SIST EN ISO 12679:2016

2003-01.Slovenski inštitut za standardizacijo. Razmnoževanje celote ali delov tega standarda ni dovoljeno.Thermisches Spritzen - Empfehlungen für das thermische Spritzen (ISO 12679:2011)Projection thermique - Recommandations pour la projection thermique (ISO 12679:2011)Thermal spraying - Recommendations for thermal spraying (ISO 12679:2011)25.220.20Površinska obdelavaSurface treatmentICS:Ta slovenski standard je istoveten z:FprEN ISO 12679kSIST FprEN ISO 12679:2015en,fr,de01-junij-2015kSIST FprEN ISO 12679:2015SLOVENSKI
STANDARD



kSIST FprEN ISO 12679:2015



EUROPEAN STANDARD NORME EUROPÉENNE EUROPÄISCHE NORM
FINAL DRAFT
FprEN ISO 12679
March 2015 ICS
Will supersede EN 14616:2004English Version
Thermal spraying - Recommendations for thermal spraying (ISO 12679:2011)
Projection thermique - Recommandations pour la projection thermique (ISO 12679:2011)
Thermisches Spritzen - Empfehlungen für das thermische Spritzen (ISO 12679:2011) This draft European Standard is submitted to CEN members for unique acceptance procedure. It has been drawn up by the Technical Committee CEN/TC 240.
If this draft becomes a European Standard, CEN members are bound to comply with the CEN/CENELEC Internal Regulations which stipulate the conditions for giving this European Standard the status of a national standard without any alteration.
This draft European Standard was established by CEN in three official versions (English, French, German). A version in any other language made by translation under the responsibility of a CEN member into its own language and notified to the CEN-CENELEC Management Centre has the same status as the official versions.
CEN members are the national standards bodies of Austria, Belgium, Bulgaria, Croatia, Cyprus, Czech Republic, Denmark, Estonia, Finland, Former Yugoslav Republic of Macedonia, France, Germany, Greece, Hungary, Iceland, Ireland, Italy, Latvia, Lithuania, Luxembourg, Malta, Netherlands, Norway, Poland, Portugal, Romania, Slovakia, Slovenia, Spain, Sweden, Switzerland, Turkey and United Kingdom.
Recipients of this draft are invited to submit, with their comments, notification of any relevant patent rights of which they are aware and to provide supporting documentation.
Warning : This document is not a European Standard. It is distributed for review and comments. It is subject to change without notice and shall not be referred to as a European Standard.
EUROPEAN COMMITTEE FOR STANDARDIZATION
COMITÉ EUROPÉEN DE NORMALISATION EUROPÄISCHES KOMITEE FÜR NORMUNG
CEN-CENELEC Management Centre:
Avenue Marnix 17,
B-1000 Brussels © 2015 CEN All rights of exploitation in any form and by any means reserved worldwide for CEN national Members. Ref. No. FprEN ISO 12679:2015 EkSIST FprEN ISO 12679:2015



FprEN ISO 12679:2015 (E) 2 Contents Page Foreword .3 kSIST FprEN ISO 12679:2015



FprEN ISO 12679:2015 (E) 3 Foreword The text of ISO 12679:2011 has been prepared by Technical Committee ISO/TC 107 “Metallic and other inorganic coatings” of the International Organization for Standardization (ISO) and has been taken over as FprEN ISO 12679:2015 by Technical Committee CEN/TC 240 “Thermal spraying and thermally sprayed coatings” the secretariat of which is held by DIN. This document is currently submitted to the Unique Acceptance Procedure. This document will supersede EN 14616:2004. Endorsement notice The text of ISO 12679:2011 has been approved by CEN as FprEN ISO 12679:2015 without any modification. kSIST FprEN ISO 12679:2015



kSIST FprEN ISO 12679:2015



qhermal spraying — oecommendations for thermal sprayingmrojection thermique — oecommandations pour la projection thermique© fpl ljkkoeference numberfpl klpqstljkkbbccirst editionljkk-js-kofplklpq9fkqbokAqflkAi pqAkaAoakSIST FprEN ISO 12679:2015



