Name Classification Description Data
Sheet
MSDS
Executive 308L ER308/308L Low carbon in this filler metal reduces the possibility of intergranular carbide precipitation. This increases the resistance to intergranular corrosion without the use of stabilizers such as niobium or titanium. Strength of this low-carbon alloy, however, is less than that of the niobium-stabilized alloys or Type 308H at elevated temperatures. Executive 308L Data Sheet Executive 308L MSDS
Executive 308H ER308H Carbon content in the range of 0.04-0.08% provides higher strength at elevated temperatures. This filler metal is used for welding 304H base metal. Executive 308H Data Sheet Executive 308H MSDS
Executive 308LSi ER308LSi This classification is the same as ER308L, except for the higher silicon content. This improves the usability of the filler metal in the gas metal arc welding process. If the dilution by the base metal produces a low ferrite or fully austenitic weld, the crack sensitivity of the weld is somewhat higher than that of a lower silicon content weld metal. Executive 308LSi Data Sheet Executive 308LSi MSDS
Executive 309L ER309/309L Low carbon in this filler metal reduces the possibility of intergranular carbide precipitation. This increases the resistance to intergranular corrosion without the use of stabilizers such as niobium or titanium. Strength of this low-carbon alloy, however, is less than that of the niobium-stabilized alloys or Type 309 at elevated temperatures. Executive 309L Data Sheet Executive 309L MSDS
Executive 309LSi ER309LSi This classification is the same as ER309L, except for the higher silicon content. This improves the usability of the filler metal in the gas metal arc welding process. If the dilution by the base metal produces a low ferrite or fully austenitic weld, the crack sensitivity of the weld is somewhat higher than that of a lower silicon content weld metal. Executive 309LSi Data Sheet Executive 309LSi MSDS
Executive 309LMo Similar to ~ER309LMo The primary application for this filler metal is surfacing of base metals to improve their corrosion resistance. The ER309Mo is used to achieve a single-layer overlay with a chemical composition similar to that of a 316 stainless steel. It is also used for the first layer of multilayer overlays with filler metals such as ER316 or ER317 stainless steels. Without the first layer of 309LMo, elements such as chromium and molybdenum might be reduced to unacceptable levels in successive layers by dilution from the base metal. Executive 309LMo Data Sheet Executive 309LMo MSDS
Executive 310 ER310 Filler metal of this classification is most often used to weld base metals of similar composition. Executive 310 Data Sheet Executive 310 MSDS
Executive 312 ER312 Filler metal of this classification was originally designed to weld cast alloys of similar composition. It also has been found to be valuable in welding dissimilar metals such as carbon steel to stainless steel, particularly those grades high in nickel. This alloy gives a two-phase weld deposit with substantial percentages of ferrite in an austenite matrix. Even with considerable dilution by austenite-forming elements such as nickel, the microstructure remains two-phase and thus highly resistant to weld metal cracks and fissures. Executive 312 Data Sheet Executive 312 MSDS
Executive 316L ER316/316L Low carbon in this filler metal reduces the possibility of intergranular carbide precipitation. This increases the resistance to intergranular corrosion without the use of stabilizers such as niobium or titanium. Strength of this low-carbon alloy, however, is less than that of the niobium-stabilized alloys or Type 316H at elevated temperatures. Executive 316L Data Sheet Executive 316L MSDS
Executive 316LSi ER316LSi This classification is the same as ER316L, except for the higher silicon content. This improves the usability of the filler metal in the gas metal arc welding process. If the dilution by the base metal produces a low ferrite or fully austenitic weld, the crack sensitivity of the weld is somewhat higher than that of a lower silicon content weld metal. Executive 316LSi Data Sheet Executive 316LSi MSDS
Executive 317L ER317L Used for welding alloys of similar composition. ER317 filler metal is utilized in severely corrosive environments where crevice and pitting corrosion are of concern. Executive 317L Data Sheet Executive 317L MSDS
