Thermal spraying — Powders — Part 2: Comparison of coating performance and spray powder chemistry

ISO/TR 14232-2:2017 gives guidelines for selecting the powder chemistry or composition for obtaining an objective coating performance. It provides comparisons of coating performance for wear resistance (Table 1) and corrosion resistance (Table 2) to spray powder chemistry/composition. The wear types shown in Table 1 are abrasive, adhesive, chemical, erosion, fretting, impact, rolling and sliding. The corrosion types shown in Table 2 are acid/alkaline/salt, atmospheric, biochemical, biological, chemical agent, chemicals in food, combustion gas, sea water, fresh water, molten metal, molten salt, non-aqueous solution, soil, steam and miscellaneous. The tables give the coating chemistries and describe the composition of spray powder of metals/alloys, ceramics and cermets. The guidelines have been produced on the basis of academic literature, in particular the Journal of Thermal Spray Technology and the Proceedings of the International Thermal Spray Conference.

Projection thermique — Poudres — Partie 2: Comparaison de enduire performance et poudre chimie

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TECHNICAL ISO/TR
REPORT 14232-2
First edition
2017-07
Thermal spraying — Powders —
Part 2:
Comparison of coating performance
and spray powder chemistry
Projection thermique — Poudres —
Partie 2: Comparaison de enduire performance et poudre chimie
Reference number
ISO/TR 14232-2:2017(E)
©
ISO 2017

---------------------- Page: 1 ----------------------
ISO/TR 14232-2:2017(E)

COPYRIGHT PROTECTED DOCUMENT
© ISO 2017, Published in Switzerland
All rights reserved. Unless otherwise specified, no part of this publication may be reproduced or utilized otherwise in any form
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ii © ISO 2017 – All rights reserved

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ISO/TR 14232-2:2017(E)

Contents Page
Foreword .iv
Introduction .v
1 Scope . 1
2 Normative references . 1
3 Terms and definitions . 1
4 Comparison table of wear resistance and spray powder chemistry .1
5 Comparison table of corrosion resistance and spray powder chemistry .4
Bibliography .10
© ISO 2017 – All rights reserved iii

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ISO/TR 14232-2:2017(E)

Foreword
ISO (the International Organization for Standardization) is a worldwide federation of national standards
bodies (ISO member bodies). The work of preparing International Standards is normally carried out
through ISO technical committees. Each member body interested in a subject for which a technical
committee has been established has the right to be represented on that committee. International
organizations, governmental and non-governmental, in liaison with ISO, also take part in the work.
ISO collaborates closely with the International Electrotechnical Commission (IEC) on all matters of
electrotechnical standardization.
The procedures used to develop this document and those intended for its further maintenance are
described in the ISO/IEC Directives, Part 1. In particular the different approval criteria needed for the
different types of ISO documents should be noted. This document was drafted in accordance with the
editorial rules of the ISO/IEC Directives, Part 2 (see www .iso .org/ directives).
Attention is drawn to the possibility that some of the elements of this document may be the subject of
patent rights. ISO shall not be held responsible for identifying any or all such patent rights. Details of
any patent rights identified during the development of the document will be in the Introduction and/or
on the ISO list of patent declarations received (see www .iso .org/ patents).
Any trade name used in this document is information given for the convenience of users and does not
constitute an endorsement.
For an explanation on the voluntary nature of standards, the meaning of ISO specific terms and
expressions related to conformity assessment, as well as information about ISO’s adherence to the
World Trade Organization (WTO) principles in the Technical Barriers to Trade (TBT) see the following
URL: w w w . i s o .org/ iso/ foreword .html.
This document was prepared by Technical Committee ISO/TC 107, Metallic and other inorganic coatings.
This first edition of ISO 14232-2, together with ISO 14232-1:2017, cancels and replaces ISO 14232:2000,
which has been technically revised.
A list of all parts in the ISO 14232 series can be found on the ISO website.
iv © ISO 2017 – All rights reserved

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ISO/TR 14232-2:2017(E)

