Payment & Shipping Terms:
|Material:||ASTM A128/A128M,or ZGMn13-3||Process:||Sand Casting Process|
|Machining:||CNC Machining||Surface:||Anti-Rust Oil|
|Packing:||Plywood Crate + VCI Anti-Rust Bag||Heat Treatment:||Water Toughening Treatment|
wear resistant castings,
cast iron wear resistance
CNC Machining Wear Resistant Steel Castings Hammer Parts ZGMn13 Material
Product Description and Process
Wear Resistant Cast Steel High Manganese Steel Hammer Parts ZGMn13 Material Foundry
Production process: green sand molding, pre-coated sand molding, lost wax investment casting process, lost foam casting process
Machining process:CNC machining
Heat Treatment:Water Toughening Treatment
Surface treatment process: paint coating
Product Material and Uses
Normally produce with ASTM A128/A128M, ZGMn13-1, ZGMn13-2, ZGMn13-3, ZGMn13-4, ZGMn13-5, ZGMn13Cr2, etc.
The wear resistant steel casting products are widely used for quarrying, excavating, coal industry, cast industry, steel industry, etc.
Wear Resistant Steel castings
We can offer a wide range of wear resistant steel castings ranging from High Chromium cast White Irons, Chromium – Nickel abrasion resistant cast irons, Austenitic Manganese steels and Alloyed / Low Alloyed abrasion resistant steels. Cast mass ranges up to 8000Kg can be achieved with CAD / CNC pattern making technology assuring accuracy of the manufactured part. Patterns will be manufactured from Wood, Aluminium – Wood combined or from Aluminium depended upon casting requirements. All castings can be supplied with material and mechanical property analysis certificates upon request.
Typical Applications for Wear Resistant castings
Chute Liner Plates
Transfer Chute Impact Backing Liners
Grinding Mill Lifter Bars and Shell Liners
Grinding Mill End Grates
Grinding Mill Feed Chute Liners
Grizzly Bars and Grizzly Bar Caps
Impact Crusher Blow Bars
Impact Crusher Liners
Skip Load Flask Liner Plates
Cone Crusher Liners
Mangalloy Wear-Resistant Cast Steel
Mangalloy, also called manganese steel or Hadfield steel, is an alloy steel containing an average of around 13% manganese. Mangalloy is known for its high impact strength and resistance to abrasion once in its work-hardened state.
Mangalloy is made by alloying steel, containing 0.8 to 1.25% carbon, with 11 to 15% manganese. Mangalloy is an unique non-magnetic steel with extreme anti-wear properties. The material is very resistant to abrasion and will achieve up to three times its surface hardness during conditions of impact, without any increase in brittleness which is usually associated with hardness. This allows mangalloy to retain its toughness.
Most steels contain 0.15 to 0.8% manganese. High strength alloys often contain 1 to 1.8% manganese. At about 1.5% manganese content, the steel becomes brittle, and this trait increases until about 4 to 5% manganese content is reached. At this point, the steel will pulverize at the strike of a hammer. Further increase in the manganese content will increase both hardness and ductility. At around 10% manganese content the steel will remain in its austenite form at room temperature if cooled correctly. Both hardness and ductility reach their highest points around 12%, depending on other alloying agents. The primary of these alloying agents is carbon, because the addition of manganese to low-carbon steel has little effect, but increases dramatically with increasing carbon content. The original Hadfield steel contained about 1.0% carbon. Other alloying agents may include metals like nickel and chromium; added most often to austenitic steels as an austenite stabilizer; molybdenum and vanadium; used in non-austenitic steels as a ferrite stabilizer; or even non-metallic elements such as silicon.
Mangalloy has fair yield strength but very high tensile strength, typically anywhere between 350 and 900 megapascals (MPa), which rises rapidly as it work hardens. Unlike other forms of steel, when stretched to the breaking point, the material does not "neck down" (get smaller at the weakest point) and then tear apart. Instead, the metal necks and work hardens, increasing the tensile strength to very high levels, sometimes as high as 2000 MPa. This causes the adjacent material to neck down, harden, and this continues until the entire piece is much longer and thinner. The typical elongation can be anywhere from 18 to 65%, depending on both the exact composition of the alloy and prior heat-treatments. Alloys with manganese contents ranging from 12 to 30% are able to resist the brittle effects of cold, sometimes to temperatures in the range of −196 °F (−127 °C).
Mangalloy has been used in the mining industry, cement mixers, rock crushers, railway switches and crossings, crawler treads for tractors and other high impact and abrasive environments. It is also used in high impact environments like inside a shot peening machine. These alloys are finding new uses as cryogenic steels, due to their high strength at very low temperatures. Mangalloy is heat treatable, but the manganese lowers the temperature at which austenite transforms into ferrite. Unlike carbon steel, mangalloy softens rather than hardens when rapidly cooled, restoring the ductility from a work-hardened state. Most grades are ready for use after annealing and then quenching from a yellow heat, with no further need of tempering, and usually have a normal Brinell hardness of around 200 HB, (roughly the same as 304 stainless steel), but, due to its unique properties, the indentation hardness has very little effect on determining the scratch hardness (the abrasion and impact resistance of the metal). Another source says that the basic Brinell hardness of manganese steel according to the original Hadfield specification is 220 but that with impact wear the surface hardness will increase to over 550.
Many of mangalloy's uses are often limited by its difficulty in machining; sometimes described as having "zero machinability." The metal cannot be softened by annealing and hardens rapidly under cutting and grinding tools, usually requiring special tooling to machine. The material can be drilled with extreme difficulty using diamond or carbide. Although it can be forged from a yellow heat, it may crumble if hammered when white-hot, and is much tougher than carbon steel when heated. It can be cut with an oxy-acetylene torch, but plasma or laser cutting is the preferred method. Despite its extreme hardness and tensile strength, the material may not always be rigid. It can be formed by cold rolling or cold bending.
Manganese Steel Castings
This is a unique alloy with high toughness, ductility, high work hardening capacity, non magnetic in nature and usually good resistance to wear. Manganese Steel's ability of work hardening is unique and probably has no equal in this respect. Manganese Steel is used extensively in field of Mining, Cement, Earthmoving, Mineral Processing, Oil Well Drilling, Railroading and Power Sector.
Common Wear-Resistant Cast Steel Grade and Chemical Composition
|C||Mn||Si||P ≤||S ≤||Cr|
Standard Composition Ranges for Austenitic Manganese Steel Castings ( ASTM A128)
IS: 276-2000 (Reaffirmed 2005)
|Grade||Chemical Composition, percentage|
Note: In case of Grade 1 & 3 it is desirable to have a min. ratio of manganese to carbon 10:1
Mechanical Properties of Austenitic Manganese Steel Casting
|IS Grade||Tensile Strength Min (MPa)||Yield Stress Min (MPa)||Elongation Percent Min.||Hardness HB Max.||Angle of Bend Degrees Min.|
Note: All the mechanical properties shown in the table are optional except for the bend test requirement for all grades and hardness values given against grades 1, 2 & 3.
Contact Person: Mr. James Wang
Tel: +86 13213152686