Allgemein
Property | Temperature | Value |
---|---|---|
Dichte | 23.0 °C | 8.6 g/cm³ Show Supplier Material materials with Dichte of 8.6 g/cm³ |
Mechanisch
Property | Temperature | Value | Comment |
---|---|---|---|
Charpy impact energy, V-notch | -196.0 °C | 140 J Show Supplier Material materials with Charpy impact energy, V-notch of 140 J | |
20.0 °C | 185 J Show Supplier Material materials with Charpy impact energy, V-notch of 185 J | ||
Dehnung | 23.0 °C | 40 % Show Supplier Material materials with Dehnung of 40 % | for 20-500°C |
Elastizitätsmodul | 100.0 °C | 200 GPa Show Supplier Material materials with Elastizitätsmodul of 200 GPa | |
200.0 °C | 194 GPa Show Supplier Material materials with Elastizitätsmodul of 194 GPa | ||
300.0 °C | 188 GPa Show Supplier Material materials with Elastizitätsmodul of 188 GPa | ||
400.0 °C | 182 GPa Show Supplier Material materials with Elastizitätsmodul of 182 GPa | ||
500.0 °C | 177 GPa Show Supplier Material materials with Elastizitätsmodul of 177 GPa | ||
600.0 °C | 169 GPa Show Supplier Material materials with Elastizitätsmodul of 169 GPa | ||
Streckgrenze Rp 0,2 | 20.0 °C | 360 MPa Show Supplier Material materials with Streckgrenze Rp 0,2 of 360 MPa | Typical mechanical properties |
400.0 °C | 200 MPa Show Supplier Material materials with Streckgrenze Rp 0,2 of 200 MPa | Typical mechanical properties | |
500.0 °C | 180 MPa Show Supplier Material materials with Streckgrenze Rp 0,2 of 180 MPa | Typical mechanical properties | |
Streckgrenze Rp 1,0 | 20.0 °C | 400 MPa Show Supplier Material materials with Streckgrenze Rp 1,0 of 400 MPa | Typical mechanical properties |
400.0 °C | 240 MPa Show Supplier Material materials with Streckgrenze Rp 1,0 of 240 MPa | Typical mechanical properties | |
500.0 °C | 220 MPa Show Supplier Material materials with Streckgrenze Rp 1,0 of 220 MPa | Typical mechanical properties | |
Zugfestigkeit | 20.0 °C | 760 MPa Show Supplier Material materials with Zugfestigkeit of 760 MPa | Typical mechanical properties |
400.0 °C | 560 MPa Show Supplier Material materials with Zugfestigkeit of 560 MPa | Typical mechanical properties | |
500.0 °C | 530 MPa Show Supplier Material materials with Zugfestigkeit of 530 MPa | Typical mechanical properties | |
Thermisch
Property | Temperature | Value |
---|---|---|
Koeffizient der thermischen Ausdehnung | 50.0 °C | 1.14E-5 1/K Show Supplier Material materials with Koeffizient der thermischen Ausdehnung of 1.14E-5 1/K |
100.0 °C | 1.16E-5 1/K Show Supplier Material materials with Koeffizient der thermischen Ausdehnung of 1.16E-5 1/K | |
200.0 °C | 1.22E-5 1/K Show Supplier Material materials with Koeffizient der thermischen Ausdehnung of 1.22E-5 1/K | |
300.0 °C | 1.25E-5 1/K Show Supplier Material materials with Koeffizient der thermischen Ausdehnung of 1.25E-5 1/K | |
400.0 °C | 1.29E-5 1/K Show Supplier Material materials with Koeffizient der thermischen Ausdehnung of 1.29E-5 1/K | |
500.0 °C | 1.32E-5 1/K Show Supplier Material materials with Koeffizient der thermischen Ausdehnung of 1.32E-5 1/K | |
600.0 °C | 1.38E-5 1/K Show Supplier Material materials with Koeffizient der thermischen Ausdehnung of 1.38E-5 1/K | |
Schmelzpunkt | 1330 - 1370 °C Show Supplier Material materials with Schmelzpunkt of 1330 - 1370 °C | |
Spezifische Wärmekapazität | 50.0 °C | 406 J/(kg·K) Show Supplier Material materials with Spezifische Wärmekapazität of 406 J/(kg·K) |
100.0 °C | 436 J/(kg·K) Show Supplier Material materials with Spezifische Wärmekapazität of 436 J/(kg·K) | |
200.0 °C | 457 J/(kg·K) Show Supplier Material materials with Spezifische Wärmekapazität of 457 J/(kg·K) | |
300.0 °C | 471 J/(kg·K) Show Supplier Material materials with Spezifische Wärmekapazität of 471 J/(kg·K) | |
400.0 °C | 482 J/(kg·K) Show Supplier Material materials with Spezifische Wärmekapazität of 482 J/(kg·K) | |
500.0 °C | 487 J/(kg·K) Show Supplier Material materials with Spezifische Wärmekapazität of 487 J/(kg·K) | |