Introduction
The performance of a sprayed coating is one of the major factors for its industrial application. However,
the chemical composition or chemistry of the sprayed powder is not always the key information for the
actual coating application. Understanding the relationship between the chemical composition/chemistry
of the sprayed powder and the resulting coating performance allows for the most effective selection of
powder to obtain the required coating performance.
This document provides technical information describing the comparison of spray powder chemistry
and coating performance. Spray coating performances are extremely diverse. This document examines
the performances of wear resistance and corrosion resistance. Other performance categories are in
preparation.
The ISO 14232 series consists of two parts. ISO 14232-1 examines the characterization of spray powders.
This document is a technical report that examines how technical literature describes the application of
powders.
© ISO 2017 – All rights reserved v

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TECHNICAL REPORT ISO/TR 14232-2:2017(E)
Thermal spraying — Powders —
Part 2:
Comparison of coating performance and spray powder
chemistry
1 Scope
This document gives guidelines for selecting the powder chemistry or composition for obtaining an
objective coating performance.
It provides comparisons of coating performance for wear resistance (Table 1) and corrosion resistance
(Table 2) to spray powder chemistry/composition. The wear types shown in Table 1 are abrasive,
adhesive, chemical, erosion, fretting, impact, rolling and sliding. The corrosion types shown in
Table 2 are acid/alkaline/salt, atmospheric, biochemical, biological, chemical agent, chemicals in food,
combustion gas, sea water, fresh water, molten metal, molten salt, non-aqueous solution, soil, steam and
miscellaneous. The tables give the coating chemistries and describe the composition of spray powder
of metals/alloys, ceramics and cermets. The guidelines have been produced on the basis of academic
literature, in particular the Journal of Thermal Spray Technology and the Proceedings of the International
Thermal Spray Conference.
2 Normative references
There are no normative references in this document.
3 Terms and definitions
No terms and definitions are listed in this document.
ISO and IEC maintain terminological databases for use in standardization at the following addresses:
— IEC Electropedia: available at http:// www .electropedia .org/
— ISO Online browsing platform: available at http:// www .iso .org/ obp
4 Comparison table of wear resistance and spray powder chemistry
Table 1 — Comparison of wear resistance and spray powder chemistry
Type of
Metals Ceramics Cermet
wear
[6][8][16][74][77][80]
Al2O3
[75] [77][80]
Abrasive 316L Al2O3-Ni
[93][96]
[9] [24][64][99] [10]
 Amorphous ferrochromes Al2O3-TiO2 Al-SiC
[100] [80] [9]
Co-based self-fluxing alloy Al2O3-ZrO2 Carbide cermet
[8][54][73][74][75][93] [37][42][52][55][62][73][74]
Cr2O3 Cr3C2-NiCr
[9]
Cobalt alloys
[94][99] [75][85][99][69]
[30] [6][28][54][96] [67]
Fe-13Cr-7Ni-4B-5W-0,2C TiO2 Cr3C2-NiCr-SFA
[31] [6][54] [70]
Fe-40Al-0,05Zr ZrO2-Y2O3 FeNiAlCr-TiC-Al2O3
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ISO/TR 14232-2:2017(E)

Table 1 (continued)
Type of
Metals Ceramics Cermet
wear
[87] [92]
FeCrMoWMnBCSi Ni-based cermet
[99] [60]
FeCrNi Ni 60
[9] [99]
Fusible NiCrSiB-WC-Co
[55] [60]
Inconel 625 NiWC25
[9] [60]
Mo alloys NiWC35
[29] [57]
Ni-21Cr-8,3Mo-5Fe-1,2Nb-Ti SiC cermet
[51] [56]
NiCr TiC-SFA
[11][50][75][99][107] [74]
NiCrSiB VC-WC-CoCr
[50] [61]
Stellite 6 WC cermet
[1][3][5][11][15][17][22][37][48]
WC-Co
[42] [49][63][65][66][68][69][74][75][85][99]
Stellite-21
[101][104]
[15][42][48][49][55][58][69][73]
WC-CoCr
[74]