Executive 320 ER320 Filler metal of this classification is primarily used to weld base metals of similar composition for applications where resistance to severe corrosion involving a wide range of chemicals, including sulfuric and sulfurous acids and their salts, is required. This filler metal can be used to weld both castings and wrought alloys of similar composition without post weld heat treatment. Executive 320 Data Sheet Executive 320 MSDS
Executive 320LR ER320LR This classification has the same basic composition as ER320; however, the elements C, Si, P, and S are specified at lower maximum levels and the Nb and Mn are controlled at narrower ranges. These changes reduce the weld metal hot cracking and fissuring (while maintaining the corrosion resistance) frequently encountered in fully austenitic stainless steel weld metals. Consequently, welding practices typically used for austenitic stainless steel weld metals containing ferrite can be used in bare filler metal welding processes such as gas tungsten arc and gas metal arc. Executive 320LR Data Sheet Executive 320LR MSDS
Executive 330 ER330 Filler metal of this type is commonly used where heat and scale resisting properties above 1800°F (980°C) are required, except in high sulfur environments, as these environments may adversely affect elevated temperature performance. Repairs of defects in the alloy castings and the welding of castings and wrought alloys of similar composition are the most common applications. Executive 330 Data Sheet Executive 330 MSDS
Executive 347 ER347 Usually used for welding chromium-nickel stainless steel base metals of similar composition stabilized with either Nb or Ti. Although Nb is the stabilizing element usually specified in Type 347 alloys, it should be recognized that tantalum (Ta) is also present. Ta and Nb are almost equally effective in stabilizing carbon and in providing high-temperature strength. If dilution by the base metal produces a low ferrite or fully austenitic weld metal, the crack sensitivity of the weld may increase substantially Executive 347 Data Sheet Executive 347 MSDS
Exocor 385 (904L) ER385 Used primarily for welding materials for the handling of sulfuric acid and many chloride containing media. ER385 filler metal also may be used to join Type 317L material where improved corrosion resistance in specific media is needed. The elements C, S, P, and Si are specified at lower maximum levels to minimize weld metal hot cracking and fissuring (while maintaining corrosion resistance) frequently encountered in fully austenitic weld metals. Exocor 385 (904L) Data Sheet Exocor 385 (904L) MSDS
Executive 409Cb ER409Nb The Columbium (aka Niobium) addition in ER409Cb forms carbides to improve corrosion resistance, increase strength at high temperature, and promote the ferritic microstructure. ER409Cb filler metals may be used to join matching or dissimilar base metals. The greatest usage is for applications where thin stock is fabricated into exhaust system components. The copper coating technology creates a smooth and uniform copper layer on the wire surface that remarkably improves the weldability of the wire. Executive 409Cb Data Sheet Executive 409Cb MSDS
Executive 410 ER410 This 12 Cr alloy (wt.-%) is an air-hardening steel. Preheat and postweld heat treatments are required to achieve welds of adequate ductility for many engineering purposes. The most common application of filler metal of this type is for welding alloys of similar composition. It is also used for deposition of overlays on carbon steels to resist corrosion, erosion, or abrasion. Executive 410 Data Sheet Executive 410 MSDS
Executive 410NiMo ER410NiMo Filler metal of this classification is primarily designed for welding ASTM CA6NM castings or similar material, as well as light-gauge 410, 410S and 405 base metals. ER410NiMo is modified to contain less chromium and more nickel to eliminate ferrite in the microstructure as it has a deleterious effect on mechanical properties. Final postweld heat treatment should not exceed 1150°F (620°C) as higher temperatures may result in re-hardening due to untempered martensite in the microstructure after cooling to room temperature. Executive 410NiMo Data Sheet Executive 410NiMo MSDS
Exocor 430 ER430 The composition is balanced by providing sufficient chromium to give adequate corrosion resistance for the usual applications, and yet retain sufficient ductility in the heat treated condition. (Excessive chromium will result in lower ductility.) Welding with filler metal of the ER430 classification usually requires preheating and postweld heat treatment. Exocor 430 Data Sheet Exocor 430 MSDS
