If the heat treatment is improper, bearing heat treatment is one of the core key processes of bearing manufacturers. The heat treatment process and the physical properties of the raw materials determine the final hardness, hardness uniformity, wear resistance and contact fatigue life of the bearing. What problems will arise?

Heat treatment deformation

During heat treatment of bearing parts, there are thermal stress and structural stress, and this internal stress can interact with each other. Superposition or partial offset is complex and changeable, because it can vary with heating temperature, heating rate, cooling method, cooling rate, shape and size of parts, so heat treatment deformation is inevitable. Knowing and mastering its changing law can make the deformation of bearing parts (such as the ellipse of the ferrule, the size increase, etc.) in a controllable range, which is beneficial to the production. Of course, the mechanical impact during the heat treatment will also deform the part, but this deformation can be reduced and avoided with improved operations.

Overheating

The microstructure after quenching can be observed overheating from the rough mouth of the bearing parts. But to accurately judge the degree of its overheating must observe the microstructure. If coarse acicular martensite appears in the quenched structure of GCr15 steel, it is a quenched superheated structure. The reason for the formation may be the overall overheating caused by the quenching heating temperature is too high or the heating and holding time is too long; it may also be due to serious banded carbides in the original structure, forming local martensitic needle-like thick in the low-carbon area between the two bands, localized overheating. The retained austenite in the superheated structure increases and the dimensional stability decreases. Due to the overheating of the quenched structure and the coarse crystals of the steel, the toughness of the parts will be reduced, the impact resistance will be reduced, and the life of the bearing will also be reduced.

Underheating

A low quenching temperature or poor cooling will cause the microstructure to exceed the standard specification. The tensite structure, called the underheated structure, reduces the hardness and wear resistance sharply, which affects the bearing life.

Soft spots

The local hardness of the bearing parts surface is not enough due to insufficient heating, poor cooling, improper quenching operation, etc. The phenomenon is called quenching soft spot. Surface decarburization can also cause a serious decrease in surface wear resistance and fatigue strength.

Surface decarburization

During the heat treatment of bearing parts, if they are heated in an oxidizing medium, the surface will Oxidation reduces the mass fraction of carbon on the surface of the part, resulting in surface decarburization. The depth of the surface decarburization layer exceeds the allowance of final machining and the part is scrapped. Determination of the depth of the surface decarburization layer can be used in metallographic examination metallographic method and microhardness method.

Quenching cracks

The cracks formed by the internal stress of the bearing parts during the quenching and cooling process are called quenching cracks. The reasons for this crack are: due to the high quenching heating temperature or the rapid cooling, the thermal stress and the structural stress of the metal mass and volume change are greater than the fracture strength of the steel; the original defects of the working surface (such as surface fine cracks or scratches) marks) or internal defects of the steel (such as slag inclusions, serious non-metallic inclusions, white spots, shrinkage cavity residues, etc.) form stress concentration during quenching; severe surface decarburization and carbide segregation; parts are insufficiently tempered after quenching Or not tempered in time; the cold stamping stress caused by the previous process is too large, forging folding, deep turning tool marks, sharp edges and corners of oil grooves, etc.