SSAB offers suggestions for suitable consumables for the welding of Hardox® and Strenx®. Note that the consumables listed are only examples. In addition to these, there are numerous suitable products that meet the recommendations from SSAB.
The consumables are classified into two main groups. The most common alternatives are unalloyed and low-alloyed grades. The second type is stainless steel consumables.
In the last part suitable handling conditions are described.
The toughness values in the weld metal
The consumables with the appropriate strengths for welding the Hardox® and Strenx® grades can, in many cases, attain favorable toughness values in the all weld metal.
The weld metal in joints of the Strenx® grades can reach an impact toughness – with many kinds of consumables – that is typically above the toughness requirements of the unaffected parent metal.
There are seldom exact, specified toughness requirements for joints in the Hardox® grades. When measured, the impact toughness values in the weld metal are normally at a level of – or above – the typical impact toughness values for these steel grades.
Unalloyed and low-alloyed consumables
Unalloyed and low-alloyed consumables should meet the specified strength criteria. The second criteria is that their hydrogen contents ought to be sufficiently low. This means a hydrogen level that corresponds to < 5 ml H2/100 g of weld metal.
Suitable strength levels for consumables used for the welding of Hardox® and Strenx® are given in the following chart.
Suitable strength levels for consumables used for the welding of Hardox® and Strenx® according to AWS
Hydrogen content
The hydrogen content of consumables depends on factors such as the welding method used. The types of consumables that can fulfill the recommended hydrogen level is stated in the table below.
| Consumables |
Type of consumable |
| Solid wires ( MAG- and TIG welding) |
All types |
| Flux cored wires (MAG) |
Basic and rutile variant |
| Metal cored wires (MAG) |
Certain type |
| Consumables for MMA-welding |
Basic variant |
| Consumables for SAW |
Basic flux/solid wire combination |
Consumables that can have the potential to reach sufficiently low hydrogen content for welding of Hardox® and Strenx® grades.
The hydrogen content of a given consumable brand can be attained by their manufacturer. This info is often attained in their datasheet. If a consumable is classified for a certain hydrogen content, it can be read out according to their standard designation. Both European and American norms applies the same principal in accordance with below. Solid wires are not qualified with respect to their hydrogen content since all of these can attain low hydrogen levels at the recommended level from SSAB.
Example:
The following rutile cored wire for MAG-welding with a yield strength of 817 MPa in the all-weld metal. It is qualified in accordance with the following standard classifications.
EN 12535: T 69 5 Mn2NiCrMo B M21 2 H5
SFA/AWS A5.29: E111T5-K4M H4
In this case the qualification includes the hydrogen content. It is stated last in the designation marked with an “H”. The no after this letter marks the hydrogen content expressed in ml/100 g of weld metal. In this case the European standard EN 12535 has a qualified hydrogen level of maximum 5 ml/100 g of weld metal. The American standard SFA/AWS thereby has a qualified level of maximum 4ml/100 g of weld metal.
Preheat/interpass temperatures due to consumable properties
When welding with consumables with yield strengths (Rp0.2) up to 690 MPa the consumable properties typically don’t influence the minimum preheat temperature of the joint. The reason is that the carbon equivalent, CET, of the parent metal typically exceeds that of the weld metal by at least 0.03 units of percentage.
For consumables with yield strengths of 690 MPa and higher, the CET value for the consumable verses the CET value for Strenx® is normally so high that the minimum preheating temperature of both the steel and the consumable are to be considered. In this situation, the highest minimum preheat temperature of either the joint plates or the consumable should be used. The software SSAB WeldCalc™ can simplify these calculations.
High strength, low-alloy consumables with yield strengths (Rₚ₀.₂) higher than 700 MPa
Strenx® 900–1300 steel types are frequently welded with consumables that have yield strengths of about 750–1100 MPa in the all-weld metal. This group of consumables represents the highest strength available on the market. Their manufacturers do not normally specify preheat/interpass temperatures for these types of consumables.
The actual temperature can for example be determined in accordance with the European Norm EN 1011-2, Method B. In addition, SSAB has made its own general estimates of the lowest suitable preheat/interpass temperature in accordance with the table below. SSAB considers that the interpass temperature should be set at a maximum of +210 °C.
The permissible heat input follows our normal recommendations for the relevant steel grade.
| Single plate thickness in the joint [mm] |
Min. preheat temperature [°C] |
| ≤ 10 |
125 |
| 10,1 – 20,0 |
140 |
| 20,1 – 40,0 |
175 |
| >40,0 |
190 |
Estimated preheat levels for high strength consumables. SSAB does not take formal responsibility of these temperatures since they depend of the individual characteristics of the consumable being used.
Examples of suitable MAG solid wires
The consumables are arranged according to the yield strength (Rp0.2) for which they are classified. In reality, a given consumable normally has a higher yield strength than its standard designation. The mechanical properties of a given consumable can be obtained from its manufacturer.
|
Consumable manufacturer/ Min yield strength MPa (ksi) |
400 (58) |
470 (68) |
540 (78) |
610 (97) |
680 (100) |
745 (108) |
| AWS Class |
ER 70X* |
ER 80X* | ER 90X* |
ER100X* |
ER110X* |
ER120X* |
| ELGA |
Elgamatic 100 |
Elgamatic 162 |
Elgamatic 163 |
Elgamatic 135 |
Elgamatic 138 |
|
| ESAB |
OK Aristorod 12.50, OK Aristorod 12.63 |
OK Aristorod 13.09, OK Aristorod 13.12 |
OK Aristorod 13.22 |
OK Aristorod 55, OK Autrod 13.25 |
OK Aristorod 69 |
OK Aristorod 79 |
| LINCOLN ELECTRIC |
LNM 25, SUPRAMIG HD |
LNM Ni1, LNM Ni2.5 |
LNM MoNi, Superarc AK 10-TM |
LNM MoNiVa |
LNM MoNiCr |
|
| BÖHLER | EMK6, EMK8 |
NiCu1-IG, DCMS-IG |
CM2-IG |
Union NiMoCr |
X70-IG, alform 700-IG |
Union X90, Union X96 |
| OERLIKON | Carbofil 1, Carbofil 1 Gold |
Carbofil NiCu |
Carbofil NiMoCr, Carbofil NiMo1 |
Carbofil 120 |
* X can stand for one or several code characters
Examples of suitable MAG flux cored wires
The consumables are arranged according to the yield strength (Rp0.2) for which they are classified. In reality, a given consumable normally has a higher yield strength than its standard designation. The mechanical properties of a given consumable can be obtained from its manufacturer.
| Consumable manufacturer/ Min yield strength MPa (ksi) |
400 (58) |
470 (68 | 540 (78) |
610 (97) |
680 (100) |
745 (108) |
| AWS Class |
ER 7X* |
ER 8X” |
ER 9X” |
ER10X* |
ER11X” |
ER12X” |
| ELGA |
Elgacore DWA 51B, Elgacore DWA 50 | Elgacore DWA 55L | Elgacore DWA 65L | Elgacore R690 | ||
| ESAB |
Tubrod 15.00, Filarc PZ 6113S | OK Tubrod 15.17 | Dual-Shield 55, Dual-Shield CrMo2 | Dual-Shield 62 | Dual-Shield 69, OK Tubrod 15.27 | Filarc PZ 6149 |
| LINCOLN ELECTRIC |
Outershield 71E-H, Outershield 71MS-H | Outershield 12-H, Outershield 19-H | Outershield 20-H | Outershield 101Ni-HSR | Outershield 690-H | |
| BÖHLER |
Ti52-FD, Union TG 55 M | Ti 60-FD, Ti 2 Ni T-FD | Kb 65 T-FD | Kb 85 T-FD | ||
| OERLIKON | Fluxofil 14HD, Fluxofil 19HD | Fluxofil 20, Fluxofil 20HD |
* X can stand for one or several code characters
Examples of suitable MAG metal cored wires
The consumables are arranged according to the yield strength (Rp0.2) for which they are classified. In reality, a given consumable normally has a higher yield strength than its standard designation. The mechanical properties of a given consumable can be obtained from its manufacturer.