Executive 2209 (Duplex) ER2209 Filler metal of this classification is used primarily to weld duplex stainless steels which contain approximately 22% chromium such as UNS S31803 and S32205. Deposits of this alloy have "duplex" microstructures consisting of an austenite-ferrite matrix. These stainless steels are characterized by high tensile strength, resistance to stress corrosion cracking, and improved resistance to pitting. Executive 2209 (Duplex) Data Sheet Executive 2209 (Duplex) MSDS
Exocor 2594 (Super Duplex) ER2594 It is designed for the welding of superduplex stainless steels UNS S32750 and 32760 (wrought), and UNS 593380, J93404(cast). It can also be used for the welding of UNS S32550, 593370, J93372 when not subject to sulfurous or sulfuric acids in service. It can also be used for the welding of carbon and low alloy steels to duplex stainless steels as well as to weld 'standard' duplex stainless steel such as UNS S32205 and J92205 especially for root runs in pipe. Exocor 2594 (Super Duplex) Data Sheet Exocor 2594 (Super Duplex) MSDS
Executive 630 (17/4PH) ER630 The composition is designed primarily for welding ASTM A564 Type 630 and some other precipitation-hardening stainless steels. The composition is modified to prevent the formulation of ferrite networks in the martensitic microstructure which have a deleterious effect on mechanical properties. Dependent on the application and weld size, the weld metal may be used as-welded; welded and precipitation hardened; or welded, solution treated, and precipitation hardened. Executive 630 (17/4PH) Data Sheet Executive 630 (17/4PH) MSDS
Kobe DW-2594 E2594T1-1/4 This wire is designed for welding 25Cr type duplex stainless steels especially for Super Duplex grade, PRE (Pitting Resistance Equivalent) is over 40. Kobe DW-2594 Data Sheet Kobe DW-2594 MSDS
Kobe DW-308H E308HT1-1/4 This wire contains no bismuth in the weld metal and is designed for use at service temperature above 1200°F. Consequently, the elongation of the weld metal at higher temperatures is higher than that of conventional flux cored wires. Kobe DW-308H  Data Sheet Kobe DW-308H  MSDS
Kobe DW-308L E308LT0-1/4 This wire is designed to be used in the flat/horizontal position. Low carbon in this filler metal reduces the possibility of intergranular carbide precipitation. This increases the resistance to intergranular corrosion without the use of stabilizers such as niobium or titanium. Strength of this low-carbon alloy, however, is less than that of the niobium-stabilized alloys or Type 308H at elevated temperatures. Kobe DW-308L  Data Sheet Kobe DW-308L  MSDS
Kobe DW-308LP E308LT1-1/4 This is an all position wire. Low carbon in this filler metal reduces the possibility of intergranular carbide precipitation. This increases the resistance to intergranular corrosion without the use of stabilizers such as niobium or titanium. Strength of this low-carbon alloy, however, is less than that of the niobium-stabilized alloys or Type 308H at elevated temperatures. Kobe DW-308LP  Data Sheet Kobe DW-308LP  MSDS
Kobe DWG-308L E308LT0-1/4 DWG is an ultra-thin sheathed stainless steel flux-cored wire designed to operate at very low amperage. DWG replaces expensive .035 wire in many applications and saves you money in filler metal costs. Kobe DWG-308L  Data Sheet Kobe DWG-308L  MSDS
Kobe DW-309L E309LT0-1/4 This wire is designed to be used in the flat/horizontal position. Low carbon in this filler metal reduces the possibility of intergranular carbide precipitation. This increases the resistance to intergranular corrosion without the use of stabilizers such as niobium or titanium. Strength of this low-carbon alloy, however, is less than that of the niobium-stabilized alloys or Type 309 at elevated temperatures. Kobe DW-309L  Data Sheet Kobe DW-309L  MSDS
Kobe DW-309LP E309LT1-1/4 This is an all position wire. Low carbon in this filler metal reduces the possibility of intergranular carbide precipitation. This increases the resistance to intergranular corrosion without the use of stabilizers such as niobium or titanium. Strength of this low-carbon alloy, however, is less than that of the niobium-stabilized alloys or Type 309 at elevated temperatures. Kobe DW-309LP  Data Sheet Kobe DW-309LP  MSDS
