copper's high electrical conductivity (100% IACS) makes it extremely useful in electrical and electronic applications. | ||
Magnesium / Magnesium Alloy (UNS M) | Magnesium and magnesium alloys are non-ferrous metals with low density (relatively high strength to weight ratio), good ductility, moderate strength, and good corrosion resistance. Magnesium and magnesium alloys are used in a variety of industries as well as in aircraft, marine, and power tool applications. | ||
Nickel / Nickel Alloy (UNS N) | Nickel and nickel alloys are non-ferrous metals with high strength and toughness, excellent corrosion resistance, and superior elevated temperature properties. Nickel can also be magnetized. Nickel's properties result in the use of nickel alloys in jet engine super-alloy components, corrosion resistant chemical process equipment (valves, piping, and pumps), magnets and electrical resistance alloys, and heating elements. Nickel is also a useful alloying element in stainless, tool, maraging, and other alloy steels. | ||
Noble / Precious Metal (UNS P) | Noble and precious metal alloys such as silver, gold, platinum, and palladium alloys are extremely resistant to corrosion and oxidation. Noble and precious metal alloys are used in electrical contacts, electronic connectors, chemical process components, catalysts, jewelry, and other specialized applications. | ||
Rare Earth (UNS E) | Metals or alloys are based on elements from the rare earth elements group. | ||
Refractory / Reactive (UNS R) | Refractory and reactive metals include boron (B), tungsten (W), tantalum (Ta), molybdenum (Mo), niobium (Nb) / columbium (Cb), zirconium (Zr), hafnium (Hf), thorium (Th), vanadium (V), chromium (Cr), cobalt (Co), rhenium ( ), and titanium (Ti). Refractory metals and alloys are metals with melting points above ~1750ºC (~ 32000ºF). Refractory metals include tungsten tantalum, molybdenum, niobium, and zirconium. Refractory metals are used in high temperature, structural, electrical, and other specialty applications. Reactive metals combine readily with oxygen at elevated temperatures to form very stable oxides. Titanium, zirconium, and beryllium are considered reactive metals. Finely divided reactive metals can react explosively with oxygen and are often added to rocket fuels or combustible mixtures. A highly stable oxide film formed on the alloy surface provides protection against further oxidization or corrosion at low to moderate temperatures. Reactive metals can become embrittled if there is too much interstitial absorption into the lattice of oxygen, hydrogen, and nitrogen. | ||
Titanium / Titanium Alloy | Titanium and titanium alloys are non-ferrous metals with excellent corrosion resistance, good fatigue properties, and a high strength-to-weight ratio. Titanium's properties result in the use of titanium and titanium alloys in aircraft or airframe parts, jet engine super-alloy components, corrosion resistant chemical process equipment (valves, piping, and pumps), prostheses or medical devices, and marine equipment. | ||
White / Low Melting (UNS L) | Lead, tin, and white metals are low melting non-ferrous metals and alloys. Lead and white metal alloys are used as solders, battery electrodes, bearing liners, decorative products, and coatings. They are also used in other specialized applications. Indium, tin, lead, and antimony are used to manufacture semiconductors. | ||
Zinc / Zinc Alloy (UNS Z) | Zinc and zinc alloys are moderately low-melting, non-ferrous alloys widely used in the production of die cast components. | ||
Specialty / Other (UNS M) | This refers to other miscellaneous nonferrous metals or alloy grades. | ||
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Alloy? | Alloys have significant amounts of intentionally added alloying elements or constituents. | ||
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Pure / Very Low Alloy? | Commercially pure, unalloyed, or very low alloy metals are free of or contain very small amounts of alloying elements such as copper and various grades of copper (e.g., ETP Cu, Be Cu, Cr Cu, Te Cu, Zr Cu); commercially pure titanium or palladium-modified titanium (e.g., C.P. titanium); and pure aluminum grades from the AA 10nnnn Series (e.g., AA 1000 to 1999). | ||
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Clad / Bimetal? | The metal or alloy stock is a clad or bimetal material, which consists of two or more different alloys bonded integrally together. | ||
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Metal Matrix Composite? | Metal matrix composites have a composite, reinforced metal, or alloy matrix filled with a second component. The second component of reinforcement may be in particulate, chopped fiber, continuous filament, or fabric form. | ||
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Grades & Specifications
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Standards / Specifications | |||
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AISI | Iron-based or ferrous alloys adhere to designations established by the American Iron and Steel Institute (AISI) and the Society of Automotive Engineers (SAE). Examples of AISI-SAE steel grades are 1018, 4140, 9610, and 52100. | ||
AA / IADS | Metals or alloys meet compositional standards established by the Aluminum Association of the United States (AA), which classifies materials based on the International Alloy Designation System (IADS). | ||
AMS | Metals or alloys meet specific Aerospace Material Specification (AMS) guidelines established by the Society of Automotive Engineers (SAE). | ||
ASTM / ASME | The American Society for Testing and Materials (ASTM) is a non-profit organization that provides a forum for the development and publication of voluntary standards for materials, products, systems, and services. Most specifications from the American Society of Mechanical Engineers (ASME) are adapted from or are very similar to ASTM specifications. | ||
