In order to make the metal workpiece have the required performance, the heat treatment process is often essential. The heat treatment process generally includes three processes: heating, heat preservation, and cooling. Depending on the process, it is divided into quenching, tempering, normalizing, and annealing. Can you tell the difference? This article takes you to understand normalizing & annealing.
Similar Articles:
- Normalizing
- Heat treatment
- Quenching & Tempering
- Quenching and tempering(QT)
- Quenched and tempered steel
- Heat treatment quality inspection
- Heat treatment workshop work instructions
- Explanation of metallographic structure terms
- Factors Affecting Heat Treatment Deformation
- Common heat treatment process of steel castings
- The reasons and effects of steel parts needing quenching and tempering
What is normalizing?
Normalizing is a heat treatment that improves the toughness of steel. After heating the steel components to 30~50℃ above the Ac3 temperature, they are kept for some time and then released for air cooling. The main feature is that the cooling rate is faster than annealing but lower than quenching. During normalizing, the crystal grains of the steel can be refined in a slightly faster cooling, which can not only obtain satisfactory strength but also significantly improve toughness (AKV value), reducing The cracking tendency of the member. After some low-alloy hot-rolled steel sheets, low-alloy steel forgings, and castings are normalized, the comprehensive mechanical properties of the material can be greatly improved, and the cutting performance is also improved.
Normalizing has the following purposes and uses:
① For hypoeutectoid steel, normalizing is used to eliminate the superheated coarse grain structure and Widmandering structure of casting, forging, and welding parts, and the banded structure in the rolled material; refine the grain, and can be used as a pre-heat treatment before quenching.
② For hypereutectoid steel, normalizing can eliminate the reticulated cementite and refine the pearlite, which not only improves the mechanical properties but also facilitates the subsequent spheroidizing annealing.
③ For low-carbon deep-drawing thin steel sheets, normalizing can eliminate free cementite at grain boundaries to improve its deep-drawing properties.
④ For low-carbon steel and low-carbon low-alloy steel, normalizing can be used to obtain a more fine flake pearlite structure, which can increase the hardness to HB140-190, avoid the phenomenon of “sticking to the knife” during cutting, and improve machinability. . For medium carbon steel, normalizing is more economical and convenient when both normalizing and annealing are available.
⑤ For ordinary medium carbon structural steel, when the mechanical properties are not high, normalizing can be used instead of quenching and high-temperature tempering, which is not only easy to operate but also makes the structure and size of the steel stable.
⑥ High temperature normalizing (150~200℃ above Ac3) can reduce the composition segregation of castings and forgings due to the high diffusion rate at high temperatures. The coarse grains after high temperature normalizing can be refined by the second normalizing at a lower temperature.
⑦ For some low and medium carbon alloy steels used in steam turbines and boilers, normalizing is often used to obtain bainite structure, and then tempered at high temperature, it has good creep resistance when used at 400-550 °C.
⑧ In addition to steel and steel, normalizing is also widely used in the heat treatment of ductile iron to obtain pearlite matrix and improve the strength of ductile iron.
Since normalizing is characterized by air cooling, ambient temperature, stacking method, airflow, and workpiece size all affect the organization and performance after normalizing. The normalized structure can also be used as a classification method for alloy steel. Usually, alloy steels are divided into pearlitic steel, bainitic steel, martensitic steel, and austenitic steel according to the microstructure obtained by air cooling after heating a sample with a diameter of 25 mm to 900 °C.
What is annealing?
Annealing is a metal heat treatment process in which the metal is slowly heated to a certain temperature, kept for a sufficient time, and then cooled at a suitable rate. Annealing heat treatment is divided into complete annealing, incomplete annealing, and stress relief annealing. The mechanical properties of annealed materials can be tested by tensile test or hardness test. Many steels are supplied in the state of annealing and heat treatment. The hardness of the steel can be tested with a Rockwell hardness tester to test the HRB hardness. For thinner steel plates, steel strips, and thin-walled steel pipes, a surface Rockwell hardness tester can be used to test the HRT hardness.
The purpose of annealing is to:
① Improve or eliminate various structural defects and residual stress caused by steel in the process of casting, forging, rolling, and welding, and prevent workpiece deformation and cracking.
② Soften the workpiece for cutting.
③ Refine the grain and improve the structure to improve the mechanical properties of the workpiece.
④ Prepare the structure for final heat treatment (quenching, tempering).
Commonly used annealing processes are:
① Fully annealed. It is used to refine the coarse superheated structure with poor mechanical properties after casting, forging, and welding medium and low carbon steel. Heat the workpiece to a temperature of 30-50°C above the temperature at which all ferrite transforms into austenite, hold for some time, and then slowly cool with the furnace. During the cooling process, the austenite transforms again, which can make the steel structure thinner.
② spheroidizing annealing. It is used to reduce the high hardness of tool steel and bearing steel after forging. The workpiece is heated to 20-40°C above the temperature at which the steel begins to form austenite, and then slowly cooled after heat preservation. During the cooling process, the lamellar cementite in the pearlite becomes spherical, thereby reducing the hardness.
③ Isothermal annealing. It is used to reduce the high hardness of some alloy structural steels with high nickel and chromium content for cutting. Generally, it is first cooled to the most unstable temperature of austenite at a relatively fast rate, and the austenite is transformed into tortenite or sorbite for an appropriate time, and the hardness can be reduced.
④ Recrystallization annealing. It is used to eliminate the hardening phenomenon (increase in hardness and decrease in plasticity) of metal wires and sheets during cold drawing and cold rolling. The heating temperature is generally 50 to 150 °C below the temperature at which the steel begins to form austenite. Only in this way can the work hardening effect be eliminated and the metal softens.
⑤ Graphitization annealing. It is used to make cast iron containing a large amount of cementite into malleable cast iron with good plasticity. The process operation is to heat the casting to about 950 ℃, keep it for a certain period and then cool it properly to decompose the cementite to form flocculent graphite.
⑥ Diffusion annealing. It is used to homogenize the chemical composition of alloy castings and improve their performance. The method is to heat the casting to the highest possible temperature without melting, keep it warm for a long time, and cool slowly after the diffusion of various elements in the alloy tends to be uniformly distributed.
⑦ Stress relief annealing. It is used to relieve the internal stress of steel castings and welded parts. For iron and steel products, it is 100 to 200°C below the temperature at which austenite begins to form after heating, and the internal stress can be eliminated by cooling in the air after heat preservation.
Recent Articles:
- Casting technical requirements and analysis of common problems of steel castings
- What is the role of Mo in high manganese steel casting production?
- What effect does carbon have on cast steel and iron during smelting?
- Prevention and Analysis of Stainless Steel Casting Defects
- Causes of cracks in steel castings
