Classifications

• • C—CHEMISTRY; METALLURGY
  • C22—METALLURGY; FERROUS OR NON-FERROUS ALLOYS; TREATMENT OF ALLOYS OR NON-FERROUS METALS
  • C22C—ALLOYS
  • C22C19/00—Alloys based on nickel or cobalt
  • C22C19/07—Alloys based on nickel or cobalt based on cobalt

Definitions

• This invention is directed to alloys for use in industrial applications where resistance to wear and corrosion are required. Examples of such applications include build up material to be applied to components such as valves by plasma transfer arc welding. Other examples include cast turbocharger parts and welding on areas subject to wear on gas turbine blades in jet engines. Certain alloys in commercial use for wear and corrosion applications are distributed by Deloro Stellite Company, Inc. under the trade designation Tribaloy. Alloys within the Tribaloy alloy family are disclosed in U.S. Pat. Nos. 3,410,732, 3,795,430, and 3,839,024. Two specific alloys in the Tribaloy family are distributed under the trade designations T-400 and T-800. The nominal composition of T- 400 is Cr-8.5%, Mo-28%, Si-2.6%, and balance Co. The nominal composition of T-800 is Cr-17%, Mo-28%, Si-3.25%, and balance Co.
• an alloy for wear and corrosion applications which has enhanced oxidation resistance
• an alloy for wear and corrosion applications which has enhanced ductility
• an alloy for wear and corrosion applications which has enhanced impact resistance
• an alloy for wear and corrosion applications which has enhanced corrosion resistance in both reducing and oxidizing acids.
• the invention is directed to a Co- based alloy comprising 13-16 wt% Cr, 20-30 wt% Mo, 2.2-3.2 wt% Si, and balance Co, with a Cr:Si ratio of between about 4.5 and about 7.5, a Mo: Si ratio of between about 9 and about 15, wear resistance, and corrosion resistance in both oxidizing and reducing acids.
• Fig. 1 is a photomicrograph illustrating the microstructure of the invention.
• Fig. 2 is graphical presentation of thermal gravitational analysis data comparing the invention to prior art.
• Fig. 3 is photograph comparing a cast surface of the invention to a cast surface of a prior art alloy.
• Fig. 4 is a photograph comparing the alloy of the invention deposited by plasma transfer arc welding to a prior art alloy deposited by plasma transfer arc welding.
• Fig. 5 is a graphical presentation comparing wear data of the alloy of the invention to wear data of a prior art alloy.
• Chromium is provided in the alloys of the invention to enhance corrosion resistance.
• the Cr content is preferably in the range of 13% to 16%. All percentages herein are by weight.
• One preferred embodiment employs about 14% Cr.
• Molybdenum is provided in the alloys of the invention to impart wear resistance.
• the Mo content is preferably in the range of 20% to 30%.
• One preferred embodiment employs about 26% Mo.
• Silicon is provided in the alloys of the invention to impart wear resistance in combination with Mo.
• the Si content is preferably in the range of 2.2% to 3.2%.
• One preferred embodiment employs about 2.6% Si.
• the Cr and Si contents are selected such that the ratio of Cr:Si in the alloy is above about 4.5. In one preferred embodiment it is between 4.5 and 7.5. In one especially preferred embodiment this ratio is about 5.4. It has been discovered that this ratio is important to achieving enhanced oxidation resistance.
• the Mo and Si contents are selected such that the ratio of Mo: Si in the alloy is above about 9. In one preferred embodiment it is between 9 and 15. In one especially preferred embodiment this ratio is about 10.8. It has been discovered that this ratio is important to achieving enhanced ductility.
• Cobalt is provided in the alloys as the alloy matrix. Cobalt is selected because it can be alloyed with the elements Cr, Mo, and Si and tends to form a tough matrix. Cobalt is selected over Ni, Fe, combinations thereof, and combinations thereof with Co because it has been discovered that a matrix which consists essentially of Co is tougher and less brittle than a matrix which contains some Ni and/or Fe.
• the Co content is preferably in the range of 48 to 62%.
• One preferred embodiment employs about 54% Co.
• Certain trace elements are present in the alloys of the invention due to the presence of such elements in scrap and otherwise due to the manufacturing process. These elements are not intentionally added, but are tolerable. Carbon may be present up to about 1%. Boron may be present up to about 1%. Nickel may be present up to about 3%. Iron may be present up to about 3%. While the combination of these element tolerances is up to 8%, in a preferred embodiment the total trace element content is no more than 2%.
• the alloy is Mn-free, Cu-free, and free of all alloying elements having a material effect on metallurgical properties other than Cr, Mo, and Si in the Co matrix.
• the microstructure of the invention typically consists of 40-55% by volume Laves phase, depending on the chemical composition and cooling rate.
• the microstructure of an undiluted weld deposit made by plasma transferred arc welding deposition is presented in Fig. 1.
• the Cr/Si ratio is between about 1.04 and about 1.36 in the Laves phase and between about 9.6 and 10.8 in the matrix.
• the Cr/Si ratio in alloy T-400 is between about 0.73 and about 0.86 in the Laves phase and between about 5.95 and about
• the alloys of the invention have improved physical properties which render them especially suitable for certain wear and corrosion applications.
• the oxidation resistance is such that weight % gain measured by thermal gravitational analysis after 200 minutes at 760 C is less than 0.5%.
• the alloys show substantially no surface defects upon casting. Plasma transfer arc welding deposits are substantially smooth.
• the alloys demonstrate corrosion resistance in reducing acid H 2 S0 4 characterized by less than about 50 mils/year (1.3 mm/year) thickness loss when tested according to ASTM specification G31-72 in a 10% solution at 102 C.
• the alloys demonstrate corrosion resistance in oxidizing acid HN0 3 characterized by less than about 300 mils/year (7.6 mm/year) thickness loss when tested according to ASTM specification G31-72 in a 65% solution at 66 C. In another aspect the alloys demonstrate corrosion resistance in reducing acid HC1 characterized by less than about 4 mils/year (0.1 mm/year) thickness loss when tested according to ASTM specification G31-72 in a 5% solution at 66 C.
• the alloys demonstrate impact strength of at least about 2.0 Joules when evaluated by an un-notched Charpy impact test according to ASTM specification E23-96. And in one aspect the alloys have excellent high-temperature metal-to-metal wear properties. These are demonstrated in that the alloys have a volume loss of less than about 0.06 cubic millimeters when tested according to the well known Cameron-Plint test of ASTM G133- 95 at 482 C with alloy cylinders in metal-to-metal wear contact with nitrided 310 stainless steel flat plates. And the 310 stainless volume loss is on the order of 0.4 cubic millimeters or less.
• the alloys of the invention are provided in the form of powder for deposition by plasma transfer arc welding deposition, laser cladding, plasma spraying, and high velocity oxyfuel spraying.
• the alloys can also be provided in the form of welding rods, wires, and electrodes for deposition by gas tungsten arc welding, shielded metal arc welding, or gas metal arc welding.
• the alloys are also provided in the form of castings and powder metallurgical components . Certain aspects of the invention are further illustrated in the following examples.
• EXAMPLE 1 The oxidation resistance of an alloy of the invention (T-400C) was evaluated in comparison to the oxidation resistance of prior art alloys T-400 and T-800.
• the compositions of the respective alloys were as follows: Cr Mo Si Cr:Si Mo: Si
• TGA Thermal gravitational analysis
• EXAMPLE 2 An un-notched Charpy impact test according to ASTM specification E23-96 was conducted on each of the alloys of Example 1.
• the impact strength of the T-800 alloy was determined to be 1.36 Joules.
• the impact strength of the T- 400 alloy was determined to be 2.72 Joules.
• the alloy of the invention demonstrates impact strength of at least about 2.0 Joules. In particular, the impact strength of the T-
• EXAMPLE 3 One-inch diameter bars were cast from the T-400 and T- 400C alloys of Example 1 to evaluate their casting surface finish and suitability for precision casting. Photographs thereof are presented in Fig. 3. These photographs illustrate the absence of oxidation surface defects on the T-400C bar. The absence of oxidation surface defects is critical in precision casting applications because it minimizes the amount of machining required and raises production yields, as less material must be removed to yield suitable surface characteristics.
• T-400C The main contribution in the improved flowability of the T-400C is its high Cr content. Cr promotes formation of a thin, impervious oxide film, which prevents further oxidation. A molten puddle with a thin oxide film generally has better flowability than otherwise.
• Alloys T-400C and T-400 of Example 1 were tested under the procedures of ASTM G31-72 for resistance to corrosion in reducing acids such as hydrochloric acid and dilute sulfuric acid, as well as in oxidizing acids such as nitric acid. The results were as follows:
• the alloys demonstrate corrosion resistance in reducing acid H 2 S0 4 characterized by less than about 50 mils/year (1.3 mm/year) thickness loss when tested according to ASTM specification G31-72 in a 10% solution at 102 C.
• the alloys also demonstrate corrosion resistance in oxidizing acid HNO 3 characterized by less than about 300 mils/year (7.6 mm/year) thickness loss when tested according to ASTM specification G31-72 in a 65% solution at 66 C.
• the alloys demonstrate corrosion resistance in reducing acid HCl characterized by less than about 4 mils/year (0.1 mm/year) thickness loss when tested according to ASTM specification G31-72 in a 5% solution at 66 C.