[84][85][99]
[69]
  WC-Ni
[34] [74][98] [97]
Adhesive Fe-0,8C Al2O3 Al2O3-Al
[34] [74][81][103] [37][74][103]
Fe-19Cr- 0,1C-1,6B Cr2O3 Cr3C2-NiCr
[88] [28] [102]
FeCrMoWMnBCSi TiO2 FeB-BN
[59]
  MoS2 cermet
[74]
  VC-WC-CoCr
[5][37][74][89]
  WC-Co
[41][74][103]
  WC-CoCr
[55] [64] [55][85]
Chemical Inconel 625 Al2O3-TiO2 Cr3C2-NiCr
[85]
  WC-Co
[41][55][85]
  WC-CoCr
[34] [94] [52][55][62][69]
Erosion Fe-0,8C Cr2O3 Cr3C2-NiCr
[34] [28] [67]
Fe-19Cr-0,1C-1,6B TiO2 Cr3C2-NiCr-SFA
[31] [4] [70]
Fe-40Al-0,05Zr ZrO2-5CaO FeNiAlCr-TiC-Al2O3
[88] [4][18][82] [60]
FeCrMoWMnBCSi ZrO2-Y2O3 Ni60
[55] [60]
Inconel 625 NiWC25
[11] [60]
NiCrSiB NiWC35
[21] [57]
NiCrSiFeB SiC cermet
[56]
  TiC-SFA
[61]
  WC cermet
[3][4][5][11][21][22][38][49][63]
WC-Co

[69][95]
[21][49][55][58][69]
  WC-CoCr
[21]
  WC-CoFe
[69]
  WC-Ni
[91] [69]
Fretting CuNiIn Cr3C2-NiCr
[69][89]
  WC-Co
[69]
  WC-CoCr
[69]
  WC-Ni
2 © ISO 2017 – All rights reserved

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ISO/TR 14232-2:2017(E)

Table 1 (continued)
Type of
Metals Ceramics Cermet
wear
[9] [9]
Impact Amorphous ferrochromes Carbide cermet
[9] [42]
Cobalt alloys Cr3C2-NiCr
[34] [21]
Fe-0,8C WC-Co
[34] [21][42]
Fe-19Cr-0,1C-1,6B WC-CoCr
[9] [21]
Fusible WC-CoFe
[9]
Mo alloys
[21]
NiCrSiFeB
[42]
Stellite-21
[83] [61]
Rolling AlSnCuNi WC cermet
[68]
  WC-Co
[25] [16][74][98] [97]
Sliding Al-20Sn-1Cu Al2O3 Al2O3-Al
[25] [32][64][106][111] [110]
Al-20Sn-1Cu-2Ni Al2O3-TiO2 Cr3C2-CoNiCrAlY
[25] [40] [7][13][71][74][103][110]
Al-20Sn-1Cu-7Si Al2O3-ZrO2 Cr3C2-NiCr
[26] [2][13][32][74][103] [67]
Co-28Mo-17Cr-3Si Cr2O3 Cr3C2-NiCr-SFA
[90] [43] [102]
CoMoCrSi Cr2O3-TiO2 FeB-BN
[79] [18][32][78] [27]
CuWZn ZrO2-Y2O3 MoCoB-CoCr
[36] [20]
Fe-15Cr-14Mo-15C-6B-2Y Mo-FEP-Al2O3-TiO2
[31] [59]
Fe-40Al-0,05Zr MoS2 cermet
[45] [60]
FeCrB Ni60
[109] [86]
FeCrNiBC NiCrWB-50Al2O3
[35] [79]
FeCrWBMoMn Ni-TiC
[23] [60]
Mo-(Cu-10Sn)-(Al-12Si) NiWC25
[29] [60]
Ni-21Cr-8,3Mo-5Fe-1,2Nb-Ti NiWC35
[33][105] [57]
Ni-3Al SiC cermet
[33][105] [56]
NiCr TiC-SFA
[112] [7]
NiCrSiB TiC-Ti
[2] [74]
Stainless steel VC-WC-CoCr
[7] [39]
Ti WC-(W/Cr)2C-Ni
[7][12][13][14][17][19][38][39][44]
WC-Co

