Inconel Steel

We manufacture Inconel Steel which is tested at every stage of its production. Our Inconel Steel is of the best quality and possesses excellent corrosion, temperature and acid resistance. We offer Inconel Steel in various forms such as wire, sheet, bar, plate, coil, etc., as per the requirements of the clients.

Applications

Components where exposure to sea water and high mechanical stresses are required
Oil and gas production where hydrogen sulfide and elementary sulfur exist at temperature in excess of 150C
Components exposed to flue gas or in flue gas desulfurization plants
Flare stacks on offshore oil platforms
Hydrocarbon processing from tar-sand and oil-shale recovery projects

Characteristics

Excellent mechanical properties at both extremely low and extremely high emperatures
Outstanding resistance to pitting, crevice corrosion and intercrystalline corrosion
Almost complete freedom from chloride induced stress corrosion cracking
High resistance to oxidation at elevated temperatures up to 105^oC
Good resistance to acids, such as nitric, phosphoric, sulfuric and hydrochloric, as well as to alkalis makes possible the construction of thin structural parts of high heat transfer

Technical Specifications

Form	Standard
Metal Type	UNS N06625
Bar	ASTM B446 AMS 5666 BS3076
Wire	AMS 5837
Sheet	ASTM B443 AMS 5599 BS3072
Plate	ASTM B443 AMS 5599 BS3072
Pipe	ASTMB444 ASTM B704 AMS 5581 BS3074 GEB50TF133
Tube	ASTM B444 ASTM B704 AMS 5581 BS3074 GEB50TF133
Fitting	ASTM B366 Din 17754
Forging	-
Weld Wire	-
Weld Electrode	-
NA 21	All forms
Din	2.4856

Chemical Requirements

	Ni	Fe	Cr	Si	Mo	Mn	C
Max		5.0	23.0	0.50	10.0	0.50	0.10
Min	58.0		20.0		8.0

Tensile Data

Mechanical Property Requirements
	Ultimate Tensile	Yield Strength (0.2% OS)	Elong. in 2 in. or 50mm or 4D, min., %	R/A	Hardness
Cold Worked/Annealed
Min	120 KSI	60 KSi	30
Max
Min
Max
Hot Worked/Annealed
Min	120 KSi	60 KSi	30
Max
Min
Max

Ratings
Nickel & cobalt base corrosion, temperature and wear-resistant alloys are classified as moderate to difficult when machining, however, it should be emphasized that these alloys can be machined using conventional production methods at satisfactory rates. During machining these alloys work harden rapidly, generate high heat during cutting, weld to the cutting tool surface and offer high resistance to metal removal because of their high shear strengths. The following are key points which should be considered during machining operations :

Capacity : Machine should be rigid and overpowered as much as possible.
Rigidity : Work piece and tool should be held rigid. Minimize tool overhang.
Tool Sharpness : Make sure tools are sharp at all times. Change to sharpened tools at regular intervals rather than out of necessity. A 0.015 inch wear land is considered a dull tool.Tools : Use positive rake angle tools for most machining operations. Negative rake angle tools can be considered for intermittent cuts and heavy stock removal. Carbide-tipped tools are suggested for most applications. High speed tools can be used, with lower production rates, and are often recommended for intermittent cuts.
Positive Cuts : Use heavy, constant, feeds to maintain positive cutting action. If feed slows and the tool dwells in the cut, work hardening occurs, tool life deteriorates and close tolerances are impossible.
Lubrication : Lubricants are desirable, soluble oils are recommended especially when using carbide tooling.