Kobe DWG-309L E309LT0-1/4 DWG is an ultra-thin sheathed stainless steel flux-cored wire designed to operate at very low amperage. DWG replaces expensive .035 wire in many applications and saves you money in filler metal costs. Kobe DWG-309L  Data Sheet Kobe DWG-309L  MSDS
Kobe DW-310 E310T0-1/4 Filler metal of this classification is most often used to weld base metals of similar composition. Kobe DW-310  Data Sheet Kobe DW-310  MSDS
Kobe DW-312 E312T0-1/4 Filler metal of this classification was originally designed to weld cast alloys of similar composition. It also has been found to be valuable in welding dissimilar metals such as carbon steel to stainless steel, particularly those grades high in nickel. This alloy gives a two-phase weld deposit with substantial percentages of ferrite in an austenite matrix. Even with considerable dilution by austenite-forming elements such as nickel, the microstructure remains two-phase and thus highly resistant to weld metal cracks and fissures. Kobe DW-312  Data Sheet Kobe DW-312  MSDS
Kobe DW-316L E316LT0-1/4 This wire is designed to be used in the flat/horizontal position. Low carbon in this filler metal reduces the possibility of intergranular carbide precipitation. This increases the resistance to intergranular corrosion without the use of stabilizers such as niobium or titanium. Strength of this low-carbon alloy, however, is less than that of the niobium-stabilized alloys or Type 316H at elevated temperatures. Kobe DW-316L  Data Sheet Kobe DW-316L  MSDS
Kobe DW-316LP E316LT1-1/4 This is an all position wire. Low carbon in this filler metal reduces the possibility of intergranular carbide precipitation. This increases the resistance to intergranular corrosion without the use of stabilizers such as niobium or titanium. Strength of this low-carbon alloy, however, is less than that of the niobium-stabilized alloys or Type 316H at elevated temperatures. Kobe DW-316LP  Data Sheet Kobe DW-316LP  MSDS
Kobe DWG-316L E316LT0-1/4 DWG is an ultra-thin sheathed stainless steel flux-cored wire designed to operate at very low amperage. DWG replaces expensive .035 wire in many applications and saves you money in filler metal costs. Kobe DWG-316L  Data Sheet Kobe DWG-316L  MSDS
Kobe DW-317L E317LT0-1/4 Used for welding alloys of similar composition. Kobelco DW317 filler metal is utilized in severely corrosive environments where crevice and pitting corrosion are of concern. This low-carbon alloy, however, may not be so strong at elevated temperatures. Kobe DW-317L  Data Sheet Kobe DW-317L  MSDS
Kobe DW-347 E347T0-1/4 Usually used for welding chromium-nickel stainless steel base metals of similar composition stabilized with either Nb or Ti. Although Nb is the stabilizing element usually specified in Type 347 alloys, it should be recognized that tantalum (Ta) is also present. Ta and Nb are almost equally effective in stabilizing carbon and in providing high-temperature strength. If dilution by the base metal produces a low ferrite or fully austenitic weld metal, the crack sensitivity of the weld may increase substantially Kobe DW-347  Data Sheet Kobe DW-347  MSDS
Kobe DW-2209 E2209T1-1/4 Filler metal of this classification is used primarily to weld duplex stainless steels which contain approximately 22% chromium such as UNS S31803 and S32205. Deposits of this alloy have "duplex" microstructures consisting of an austenite-ferrite matrix. These stainless steels are characterized by high tensile strength, resistance to stress corrosion cracking, and improved resistance to pitting. If post weld annealing is required, this weld metal will require a higher annealing temperature than that required by the duplex base metal. Kobe DW-2209  Data Sheet Kobe DW-2209  MSDS
Kobe DW-309LMo E309LMoT0-1/4 For joining stainless steel to carbon and low-alloy steels for service below 600°F [316°C], and for overlaying of carbon and low-alloy steels. The presence of molybdenum provides pitting resistance in a halide environment and helps provide high temperature ductility in dissimilar joints. The ferrite level for this electrode deposit is approximately 20 FN. Kobe DW-309LMo  Data Sheet Kobe DW-309LMo  MSDS
