Nickel-based powders for plasma transferred arc (PTA)
Surfit® nickel (Ni) based powders
Surfit 1515-00 | Ni <0.06C 2Si 1.1B 0.5Fe 20Cu | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni <0.06C 2Si 1.1B 0.5Fe 20Cu
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 1520-00 | Ni <0.06C 2.3Si 1.4B 0.4Fe | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni <0.06C 2.3Si 1.4B 0.4Fe
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 1525-30 | Ni 0.1C 2.6Si 1B 1.9Fe 3.3Cr 0.4Al | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni 0.1C 2.6Si 1B 1.9Fe 3.3Cr 0.4Al
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 1725-30 SP570 | Ni 0.13C 2.6Si 1B 1.9Fe 3.2Cr 0.4Al | 212/63 µm
Particle size: 212/63 µm
Chemistry: Ni 0.13C 2.6Si 1B 1.9Fe 3.2Cr 0.4Al
Powder type: Gas atomised
Typical deposition techniques: Plasma transferred arc (PTA)
Remarks:
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Surfit 1532-40 | Ni 0.15C 3.4Si 1.2B 3.1Fe 7Cr | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni 0.15C 3.4Si 1.2B 3.1Fe 7Cr
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 1535-30 | Ni <0.07C 3Si 1B 1Al 2.4Fe 5.6Cr | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni <0.07C 3Si 1B 1Al 2.4Fe 5.6Cr
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 1735-30 | Ni <0.07C 3Si 1B 1Al 2.4Fe 5.6Cr | 212/63 µm
Particle size: 212/63 µm
Chemistry: Ni <0.07C 3Si 1B 1Al 2.4Fe 5.6Cr
Powder type: Gas atomised
Typical deposition techniques: Plasma transferred arc (PTA)
Remarks:
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Surfit 1538-40 | Ni <0.07C 3Si 2.3B <0.8Fe | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni <0.07C 3Si 2.3B <0.8Fe
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 1540-00 | Ni 0.25C 3.5Si 1.6B 2.5Fe 7.5Cr | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni 0.25C 3.5Si 1.6B 2.5Fe 7.5Cr
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 1545-00 | Ni 0.35C 3.6Si 1.9B 2.7Fe 9Cr | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni 0.35C 3.6Si 1.9B 2.7Fe 9Cr
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 1550-00 | Ni 0.45C 3.8Si 2.3B 2.9Fe 11Cr | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni 0.45C 3.8Si 2.3B 2.9Fe 11Cr
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 1750-00 | Ni 0.45C 3.8Si 2.3B 2.9Fe 11Cr | 212/63 µm
Particle size: 212/63 µm
Chemistry: Ni 0.45C 3.8Si 2.3B 2.9Fe 11Cr
Powder type: Gas atomised
Typical deposition techniques: Plasma transferred arc (PTA)
Remarks:
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Surfit 1.53 | Ni 0.9C 5.3Si 2.1B 5.4Fe 17.8Cr | 180/53 µm
Particle size: 180/53 µm
Chemistry: Ni 0.9C 5.3Si 2.1B 5.4Fe 17.8Cr
Powder type: Gas atomised
Typical deposition techniques: Plasma transferred arc (PTA)
Remarks:
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Surfit 1555-20 | Ni 0.5C 4Si 3.4B 2.8Fe 16Cr 3Mo 3Cu | 150/53 µm
Particle size: 150/63 µm
Chemistry: Ni 0.5C 4Si 3.4B 2.8Fe 16Cr 3Mo 3Cu
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 1559-40 | Ni <0.06C 3Si 2.9B | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni <0.06C 3Si 2.9B
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 1759-40 | Ni <0.06C 3Si 2.9B | 212/63 µm
Particle size: 210/63 µm
Chemistry: Ni <0.06C 3Si 2.9B
Powder type: Gas atomised
Typical deposition techniques: Plasma transferred arc (PTA)
Remarks:
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Surfit 1560-00 | Ni 0.75C 4.3Si 3.2B 3.8Fe 14.8Cr | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni 0.75C 4.3Si 3.2B 3.8Fe 14.8Cr
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 1562-00 | Ni 0.6C 3.7Si 2.8B 3.5Fe 14.3Cr 9.5W | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni 0.6C 3.7Si 2.8B 3.5Fe 14.3Cr 9.5W
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit 5510-40 | Ni 5Al | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni 5Al
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Surfit IN 625 | Ni <0.03C 0.4Si 0.75Fe 21.5Cr 9Mo 3.7Nb | 125/45 µm
Particle size: 125/45 µm
Chemistry: Ni <0.03C 0.4Si 0.75Fe 21.5Cr 9Mo 3.7Nb
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit IN 625 | Ni <0.03C 0.4Si 0.75Fe 21.5Cr 9Mo 3.7Nb | 150/45 µm
Particle size: 150/45 µm
Chemistry: Ni <0.03C 0.4Si 0.75Fe 21.5Cr 9Mo 3.7Nb
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit IN 625 | Ni <0.03C 0.4Si 0.75Fe 21.5Cr 9Mo 3.7Nb | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni <0.03C 0.4Si 0.75Fe 21.5Cr 9Mo 3.7Nb