fpl klpq9:lMkkbbc Clmvofdeq molqbCqba alCrMbkq© fpl ljkkAll rights reserved. rnless otherwise specii�edf no part of this publication may be reproduced or utilized in any form or by any meansf electronic or mechanicalf including photocopying and microi�lmf without permission in writing from either fpl at the address below or fpl’s member body in the country of the requester.fpl copyright ofi�ceCase postale op • Ce-klkk deneva ljqel. e 4k ll q4s jk kkcax e 4k ll q4s js 4qb-mail copyrightziso.orgteb www.iso.orgmublished in pwitzerlandii © fpl ljkk – All rights reservedkSIST FprEN ISO 12679:2015



fpl klpq9:lMkkbbc Contents magecoreword .ivfntroduction .vk pcope .kl kormative references .km qerms and dei�nitions .ln marent material .lo Component geometry .mp ppray materials .mp.k deneral .mp.l pelection of spray materials .mp.m pupplyf handling and storage .nq dases for spraying .nr iiquid fuels for spraying .o9 ppray equipment .o9.k deneral .o9.l ppray device .o9.m Mechanical equipmentf rotating devicesf handling systemsf robots .o9.n bssential auxiliary equipment .okM purface preparation prior to spraying .pkM.k deneral .pkM.l deneral pretreatmentsf degreasingf cleaning .pkM.m drit-blasting and other preparation methods .pkM.n Coveringf masking of areas not to be coated .qkk qhermal spraying procedure .qkk.k ppraying procedure specii�cation .qkk.l Applying the spraying process .rkl most-treatment of the coating .9km eealthf safety and environmental aspects .kMkn oecommendations for quality assurance .kMkn.k nuality-assurance measures .kMkn.l mersonnel qualii�cation .klko qesting of components and accompanying specimens .klko.k deneral .klko.l qests on the component itself .klBibliography .kn© fpl ljkk – All rights reserved iiikSIST FprEN ISO 12679:2015



corewordfpl bthe fnternational lrganization for ptandardizationc is a worldwide federation of national standards bodies bfpl member bodiesc. qhe work of preparing fnternational ptandards is normally carried out through fpl technical committees. bach member body interested in a subject for which a technical committee has been established has the right to be represented on that committee. fnternational organizationsf governmental and non-governmentalf in liaison with fplf also take part in the work. fpl collaborates closely with the fnternational blectrotechnical Commission bfbCc on all matters of electrotechnical standardization.fnternational ptandards are drafted in accordance with the rules given in the fplifbC airectivesf mart l.qhe main task of technical committees is to prepare fnternational ptandards. araft fnternational ptandards adopted by the technical committees are circulated to the member bodies for voting. mublication as an fnternational ptandard requires approval by at least qo B of the member bodies casting a vote.Attention is drawn to the possibility that some of the elements of this document may be the subject of patent rights. fpl shall not be held responsible for identifying any or all such patent rights.fpl klpqs was prepared by qechnical Committee fpliqC kjqf jetallic and other inorganic coatings.fpl klpq9:lMkkbbc iv © fpl ljkk – All rights reservedkSIST FprEN ISO 12679:2015



fntroductionqhermal spraying encompasses processes used in the production of coatings and free-standing bodies for which spray materials are surface-meltedf melted off or melted and then propelled onto suitably prepared workpiece surfaces. qhe workpiece surfaces are not surface-melted. fn order to achieve specii�c coating propertiesf the spray coating can undergo additional post-treatmentf either thermal or otherwisef for examplef sealing.qhermally sprayed coatings serve to improve the surface properties of a workpiece by manufacturing or repair operations. qhis can be donef for examplef in relation to wearf corrosionf heat transfer or heat insulationf electrical conductivity or insulationf appearance andior for restoring the part to working order. fn certain casesf a spray coating can render a surface solderable.Chiel�y due to their bonding mechanismf thermally sprayed coatings without thermal post-treatment can be distinguished from coatings applied with other processesf such as deposition weldingf brazingf physical vapour deposition bmsac or chemical vapour deposition bCsac.qhe advantages of thermal spraying are the following.— qhe workpieces to be coated are only slightly heated so that distortion and any other undesired structural changes to the parent material are avoided. qhis does not apply if the coatings are thermally treated during or after the spraying process.— qhe application is not dependent on the size of the workpiece or component. qhe operation can be stationary or mobile depending on the spraying process.— bven geometrically complex components can be coated using the appropriate spray set-up.— qhe untreated surface of spray coatings generally provides a good bond coat for painting.— aepending on the spraying process and spray materialf different coating thicknesses can be appliedf although a coating thickness of approximately kj µm is currently considered to be the lower limit.mrocess-related disadvantages are as followst— the bond strength of thermally sprayed coatings without thermal post-treatment derives from adhesive forces only;— the bond strength can be inl�uenced due to an expansion mismatch between the coating and substrate materialf especially in the case of a high operation temperature;— spray coatings are micro-porous;— the thicker the spray coatingf the higher the residual stresses in the coatingf and the degree of multi-axial stress thus increases;— spray coatings without additional thermal post-treatment are sensitive to edge pressuref localized and linear loads and to impact stresses;— there are restrictions in relation to the geometric dimensionsf for examplef for the inner coatings of workpieces whose inner diameter is too small.fpl klpq9:lMkkbbc © fpl ljkk – All rights reserved vkSIST FprEN ISO 12679:2015