[46][53][63][68][72][74][76][86][110]
[12][14][19][20][32][41][44][46]
WC-CoCr

[53][58][74][103][108]
[47]
  WC-Co-NiCrSiB
[44][110]
  WC-Cr3C2-Ni
[20]
  WC-Ni
© ISO 2017 – All rights reserved 3

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ISO/TR 14232-2:2017(E)

5 Comparison table of corrosion resistance and spray powder chemistry
Table 2 — Comparison of corrosion resistance and spray powder chemistry
Type of
Environment and effects Materials Ref. no.
corrosion
Acid/alkaline/
Galvanic Al on Ni-20Cr [196]
salt
  Al2O3, Cr2O3 [129]
  Fe-based alloy [178]
  Fe-17Cr-38Mo-4C alloy [124]
  Inconel 625 [289]
  Inconel 690 [202]
  Many kinds of materials [190]
  NiCrMoB [210]
  Stainless steel [184]
  316L [183]
Ternary coating system involving
  [209]
aluminium, zinc and magnesium
Twin-wire electric arc spraying of zinc
  [188]
and aluminium coatings
Mechanical Al2O3, Cr2O3, Al2O3-ZrO2 [205]
Metallographic Al2O3-TiO2 [160], [261]
Fe-10Cr-10Mo containing a large
  amount of [121]
carbon and/or boron
  Fe-based alloy [168]
  Hastelloy C-22 [145]
  Ni-Ti composite [169]
  WC, NiCrMo [243]
  WC-Co [239]
 Mechanical Cr2O3, WC-12%Co, Ni-11%P, Al-2%Zn [123]
Uniform Al, Al+Al2O3, Al+Al2O3+Zn [174]
  Al2O3, Al2O3-Cr2O3 [295]
  Al2O3-TiO2 [270], [273]
  Al-Al2O3 [272]
  Cr3C2–20NiCr [267]
TM
  Fe-Cr-based Armacor C coating [194]
Fusible Ni-B-Si alloys with a variety of
  [191]
alloy additions (Cr, Mo, Cu, etc.)
  Inconel 625 [279]
Ni, Ni-20Cu, Ni-20Cr, Ni-20Cr+50Al2O3,
  [161]
Ni-20Cr+30WC-CoCr
  Ni-20Cr [116]
  NiCrBSi [282]
SM 8625, Inconel 625, SM8276,
  Hastelloy276, Deloro Stellite 21, Mo [294]
wire
  316L [193]
  Ta [271]
4 © ISO 2017 – All rights reserved

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ISO/TR 14232-2:2017(E)

Table 2 (continued)
Type of
Environment and effects Materials Ref. no.
corrosion
[164], [192],
  Ti
[269], [278]
  TiO2 [165]
  WC-10Co4Cr, Cr3C2–25NiCr, Sanicro28 [283]
  YSZ [167]
  Zn, Al, Zn-15Al [266]
 Galvanic Al-5%Mg [171]
  Fe-10Cr-13P-7C [127]
  Fe-based amorphous alloys [138]
  IN 625 [139]
Ni-50%Cr mixed with NbC, TaC, TiC,
  [125]
WC, Cr3C2, or VC
  Ni-based amorphous alloys [135]
NiCr, NiCrSiB, NiCrMoFeCuBSi,
  NiCrMoNb, CoNiCrMoBSi, WC-Co, [204]
CrC-NiCr
WC-Co, WC-Co-Cr, WC-NiMoCrFeCo,
WC-FeCrAl, WC-SS316L, WC-FeNiCr
  [285]
alloy, Cr3C2-NiCr, Cr3C2-NiCrMoNb,
FeCrC-Ni
 Mechanical TiO2 [149]
 Metallographic Cr3C2-NiCr [156]
  WC-CoCr [170]
Atmospheric
Galvanic Zn [119], [120]
corrosion
High
 CrC-NiCr [232]
temperature
  MCrAlY [247]
  NiCrAlY [288]
  YSZ [128]
  YSZ, CaO-SiO2-ZrO2 [122]
Environmental
 Cr3C2-NiCr [148]
embrittlement
  Cr3C2-NiCr, WC [154]
Mechanical Uniform Al2O3, CrNi-steel, CrMo-steel [224]
Metallographic Al, Zn, NiAl, NiCrBSi [233]
Uniform CrMo-steel, TiC-Ni-Ti [226]
  AlSi/Graphite, AlSi/hBN [216]
Environmental
 Zn [252]
embrittlement
 Galvanic Zn [220]
 High temperature Al, FeCrNi, FeCrNiSiB [140]
 Metallographic CrC-NiCr [228]
Ethylene methacrylic acid and ethylene
Biochemical Uniform [195]
tetrafluoroethylene
Biological Metallographic Ti [177]
© ISO 2017 – All rights reserved 5