Exocor 16/8/2 E16-8-2-16 Used primarily for welding stainless steel, such as Types 16-8-2, 316, and 347, for high-pressure, high-temperature piping systems. The weld deposit usually has a Ferrite Number no higher than 5 FN. The deposit also has good, hot ductility properties which offer relative freedom from weld or crater cracking even under high-restraint conditions. Exocor 16-8-2 is usable in either the as-welded or solution-treated condition. These electrodes depend on a very carefully balanced chemical composition to develop their fullest properties. Corrosion tests indicate that Type 16-8-2 weld metal may have less corrosion resistance than Type 316 base metal depending on the corrosive media. Where the weldment is exposed to severely corrosive agents, the surface layers should be deposited with a more corrosion-resistant weld metal. Exocor 16/8/2  Data Sheet Exocor 16/8/2  MSDS
Exocor 2209 (Duplex) E2209-16 For welding duplex stainless steels which contain approximately 22% of chromium. Weld metal deposited by these electrodes has "duplex" microstructure consisting of an austenite ferrite matrix and combines increased tensile strength with improved resistance to pitting corrosive attack and to stress corrosion cracking. Exocor 2209 (Duplex)  Data Sheet Exocor 2209 (Duplex)  MSDS
Exocor 2594 (Super Duplex) E2594-16 Exocor 2594 is a Super Duplex stainless steel for welding of Type 2507, UNS S32750 (wrought) and UNS J93404 (cast), and similar compositions. It can also be used for the welding of carbon and low alloy steels to duplex stainless steels as well as to weld “standard” duplex stainless steels such as Type 2205 although the weld metal impact toughness may be inferior to that from E2209 electrodes. Exocor 2594 (Super Duplex)  Data Sheet Exocor 2594 (Super Duplex)  MSDS
Exocor 308/308H E308/308H-16 Carbon content in the range of 0.04 to 0.08 percent provides higher tensile and creep strengths at elevated temperatures. Exocor 308H are used for welding Type 304H base metal. Weld metal ferrite content is normally targeted for 5 FN to minimize the effect of sigma embrittlement in high-temperature service. Exocor 308/308H  Data Sheet Exocor 308/308H  MSDS
Exocor 308/308L E308/308L-15/16 The 0.04 percent maximum carbon content of weld metal deposited by Exocor 308L reduces the possibility of intergranular carbide precipitation and thereby increases the resistance to intergranular corrosion without the use of stabilizers such as niobium or titanium. A carbon content of 0.04 percent maximum has been shown to be adequate in weld metal, even though it is recognized that similar base metal specifications require a 0.03 percent limitation. This low-carbon alloy, however, is not as strong at elevated temperature as Exocor 308H or Exocor 347. Exocor 308/308L  Data Sheet Exocor 308/308L  MSDS
Exocor 309/309H E309/309H-16 Carbon content in the range of 0.04 to 0.15 of Exocor 309H will provide higher tensile and creep strengths at elevated temperatures. This together with a typical ferrite content of about 6 FN make these electrodes suitable for the welding of 24 Cr 12 Ni wrought and cast steels designed for corrosion and oxidation resistance. Exocor 309/309H  Data Sheet Exocor 309/309H  MSDS
Exocor 309/309L E309/309L-15/16 The 0.04 percent maximum carbon content of these weld deposits ensures a higher ferrite content than the E309H, usually greater than 8FN and reduces the possibility of intergranular carbide precipitation. This thereby increases the resistance to intergranular corrosion without the use of Nb(Cb). Exocor 309L deposits are not as strong at elevated temperature as the niobium-stabilized alloy or Exocor 309H deposits. Commonly used for welding dissimilar steels, such as joining Type 304 to mild or low alloy steel, welding the clad side of Type 304-clad steels, welding the first layer of E308L weld cladding and applying stainless steel sheet linings to carbon steel. Embrittlement or cracking can occur if these dissimilar steel welds are subjected to a post weld heat treatment or to service above 700°F [370°C]. If postweld heat treatment of the carbon steel is essential, the total procedure, welding and heat treatment should be proven prior to implementation. Exocor 309/309L  Data Sheet Exocor 309/309L  MSDS
Exocor 310 E310-16 This electrode is most often used to weld base metals of similar composition. Exocor 310  Data Sheet Exocor 310  MSDS
Exocor 312 E312-16 These electrodes were originally designed to weld cast alloys of similar composition. They have been found to be valuable in welding dissimilar metals, especially if one of them is a stainless steel, high in nickel. This alloy gives a two-phase weld deposit with substantial amounts of ferrite in an austenitic matrix. Even with considerable dilution by austenite forming elements, such as nickel, the microstructure remains two-phase and thus highly resistant to weld metal cracks and fissures. Applications should be limited to service temperature below 800°F [420°C] to avoid formation of secondary brittle phases Exocor 312  Data Sheet Exocor 312  MSDS