kSIST FprEN ISO 12679:2015



fkqbokAqflkAi pqAkaAoa fpl klpq9:lMkkbbcqhermal spraying — oecommendations for thermal sprayingk pcopeqhis fnternational ptandard includes general guidelines for the workmanlike production of metallicf metal-ceramicf oxide-ceramic and plastic coatingsf by means of thermal spraying on metallic and non-metallic parent materials.qhis fnternational ptandard provides recommendations for an appropriate and practical spray set-upf faultless manufacturingf monitoringf quality assurance and for non-destructive and destructive tests on the component and accompanying specimen. ft describes details about negative effects which can occur. ft also gives advice on how to prevent such effects.mermissible coating loads and evaluation categories for quality are not the subject of this fnternational ptandardf as they are dependent on the operating conditions.qhis fnternational ptandard can be used for contract purposes.l kormative referencesqhe following referenced documents are indispensable for the application of this document. cor dated referencesf only the edition cited applies. cor undated referencesf the latest edition of the referenced document bincluding any amendmentsc applies.fpl m4ol-kf kon-destructive testing — menetrant testing — mart kt deneral principlesfpl k4lmkf qhermal spraying — Acceptance inspection of thermal spraying equipmentfpl k4lmlf qhermal spraying — mowders — Composition and technical supply conditionsfpl k4skrf qhermal spraying — Approval testing of thermal sprayersfpl k4sksf qhermal spraying — tiresf rods and cords for l�ame and arc spraying — Classii�cation — qechnical supply conditionsfpl k4sljf qhermal spraying — ppraying and fusing of self-l�uxing alloysfpl k4slkf qhermal spraying — mrocedures for the application of thermally sprayed coatings for engineering componentsfpl k4sll-kf qhermal spraying — nuality requirements of thermally sprayed structures — mart kt duidance for selection and usefpl k4sll-lf qhermal spraying — nuality requirements of thermally sprayed structures — mart lt Comprehensive quality requirementsfpl k4sll-mf qhermal spraying — nuality requirements of thermally sprayed structures — mart mt ptandard quality requirementsfpl k4sll-4f qhermal spraying — nuality requirements of thermally sprayed structures — mart nt blementary quality requirementsfpl k4slmf qhermal spraying — Characterization and testing of thermally sprayed coatingsfpl k4sl4f qhermal spraying — most-treatment and i�nishing of thermally sprayed coatings © fpl ljkk – All rights reserved kkSIST FprEN ISO 12679:2015