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit IN 625 | Ni <0.03C 0.4Si 0.75Fe 21.5Cr 9Mo 3.7Nb | 180/63 µm
Particle size: 180/63 µm
Chemistry: Ni <0.03C 0.4Si 0.75Fe 21.5Cr 9Mo 3.7Nb
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit HAST C22 | <0.015C Ni 4Fe 24Cr 1Co 14Mo 3W|180/53 µm
Particle size: 180/53 µm
Chemistry: <0.015C Ni 4Fe 24Cr 1Co 14Mo 3W
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Surfit HAST C276-M | Ni 0.12C 0.5Si 3Fe 15.5Cr 16Mo 4.5W 1.2Mn 0.5V | 53/20 µm
Particle size: 53/20 µm
Chemistry: Ni 0.12C 0.5Si 3Fe 15.5Cr 16Mo 4.5W 1.2Mn 0.5V
Powder type: Gas atomised
Typical deposition techniques: -
Surfit HAST C276-M | Ni 0.12C 0.5Si 3Fe 15.5Cr 16Mo 4.5W 1.2Mn 0.5V | 150/53 µm
Particle size: 150/53 µm
Chemistry: Ni 0.12C 0.5Si 3Fe 15.5Cr 16Mo 4.5W 1.2Mn 0.5V
Powder type: Gas atomised
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit Ni self-fluxing + Carbide mixes
Höganäs offers a wide range of Surfit powder mixes with Ni self-fluxing (SF) alloys and tungsten carbides.
With a broad portfolio of Ni self-fluxing alloys in combination with different tungsten carbides, we tailor mixes to meet the application requirements.
- Ni self-fluxing alloys
- Amperweld® Tungsten carbides
- Amperweld CTC - Cast Tungsten Carbides
- Amperweld SCTC - Spherical Cast tungsten carbide
- Amperweld MTC - Macroline Tungsten Carbide
- Amperit® Tungsten carbide cobalt
- Amperit 519 WC-Co 88-12
- Amperit 526 WC-Co 83-17
Please contact your local Höganäs sales representative to find a matching Surfit mix for your application.
Particle size: -
Chemistry: -
Powder type: Blended
Typical deposition techniques: Flame spraying, HVOF, laser cladding, plasma transferred arc (PTA), powder welding
Amperweld® hard phase powders
Amperweld CTC | C 4% | 150/53 µm
Particle size: 150/53 µm
Chemistry: C 4%
Powder type: -
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Amperweld CTC | C 4% | 106/36 µm
Particle size: 106/36 µm
Chemistry: C 4%
Powder type: -
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Amperweld SCTC | C 4% | 150/53 µm
Particle size: 150/53 µm
Chemistry: C 4%
Powder type: -
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Amperweld MTC | C 4.3% – 5.2% | 150/53 µm
Particle size: 150/53 µm
Chemistry: C 4.3% – 5.2% (depending on particle size)
Powder type: -
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Amperweld MTC | C 4.3% – 5.2% | 180/53 µm
Particle size: 180/53 µm
Chemistry: C 4.3% – 5.2% (depending on particle size)
Powder type: -
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Amperweld VC | 160/63 µm
Particle size: 160/63 µm
Chemistry: -
Powder type: -
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Amperweld VC | 90/45 µm
Particle size: 90/45 µm
Chemistry: -
Powder type: -
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Amperweld VC | 45/5 µm
Particle size: 45/5 µm
Chemistry: -
Powder type: -
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Amperweld TiC | 200/106 to 45/5 µm
Particle size: 200/160 to 45/5 µm
Chemistry: -
Powder type: -
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Amperweld CrB | 400/63 µm
Particle size: 400/63 µm
Chemistry: -
Powder type: -
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Amperweld CrB2 | 400/63 µm
Particle size: 400/63 µm
Chemistry: -
Powder type: -
Typical deposition techniques: Laser cladding, plasma transferred arc (PTA)
Remarks:
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Surfit® hard phase powders
Surfit Ni self-fluxing + Carbide mixes
Höganäs offers a wide range of Surfit powder mixes with Ni self-fluxing (SF) alloys and tungsten carbides.
With a broad portfolio of Ni self-fluxing alloys in combination with different tungsten carbides, we tailor mixes to meet the application requirements.
- Ni self-fluxing alloys
- Amperweld® Tungsten carbides
- Amperweld CTC - Cast Tungsten Carbides
- Amperweld SCTC - Spherical Cast tungsten carbide
- Amperweld MTC - Macroline Tungsten Carbide
- Amperit® Tungsten carbide cobalt
- Amperit 519 WC-Co 88-12
- Amperit 526 WC-Co 83-17
Please contact your local Höganäs sales representative to find a matching Surfit mix for your application.
Particle size: -
Chemistry: -
Powder type: Blended
Typical deposition techniques: Flame spraying, HVOF, laser cladding, plasma transferred arc (PTA), powder welding
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