1Cr13Al4
0Cr15Al5
0Cr19Al2
0Cr21Al4
0Cr21Al6
0Cr25Al5
0Cr21Al6Nb
0Cr27Al7Mo2
1Cr13Al4
0Cr15Al5
0Cr19Al2
0Cr21Al4
0Cr21Al6
0Cr25Al5
0Cr21Al6Nb
0Cr27Al7Mo2
1Cr13Al4
0Cr15Al5
0Cr19Al2
0Cr21Al4
0Cr21Al6
0Cr25Al5
0Cr21Al6Nb
0Cr27Al7Mo2
1Cr13Al4
0Cr15Al5
0Cr19Al2
0Cr21Al4
0Cr21Al6
0Cr25Al5
0Cr21Al6Nb
0Cr27Al7Mo2
1Cr13Al4
0Cr15Al5
0Cr19Al2
0Cr21Al4
0Cr21Al6
0Cr25Al5
0Cr21Al6Nb
0Cr27Al7Mo2
1Cr13Al4
0Cr15Al5
0Cr19Al2
0Cr21Al4
0Cr21Al6
0Cr25Al5
0Cr21Al6Nb
0Cr27Al7Mo2
6J12
6J8
6J13
6J40
CuMn7SN
CuMn30Ni5
6J12
6J8
6J13
6J40
CuMn7SN
CuMn30Ni5
6J12
6J8
6J13
6J40
CuMn7SN
CuMn30Ni5
6J12
6J8
6J13
6J40
CuMn7SN
CuMn30Ni5
CuNi30
CuNi34
CuNi44
CuNi30
CuNi34
CuNi44
CuNi30
CuNi34
CuNi44
CuNi30
CuNi34
CuNi44
4J336(4J36)
4J342(4J42)
4J343(4J43)
4J352(4J49)
4J350(4J50)
6J415(6J15)
6J420(6J20)
6J422(6J22)
6J423(6J23)
6J424(6J24)
6J425(6J25)
6J426(6J26)
6J520(6J27)
4J336(4J36)
4J342(4J42)
4J343(4J43)
4J352(4J49)
4J350(4J50)
6J415(6J15)
6J420(6J20)
6J422(6J22)
6J423(6J23)
6J424(6J24)
6J425(6J25)
6J426(6J26)
6J520(6J27)
4J336(4J36)
4J342(4J42)
4J343(4J43)
4J352(4J49)
4J350(4J50)
6J415(6J15)
6J420(6J20)
6J422(6J22)
6J423(6J23)
6J424(6J24)
6J425(6J25)
6J426(6J26)
6J520(6J27)
6J525(6J28)
4J336(4J36)
4J342(4J42)
4J343(4J43)
4J352(4J49)
4J350(4J50)
6J415(6J15)
6J420(6J20)
6J422(6J22)
6J423(6J23)
6J424(6J24)
6J425(6J25)
6J426(6J26)
6J520(6J27)
6J525(6J28)
Ni95Al5
monel 400
monel R405
monel K500
monel 502
monel 400
monel R405
monel K500
monel 502
monel R405
monel K500
monel 502
Hastelloy C-22
Hastelloy C-22
Hastelloy C-22
Inconel 800
Inconel 800H
Inconel 800HT
Inconel 825
Inconel 800
Inconel 800H
Inconel 800HT
Inconel 825
Inconel 800
Inconel 800H
Inconel 800HT
Inconel 825
Strip & Foil
Round Wire
Bar & Rod
Electrothermal strip
Bolts & Fasteners
Flange & Ring
Wire & Welding
Reststance wire & flat wire
Electric alloy wire
Electric furnace wire
0102030405
The forging process of alloy typically
2024-10-14
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The forging process of alloy typically includes the following key steps:
1. Material Preparation: According to the composition requirements of the alloy, select the appropriate metallic and non-metallic elements, such as copper, zinc, aluminum, nickel, etc. The raw materials are generally in solid form and need to go through a melting process to be transformed into liquid metal.
2. Melting: Place the raw materials into a crucible or other melting equipment and heat them above their melting point to completely melt and mix them. The melting temperature and time need to be precisely controlled according to the composition and requirements of the alloy to ensure that the resulting alloy is uniform and meets the specifications.
3. Casting: After melting, pour the molten metal into molds to cast. Casting is the process of injecting liquid metal into molds, allowing it to cool and solidify, and obtaining the desired shape and size. Casting methods mainly include sand casting, metal casting, die casting, etc.
4. Deburring: After casting, the surface of the metal parts needs to be deburred to remove burrs and particles. Deburring can be done through mechanical, chemical, or electrochemical methods. This step ensures the smoothness and purity of the metal part's surface.
5. Forging Shaping: In the forging shaping stage, the heated alloy material is pressed and shaped by forging machinery to obtain parts with the required shape and size.
6. Subsequent Treatment: This includes cooling, deburring, surface treatment, and inspection processes to ensure the quality and precision of the alloy components.
7. Heat Treatment: The forged alloy usually needs to undergo heat treatment to improve its microstructure and mechanical properties. The heat treatment process may include solution treatment, aging treatment, etc.
8. Cleaning and Inspection: Finally, the forgings are cleaned to remove surface oxides, burrs, etc., and undergo final inspection to ensure that the dimensions, shape, and performance of the forgings meet the requirements.
Each step requires precise control to ensure the quality of the final product. Different alloys may require specific process adjustments to accommodate their unique material characteristics.
2. Melting: Place the raw materials into a crucible or other melting equipment and heat them above their melting point to completely melt and mix them. The melting temperature and time need to be precisely controlled according to the composition and requirements of the alloy to ensure that the resulting alloy is uniform and meets the specifications.
3. Casting: After melting, pour the molten metal into molds to cast. Casting is the process of injecting liquid metal into molds, allowing it to cool and solidify, and obtaining the desired shape and size. Casting methods mainly include sand casting, metal casting, die casting, etc.
4. Deburring: After casting, the surface of the metal parts needs to be deburred to remove burrs and particles. Deburring can be done through mechanical, chemical, or electrochemical methods. This step ensures the smoothness and purity of the metal part's surface.
5. Forging Shaping: In the forging shaping stage, the heated alloy material is pressed and shaped by forging machinery to obtain parts with the required shape and size.
6. Subsequent Treatment: This includes cooling, deburring, surface treatment, and inspection processes to ensure the quality and precision of the alloy components.
7. Heat Treatment: The forged alloy usually needs to undergo heat treatment to improve its microstructure and mechanical properties. The heat treatment process may include solution treatment, aging treatment, etc.
8. Cleaning and Inspection: Finally, the forgings are cleaned to remove surface oxides, burrs, etc., and undergo final inspection to ensure that the dimensions, shape, and performance of the forgings meet the requirements.
Each step requires precise control to ensure the quality of the final product. Different alloys may require specific process adjustments to accommodate their unique material characteristics.