CDA | Metals or alloys meet compositional standards established by the Copper Development Association (CDA) of the United States. | ||
EN | European Norm or EuroNorm (EN) specifications have superseded several older, national designation systems such as BS, DIN, NS, and SS. | ||
MIL-SPEC / Federal (QQS) | MIL-SPEC metals meet U.S. government standards and are suitable for military applications. QQ and QQS are prefixes used to designate specific metals. | ||
JIS | Japanese Industrial Standards (JIS) specify the standards used for industrial activities in Japan. The standardization process is coordinated by the Japanese Industrial Standards Committee and published through the Japanese Standards Association. | ||
SAE | Products meet alloy grades, specifications, or designations established by the Society of Automotive Engineers (SAE). | ||
UNS | Metals or alloys meet the compositional standards in the Unified Numbering System (UNS), which was established by the ASTM, SAE, and several metal trade associations and societies. UNS identifies metals and alloys with a letter and five numbers. For example, carbon and alloy steels are identified as Gnnnnn, where G is the letter nnnnn is the number. | ||
Specialty / Other | This refers to other unlisted, specialized, and OEM-specific (e.g., GE, P&W, Boeing, etc.) or proprietary material specifications. | ||
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UNS Number | |||
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Features
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Processing Features: | |||
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Annealed | These metals and alloys are provided in an annealed or softened condition. Some materials anneal during thermal-mechanical processing depending on the process temperature range and alloy type. | ||
Cast (Continuous, Centrifugal, etc.) | Cast alloy stocks or shapes are produced in a casting process such as continuous casting or centrifugal casting. | ||
Forged | Metal stock or shapes are available as forged billets, blooms, slabs, or bar stock. The forging process presses, pounds, or squeezes metal stock under very high pressure. Material flow occurs during the forging process, closing any internal porosity and refining the microstructure. | ||
Hardened / Heat Treated | Hardened or heat-treated metals and alloys are provided in a hard or hardened condition. Higher hardness or strength levels can be developed through work hardening (mechanical deformation), conventional quench and tempering hardening, aging, precipitation hardening, and other specialized heat treating processes. | ||
Wrought | Wrought metals or alloys are worked mechanically to refine their structure, break up inclusion, close porosity, and improve homogeneity. | ||
Powdered Metal (Compacted) | Powered metal stock or shapes are fabricated by consolidating or compacting powdered or atomized versions of the metal or alloy. Powder processing eliminates the possibility of large inclusions and can produce a finer structure compared to conventional wrought processes. | ||
Extruded | These alloy stocks or shapes are produced by using an extrusion process. | ||
Cold Finished / Rolled / Drawn | Alloy stock or shapes are produced in a process that mechanically deforms or works the material at a temperature that is below the recrystallization point of the alloy. Rolling processes squeeze the metal between two steel rolls. Drawing processes pull the metal from a die opening or gap. The elevated temperature allows a greater degree of deformation as well as annealing during the process. Hot rolled metals tend to have more scale on their surface. | ||
Hot Rolled | Hot rolled alloy stock or shapes are produced in a process that mechanically deforms or works the material at an elevated temperature (e.g., steels in the "red" hot condition). This temperature is above the recrystallization point of the alloy. The elevated temperature allows a greater degree of deformation or a reduction of thickness. A post-annealing process is not required after hot rolling. Hot rolled metals tend to have more surface scale and require pickling and oiling. | ||
Vacuum Arc Melted (E, VAR, etc.) | The metal alloy has been melted or remelted using an electrical arc in a vacuum chamber or vacuum arc furnace, and then cast into a ingot, billet, or other shape. The vacuum protects the metal alloy from oxidation and contamination during the high temperature melting process. Vacuum melting can also remove undesirable contaminants through evaporation such as magnesium chloride in titanium sponge. Electric arc furnaced steels or E-grade steels are very clean and have less inclusions and lower variability. Aircraft, bearing, and premium steels are usually electric arc furnaced or E-grade steels. | ||
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Performance Features | |||
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Shock / Impact Resistant | Alloys are designed or suitable for service applications that require shock or impact resistance. | ||
Super Alloy | Superalloys are nickel, cobalt, or iron-based alloys with excellent elevated temperature strength, creep properties, and oxidation resistance. | ||
Soft Magnetic Alloy | Soft magnetic alloys are easily magnetized and demagnetized. These alloys are used in motor, transformer, electromagnet, magnetic bearing, solenoid, GFCI, relays, generators, tape heads, and shielding applications in sheet, lamination, and core configurations. Depending on the specific application, alloys are selected based on their permeability, resistivity, core loss, and flux density or saturation characteristics | ||
