[ Wiki ] THE STRONGEST METALS

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Strength is an important quality in the use of metals. This is especially true in construction, transportation, heavy industry and tool making. Metal alloys are often stronger than a metal in their pure form. In discussing the strongest metals, we should first consider what we mean by strength.

The different types of strength

There are a number of different measures of strength of a metal:

• Yield strength measures the lowest stress that will result in permanent deformation.
• Compressive strength measures the amount of squeezing stress that will cause defects.
• Tensile strength measures the amount of pulling stress that will cause defects.
• Impact strength measures the amount of impact energy that will cause a fracture.

The importance of the different types of strength depends on the intended use of the metal.

The strongest metals

There are a number of metals which can be considered “the strongest”. Of course, this depends greatly on the intended application of the metal. Another consideration is the various alloys that can be formed with each metal.

That said, four metals stand out as being the strongest: Steel, Titanium, Tungsten and Inconel.

Steel

Steel is an alloy of iron and carbon, often in combination with other elements. It is made by heating iron ore in furnaces where impurities are removed and carbon is added. Raw iron is ductile and weak, but the addition of other elements such as manganese, niobium, or vanadium gives steel strength and hardness. However, it is important to remember that these additional elements also impact other properties, such as toughness and ductility.

Steel is one of the most common materials of the modern world – with more than 1.3 billion tons of steel are produced every year. It is widely used in the transportation, infrastructure, building, and weapons industries. Most large modern buildings – including skyscrapers, airports and bridges – are held up by steel structures. In the automotive industry, steel is still the principal material, although aluminum is increasingly popular. Steel is also used in smaller items such as screws, nails and kitchen utensils.

There are many forms of steel alloys:

Stainless steel is a corrosion resistant alloy containing a minimum of 11% chromium.

Tool steels are alloyed with tungsten and cobalt and are notable for their hardness. Tool steel can retain a sharp cutting edge and is used in axes and drills.

Maraging steel is alloyed with nickel and other elements. It has a low carbon content and is extremely strong. Maraging steel is used in rocket and missile skins, gas centrifuges for uranium enrichment, and fencing blades.

Titanium

Titanium is a silvered colored metal with low density and high strength. It is notable for having the highest tensile strength-to-density ratio of any metallic element. However, it’s not as hard as some varieties of heat-treated steel.

Titanium is commonly alloyed with a range of elements including iron, aluminum, and vanadium. Titanium alloys are strong and lightweight making them ideal for automotive, aerospace, military and industrial applications. Two-thirds of all titanium metal produced is used for aircraft parts. Titanium is also highly resistant to seawater corrosion making it perfect for propeller shafts and rigging as well as divers’ knives.

Tungsten

Tungsten is a rare metal found on Earth in the form of chemical compounds. It has a metallic grey color, is brittle and hard to work. If refined to its purest form, it has a hardness that exceeds that of most steels. Of all the pure metals, tungsten has the highest melting point, lowest vapor pressure and highest tensile strength. It has the lowest coefficient of thermal expansion of any pure metal.

Tungsten’s toughness is greatly enhanced by alloying it with steel.

Around half of all tungsten is used for the production of hard materials, principally tungsten carbide. Tungsten carbide is used to make knives, drills, circular saws, and lathes. The metalworking, mining, construction, and petroleum industries rely heavily on tungsten carbide tools. Tungsten is also used to make alloys. The high melting point of tungsten makes it ideal for rocket and missile manufacture.

Inconel

Inconel is a type of superalloy made from austenite, nickel, and chromium. It is distinguished by its high strength which is not diminished at high temperatures. It’s also highly oxidation and corrosion resistant.

Inconel’s properties make it suitable for service in extreme environments. It’s commonly used in gas turbine blades, well pump motor shafts, chemical processing plants, and nuclear-pressurized water reactors.

[ Wiki ] Metal Type , never miss it!

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Holly Zhang

E-mail: sales4@sunraysteel.com

Mob: 86-13417960037 / Tel: 86-0757-63999952

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Address: 1507, A6, Hao Science Park, Guicheng, Nanhai District, Foshan, Guangdong, China.

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Hot Rolled Steel is available in many shapes, grades and sizes. Choose from the selection below.

Hot rolling involves the production of sheet metal from billets by passing the steel through rollers while above its recrystallization temperature to desired physical dimensions. Multiple passes through the rollers may be necessary to produce the final dimensions. Read more about the differences between hot and cold rolled steel.

