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Categories | Nickel Alloy Wires |
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Brand Name: | DINGSCO |
Model Number: | According to customers requirements |
Certification: | ISO 9001:2015,PED 2014/68/EU,API 6A,API-20B,TSG,NORSOK |
Place of Origin: | China |
MOQ: | Negotiable |
Price: | Negotiable |
Payment Terms: | T/T |
Supply Ability: | Negotiable |
Delivery Time: | (Sample Order) 7 days |
Packaging Details: | According to Customers' Requests |
Product Name: | Nickel Alloy Wires |
Grade: | Inconel 600 |
UNS: | N06600 |
Density: | 8.47g/cm³ |
Electric Resistivity: | 1030nΩ.m |
Thermal Condctivity: | 14.9W/m.K |
Elastic Modulus: | 206Gpa |
Standard: | ASTM B163/B166/B167/B168/B366/B516; ASME SB-163/166/168 |
Company Info. |
Hunan Dinghan New Material Technology Co., LTD |
Verified Supplier |
View Contact Details |
Product List |
Nickel Alloy Wires Inconel 600 UNS N06600 Valves Pumps Electronic Instrument Parts
Welding wires are slim metallic wires that are usually coiled up in spools. These spools are loaded on a wire feeder and the welding wire is continuously fed through a welding gun into the molten weld pool. As a result, arc welding processes that use a welding wire tend to offer higher deposition rates and faster travel speeds, as compared to TIG and Stick welding where the welder must manually feed the filler metal into the weld puddle.
Alloy 600 (UNS N06600) is a nickel-chromium alloy designed for use fromcryogenic to
elevated temperatures in the range of 2000F(1093 °C) qood oxidation
resistance at higher temperatures, with good resistance in
carburizing andchloride containing environments. The high nickel
contentof the aloy enables it to retain considerable resistance
under reducing conditions and makes it resistant to corrosion by a
number of organic and inorganic compounds.The nickel content gives
it excellent
resistance to chloride-ion stress-corrosion cracking andalso
provides excellent resistance to alkaline solutions. Its chromium
content gives the alloy resistance to sulfurcompounds and various
oxidizing environments. The chromium content of the alloy makes it
superior to commercially pure nicke under oxidizing
conditions.rstrong oxidizing solutions, like hot concentrated
nitricacid,600 has poor resistance. Alloy 600 is
relativelyunattacked by the majority of neutral and alkaline
saltsolutions and is used in some caustic environments.
Applications
Thermocouple sheaths / Ethylene dichloride (EDC) cracking tubes /
Conversion of uranium dioxide to tetrafluoride in contact with
hydrofluoric acid / Production of caustic alkalis particularly in
the presence of sulfur compounds / Reactor vessels and heat
exchanger tubing used in the production of vinyl chloride / Process
equipment used in the production of chlorinated and fluorinated
hydrocarbons / Furnace retort seals, fans, and fixtures/Roller
hearths and radiant tubes, especially in carbonnitriding processes
/ Heat treating muffles and retorts / Vacuum furnace
fixtures.Chlorination equipment to 1000°F Titanium dioxide plants,
Machining:
Nickel based alloys can be difficult tomachinine.However, it should
be emphasized that thesealloys can be machined using conventional
productionmethods at satisfactory rates. These alloys harden
rapidlygenerate high heat during cutting, weld to the cuttingtool
surface and offer high resistance to metal removabecause of their
high shear strengths. The following arekey points which should be
considered during machining operations: capacity/tools/positive
cut/lubrication.
Chemical Composition:
Element | Ni+Co | Cr | Fe | C | Mn | S | Si | Cu |
Minimum(%) | 72 | 14 | 6 | - | - | - | - | - |
Max(%) | - | 17 | 10 | 0.15 | 1 | 0.015 | 0.5 | 0.5 |
Thermal Properties:
Temperature | Coefficient of Expansiona | Electrical Resistivity | Thermal Conductivity | Specific Heat |
°F | 10-6 in/in•°F | ohm•circ•mil/ft | Btu•in/ft2•h•°F | Btu/lb•°F |
-250 | 6.0 | - | 86 | 0.073 |
-200 | 6.3 | - | 89 | 0.079 |
-100 | 6.7 | - | 93 | 0.090 |
70 | 5.8 | 620 | 103 | 0.106 |
200 | 7.4 | 625 | 109 | 0.111 |
400 | 7.7 | 634 | 121 | 0.116 |
600 | 7.9 | 644 | 133 | 0.121 |
800 | 8.1 | 644 | 145 | 0.126 |
1000 | 8.4 | 680 | 158 | 0.132 |
1200 | 8.6 | 680 | 172 | 0.140 |
1400 | 8.9 | 680 | 186 | 0.145 |
1600 | 9.1 | 686 | 200 | 0.149 |
1800 | 9.3 | 698 | - | - |
2000 | - | 704 | - | - |
°C | μm/m•°C | μΩ•m | W/m•°C | J/kg•°C |
-150 | 10.9 | - | 12.5 | 310 |
-100 | 11.7 | - | 13.1 | 352 |
-50 | 12.3 | - | 13.6 | 394 |
20 | 10.4 | 1.03 | 14.9 | 444 |
100 | 13.3 | 1.04 | 15.9 | 444 |
200 | 13.8 | 1.05 | 17.3 | 486 |
300 | 14.2 | 1.07 | 19.0 | 502 |
400 | 14.5 | 1.09 | 20.5 | 519 |
500 | 14.9 | 1.12 | 22.1 | 536 |
600 | 15.3 | 1.13 | 22.1 | 578 |
700 | 15.8 | 1.13 | 25.7 | 595 |
800 | 16.1 | 1.13 | 27.5 | 611 |
900 | 16.4 | 1.15 | - | 628 |
Processing Flow Chart: