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Cobalt alloys

Applications at temperatures above 700 °C frequently demand the use of Co-based matrices, whose high-temperature strength is even higher. The high-temperature strength of the element cobalt is due to its very low SFE. Consequently, a high degree of hardening is thus achieved, on the one hand, and the beginning of recovery and recrystallisation is shifted toward higher temperatures, on the other hand. As a result, processes of cohesion loss are effectively hindered. In this manner, hardening processes are effective even at elevated temperatures.

Cast Co-based hard alloys are employed especially for guide blades in aircraft engines and stationary gas turbines. Moreover, Co alloys are extensively employed for furnace baffles in the glass, ceramics, and metallurgical industries.

The long-term stability and oxidation resistance of these materials are situated between the values for austenitic steels and those for γ’-hardened Ni alloys, whereas the strength values are decidedly closer to those for steels. The essential advantages and disadvantages of Co-based hard alloys are the following:

+ Since the usual Co alloys do not contain highly reactive elements, such as Ti and Al, they can be cast in air. Moreover, the size of the components is not limited by the capacity of vacuum-casting equipment. There is no need for an elaborate heat treatment; hence, the components can be manufactured more economically than comparable γ’-hardened Ni alloys.

+ The weldability of Co alloys is comparable to that of austenitic steels.

+ Because of the low SFE of Co, the matrix of Co exhibits relatively high (creep) strength.

+/- Under certain conditions, the hot-gas corrosion resistance may be higher than that of Ni alloys. The liquid Co-S phase cannot occur below 877 °C (Ni-S: 637 °C). Furthermore, the Cr content of Co alloys is decidedly higher than that of most Ni versions. However, the low-temperature hot-gas corrosion behaviour tends to be worse in the case of Co materials, unless the Cr content is extremely high.

- It is not possible to obtain especially high contents of hardening phases, unless other disadvantages are tolerated.

- In a manner similar to that of iron, cobalt undergoes a reversible allotropic phase transformation upon heating and cooling. As with iron, the face-centred cubic phase (α Co) is stable at high temperature; upon cooling, this phase transforms to the hexagonal dense phase (ε-Co) at about 420 °C. The associated changes in properties are undesirable; consequently, the more ductile fcc phase must be stabilised with the addition of Ni and Fe, which results in a higher SFE.

Since industrial Co-based alloys contain up to 30 per cent chromium, up to 15 per cent tungsten, and up to 8 per cent molybdenum (mass contents), their metal matrices are usually phase mixtures of α and ε cobalt. Molybdenum and tungsten exert a favourable effect on the high-temperature strength, since their atomic radii are very much larger than that of the Co atom. In this manner, they prevent the motion of dislocations; consequently, recovery can occur only at considerably higher temperatures.

The structure of the carbide phases is determined by the primary crystallisation – notwithstanding exceptions. For the use of metal powders in welding processes, this structure can be altered by the previous addition of various further carbides or other hard materials. In the weld metal, the hard material phases thus formed with carbon, boron, and in part silicon are often thermodynamically unstable, but are of interest for increasing the wear resistance.

The melting point or melting range is determined exclusively by the chemical composition of the alloys. Commercially available alloys for powder-welding technology contain additions of nickel, manganese, iron, silicon, and in some cases boron. The melting points of these multi-component alloys usually range between 1050 and 1400 °C.

The more ductile α phase is frequently desired for components subject to wear, since it is metastable and can undergo a stress-induced transformation. The transformation temperature (MS, AS) is shifted by the addition of alloying elements. Consequently, all phase mixtures are possible between the pure α and the pure ε phase in industrial alloys. Hard alloys and hard composite materials on a Co basis are derived primarily from the Co-Cr-W-C system. In these alloys, which are designated by the trade name Stellite, the metal matrix is a Co-Cr-W solid solution, which can also contain precipitated WC because of the decrease in the solubility of WC with increasing temperature. The metal matrices of industrial alloys can thus attain a microhardness value up to 450 HV0.05. In surfaces subject to friction, metal matrices of this type can attain a hardness value of 650 HV0.05 by cold-hardening and transformation of the metastable α phase. This hardness level is otherwise restricted to martensitic Fe matrices. Besides solid-solution hardening, precipitation hardening by intermetallic phases is also important. With appropriate contents of tungsten and molybdenum in α as well as in ε Co alloys, intermetallic phases of type Co3(W, Mo) can precipitate after solution heat treatment by postweld ageing at 850 °C for 70 hours. These metal matrices are well suited for application even up to 1000 °C, since the loss of hardness associated with overageing is very small.