Hot Rolled tubing is available in: Electric Resistance Welding (ERW), Cold Drawn Seamless (CDS), Drawn-Over-Mandrel (DOM), Hydraulic and Hot Finished.

Alloy steel is a steel that has had small amounts of one or more alloying elements (other than carbon) such as such as manganese, silicon, nickel, titanium, copper, chromium and aluminum added. This produces specific properties that are not found in regular carbon steel. Alloy steels are workhorses of industry because of their economical cost, wide availability, ease of processing, and good mechanical properties. Alloy steels are generally more responsive to heat and mechanical treatments than carbon steels.

The heat-treated type is available in both Annealed and Normalized. To learn more about Annealing and Normalizing

Aluminum is a silver-colored, low density metal. It finds use in a huge variety of commercial applications. The Unalloyed type is ductile, exhibits moderate strength, and is very resistant to corrosion under most circumstances. Aluminum can be dramatically strengthened by the addition of appropriate alloying elements (Cu, Mg, Mn, Si, etc.) and subsequent heat/work treatments. It is commonly used in both wrought and cast forms.

The low density of this metal results in its extensive use in the aerospace industry, and in other transportation fields. Its resistance to corrosion leads to its use in food and chemical handling (cookware, pressure vessels, etc.) and to architectural uses.

Brass is an alloy of both copper and zinc. It has low friction properties and acoustic properties, which make it one of the most popular metals to use when making musical instruments. It is commonly used as a decorative metal because of its resemblance to gold. It is also germicidal which means it can kill microorganisms on contact.

Other applications include architectural uses, condenser/heat exchangers, plumbing, radiator cores, musical instruments, locks, fasteners, hinges, ammunition components, and electrical connectors.

Bronze is an alloy that consists primarily of copper with the addition of other ingredients. In most cases the ingredient added is typically tin, but arsenic, phosphorus, aluminum, manganese, and silicon can also be used to produce different properties in the material. All of these ingredients produce an alloy much harder than copper alone.

Bronze is characterized by its dull-gold color, and has faint rings on its surface (which helps one to differentiate it from brass). It is used in the construction of sculptures, musical instruments and medals, and in industrial applications such as bushings and bearings, where its low metal on metal friction is an advantage. Bronze also has nautical applications because of its resistance to corrosion. Other applications include bearings and bushings, pump impellers, valve components, wire brushes, chemical hardware, gears, and pipe fittings.

Cold Rolled Steel is steel which has been rolled at room temperature, below its recrystallization temperature. This increases its strength and hardness and decreases its ductility. In addition to improvement of mechanical properties, cold rolling results in more control over the shape and dimensions of the finished product.

Cold Rolled steel has an improved surface finish and tighter tolerances compared to hot rolled steel. It is commonly used for parts requiring cold forming, such as crimping, swaging or bending. It can also be used for Shafts, machinery parts, bolts, pinions, gears, as well as in the creation of furniture, appliances and other consumer goods.

In general, copper alloys exhibit good to excellent corrosion resistance and high thermal conductivity and very high electrical conductivity. Pure copper’s electrical conductivity is so high that many metals are measured against it in the form of the IACS (International Annealed Copper Standard). Applications include architectural uses, coinage, condenser/heat exchangers, plumbing, radiator cores, musical instruments, locks, fasteners, hinges, ammunition components, and electrical connectors.

Small amounts of alloying elements are often added to it to improve certain characteristics. Alloying can increase or reduce the strength, hardness, electrical and thermal conductivity, corrosion resistance, or change the color. Common primary alloying elements include tin (resulting in bronze) or zinc (resulting in brass).

Hot-dip galvanizing is the process of coating iron or steel with a thin zinc layer, by passing the steel through a molten bath of zinc at a temperature of around 860 °F (460 °C). When exposed to the atmosphere, pure zinc reacts with oxygen to form zinc oxide, which further reacts with carbon dioxide to form zinc carbonate, a dull grey, fairly strong material that stops further corrosion in many circumstances, protecting the steel below from the elements. Galvanized steel is widely used in applications where rust resistance is needed, and can be identified by the crystallization patterning on the surface (often called a “spangle”).