600.0 °C | 546 J/(kg·K) Show Supplier Material materials with Spezifische Wärmekapazität of 546 J/(kg·K) | |
Wärmeleitfähigkeit | 50.0 °C | 9.8 W/(m·K) Show Supplier Material materials with Wärmeleitfähigkeit of 9.8 W/(m·K) |
100.0 °C | 11.1 W/(m·K) Show Supplier Material materials with Wärmeleitfähigkeit of 11.1 W/(m·K) | |
200.0 °C | 13 W/(m·K) Show Supplier Material materials with Wärmeleitfähigkeit of 13 W/(m·K) | |
300.0 °C | 15.5 W/(m·K) Show Supplier Material materials with Wärmeleitfähigkeit of 15.5 W/(m·K) | |
400.0 °C | 16.9 W/(m·K) Show Supplier Material materials with Wärmeleitfähigkeit of 16.9 W/(m·K) | |
500.0 °C | 18.5 W/(m·K) Show Supplier Material materials with Wärmeleitfähigkeit of 18.5 W/(m·K) | |
600.0 °C | 21.8 W/(m·K) Show Supplier Material materials with Wärmeleitfähigkeit of 21.8 W/(m·K) | |
Elektrisch
Property | Temperature | Value |
---|---|---|
spezifischer Widerstand | 50.0 °C | 1.24E-6 Ω·m Show Supplier Material materials with spezifischer Widerstand of 1.24E-6 Ω·m |
100.0 °C | 1.25E-6 Ω·m Show Supplier Material materials with spezifischer Widerstand of 1.25E-6 Ω·m | |
200.0 °C | 1.25E-6 Ω·m Show Supplier Material materials with spezifischer Widerstand of 1.25E-6 Ω·m | |
300.0 °C | 1.26E-6 Ω·m Show Supplier Material materials with spezifischer Widerstand of 1.26E-6 Ω·m | |
400.0 °C | 1.27E-6 Ω·m Show Supplier Material materials with spezifischer Widerstand of 1.27E-6 Ω·m | |
500.0 °C | 1.29E-6 Ω·m Show Supplier Material materials with spezifischer Widerstand of 1.29E-6 Ω·m | |
600.0 °C | 1.3E-6 Ω·m Show Supplier Material materials with spezifischer Widerstand of 1.3E-6 Ω·m | |
Magnetisch
Property | Value |
---|---|
Relative magnetische Permeabilität | The material is non-magnetic. |
Chemical properties
Property | Value | Comment | |
---|---|---|---|
Aluminium | 0.4 % Show Supplier Material materials with Aluminium of 0.4 % | max. | |
Chrom | 20 - 23 % Show Supplier Material materials with Chrom of 20 - 23 % | ||
Eisen | 1.5 % Show Supplier Material materials with Eisen of 1.5 % | max. | |
Kobalt | 0.3 % Show Supplier Material materials with Kobalt of 0.3 % | max. | |
Kohlenstoff | 0.01 % Show Supplier Material materials with Kohlenstoff of 0.01 % | max. | |
Kupfer | 0.5 % Show Supplier Material materials with Kupfer of 0.5 % | max. | |
Mangan | 0.5 % Show Supplier Material materials with Mangan of 0.5 % | max. | |
Molybdän | 18.5 - 21 % Show Supplier Material materials with Molybdän of 18.5 - 21 % | ||
Nickel | Balance | ||
Phosphor | 0.02 % Show Supplier Material materials with Phosphor of 0.02 % | max. | |
Schwefel | 0.01 % Show Supplier Material materials with Schwefel of 0.01 % | max. | |
Silizium | 0.1 % Show Supplier Material materials with Silizium of 0.1 % | max. | |
Stickstoff | 0.02 - 0.15 % Show Supplier Material materials with Stickstoff of 0.02 - 0.15 % | ||
Wolfram | 0.3 % Show Supplier Material materials with Wolfram of 0.3 % | max. |
Technological properties
Property | ||
---|---|---|
Application areas | VDM® Alloy 2120 MoN has a wide range of applications in the chemical, petrochemical and pharmaceutical industries as well as in energy production and environmental technologies. Typical applications include: components in flue gas desulfurization and waste incineration plants as e.g. scrubbers, raw gas inlets and heat recovery systems, handling of mineral acids like sulfuric acid, hydrochloric acid and acid mixtures even when contaminated with chlorides, acetic acid and acetic anhydride production, production and processing of halogen containing chemicals, equipment for organic synthesizes and fine and specialty chemicals production, components exposed to seawater and to highly concentrated brines, sour gas and geothermal services. | |