The thermal fatigue strength is sometimes claimed to be higher, in comparison with that of Ni materials, because of the relatively high thermal conductivity of pure Co; however, such a result cannot be confirmed for Co alloys. Thus, a value of about 11 Wm-1K-1 is indicated for the wrought alloy, “Haynes 188” as well as for the cast alloys X 40 and X 45 at room temperature; this value is the same as that for Ni alloys and austenitic steels. The temperature dependence of λ is also similar. Furthermore, no appreciable difference in thermal expansion coefficient has been detected; the values are in the range from 16 to 17.10-6 K-1. A slight tendency toward thermal fatigue cracking of Co-based hard alloys likewise does not correspond to practical experience under comparable operating conditions. In view of the lower strength value in comparison with that of the competing Ni alloys, the opposite trend is more likely to be observed.

 

corrosion behavior of NT® - Cobalt-based hard alloys

  Corrosion-Medium
 
Concentration
Gew.-%
Temperature
oC
NT®
Lite 21
NT®
Lite 6
NT®
Lite12
NT®
Lite 1
  Phosphoric acid
  H3PO4
 
10
85
10
RT
RT
65
 
 
 
1
1
1
 
 
 
1
1
1
  Nitric acid
  HNO3
 
10
70
70
RT
RT
65

 
 1
1
1
2
1
1
1
1
1
1
  Sulphuric acid
  H2SO4
 
10
90
10
RT
RT
65
1
1
1
1
2
4
1
1
4
1
1
1
  Hydrochloric acid
  HCl
 
5
37
10
RT
RT
TE
1
2
 
3
4
4
3
4
4
1
3-4
4
  Acetic acid
  CH3COOH
 
20
90
30
RT
RT
TE
1
1
1
1
1
1
1
1
1

1
 
  Hydrofluoric acid
  HF
 
6
40
 
RT
TE
 

 
 
4
 
 
4
 
 
2
4
 
  Chromic acid
  
 
10
10
 
RT
TE
 

 
 
1
4
 
1
4
 

 
 
  Sodium hydroxide solution
  NaOH
 
10
40
5
RT
RT
TE

 
 
1
1
 
1
 
 
1
 
1
  Copper chloride
  CuCl2
 
2
10
 
RT
RT
 

 
 
1
1
 

 
 
1
1
 
  Ferric chloride
  FeCl3
 
2
 
 
RT
 
 

 
 
1
 
 
1
 
 
1
 
 
  Ammonium nitrate
  NH4NO3
 
10
 
 
RT
 
 
1
 
 

 
 
1
 
 

 
 
  Strauß test
  
 
 
 
 
 
 
 
1
 
 
1
 
 
3
 
 
1
 
 

 

  Degradation rates
     
1 = < 1 g/m2 per diem 2 = 1–10 g/m2 per diem 3 = 11–25 g/m2 per diem 4 = > 25 g/m2 per diem

 