Recommended Tool Types and Machining Conditions

Operations	Carbide Tools
Roughing, with severe interruption	Turning or Facing C-2 and C-3 grade: Negative rake square insert, 45 degree SCEA1, 1/32 in. nose radius. Tool holder: 5 degree neg. back rake, 5 degree neg. side rake. Speed: 30-50 sfm, 0.004-0.008 in. feed, 0.150 in depth of cut. Dry2, oil3, or water-base coolant4.
Normal roughing	Turning or Facing C-2 or C-3 grade: Negative rate square insert, 45 degree SCEA, 1/32 in nose radius. Tool holder: 5 degree neg. back rake, 5 degree neg. side rake. Speed: 90 sfm depending on rigidity of set up, 0.010 in. feed, 0.150 in. depth of cut. Dry, oil, or water-base coolant.
Finishing	Turning or Facing C-2 or C-3 grade: Positive rake square insert, if possible, 45 degree SCEA, 1/32 in. nose radius. Tool holder: 5 degree pos. back rake, 5 degree pos. side rake. Speed: 95-110 sfm, 0.005-0.007 in. feed, 0.040 in. depth of cut. Dry or water-base coolant.
Rough Boring	C-2 or C-3 grade: If insert type boring bar, use standard positive rake tools with largest possible SCEA and 1/16 in. nose radius. If brazed tool bar, grind 0 degree back rake, 10 degree pos. side rake, 1/32 in. nose radius and largest possible SCEA. Speed: 70 sfm depending on the rigidity of setup, 0.005-0.008 in. feed, 1/8 in. depth of cut. Dry, oil or water-base coolant.
Finish Boring	C-2 or C-3 grade: Use standard positive rake tools on insert type bars. Grind brazed tools as for finish turning and facing except back rake may be best at 0 degrees. Speed: 95-110 sfm, 0.002-0.004 in feed. Water-base coolant.
Facing Milling	Carbide not generally successful, C- grade may work. Use positive axial and radial rake, 45 degree corner angle, 10 degree relief angle. Speed: 50-60 sfm. Feed: 0.005-0.008 in. Oil or waterbase coolants will reduce thermal shock damage of carbide cutter teeth.
End Milling	Not recommended , but C-2 grades may be successful on good setups. Use positive rake. Speed: 50-60 sfm. Feed: Same as high speed steel. Oil or water-base coolants will reduce thermal shock damage.
Drilling	C-2 grade not recommended, but tipped drills may be successful on rigid setup if no great depth. The web must thinned to reduce thrust. Use 135 degree included angle on point. Gun drill can be used. Speed: 50 sfm. Oil or water-base coolant. Coolant-feed carbide tipped drills may be economical in some setups.
Reaming	C-2 or C-3 grade: Tipped reamers recommended, solid carbide reamers require vary good setup. Tool geometry same as high speed steel. Speed: 50 sfm. Feed: Same as high speed steel.
Tapping	Not recommended, machine threads, or roll-form them.
Electrical Discharge Machining	The alloys can be easily cut using any conventional electrical discharge machining system (EDM) or wire (EDM).
Plasma Arc Cutting	Our alloys can be cut using any conventional plasma arc cutting system. The best arc quality is achieved using a mixture of argon and hydrogen gases. Nitrogen gas can be substituted for hydrogen gases, but the cut quality will deteriorate slightly. Shop air or any oxygen bearing gases should be avoided when plasma cutting these alloys.

Notes

SCEA - Side cutting edge angle or lead angle of the tool.
At any point where dry cutting is recommended, an air jet directed on the tool may provide substantial tool life increases. A water-base coolant mist may also be effective.
Oil coolant should be premium quality, sulfochlorinated oil with extreme pressure additives. A viscosity at 100 degrees F from 50 to 125 SSU.
Water-base coolant should be premium quality, sulfochlorinated water soluble oil or chemical emulsion with extreme pressure additives. Dilute with water to make 15:1 mix. Water-base coolant may cause chipping and rapid failure of carbide tools in interrupted cuts.
M-40 series High Speed Steels include M-41 , M-42, M-43, M-44, M-45 and M-46 at the time of writing. Others may be added and should be equally suitable.
Oil coolant should be a premium quality, sulfochlorinated oil with extreme pressure additives. A viscosity at 100 degree F from 50 to 125 SSU.
Water-base coolant should be premium quality, sulfochlorinated water soluble oil or chemical emulsion with extreme pressure additives. Dilute with water to make 15:1 mix.