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ISO/TR 14232-2:2017(E)

Table 2 (continued)
Type of
Environment and effects Materials Ref. no.
corrosion
High
Chemical agent Fe-Al, Incoloy 800H [213]
temperature
  In 625 [254]
Environmental
 SFA [152]
embrittlement
  SFA, In 625 [153]
Mechanical Hastelloy C276, SUS316L [115]
Chemicals in
Mechanical NiCr [219]
food
Combustion High
304, Al [245]
gas temperature
  CoNiCrAlY [114]
  Cr-based alloy [225]
Cr-Ni-2,5Mo-1Si-0,5B (55 % and 58 %
  [118]
Cr)
  Fe-Cr-Si [276]
  In 625 [254]
  MCrAlY, YSZ [131]
  MoSi [179]
  Ni-20Cr [173]
  Ni-50Cr [151], [211]
  NiAl, WC [246]
Nickel and cobalt-based self-fluxing
  alloys, iron-based amorphous alloy and [176]
chromium carbide cermet coatings
  Phosphoric acid sealed ceramic coatings [182]
  Sol-gelled 8YZ [181]
  Y2O3-ZrO2 [144]
  YSZ [180], [234]
  YSZ, NiAl [136]
Environmental
 Cr3C2NiCr [148]
embrittlement
  Cr3C2NiCr, WC [154]
  SFA [152]
  SFA, In 625 [153]
Metallographic Ni-5Al [113]
Sea water Galvanic Al [249]
  Al, Zn, ZnAl [253]
  AlSn, AlSnCu [203]
  Al-Zn [286]
  FeCrNiMo stainless steel [217]
  Inconel 625 [289]
  Inconel 690 [202]
  Many kinds of off-shore application [189]
  Ni-based 16C, Co-based Stellite 6 [207]
6 © ISO 2017 – All rights reserved

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ISO/TR 14232-2:2017(E)

Table 2 (continued)
Type of
Environment and effects Materials Ref. no.
corrosion
  NiCr+Mo, laser alloy [198]
  Stainless steel [184]
  Ti [291], [297]
TiC+NiTi, (Ti, W)C+Ni, WC-Co,
  [200]
WC-CoCr, CrC-NiCr, Inconel
  WC-Co, Inconel [215]
  WC-CoCr, NiCrSiB [201]
  Zn, Zn-Al [260]
  Zn, ZnAl, ZnSnAl, ZnMgAl, ZnCr5 [293]
  ZnAl [264]
Uniform Al [287]
  Al2O3+sealants [133]
  Al-Cu, Al-Zn, Zn [275]
  AlSi/Graphite, AlSi/hBN [216]
  Polymer [235]
  Ta, Ti [126]
  Ti [134]
  Ti [281]
  WC-CoCr [187]
  WC-CoCr/HVOF, Sealing [166]
Zn, Zn-15Al, Al, Al-5Si, Al-12Si,
Cu-7Al-0,5Fe, Cu-9Al-4Ni-4Fe-1,5Mg,
  [162]
60Cu-40Zn-0,7Sn-0,05Pb, 420 stainless
steel, 316 stainless steel
  ZnNi-Al2O3, ZnCu-Al2O3, Zn-Al-Al2O3 [284]
Environmental
 Al [130]
embrittlement
  Zn [197]
 Galvanic Al, Al+Al2O3, Al+Al2O3+Zn [292]
  WC-Co, Ni [137]
WC-Co, WC-Co-Cr, WC-NiMoCrFeCo,
WC-FeCrAl, WC-SS316L, WC-FeNiCr
  [285]
alloy, Cr3C2-NiCr, Cr3C2-NiCrMoNb,
Fe-CrC-Ni
WC-CoCr, WC-NiCr, WC-CoCrMo,
  [208]
WC-CrMoNi
  Zn, Al, Zn15Al, Al5Mg [199]
  Zn, Al [242]
  Zn [220]
High
 Al, FeCrNi, FeCrNiSiB [140]
temperature
 Mechanical PEEK [230]
  TiO2 [149]
  WC-Co, WC-CoCr, Cr2O3, NiCrSiB [212]
 Metallographic Cr3C2-NiCr [156], [228]
  WC-CoCr [251]
© ISO 2017 – All rights reserved 7

