1.7228 708M50 50CrMo4 Quenched Tempered Alloy Steel Round Bar
1.7228 708M50 50CrMo4 Quenched Tempered Alloy Steel Round Bar
Model
1.7228 708M50 50CrMo4

Item specifics

Delivery Condition
+N or +A or +QT
Surface Condition
black or turned or polished

Review

Description

1.7228 708M50 50CrMo4 Quenched Tempered Alloy Steel

 

Our supply size :

Diameter : 80 to 600 mm ;

Length : 1000 to 9000 mm ;

 

Our capacity :

Delivery condition : Normalized, or Annealed, or Quenched and Tempered ;

Surface condition : Grounded, or Turned, or Polished

 

Our advantage :

1. High Quality, Reasonable Price

2. Over 40 Years Experience

3. ISO NQA Certificated Factory

4. Worldwide shipping

5. Emergency Orders and Fast Delivery

 

Chemical Composition

Standard "1.7228 Grade" Chemical Composition

Carbon

0.48-0.53

Manganese

0.75-1.00

Phosphorus (max)

0.035

Sulfur (max)

0.04

Silicon

0.15-0.35

Chromium

0.80-1.10

Molybdenum

0.15-0.25

Estimated Mechanical Property Ranges for "Grade 1.7228"

Tensile strength (psi)

100,000 - 110,000

Yield strength (psi)

70,000 - 80,000

Elongation in 2(%)

15 - 25

Reduction of area (%)

30 - 40

Brinell Hardness (BHN)

210 - 240

 

Alloy Steel 1.7228, also sold under the name EN/DIN 1.7228, is a high-carbon alloy that includes chromium, manganese, and molybdenum. This tough steel alloy offers uniform strength, wear resistance, and great hardness. It is important to note that Alloy Steel 1.7228 must be heat-treated to be suitable for machining. The weldability of Alloy Steel 1.7228 is high and can be achieved through most commercial methods. The finest of grain size relates directly with the temperature of forging.

 

Alloy Steel 1.7228 is used in the aerospace, defense, oil and gas, and automotive industries for products such as:

Shafts

Valves

Sprockets

Aerospace parts

Axles

Spindles

Forged gears

 

HEAT TREATMENT

The alloy is heat treated to render it suitable for machining, and to meet the mechanical property ranges specified for its particular applications.

 

ANNEALING

Annealing of 1.7228 forgings may be carried out by transferring the part straight from the forging operation to a furnace held at a suitable temperature, around 1500 º F (815 º C), for annealing, holding for a suitable time then furnace cooling, forming a structure suitable for machining. This kind of treatment is best used for parts with simple shapes. If some areas of a forging will finish much colder than others then a uniform structure will not be obtained, in which case a spheroidizing anneal at around 1380 º F (750 º C) might be used. It is safe to say that experience alone will decide the best type of annealing treatment to be used prior to machining.

 

NORMALIZING

Normalizing may be defined as heating a steel to a temperature above the ferrite to austenite transformation range and then cooling in air to a temperature well below this transformation range. This treatment may be carried out on forged or rolled products as a conditioning treatment prior to final heat treatment. Normalizing also serves to refine the structure of forgings that might have cooled non-uniformly from their forging operation. The nominal normalizing temperature range for 1.7228 grade is 1600 to 1700 º F (870 to 925 º C). followed by air cooling. In fact when forgings are normalized before, say, carburizing or hardening and tempering, the upper range of normalizing temperatures is used. When normalizing is the final heat treatment, the lower temperature range is used.

 

HARDENING

This heat treatment results in the formation of martensite after quenching and hence an increase in strength and hardness together with a significant loss of ductility. The steel should be austenitized at 1500 to 1550 º F (815 to 845 º C), the actual temperature being a function of chemical composition within the allowed range, section size and cooling method. Smaller sections of 1.7228 might be quenched in oil, heavier sections in water.

 

Tempering is carried out to relieve stresses from the hardening process, but primarily to obtain the required mechanical properties. The actual tempering temperature will be chosen to meet the required properties, and in many cases will be a matter of trial and error.

 

MACHINABILITY

The alloy is readily machinable after annealing. The optimum structure for machining of this alloy is normally one of coarse lamellar pearlite to coarse spheroidite.

 

WELDABILITY

Weldability of 1.7228 is good, and the alloy may be welded using any commercial method. Parts should be preheated before welding at around 1100 º F (590 º C) and stress relieved after. Parts in the hardened and tempered condition should not be welded since mechanical properties will be adversely affected : parts should only be welded in the annealed condition.

 

COLD FORMABILITY

This alloy may be cold formed on material that has a spheroidized structure. Further heat treatment, such as hardening and tempering, is carried out, as required on the finally formed part.