A standard alloy in the family of superalloys, Hastelloy C2000 Round Bars, is used for various purposes. They are a popular choice due to their ability to provide high corrosion resistance, durability, and rust-free finish. As a result, they are often used in machinery and equipment that comes in contact with water and other contaminants.
Typical uses of Hastelloy C2000 Round Bars
Hastelloy C2000 round bars have several great features. Also, these include excellent corrosion resistance, high strength, and weldability. They are used in a wide range of applications. The Hastelloy C2000 Round Bars are available in various forms, shapes, and thicknesses. Also, they are ideal for multiple industrial applications. For example, they are suitable for oilfields, drilling rigs, chemical processing, petrochemical industries, pharmaceuticals, and food processing equipment.
This nickel-chromium-molybdenum alloy has a long history of use in the Chemical Process Industries. It offers superior resistance to ferric ions and stress corrosion cracking. In addition to this, the alloy is resistant to halide solutions, localized corrosion, and pitting.
Aside from its corrosion resistance, Hastelloy C2000 Round Bars also have excellent oxidation and creep resistance. Moreover, they can also withstand high temperatures. Furthermore, they are used in both reducing and oxidizing environments. Because of this, they are also suited for applications such as exhaust gas desulfurization.
Corrosion resistance
Hastelloy C2000 round bars are ideal for a wide variety of applications. Also, they provide excellent resistance to hydrochloric, sulphuric acid, and many other corrosive chemicals. These bars are also resistant to reducing and oxidizing media.
The Hastelloy alloy is a nickel-chromium-molybdenum alloy that has high corrosion resistance. It is used in various applications, including aerospace and chemical process equipment.
Various forms of the alloy are available. In addition to round bars, rods, and pipe, Hastelloy C2000 is also available in multiple shapes. Compared to traditional steel, these alloys are more durable. This allows them to be used for several applications, such as furnace baffles, catalyst support grids, afterburners, and aircraft components.
C2000 has high resistance to stress corrosion cracking and sulfuric acid. However, it is not recommended for welding. For this reason, it is essential to have a partial solution heat treated before use.
Metallurgical stability
C2000 has good metallurgical stability. It is an upgraded alloy of Ni-Cr-Mo, which offers better corrosion resistance. Also, this makes it an excellent choice for chemical process equipment. Hastelloy C2000 has a high chromium content, which helps to resist corrosion from oxidizing media. The alloy is also resistant to pitting and crevice corrosion. These characteristics make this alloy an ideal choice for chemical process equipment. In addition, this alloy has a more excellent safety factor under heavy conditions, allowing it to be used in multiple applications.
C-2000 has been listed in ASTM B562-564-B. While it is not the only nickel-based alloy that can be used for chemical processing applications, it is one of the most reliable and versatile.
It is also resistant to iron ions and dissolved oxygen. Besides, the alloy is vital in terms of thermal conductivity. For example, the density of Hastelloy C-2000 is 12.4 m m / m deg C. And it has a thermal conductivity of 10.8 W / m – k.
Common alloys in the “superalloy” family
A superalloy is a class of high-performance alloys with excellent strength, toughness, and resistance to corrosion and environmental attack. They are used in many applications and can perform at temperatures close to their melting point. Commonly, these alloys are based on iron, nickel, or cobalt. However, other metals are also used, such as aluminum.
The development of superalloys primarily depends on a combination of chemical and process innovations. These alloys usually contain refractory elements and thus have high density. In addition, chromium, which provides oxidation resistance, is usually present.
Superalloys are typically face-centered cubic austenitic in the crystal structure. A low in-plane modulus, critical to strain tolerance, characterizes them. Various methods have been used to improve their flexibility, such as grain-boundary strengthening.
Superalloys are usually fabricated from a base metal, and alloy elements are added to the metal to improve the final composition. Some alloys are also oxide dispersion strengthened.