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ISO/TR 14232-2:2017(E)

Table 2 (continued)
Type of
Environment and effects Materials Ref. no.
corrosion
  WC-NiCr, CrC-NiCr, TiC-NiCr [229]
  ZnAl [132]
Metallographic 316L [238]
  316L, Hastelloy C [236]
  Al, Zn, NiAl, NiCrBSi [233]
  Fe-based [257]
  Hasrelloy C [240]
  Inconel 625 [237]
  NiCrMoNb [241]
  NiCrWBSi [143]
  316 [263]
  Ti [158]
  WC-CoCr [244]
  WC-CoCr, WC-Co [146]
 Galvanic WC-Co [227]
 Uniform NiCrMoSiB [141]
Mechanical Al2O3 [214]
  Al2O3, Cr2O3, Al2O3-Cr2O3 [206]
  NiCrMoSiB [142]
WC-CoCr, WC-NiCr, WC-CoCrMo,
 Galvanic [218]
WC-CrMoNi
High
 SUME SOL, Mo, WC-CoCr [223]
temperature
 Uniform Al2O3, CrNi-steel, CrMo-steel [224]
Environmental
 Stainless steel [147]
embrittlement
  Zn, Al [268]
Environmental
Fresh water Stainless steel wire [147]
embrittlement
Galvanic Al, Zn, ZnAl [253]
Metallographic Stainless steel [250]
Uniform Stainless steel [155]
Mechanical WC-Co, SFA, Cr2O3, Al2O3 [221]
Environmental
Zn [252]
embrittlement
Molten metal Galvanic WC-Co, WC-CoCr, MoB-CoCr [163]
Metallographic WC, Cr3C2-cermet [258]
High
Molten salt Cr3C2-NiCr [157]
temperature
Cr-Ni-2,5Mo-1Si-0,5B (55 % and 58 %
  [118]
Cr)
  Ni-20Cr [274]
  Ni-5Al, NiCrAl [262]
Nickel and cobalt-based self-fluxing
  alloys, iron-based amorphous alloy and [176]
chromium carbide cermet coatings
8 © ISO 2017 – All rights reserved

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ISO/TR 14232-2:2017(E)

Table 2 (continued)
Type of
Environment and effects Materials Ref. no.
corrosion
  NiCr [159]
  WC-Co [265]
  WC-NiCrFeSiB [255]
  YSZ, CaO-SiO2-ZrO2 [122]
Metallographic Cr [248]
Uniform Ni-20Cr [290]
 Metallographic Ni-20Cr [298]
Non-aqueous
Galvanic Al [256]
solution
High
 CaZrO3 [172]
temperature
  CoNiCrAlY [175]
  Ni-Cr, NiCrAlY [277]
Soil corrosion Mechanical Ni-based [259]
High
Steam Ni-50Cr [151]
temperature
Environmental
 Mullite/YSZ [280]
embrittlement
High
Miscellaneous FeCrAl, NiAl [296]
temperature
Mechanical Slurry erosion test [185]
  WC-(Co/Cr/Mo/Ni) erosion-corrosion [186]
Metallographic Titanium-manganese alloy [117]
Uniform Metallographic WC-CoCr [251]
© ISO 2017 – All rights reserved 9

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ISO/TR 14232-2:2017(E)