| Consumable manufacturer/ Min yield strength MPa (ksi) |
400 (58) | 470 (68) |
540 (78) |
610 (97) |
680 (100) |
745 (108) |
| AWS Class |
ER 7X* |
ER 8X” |
ER 9X” |
ER10X* |
ER11X” |
ER12X” |
| ELGA |
Elgacore MXA 100, Elgacore MXA 100XP |
Elgacore MXA 55 |
Elgacore M690 |
|||
| ESAB |
OK Tubrod 14.13, PZ6105R | OK Tubrod 14.03 |
Coreweld 89 |
|||
| LINCOLN ELECTRIC |
Outershield MC710-H, Outershield MC715-H | |||||
| BÖHLER | HL 46-MC, HL 51 T-MC |
HL53 T-MC, NiCu1 T-MC |
HL65 T-MC |
HL75 T-MC |
alform 700-MC |
alform 900-MC, alform 960-MC |
* X can stand for one or several code characters
Examples of suitable MMA electrodes
The consumables are arranged according to the yield strength (Rp0.2) for which they are classified. In reality, a given consumable normally has a higher yield strength than its standard designation. The mechanical properties of a given consumable can be obtained from its manufacturer.
| Consumable manufacturer/ Min yield strength MPa (ksi) |
400 (58) |
470 (68) |
540 (78) |
610 (97) |
680 (100) |
745 (108) |
| AWS Class |
E7016-X*, E7018-X* | E8016-X*, E8018-X* |
E9018-X* | E10018-X* |
E11018-X* |
E12018-X* |
| ELGA |
P48S, P51 |
P48K, P65MR | P110MR | |||
| ESAB |
OK 48.00, OK 48.50 |
OK 73.68, OK 73.15 |
OK 74.78 |
OK 74.86 Tensitrode |
OK 75.75, Filarc 118 |
OK 75.78 |
| LINCOLN ELECTRIC |
Basic 7018, Baso 100 |
Conarc 74 |
Conarc 60G, Conarc 70G |
Conarc 80 |
Conarc 85 |
|
| BÖHLER |
Fox ev 50, AWS E7018-1 |
Fox ev 60, Fox Fox 2.5Ni |
Fox ev 70 |
Fox EV 85, Fox alform 700 |
||
| OERLIKON | Carbofil 1, Carbofil 1 Gold | Tenacito 70 |
Tenacito 65R |
Tenacito 75 |
Tenacito 80 |
Tenacito 100 |
* X can stand for one or several code characters
Examples of suitable SAW flux and wire combinations
The consumables are arranged according to the yield strength (Rp0.2) for which they are classified. In reality, a given consumable normally has a higher yield strength than its standard designation. The mechanical properties of a given consumable can be obtained from its manufacturer.
|
Consumable manufacturer/ Min yield strength MPa (ksi) |
400 (58) |
470 (68) |
540 (78) |
610 (97) |
680 (100) |
745 (108) |
| AWS Class |
F7X* |
F8X” |
F9X” |
F10X* |
F11X” |
F12X” |
| ELGA |
Elgasaw 102/ Elgaflux 251B, Elgasaw 102Si/ Elgaflux 251B |
Elgasaw 102Mo/Elgaflux 251B |
||||
| ESAB |
OK Autrod 12.22/OK Flux 10.62, OK Autrod 12.32/OK Flux 10.62 |
OK Autrod 12.24/OK Flux 10.62, OK Autrod 12.34/OK Flux 10.62 |
OK Autrod 12.44/OK Flux 10.62 |
OK Autrod 13.40/OK Flux 10.62 |
OK Autrod 13.43/OK Flux 10.62 |
|
| LINCOLN ELECTRIC |
L-61/Lincolnweld 8500, L-50M/P 240 |
LNS 40A/Lincolnweld 8500, LNS 150/P 240 |
LNS 164/839, LNS 151/P 240 |
LA82/Lincolnweld MIL 800-H, LA100/Lincolnweld MIL 800-H |
||
| BÖHLER |
EMS 2/BB 24, Union S 2/ UV 420TT |
EMS 2 Mo/BB 24 |
3NiMo 1-UP/BB24 |
3 NiMoCr/BB24 Union S 3 NiMoCr/ UV 420TT |
||
| OERLIKON | OE-S3/OP121TT |
OE-S2Mo/OP121TT |
OE-S3NiMo1/ OP121TT |
* X can stand for one or several code characters
Stainless steel consumables
Hardox® and Strenx® can always be welded with austenitic stainless steel consumables of type AWS 307. The typical basic chemical composition for this grade is 18 % Cr, 8 % Ni, 6 % Mn. After welding, high resistance is achieved to both hydrogen cracks and hot cracks in the joint. The structure of the weld metal will contain austenite, which contributes to a high toughness of the weld metal.
