Heat Resistant Steel
What Is Heat Resistant Steel
For most types of steel, the desirable properties and yield strength lessen significantly as the steel is exposed to high temperatures. heat resistant steels are resistant to temperatures over 500°C, maintaining their strength and other properties.
High temperature resistance
Certified high temperature steels are capable of withstanding extreme temperatures that would normally cause other materials to warp and break.
Corrosion resistance
Such steels also have high corrosion and oxidation resistance, making them suitable for use in harsh environments.
Durability
Due to their ability to withstand high temperatures and corrosive attack, heat resistant steels typically have a long service life.
Strengh
This type of steel has high strength and rigidity, which allows them to cope with heavy loads and avoid deformation and destruction.
Ease of processing
Modern high temperature steels can usually be easily machined and formed into various configurations and sizes. Thanks to this, the scope of application is constantly expanding.
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Heat-resistant steel has four types of structures: austenitic, martensitic, ferritic, and precipitation hardening, each of which has different applications and properties.
Austenitic steels are composed of chromium steel with nickel added. They maintain their microstructure even at room temperature and are characterized by excellent corrosion resistance. It is used in household products, construction, LNG tanks, nuclear facilities, etc.
The martensitic type is a microstructure obtained by cooling austenite rapidly and is characterized by hardness and brittleness. Due to its wear resistance, it is used for bearing components within bearings and for blades.
The ferritic type is inexpensive because it does not contain nickel, but it has the disadvantage of inferior corrosion resistance and strength compared to the austenitic type. It is used for indoor kitchen equipment that does not require much corrosion resistance.
Precipitation hardening type is characterized by low distortion due to heat treatment at low temperatures while maintaining strength, and is less prone to age-related deterioration, such as baking cracks caused after heat treatment.
Applications of Heat Resistant Steel




For most types of steel, the desirable properties and yield strength lessen significantly as the steel is exposed to high temperatures. heat resistant steels are resistant to temperatures over 500°C, maintaining their strength and other properties. Here we will outline the basics of heat resistant steels and their key applications.
How is Heat Resistant Steel Made
Heat resistant steel is strengthened using alloys, heat treatment, solid solution, and precipitation. Chromium is present in all types of heat resistant steel, offering oxidation resistance, high-temperature strength, and carburization resistance. Chromium makes heat resistant steel ferritic.
Nickel is sometimes added to heat resistant steel to enhance ductility, temperature strength, and carburizing and nitriding resistance. Nickel makes the atomic structure of steel austenitic. Carbon can also be added to steel as a strengthening element, dissolving in alloy and enhancing solution strength.
Heat Resistant Steel for the Oil and Gas Industry
Steel is a critical material in the oil and gas industry, used in every part of the industry from the marketplace to transportation, to construction. The demands put on heat resistant steel in these industries are extremely high, meaning they must go under stringent testing and come from reputable steel mills that are high quality.
Some of the applications in the oil and gas industry can lead to structural or thermal stresses, crack growth, fatigue, and corrosion which must be frequently inspected and maintained. Applications in the oil and gas industry require extremely high temperatures which can make standard steel brittle.
Why Furnaces Use Heat Resistant Steel
Industrial furnaces are used for smelting at high temperatures, tempering, drying, and heat treatment. Industrial furnaces can sometimes require temperatures of up to 3000°C, meaning standard steel would be adversely impacted by the high temperatures required.
In furnace applications, the exposure to heat will be intermittent rather than prolonged. Heat resistant steel can tolerate frequent exposure to high temperatures in short stretches as well as over long periods.
Chrome Moly Heat Resistant Steel
Chrome Moly is a widely used heat resistant steel that is used in petrochemical, oil, and gas industries. The mixture of chromium for corrosion resistance and molybdenum for increased tensile strength means it is well suited to environments that require extremely high temperatures.
Chrome Moly also has an excellent strength-to-weight ratio, making it easier and more cost-effective to install and manage than many other heat resistant materials.
Masteel supplies chrome-moly steel for a huge selection of industries, available in various thicknesses and widths, and they provide in-house profiling and cutting services. Masteel's materials are fully traceable, coming from reputable sources. To find out more about the benefits of heat resistant steel, get in touch for more details.