Bibliography
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coatings. JTST. 1 (2), pp. 147–152, WC-Co
[2] Usmani S., & Tandon K.N. Evaluation of thermally sprayed coatings under reciprocating
lubricated wear conditions. JTST. 1 (3), pp. 249–255, “Cr2O3, Stainless steel”
[3] Wayne S.F., & Sampath S. Structure/property relationships in sintered and thermally sprayed
WC-Co. JTST. 1 (4), pp. 307–315, WC-Co
[4] Guo D.Z., & Wang L.J. Study of fracture and erosive wear of plasma sprayed coatings. JTST. 2
(3), pp. 257–263, “ZrO2-5CaO, ZrO2-Y2O3, WC-Co”
[5] Kim  H.J., Kweon Y.G., Chang R.W. Wear and erosion behavior of plasma-sprayed WC-Co
coatings. JTST. 3 (2), pp. 169–178, WC-Co
[6] Niemi K., Vuoristo P., Mäntylä T. Properties of alumina-based coatings deposited by plasma
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[7] Mohanty M., & Smith R.W. Lightweight TiC/Ti wear-resistant coatings for lightweight
structural applications. JTST. 4 (4), pp. 384–394, “Ti, TiC-Ti, Cr3C2-NiCr, WC-Co”
[8] Leivo E.M., Vippola  M.S., Sorsa P.P.A., Vuoristo P.M.J., Mäntylä T.A. Wear and corrosion
properties of plasma sprayed AI2O3 and Cr2O3 coatings sealed by aluminum phosphates. JTST.
6 (2), pp. 205–210, Al2O3, Cr2O3
[9] Moskowitz L., & Trelewicz K. HVOF coatings for heavy-wear, high-impact applications. JTST.
6 (3), pp. 294–299, “Carbide cermet, Fusible, Cobalt alloys, Mo alloys, Amorphous ferrochromes”
[10] Ghosh K., Troczynski T., Chaklader A.C.D. Aluminum-silicon carbide coatings by plasma
spraying. JTST. 7 (1), pp. 78–86, Al-SiC
[11] Kulu P., & Halling J. Recycled hard metal-base wear-resistant composite coatings. JTST. 7 (2),
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[12] Jacobs L., Hyland M.M., De Bonte M. Comparative study of WC-cermet coatings sprayed via
the HVOF and the HVAF process. JTST. 7 (2), pp. 213–218, WC-CoCr, WC-Co
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[14] Jacobs L., Hyland M.M., De Bonte M. Study of the influence of microstructural properties
on the sliding-wear behavior of HVOF and HVAF sprayed WC-cermet coatings. JTST. 8 (1), pp.
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[15] Schwetzke R., & Kreye H. Microstructure and properties of tungsten carbide coatings sprayed
with various high-velocity oxygen fuel spray systems. JTST. 8 (3), pp. 433–439, WC-Co, WC-CoCr
[16] Saravanan P., Selvarajan V., Srivastava M.P., Rao D.S., Joshi S.V., Sundararajan G. Study
of plasma-and detonation gun-sprayed alumina coatings using Taguchi experimental design.
JTST. 9 (4), pp. 505–512, Al2O3
[17] Qiao Y., Liu Y.R., Fischer T.E. Sliding and abrasive wear resistance of thermal-sprayed WC-CO
coatings. JTST. 10 (1), pp. 118–125, WC-Co
[18] Guilemany J.M., Armada S., Miguel J.M. Evaluation of wear damage in zirconia plasma-sprayed
coatings using scanning white light interferometry. JTST. 10 (1), pp. 142–146, ZrO2-Y2O3
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[19] Savarimuthu A.C., Taber H.F., Megat I., Shadley J.R., Rybicki E.F., Cornell W.C. Sliding wear
behavior of tungsten carbide thermal spray coatings for replacement of chromium electroplate
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[20] Marple B.R., & Voyer J. Improved wear performance by the incorporation of solid lubricants
during thermal spraying. JTST. 10 (4), pp. 626–636, “WC-Ni, WC-CoCr, Mo-FEP-Al2O3-TiO2”
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[22] Dent A.H., DePalo S., Sampath S. Examination of the wear properties of HVOF sprayed