The yield strength (Rp0.2) of this type of consumables is around 450–550 MPa. The resistance to hydrogen cracks are very high for these types of consumables. It means that it is no need to state a max hydrogen content for stainless consumables.
This type of consumable is suitable as the buffer layer in hard facing. An alternative to the welding consumable AWS 307 is an austenitic stainless steel consumable according to AWS 309. However, the risk of hot cracking is somewhat higher for type AWS 309 compared to AWS 307. Consumables according to AWS 307 are listed in the table below.
| Consumable manufacturer/Min yield strength MPa (ksi) | MMA |
MAG, solid ware |
MAG, flux cored wire |
MAG, metal cored wire |
SAW |
| AWS Class |
A5.4: E307X* |
A5.9: E307 |
A5.22: E307X* |
A5.22: E307X* |
|
| ELGA |
Cromamig 307Si |
||||
| ESAB |
OK 67.45, OK67.52 |
OK 16.95 |
OK Tubrod 15.34 |
||
| LINCOLN ELECTRIC |
Arosta 307 |
LNM 307 |
|||
| BÖHLER |
Fox A7 |
A7-IG |
A7-FD |
A7-MC |
|
| OERLIKON |
Supercromax R |
Inertfil 307 |
Fluxinox 307 |
* X can stand for one or several code characters
Handling of consumables
In order to achieve the intended hydrogen content, it is important that the consumables are handled in accordance with their manufacturer. Otherwise, the consumables can be subjected to excessive hydrogen pick-up from different substances in their environment.
General issues to consider in this respect are that:
- The consumables are to be stored and kept away from contaminants. Examples of these are dampness, oil and grease.
- Opened packages of consumables for MMA welding and fluxes for SAW often need to be stored at elevated temperatures. The reason is to avoid excessive hydrogen pick-up from the humidity in the air. This is normally done by keeping them in small furnaces especially designed for consumables. Unopened packages can normally be stored at room temperature.
- Unopened and opened packages of solid wires and cored wires can normally be stored at room temperature. The cause is that they have a relatively high resistance for moisture pick-up.
The information in this report is only applicable to SSAB’s products and should not be applied to any other products than original SSAB products.
This report provides general results and recommendations for SSAB steel products. This report is subject to SSAB’s Terms of Use. It shall be the user's responsibility to verify that the information contained herein is correct and is suitable to be used for the particular purpose and application of the user. The report is intended to be used by professional users only who possess adequate expertise, qualification and knowledge for the safe and correct use of the results and recommendations in this report. This report is provided “as is”. The use of the report is at user’s own discretion and risk and that users will be solely responsible for any use of this report. SSAB disclaims any liability for the content or potential errors of this report, including but not limited to warranties and condition of merchantability or fitness for a particular purpose or suitability for individual applications. SSAB shall not be liable for any kind of direct or indirect damages and/or costs related to or arising therefrom, whether special, incidental, consequential or directly or indirectly related to the use of, or the inability to use, the report or the content, information or results included therein.