Cold Forming | For cold forming the material should be in the annealed condition. VDM® Alloy 2120 MoN has a higher work-hardening rather than austenitic stainless steels. This should be taken into account when selecting forming equipment. Interstage annealing may be necessary with high degrees of cold forming. After cold working with more than 15% deformation solution annealing is required before use. | |
Corrosion properties | VDM® Alloy 2120 MoN can be used in many chemical processes with both oxidizing as well as reducing media. The high chromium and molybdenum concentrations make the alloy very resistant to chloride attacks. VDM® Alloy 2120 MoN has a PREN no. of 86 (PREN = %Cr+3.3Mo+30N). In general, the material is superior to other C-alloys in terms of crevice and pitting corrosion. The material possesses outstanding corrosion resistance in reducing acids, such as hydrochloric acid and sulfuric acid. VDM® Alloy 2120 MoN exhibits a good resistance to intercrystalline corrosion according to ASTM G28 method A. Optimum corrosion resistance is only ensured if the material is used in a clean and metallic bright condition. | |
General machinability | Machining of VDM® Alloy 2120 should take place in an annealed condition. Because of the considerably elevated tendency toward work hardening in comparison with low-alloy austenitic stainless steels, a low cutting speed and a feed level that is not too high should be selected and the cutting tool should be engaged at all times. An adequate chip depth is important in order to cut below the previously formed strain-hardened zone. Optimum heat dissipation through the use of large quantities of suitable, preferably aqueous, lubricants has considerable influence on a stable machining process. | |
Heat Treatment | Solution annealing should take place at temperatures of between 1,150 and 1,185°C (2,102–2,156°F) to achieve optimal properties. The retention time during annealing depends on the semi-finished product thickness. The retention time commences with material temperature equalization; longer times are generally considerably less critical than retention times that are too short. For maximum corrosion resistance, the workpieces must be quickly cooled from the annealing temperature of at least 1,100 to 500°C (2,012 to 932°F) with a cooling rate of >150°C/min (302°F). The material must be placed in a furnace that has been heated up to the maximum annealing temperature before any heat treatment. The cleanliness requirements listed under "Heating" must be observed. For strip product form, the heat treatment can be performed in a continuous furnace at a speed and temperature that is adapted to the strip thickness. | |
Hot forming | VDM® Alloy 2120 can be hot-formed at a temperature range of between 1,200 and 1,050 °C (2,190 and 1,922 °F) with subsequent rapid cooling down in water or in air. For heating up, workpieces should be placed in a furnace that has been heated up to the maximum hot-forming temperature (solution annealing temperature). The workpieces should be retained in the furnace for around 60 minutes per 100 mm of thickness once the furnace has reached its temperature again. After this, they should be removed from the furnace immediately and formed within the temperature range stated above, with reheating necessary once the temperature reaches 1,050°C (1,922°F). Solution annealing after hot forming is recommended for the achievement of optimal properties and maximum corrosion resistance. | |
Other | VDM® Alloy 2120 MoN has a face-centered cubic structure. In the temperature range from 600 to 1140°C, intermetallic phases may form in the event of longer exposure times or too slow cooling down. In addition, carbides can precipitate on the grain boundaries, which reduce resistance against intercrystalline corrosion. | |
Welding | Care should be taken that the work is performed with a deliberately chosen, low heat input. The stringer bead technique is recommended. The interpass temperature should not exceed 150°C (302°F). The welding parameters should be monitored as a matter of principle. |