RT: Room temperature; TE: Temperature of ebullition

Iron alloys

NT® Iron-based metal powders

BRAND NT® Weld metal
Standard analysis, %
Hardness Applications and properties Process
NT® 304L
1.4306
C
Si
Cr
Ni
Mn
< 0,03
0,5
18,0
11,0
1,3
< 200 HV Completely austenitic alloys with high corrosion resistance, high ductility, and high crack resistance; well suited for use as moderating layer PTA
PS
HVOF
NT® 316 L
1.4404
C
Si
Cr
Ni
Mo
Mn
< 0,03
0,5
17,0
12,0
2,5
1,5
< 200 HV Stainless austenitic CrNiMo alloy with low carbon content; very well suited for use as moderating layer in hard facing PTA
PS
HVOF
NT® 630
1.4542
17-4-PH
C
Si
Cr
Ni
Cu
Nb
0,05
0,4
17,0
4,0
4,0
0,4
< 380 HV Stainless, precipitation-hardenable CrNi alloy stabilised with niobium; characterised by high-strength properties as well as corrosion resistance; especially high resistance to stress-corrosion cracking, in comparison with NT® 304L PTA
PS
HVOF
NT® 410
1.4006
C
Si
Cr
0,12
0,3
13,0
< 220 HB Martensitic alloys with good mechanical properties as well as high corrosion resistance in moderately aggressive media; version NT® 420 also stable toward oxidising environments up to 600 °C PTA
PS
HVOF
NT® 420
1.4021
C
Si
Cr
0,2
0,5
13,0
< 230 HB
NT® FeCrMn250 C
Si
Cr
Ni
Mn
0,6
0,7
15,7
1,5
14,7
250 HB
after hardening
500 HB
Impact-resistant austenitic alloy with Mn and Cr, also suited for use as moderating layer; NT® FeCrMn250 with high ductility and crack resistance; possible applications: pistons, roller-table rolls, bearing seats, transport wheels, production masters, gear teeth, tool components PTA
NT® FeV12 C
Si
Cr
Mn
Mo
V
2,8
1,0
5,0
1,0
1,5
12,0
60-62 HRC Fe-Cr-V-C-alloy with high resistance to fine abrasive wear; homogeneous and fine distribution of vanadium carbide (hardness: about 2900 HV) in a martensitic matrix; for crack-free cladding of cutting-tool edges and component edges subject to severe load PTA
NT® FeV18 C
Si
Cr
Mn
Mo
V
4,0
1,0
5,0
1,0
1,5
18,0
62-64 HRC In comparison with NT FeV12, even greater hardness and higher wear resistance because of the higher carbon and vanadium contents; likewise well suited for crack-free weld surfacing to satisfy the most stringent requirements PTA
NT® FeCrV15 C
Si
Cr
Mn
Mo
V
Ni
4,4
0,9
17,0
0,9
2,0
15,0
3,0
60-62 HRC Martensitic wear-resistant alloy, NT Fe-CrV15, with a high content of vanadium carbide, specially developed for weld surfacing of components subject to abrasive wear; also corrosion-resistant by virtue of the free Cr content of more than 13 %; moreover, capable of secondary hardening in the range from 500 °C to 550 °C; decrease in hardness beyond the latter temperature, but maximal retention of wear resistance because of the carbide content PTA
NT® FeCrV15Ni6 C
Si
Cr
Mn
Mo
V
Ni
4,6
0,7
20,0
0,8
2,0
15,0
6,0
50 HRC Formation of a high-temperature-resistant austenitic matrix structure with the addition of 6 % nickel to alloy version FeCrV15; thermally stable up to 800 °C; high wear resistance at high temperature because of the carbide content PTA
NT® FeCrV15Ni9 C
Si
Cr
Mn
Mo
V
Ni
4,6
0,7
20,0
0,8
2,0
15,0
9,0
45 HRC Improved ductility properties in comparison with NT® FeCrV15Ni6 PTA
NT® Fe23C C
Si
Cr
Ni
Mo
2,0
1,5
26,0
10,0
5,0
350 HV Fe-Cr-Ni-Mo alloy for cladding of engine valves; characterised by high corrosion and scaling resistance

Further powder alloy types available on request.

Cobalt-based continuous-cast rods

NT® cobalt-based continuous-cast rods

BRAND NT® Weld metal standard analysis, % Hardness at RT Applications and properties Diameter as delivered ø, mm
NT® Lite 6 C
Si
Cr
Ni
W
Fe
1,1
1,3
27,0
1,0
4,5
1,0
41 HRC

600°C
272 HV
Corrosion- and wear-resistant Co-based alloy for operation at high temperatures; typical fields of application: engine valves and seats for automotive and naval construction, valves, bushings, seat rings, and spindles for power plant construction, extruder worm conveyors and bushings for the plastics industry, seat and guide surfaces for valves, fittings, and pumps, cutting edges and knives, agitators for the woodworking and paper industries, transport and guide rollers, hot shears, rolls for rolling mills 3,0
3,2
4,0
5,0
6,0/6,4
8,0
NT® Lite 12 C
Si
Cr
Ni
W
Fe
1,8
1,3
29,0
1,0
8,5
1,0
48 HRC

600°C
357 HV
For cladding of sealing surfaces, discharge valves for Diesel engines, press-forging and deep-drawing tools, hot-trimming dies, grinding and transport equipment; preheating and working temperature: 250 to 400 °C; earth augers, knives, chisels for woodworking and processing of paper and plastics; resistant to organic and inorganic acids (such as hydrochloric acid); resistant to scaling up to 900 °C; post-weld treatment: slow cooling in a furnace or under diatomaceous earth; for more extensive welding work, stress-relief annealing at 500 to 700 °C immediately after exposure to welding heat 3,0
3,2
4,0
5,0
6,0/6,4
8,0
NT® Lite 1 C
Si
Cr
Ni
W
Fe
2,4
1,1
32,0
1,0
13,0
1,0
53 HRC

600°C
445 HV
Very high-temperature-resistant Co-based alloy with high resistance to abrasive wear and compressive stress, very well suited for cladding of valve-stem ends, wear rings, grinding and edge runners, earth augers and carving tools; heat-resistant up to 1000 °C; preheating and working temperature: 250 to 400 °C; post-weld treatment: slow cooling in a furnace or under diatomaceous earth; for extensive welding work, stress-relief annealing at 500 to 700°C immediately after exposure to welding heat 3,0
3,2
4,0
5,0
6,0/6,4
8,0
NT® Lite 20 C
Cr
Ni
W
Fe
2,2
32,0
1,0
16,5
1,0
56 HRC NT® Lite 20: cobalt-based alloy with especially high wear resistance, as well as high corrosion resistance; low shock resistance, but very well suited for certain applications, such as slush pumps, rotating seal rings, or bearing sleeves 4,0
5,0
6,0/6,4
8,0
NT® Lite 21 C
Si
Cr
Mo
Ni
Fe
0,25
0,5
28,0
5,0
2,8
1,0
32 HRC