- Industrial furnace construction (hood-type furnace for the heat treatment of coils and wires, glow systems for steel, stainless steel and nonferrous heavy metals), pusher furnace and so on
- Exhaust systems, for example in the automotive industry for exhaust elbows
Industries
Incineration plant
Ceramic industry
Steam boiler
Glass industry
Pulp industry
Chemical and petrochemical industry
Various applications in the apparatus engineering
Hardening plant
Cement industry (for example for revolving cylindrical furnace)
Food industry
Heat exchanger for different applications in higher temperature range
The Importance of Heat Resistant Steel Maintenance
Always remember to take appropriate precautions when cleaning your steel to protect both yourself and the metal. Specific precautions for most cleaners can be found in their respective material safety data sheets (MSDS). However, these tips will cover a broad range of concerns.
Never use an abrasive on Heat Resistant Steel: This includes but is not limited to sandpaper, steel wool, metal brushes, and harsh abrasive cleaners. Soft abrasives might work in specific scenarios. However, spot testing in an inconspicuous place is recommended before performing widespread maintenance. You should also take care to use abrasives in the same direction as the grain or polish on the surface of the steel to ensure an optimal appearance.
Always use appropriate safety gear: Goggles, gloves, and other protective gear will help to improve worker safety and provide an unobstructed view and unhindered cleaning of stainless surfaces.
Always use cleaners in a ventilated environment: Should cleaning require more than soap and water, be sure to use cleaners in a ventilated environment. Inhaling fumes might carry health risks.
Always add water to acid, not acid to water: Many of the acids used in cleaning Heat Resistant Steel are highly caustic. Adding acid to water slowly will help reduce splashing and avoid potential injury.
Check follow-up procedures for cleaning: As mentioned above, most cleaning methods require a warm water rinse, a separate washing with warm soap and water or both.
Types of Heat-Resistant Steels
Heat-resistant steels have chemical stability, sufficient strength, and gas corrosion-resistance. These steels can be classified into low alloy steels, martensitic steels, and austenitic steels as per their chemical composition and microstructure.
Low alloy steels– Because of good mechanical properties at high temperatures and sufficient corrosion resistance, low alloy steels are widely used in pressure part applications in boilers. The most recent advancement in low alloy steel is the development of 3Cr-3W(Mo)V steels, which has a higher creep strength than 2.25Cr-1Mo steel and 2.25Cr-1.6W-VNb steel.
In general, Cr-Mo low alloy ferritic steels are tough and ductile at lower operating temperatures and maintain good strength at higher temperatures. Unfortunately, when subjected to prolonged exposure to intermediate service temperatures, these steels can become embrittled with an associated decrease in fracture toughness and a shift in ductile-to-brittle transition temperature (DBTT) to higher temperatures. The embrittlement is mainly caused by changes in the micro-chemistry of grain boundaries, which is referred to as temper embrittlement. Temper embrittlement is non-hardening embrittlement and is caused by grain boundary segregation of impurity elements such as P, Sn (tin), and Sb (antimony) as a result of long term exposure in the temperature range of 350 deg C to 600 deg C. P is considered to be the major embrittling impurity element in steel.
Another type of low alloy steels extensively used for various engineering components are Cr1Mo steels, such as 12Cr1MoV, 14CrMo4-5 (ISO 9328-2, 1991), 13CrMo4-5 (EN 10028-2, 1992), or 12C1.1 (ASTM A182-96) etc. These steels are the heat resistant steels with low additions of alloying elements in chemical composition. These grades are normally used for the pipelines used to transport superheated steam in the temperature range 500 deg C to 560 deg C and under a pressure of 10 MPa to 15 MPa.
The initial microstructure of low alloy steels is ferrite-bainite or ferrite-pearlite. Normally, the Cr-Mo and Cr-W heat resistant steels are used in the normalized and tempered condition. Normalizing consists of heating above A1 equilibrium temperature where ferrite transforms to austenite, and then cooling in air.