Exocor 316/316L E316/316L-15/16 The 0.04 percent maximum carbon content of weld metal deposited by these electrodes reduces the possibility of intergranular carbide precipitation and thereby increases the resistance to intergranular corrosion without the use of stabilizers such as niobium or titanium. These electrodes are used principally for welding low-carbon, molybdenum-bearing austenitic alloys. Tests have shown that 0.04 percent carbon limit in the weld metal gives adequate protection against intergranular corrosion in most cases. This low-carbon alloy, however, is not as strong at elevated temperatures as Type E316H. E316L with maximum ferrite content of 2 FN has traditionally been the choice for welding Types 304 and 316 stainless steels for cryogenic service at temperatures down to -452°F [-269°C]. Exocor 316/316L  Data Sheet Exocor 316/316L  MSDS
Exocor 317L E317L-16 The alloy content of weld metal deposited by these electrodes is somewhat higher than that of Exocor 316L electrodes, particularly in molybdenum. These electrodes are usually used for welding alloys of similar composition and are utilized in severely corrosive environments (such as those containing halogens) where crevice and pitting corrosion are of concern. Exocor 317L  Data Sheet Exocor 317L  MSDS
Exocor 320LR E320LR-16 Weld metal deposited by Exocor 320LR electrodes has the same basic composition as that deposited by E320 electrodes; however, the elements C, Si, P, and S are specified at lower maximum levels, and Nb and Mn are controlled within narrower ranges. These changes reduce the weld metal fissuring (while maintaining the corrosion resistance) frequently encountered in fully austenitic stainless steel weld metals. Consequently, welding practices typically used to deposit ferrite-containing austenitic stainless steel weld metals can be used. Exocor 320LR  Data Sheet Exocor 320LR  MSDS
Exocor 330 E330-16 Commonly used where heat- and scale-resisting properties above 1800°F [980°C] are required. However, high sulfur environments may adversely affect performance at elevated temperature. Repairs of defects in alloy castings and the welding of castings and wrought alloys of similar compositions are the most common applications. Exocor 330  Data Sheet Exocor 330  MSDS
Exocor 347 E347-16 Used for welding chromium nickel alloys of similar compositions stabilized either with niobium or titanium. Although niobium is the stabilizing element usually specified in Type 347 alloys, it should be recognized that tantalum also is present. Tantalum and niobium are almost equally effective in stabilizing carbon and in providing high-temperature strength. This specification recognizes the usual commercial practice of reporting niobium as the sum of niobium plus tantalum. If dilution by the base metal produces a low-ferrite or fully austenitic weld metal deposit, crack sensitivity of the weld may increase substantially. Some applications, especially those involving high temperature service, are adversely affected if the ferrite content is too high. Consequently, a high ferrite content should not be specified unless tests prove it to be absolutely necessary. Exocor 347  Data Sheet Exocor 347  MSDS
Exocor 385 (904L) E385-16 Used primarily for welding of Type 904L materials for the handling of sulfuric acid and many chloride-containing media. Type Exocor 385 electrodes also may be used to join Type 317L material where improved corrosion resistance in specific media is needed. Exocor 385 electrodes also can be used for joining Type 904L base metal to other grades of stainless. The elements C, Si, P, and S are specified at lower maximum levels to minimize weld metal hot cracking and fissuring (while maintaining corrosion resistance) frequently encountered in fully austenitic weld metals. Exocor 385 (904L)  Data Sheet Exocor 385 (904L)  MSDS
Exocor 410 E410-16 This 12 Cr alloy is an air-hardening steel. Preheat and postheat treatments are required to achieve welds of adequate ductility for many engineering purposes. The most common application of these electrodes is for welding alloys of similar compositions. They are also used for surfacing of carbon steels to resist corrosion, erosion or abrasion. Exocor 410  Data Sheet Exocor 410  MSDS