Wear Resistant / High Speed | Alloys are designed or suitable for service applications that require wear or erosion resistance. | ||
Specialty / Other | This refers to other unlisted, specialty or proprietary metals or alloy grades. These materials are based on a unique composition or alloy system, use a novel processing technology, or have properties designed for specific applications. | ||
Amorphous / Glassy Alloy | Amorphous or glassy alloys do not have a crystal structure, which results in their superior or unique magnetic properties, corrosion resistance, and mechanical and electrical properties. | ||
Austenitic | 200-series austenitic steels are stainless steels that contain chromium, nickel, and manganese. 300-series austenitic steels are stainless steels that contain chromium and nickel. The stainless steels in each austenitic group have different compositions and properties, but share many common characteristics. They can be hardened by cold working but not by heat treatment. In the annealed condition, all are essentially nonmagnetic, although some may become slightly magnetic by cold working. They have excellent corrosion resistance, unusually good formability, and increased strength due to cold working. Type 304 or 18-8 stainless steel is the most widely used alloy in the 300-series austenitic group. It has a nominal composition of 18% chromium and 8% nickel. Type 316 stainless steel has an 18-8 composition modified with molybdenum to improve pitting corrosion resistance. Austenitic grades consist of 201, 301, 301, 303, 304, 304L, 305, 309, 310, 316, 316L, 317, 317L, 321, 347, and 348 as well as specialized or proprietary austenitic stainless steels. | ||
Coiled Stock | Materials are supplied or available as coils, reels, or other wound stock forms. | ||
Controlled / Low Expansion Alloy | Alloys are engineered to provide controlled or low thermal expansion characteristics. These low thermal expansion characteristics are useful in metal-to-glass or ceramic sealing applications. | ||
Corrosion Resistant | These alloys are designed or suitable for service applications that require corrosion resistance. | ||
Cold Work (Die / Mold) | Steels and alloys are designed or suitable for die, mold, or other cold work service applications. Cold work steels have good compressive strength and wear resistance under room temperature conditions. | ||
Ferritic | Ferritic stainless steels are straight-chromium 400-series metals that cannot be hardened by heat treatment, and only moderately hardened by cold marketing. They are magnetic, have good ductility, and resistant against corrosion and oxidation. Ferritic stainless steels have chromium levels that range from 10.5% to 40% (typically 12% or more) and carbon levels less than 0.20%. Types 409, 430, 434, 430, 439, 442, and 446 belong in this category. Type 430 is a general-purpose ferritic stainless steel. | ||
Heat Resistant / Hot Work | Alloys are designed or suitable for service applications that require heat resistance. | ||
Leaded / Free Machining | Alloys contain additions of lead, selenium, tellurium, bismuth, sulfur, phosphorus or other free-machining additives that help break up chips during the machining process. Free-machining steels include leaded steels (SAE 12L13, 12L14), resulfurized steels (SAE 1117, 1118, 1119) and rephosphorized and resulfurized steels (SAE 1211, 1212, 1213). Tellurium (5% Te) additions to copper increase machinability 20 to 90% while maintaining high conductivity. | ||
Light Alloy | Light alloys include aluminum, magnesium, titanium, beryllium alloys, and composites with low densities and high strength to weight ratios. Light alloys are useful in aerospace and automotive applications where reduction in weight can improve performance or fuel efficiency. | ||
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Finish | |||
Your choices are... | |||
Anti-slip / Textured | Plates, bars, angles, or other stock metal shapes have a textured or non-slip surface such as an embossed diamond pattern or an anti-slip abrasive coating. | ||
Coated / Painted | Metal or alloy stock or shapes are coated with a protective or decorative layer of paint, resin, plating, thermal spray deposit, or other organic or inorganic material. | ||
Galvanized | Galvanized steel sheets and products are protected with an electrodeposited or dip zinc layer. The zinc and steel form a galvanic cell under wet or moist conditions. The zinc layer has a lower electro-galvanic potential compared to steel causing the zinc to be attacked and sacrificed while protecting the underlying steel. | ||
Ground / Machined | The surface of the metal shape or stock is ground or machined, resulting in a better finish compared to the processed stock. The processed condition can be rolled, cast, extruded, forged, compacted, and sintered. | ||
Polished | The surface of the metal shape or stock is polished or buffed, which provides a better finish compared to the rolled, ground, machined, or other processed stock conditions. Polishing uses fine grit or loose or fixed abrasive products to refine the surface finish to a mirror-like condition. Loose abrasive media could include abrasive slurries, polishing compounds, and lapping compounds. Fixed polishing abrasives could include lapping films, fine grit discs or belts, honing tools, and superfinishing products. | ||
Other | Other unlisted proprietary, patented, or specialized finish, processing, heat treatment, or temper condition. | ||
Search Logic: | All products with ANY of the selected attributes will be returned as matches. Leaving all boxes unchecked will not limit the search criteria for this question; products with all attribute options will be returned as matches. | ||