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• Chemical & Material Sciences (AREA)
• Engineering & Computer Science (AREA)
• Materials Engineering (AREA)
• Mechanical Engineering (AREA)
• Metallurgy (AREA)
• Organic Chemistry (AREA)
• Coating By Spraying Or Casting (AREA)
• Injection Moulding Of Plastics Or The Like (AREA)
• Valve-Gear Or Valve Arrangements (AREA)
• Electroplating Methods And Accessories (AREA)
• Polishing Bodies And Polishing Tools (AREA)

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• 2003
  • 2003-06-12 US US10/250,205 patent/US6852176B2/en not_active Expired - Lifetime
  • 2003-06-16 CA CA2491754A patent/CA2491754C/en not_active Expired - Fee Related
  • 2003-06-16 WO PCT/US2003/019128 patent/WO2004009860A1/en not_active Ceased
  • 2003-06-16 EP EP03765448A patent/EP1521859B1/en not_active Expired - Lifetime
  • 2003-06-16 DE DE60318579T patent/DE60318579T2/de not_active Expired - Lifetime
  • 2003-06-16 AT AT03765448T patent/ATE383449T1/de not_active IP Right Cessation
  • 2003-06-16 JP JP2005505505A patent/JP4463763B2/ja not_active Expired - Lifetime

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