Exocor 410NiMo E410NiMo-16 Used for welding ASTM CA6NM (CA-6NM) castings or similar materials, as well as light-gauge Type 410,41OS, and 405 base metals. Weld metal deposited by these electrodes is modified to contain less chromium and more nickel than weld metal deposited by E410 electrodes. The objective is to eliminate ferrite in the microstructure, as ferrite has a deleterious effect on mechanical properties of this alloy. Final postweld heat treatment should not exceed 1150°F [620°C]. Higher temperatures may result in re-hardening due to untempered martensite in the microstructure after cooling to room temperature. Exocor 410NiMo  Data Sheet Exocor 410NiMo  MSDS
Exocor 630 (17/4PH) E630-16 Designed for welding ASTM A 564, Type 630, and some other precipitation-hardening stainless steels. The weld metal is modified to prevent the formation of ferrite networks in the martensite microstructure which could have a deleterious effect on mechanical properties. Dependent on the application and weld size, the weld metal may be used either as-welded, welded and precipitation hardened, or welded, solution treated and precipitation hardened. Exocor 630 (17/4PH)  Data Sheet Exocor 630 (17/4PH)  MSDS
Thermanit 308L-17 E308L-17 Generation 2000 is a superior product versus the leading competitor due to things such as a coating that resists moisture pickup, thus providing a higher resistance to porosity and excellent strike & restrike characteristics. These features ensure the benefit of a clean and consistent weld – every time. Thermanit 308L-17  Data Sheet Thermanit 308L-17  MSDS
Thermanit 309L-17 E309L-17 Generation 2000 is a superior product versus the leading competitor due to things such as a coating that resists moisture pickup, thus providing a higher resistance to porosity and excellent strike & restrike characteristics. These features ensure the benefit of a clean and consistent weld – every time. Thermanit 309L-17  Data Sheet Thermanit 309L-17  MSDS
Thermanit 316L-17 E316L-17 Generation 2000 is a superior product versus the leading competitor due to things such as a coating that resists moisture pickup, thus providing a higher resistance to porosity and excellent strike & restrike characteristics. These features ensure the benefit of a clean and consistent weld – every time. Thermanit 316L-17  Data Sheet Thermanit 316L-17  MSDS
OK 10.92 Chrome compensating flux OK 10.92  Data Sheet OK 10.92  MSDS
OK 10.93 Basic bonded stainless flux OK 10.93  Data Sheet OK 10.93  MSDS
Soudokay Record IN Versatile chrome compensating flux Soudokay Record IN  Data Sheet Soudokay Record IN  MSDS
Soudokay Record IND 24 Duplex, Cb/Nb stabilized flux Soudokay Record IND 24  Data Sheet Soudokay Record IND 24  MSDS
Kobe DW-308L-XR E308LT0-1/4 The DW-308L-XR wire has the same attributes as DW-308L with one important addition. The XR-series of stainless steel flux cored wire has reduced the Hexavalent Chromium production in the welding fume over conventional wires. This reduction contributes to a safer environment by reducing the potential exposure to Hexavalent Chromium in the workplace. Kobe DW-308L-XR Data Sheet Kobe DW-308L-XR MSDS
Kobe DW-309L-XR E309LT0-1/4 The DW-309L-XR wire has the same attributes as DW-309L with one important addition. The XR-series of stainless steel flux cored wire has reduced the Hexavalent Chromium production in the welding fume over conventional wires. This reduction contributes to a safer environment by reducing the potential exposure to Hexavalent Chromium in the workplace. Kobe DW-309L-XR Data Sheet Kobe DW-309L-XR MSDS
Kobe DW-316L-XR E316LT0-1/4 The DW-316L-XR wire has the same attributes as DW-316L with one important addition. The XR-series of stainless steel flux cored wire has reduced the Hexavalent Chromium production in the welding fume over conventional wires. This reduction contributes to a safer environment by reducing the potential exposure to Hexavalent Chromium in the workplace. Kobe DW-316L-XR Data Sheet Kobe DW-316L-XR MSDS
Executive 439Ti ER439 Executive 439Ti is a copper coated stainless steel wire primarily used for the welding of automotive stainless steel exhaust systems and components. The coating technology creates a smooth and uniform copper layer on the wire surface that remarkably improves the weldability of the wire. Executive 439Ti Data Sheet Executive 439Ti MSDS