In low alloy steels with less than 5 % Cr, bainite (ferrite containing a high dislocation density and carbides), polygonal ferrite, or a combination of these two constituents form, depending on the section size is produced. Their creep strength enhanced by the formation of precipitates, which are stable alloy carbides and intermetallic compounds obtained following normalizing heat treatment later on subjected to very severe tempering (around 700 deg for several hours).
Thermal Heat Resistance of Heat Resistant Steel
How to measure performance
However, the key component of a heat resistant steel is its durability at high temperatures, which can be measured in a variety of different ways. One way to measure the performance of a steel at high temperatures is to measure the UTS and the YS at elevated temperatures, typically more than 1200F. Many heat resistant steels can hold a UTS of 30-50ksi at 1400F and a YS of up to 30ksi. Typically, alloys that have a sufficiently high chromium and nickel content perform the best in this category of elevated temperature tensile and yield strength, including HL, HP, HU, and HK. Alloys in this category typically have a fully austenitic structure. Due to the higher presence of alloying elements, these alloys also tend to be more expensive.
Another way that performance of heat resistant steel is measured is in terms of its creep and stress rupture strength. Creep is extremely common in heat resistant steel castings. For those who are unfamiliar, creep is the stress that occurs to castings that are under strain at high temperatures. While entirely preventing creep is not possible, most heat resistant steel alloys are designed to minimize the effect of creep to some degree, which in turn, prolongs the service life of the casting. Where creep becomes the most problematic is in select cases where it leads to casting deformation and can even lead to fractures due to the strength of the casting being compromised such that it fractures below the properties defined in an elevated temperature tensile test.
Alloy selection
Creep can be accounted for in casting design and in alloy selection, an engineer can select a casting design that will allow the casting to continue to perform for an extended period in the event of creep and may also select an alloy that is more resistant to creep. In terms of alloy selection, an engineer should select an alloy that slows the process of plastic deformation and has a high rupture stress, prioritizing one or the other based upon the application. In terms of deformation control, the best bet is typically to go with an alloy that contains at least 30% nickel and 15% chrome to obtain a fully austenitic structure, HT, HU, and HP are great examples. Some iron-chromium-nickel alloys such as HK also perform well in this arena.
When it comes to the rupture stress, controlling carbon content to be in the 0.3-0.7% range will be the most important variable. In the 0.3-0.7% carbon range, the metal will be much more resistant to rupture stresses than those that are 0.2% and below. Other alloying elements are also key, particularly enough nickel to form an austenitic structure (At least 18%, preferably 22%+) and a chromium content more than 15% are key, HK, HN, and HP are quality examples. Some of the most rupture resistant alloys will contain some content of specialized alloying elements such as tungsten or niobium, though carbon content remains the most impactful variable to control.
Avoiding oxidation
Another key in stainless steel is resistance to oxidation at high temperatures. For this reason, a heat resistant stainless steel must contain a minimum of 12% chromium to resist iron oxide formation at high temperatures. Further oxidation resistance can be obtained through a higher chromium and nickel content.
Thermal fatigue
If a casting is subjected to thermal cycling or shock, that must also be taken into account when it comes to alloy selection for a heat resistant steel. There is not a great way to measure thermal fatigue in a casting, there are thermal fatigue tests, but they do not greatly carry over to reality.
How to resist carburization
Carburization resistance is another consideration to be made, especially for castings that will be involved in an application like commercial heat treatment. Higher nickel and chromium contents largely increase the resistance of the metal to carbon penetration into the surface of the casting. Silicon plays a vital role in carburization resistance as well, small increases in silicon can make a drastic difference on the ability of the alloy to resist carbon penetration, typically around 2% silicon is used in castings that are meant to resist carburization. Other alloying elements have been added to stainless steels to resist carburization though are not widely used and their effectiveness remains debatable.
Other considerations
In rare cases, considerations need to be made for a high sulfur environment that will cause oxidation in the steel castings. High nickel content heat resistant alloys are very prone to corrosion in a high sulfur environment due to their fully austenitic structure, so alloys that are entirely ferritic are typically a better selection.
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