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[23] Ahn J., Hwang B., Lee S. Improvement of wear resistance of plasma-sprayed molybdenum
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nanostructured TiO2 in comparison to air plasma-sprayed conventional Al2O3-13TiO2. JTST. 14
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[25] Marrocco T., Driver L.C., Harris S.J., McCartney D.G. Microstructure and properties of
thermally sprayed Al-Sn-based alloys for plain bearing application. JTST. 15 (4), pp. 634–639,
“Al-20Sn-1Cu, Al-20Sn-1Cu-2Ni, Al-20Sn-1Cu-7Si”
[26] Bolelli G., & Usvarghi L. Heat treatment effects on the tribological performance of HVOF
sprayed Co-Mo-Cr-Si coatings. JTST. 15 (4), pp. 802–810, Co-28Mo-17Cr-3Si
[27] Hamashima K.  Application of new boride cermet coating to forming of glass sheets. JTST. 16
(1), pp. 32–33, MoCoB-CoCr
[28] Kim G.E., & Walker J . Successful application of nanostructured titanium dioxide coating for
high-pressure acid-leach application. JTST. 16 (1), pp. 34–39, nano-TiO2
[29] Guilemany J.M., Torrell M., Miguel J.R. Study of the HVOF Ni-based coatings’ corrosion
resistance applied on municipal solid-waste incinerators. JTST. 17 (2), pp. 254–262, “Ni-21Cr-
8.3Mo-5Fe-1.2Nb-Ti”
[30] He D.-Y., Fu B.-Y., Jiang J.-M, Li X.-Y Microstructure and wear performance of arc sprayed Fe-
FeB-WC coatings. JTST. 17 (5–6), pp. 757–761, “Fe-13Cr-7Ni-4B-5W-0.2C”
[31] Guilemany J.M., Cinca N., Fernández J., Sampath S. Erosion, abrasive, and friction wear
behavior of iron aluminide coatings sprayed by HVOF. JTST. 17 (5–6), pp. 762–773, Fe-40Al-0.05Zr
[32] Giolli C., Turbil M., Rizzi G., Rosso M., Scrivani A. Wear resistance improvement of small
dimension invar massive molds for CFRP components. JTST. 18 (4), pp. 652–664, “ZrO2-Y2O3,
Al2O3-13TiO2, Cr2O3, WC-CoCr”
[33] Kaur M., Singh H., Singh B., Singh B. Studies on the sliding wear performance of plasma spray
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[34] Hahn M., & Fischer A. Characterization of thermal spray coatings for cylinder running surfaces
of diesel engines. JTST. 19 (5), pp. 866–872, “Fe-0.8C, Fe-19Cr-0.1C-1.6B”
[35] Voyer J. Wear-resistant amorphous iron-based flame-sprayed coatings. JTST. 19 (5), pp. 1013–
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[36] Zhou Z., Wang L., He D.Y., Wang F.C., Liu Y.B. Microstructure and wear resistance of Fe-based
amorphous metallic coatings prepared by HVOF thermal spraying. JTST. 19 (6), pp. 1287–1293,
“Fe-15Cr-14Mo-15C-6B-2Y”
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[37] Kašparová M., Zahálka F., Houdková S. WC-Co and Cr3C2-NiCr coatings in low- and high-
stress abrasive conditions. JTST. 20 (3), pp. 412–424, “WC-Co, Cr3C2-NiCr”
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[39] Hou G., An Y., Liu G., Zhou H., Chen J., Chen Z. Effect of atmospheric plasma spraying power
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[40] Dejang N., Limpichaipanit A., Watcharapasorn A., Wirojanupatump S., Niranatlumpong
P., Jiansirisomboon S. Fabrication and properties of plasma-sprayed Al2O3/ZrO2 composite
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[41] Agüero A., Camón F., García de Blas J., del Hoyo J.C., Muelas R., Santaballa A. HVOF-
deposited WCCoCr as replacement for hard Cr in landing gear actuators. JTST. 20 (6), pp. 1292–
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ASM), pp. 679–684, “WC-Co, WC-CoCr, WC-Cr3C2-Ni”
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