The process of hot-dip galvanizing results in a metallurgical bond between zinc and steel with a series of distinct iron-zinc alloys. The resulting coated steel can be used in much the same way as uncoated. Galvanized steel can be welded; however, one must exercise caution around the resulting zinc fumes. Galvanized steel is suitable for high-temperature applications of up to 392 °F (200 °C). Use at temperatures above this level will result in peeling of the zinc at the intermetallic layer. Galvanized sheet steel is commonly used in automotive manufacture to enhance corrosion performance of exterior body panels of some models.

Stainless steel is a steel alloy with increased corrosion resistance compared to carbon/alloy steel. Common alloying ingredients include chromium (usually at least 11%), nickel, or molybdenum. Alloy content often is on the order of 15-30%.

Common applications include food handling/processing, medical instruments, hardware, appliances, and structural/architectural uses.

Tool steel is a term used for a variety of high-hardness, abrasion resistant steels. Specific tool applications are dies (stamping or extrusion), cutting, moldmaking, or impact applications like hammers (personal or industrial). It is also a common material used to make knives.

Tool Steels are extremely hard and are quite often used to form other metal products.

Tool Steel is available in a wide variety of shapes including round bar, flat bar, square bar and more.

[ Wiki ]What are the correct standards for stainless steel?

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Holly Zhang

E-mail: sales4@sunraysteel.com

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Address: 1507, A6, Hao Science Park, Guicheng, Nanhai District, Foshan, Guangdong, China.

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What are the correct standards for stainless steel?

The most common current European standards for stainless steel are:

Standard Number	Title	Relevant Technical Information
EN 10088-1	List of stainless steels
EN 10088-2	Technical delivery conditions for sheet/plate and strip for corrosion resisting steels for general purposes	Chemical Composition Properties of Ferritic Steels Properties of Martensitic Steels Properties of Austenitic Steels Properties of Duplex Steels Properties of PH Steels
EN 10088-3	Technical delivery conditions for semi-finished products, bars, rods, wire, sections and bright products for corrosion resisting steels for general purposes	All Products Chemical Composition Standard Products Properties of Ferritic Steels Properties of Martensitic Steels Properties of Austenitic Steels Properties of Duplex Steels Properties of PH Steels Bright Bars Properties of Ferritic Steels Properties of Martensitic Steels Properties of Austenitic Steels Properties of Duplex Steels Properties of PH Steels
EN 10095	Heat resisting steels and nickel alloys	Chemical Composition Ambient Temperature Properties
EN 10028-7	Flat products made of steels for pressure purposes – Stainless steels	Elevated Temperature Properties
EN 10296-2	Welded circular steel tubes for mechanical and general engineering purposes – Technical delivery conditions – Stainless steel	Chemical Composition Mechanical Properties Tolerances
EN 10297-2	Seamless circular steel tubes for mechanical and general engineering purposes – Technical delivery conditions – Stainless steel	Chemical Composition Mechanical Properties Tolerances
EN 10216-5	Seamless steel tubes for pressure purposes – Technical delivery conditions – Stainless steel tubes	Chemical Composition
EN 10217-7	Welded steel tubes for pressure purposes – Technical delivery conditions – Stainless steel tubes	Chemical Composition Mechanical Properties

These standards have replaced the old national standards and users are encouraged to use them. However, it is clear that the old standards are still used, not least because many existing drawings and company specifications refer to them. Therefore, it is still possible to come across standards such as:

BS 1449 and BS1501 for flat products

BS 970 for long products

The US standards such as ASTM and ASME are very important and will never be replaced. Common standards are:

Standard Number	Title	Relevant Technical Information
ASTM A240	Chromium and chromium-nickel stainless steel plate, sheet and strip for pressure vessels	Chemical Composition Austenitic Steels Chemical Composition Ferritic Steels Chemical Composition  Martensitic Steels Chemical Composition  Duplex Steels Chemical Composition  PH Steels
ASTM A276	Standard Specification for Stainless Steel Bars and Shapes	Chemical Composition Austenitic Steels Chemical Composition Ferritic Steels Chemical Composition  Martensitic Steels Chemical Composition  Duplex Steels Chemical Composition  PH Steels
ASTM A312	Standard Specification for Seamless and Welded Austenitic Stainless Steel Pipes	Chemical Composition Austenitic Steels Chemical Composition Ferritic Steels Chemical Composition  Martensitic Steels Chemical Composition  Duplex Steels Chemical Composition  PH Steels