600°C
201HV
By virtue of the ductile, corrosion-and high-temperature-resistant weld metal, wide range of application on components subject to impact stress, corrosion, and elevated temperatures; on discharge-valve seats, valves and fittings of all kinds, pumps for handling spent lye and high-temperature liquids, hot-stamping tools, among other uses; preheating and working temperature: 250 to 300 °C, no preheating necessary for small workpieces sufficiently heated by the welding process; 3,0
3,2
4,0
5,0
6,0/6,4
8,0
NT® Lite 25 C
Cr
Ni
W
< 0,1
20,0
10,0
15,0
230 HB 230 HBCo-based alloy of low hardness, high thermal conductivity with no appreciable decrease in hardness in the upper temperature range; possible application: continuous-casting rolls and guides  
NT® Lite F C
Si
Cr
Ni
W
Fe
1,6
1,2
26,5
23,0
12,5
1,0
45 HRC

600°C
304 HV
High abrasion and corrosion resistance, similar to NT® Lite 6, but with greater hardness and better flow behaviour 3,0
3,2
4,0
5,0
6,0/6,4
8,0
NT® Alloy T-400 C
Si
Cr
Ni
Fe
0,08
2,4
8,5
1,5
1,5
  NT® Alloy T-400: intermetallic cobalt-based alloy with especially high resistance to seizing wear and corrosion; low coefficient of friction; therefore employed especially in cases where good dry-running properties are required 5,0

Rod surface: continuous-cast, bare surface in the standard version; polished version available on request

Further continuous-cast quality grades and lengths available on request.

Nickel-based continuous-cast rods

NT® nickel-based continuous-cast rods

BRAND NT® Weld metal standard
analysis, %
Hardness at RT Applications and properties Diameter as delivered ø mm
NT® Alloy T-700 C
Si
Cr
Mo
Fe
0,04
2,9
15,0
32,0
0,5
47 HRC NT® Alloy T-700, highly resistant to corrosion and oxidation; cobalt-free, intermetallic nickel-based alloy especially well suited for use as a substitute for Co-Cr-W alloys for applications in nuclear technology - not susceptible to activation by radiation. 5,0
NT® Alloy Ni 60 W C
Si
Cr
Fe
B
0,7
2,0
14,5
4,5
3,2
54 HRC Self-flowing NiCrBSi hard alloys for the application of hard, high-temperature-resistant claddings by hard-surfacing techniques; low coefficient of friction and high adhesion resistance; constant hardness value up to 650 °C, but pronounced decrease in hardness above this temperature; smooth weld-bead surface with low penetration by virtue of the low melting point of the alloy; typical applications: hard facing of valves and fittings, extruder worm conveyors, stone-cutting tools, centrifuges, fan blades, shaping tools. 4,0
5,0
6,0/6,4
NT® Alloy Ni 60 H C
Si
Cr
Fe
B
0,75
2,0
14,5
4,0
3,8
58 HRC
NT® Alloy 50 C
Si
Cr
Fe
B
0,6
3,5
11,5
3,7
1,9
50 HRC

Rod surface: continuous-cast, bare surface in the standard version; polished version available on request.

Further continuous-cast quality grades and lengths available on request.

Strip-powder combinations

NT® Strip-powder combinations

Strip-powder combinations for buffer passes

Strip-powder combinations for wear-resistant weld surfacing

Submerged-arc welding powder for joining and weld surfacing


Instructions for the user

The aforementioned information and technical data have been compiled as a support for the user in selecting the strip-powder combinations which are best suited for each specific submerged-arc-RES welding requirement. The exact, specific application as well as the approvals should be discussed with us before use.

The properties should be regarded as minimal data for the condition without removal; the values are based on laboratory and approval tests. In the case of multipass welding, the data are based on the pure, untreated test weld metal as specified in EN 756, with the application of the measuring set-up as specified in EN 1594-1 or AWS A 5.17 / 5.23, if mentioned. For single-pass welding (pass / capping pass), the measuring set-up specified in EN 1597-2 has been employed. The European regulations for strip electrodes and welding powder for submerged-arc welding are similar to the corresponding ASME / AWS standards A 5.17 / 5.23 for carbon and low-alloy steels or for corrosion-resistant stainless steels (AWS 5.9).

During the single-pass or two-pass welding process, both the dilution with the base metal and the heat input affect the mechanical properties of the weld. Consequently, the selection of the best-suited strip-powder combinations as well as appropriate process tests before use are decisive. The same applies to strip-powder combinations which have already been approved. Details can be furnished upon request.

All data are intended solely for informative purposes and do not involve any guarantee whatsoever.