m qerms and dei�nitionscor the purposes of this documentf the following terms and dei�nitions apply.m.kshot-peening effectpressure strengthening by grit-blastingm.lsound pressure levelmean value of emitted soundklqb pound pressure level is measured in decibels bdBc.m.metchingremoving of surface materialklqb btching can be applied using liquid agents bwet chemical etchingc or using gases in a recipient bdry etchingf plasma etchingc. qhe etching agent reacts chemically with the substrate.m.nion-etchingmaterial removed by shooting the surface with high-energetic particles like ionsklqb qhe ions cut off material at the impact point. qhe procedure is used in plasma technology application bvacuum coating technologyc.m.ocorona dischargedielectric discharge in air after exceeding the break-down i�eld intensity; air molecules will be ionized by generating short-living ozonen marent materialsirtually every kind of solid-state material can be coated by means of thermal sprayingf provided its surface is suitably prepared. qhe achievable bond strength of the coating to the substrate is dependent on the spray materialf spraying process and the physical and technological properties of the parent material used. qhe bond strengthf amongst other thingsf is particularly inl�uenced by the thermal conductivity of the parent material in comparison to the conductivity of the spray coating and the state of the parent material’s surface. fn generalf hardened materials need a bond coat to give adequate bond strength. qhe possible coating thickness may be limitedf depending on the bonding material being used. Certain surface-hardening processesf e.g. “nitriding”f may leave gaseous inclusions which would prevent proper bonding.A variety of plasticsf as well as glass and paperf can be thermally sprayed when using the appropriate spraying process and a surface treatment method adapted for the respective material.As the workpieces to be coated by means of thermal spraying are generally only slightly heatedf undesired structural changes to the parent material and changes to the component’s geometry due to distortion are avoided to the greatest possible extent. eoweverf distortions resulting from intensive grit-blasting during surface preparationf especially with thin-walled parts or as a result of residual compressive stresses on the surface of the substrate caused by process-related shot-peening effectsf can occur. ff coatings are thermally treated during spraying bprocesses with simultaneous fusingc or subsequentlyf undesired structural changes and signii�cant geometric changes can occur.cor purposes of quality assurance during the manufacturing processf the parent materials and components to be coated should be stored in such a way that damage andior undesired changes to the shape or surface are avoided.fpl klpq9:lMkkbbc l © fpl ljkk – All rights reservedkSIST FprEN ISO 12679:2015



o Component geometryqhe application of thermal spraying is independentf to the greatest possible extentf of the size of the workpiece or component to be coated. qhis is mainly true for l�ame and arc spraying. cor plasma and eslc bhigh-velocity oxygen fuelc sprayingf closed-off spray booths are normally required due to the high noise and dust emissions. As a resultf there may be restrictions to size of the component.Certain prerequisites concerning the practical set-up shall be considered when using thermal spraying. ff these rules are followedf even complex geometric parts can be coated with expertise. qhe most important rules can be summarized as followst— the area to be coated shall be accessible to the spray gun with all its electrical andior gas connectionsf and the necessary spray distance and spray angle shall be maintained;— sharp edges should be avoided; they cannot be covered with a spray coating;— narrow radii should be avoidedf otherwise turbulence in the spray jet can occurf which can lead to unsatisfactory coatings in terms of bond strength and density;— problems with turbulence and undesiredf loose particles sticking to the walls occur especially when spraying in narrow bores or blind holes;— to prevent the coating from spallingf it has proved advantageous to pull the coating around rounded or chamfered edges;— the arguments listed for thermal sprayingf i.e. accessibilityf sharp edgesf narrow radiif bores and blind holesf also apply to grit-blasting when preparing the surface to be sprayed.p ppray materialsp.k deneralqhe spray materials used for thermal spraying cover a wide range of very different materials. ft is virtually possible to spray any material which can be produced as a solid wiref cored wiref rodf cord or powderf and which does not sublimate in the arc or plasma or decompose when passing through the l�ame. fn the special case of molten-bath sprayingf the material is processed in its liquid state.denerallyf the following spray materials can be used for thermal sprayingt— metals and metal alloys;— metal ceramics;— hard phases embedded in a matrix material;— oxide ceramicsf plasticsf as well as various hybrid materials.p.l pelection of spray materialsAn important task for the designer andior person responsible for the spray technology is the selection of the spray material which is most suited to the application. cundamental to the selection are the demand’s proi�le of the coatingf the subsequent operating conditions and the most suitable spraying process. Corrosion andior wear loadsf for examplef can determine the demand’s proi�le. qhe operating conditions in a tribological system can be determined by an increased operating temperature or by operating temperatures which l�uctuate in level andf in some casesf also in speed. qhe most suitable spraying process distinguishes itself in terms of its ability to fuli�l coating requirementsf such as densityf bond strengthf porosityf purityf etc. eeref the relevant process dataf such as temperature level in the l�amef in the arc or in the plasmaf the dwell time of the spray particles in the hot zone and the particle velocity in l�ight and on impact on the substratef play a decisive role.fpl klpq9:lMkkbbc © fpl ljkk – All rights reserved mkSIST FprEN ISO 12679:2015



qhe most important spray materials have been standardized. qhe following are specii�ed in standardst chemical composition of the material and its supply form as powder with its special features based on the manufacturing processf particle shape and particle size distributionf or as wiref rod or cord.qhe following fnternational ptandards applyt— for powdert fpl k4lml;— for wiresf rods and cordst fpl k4sks.p.m pupplyf handling and storageqhe supply form and its constancy from batch to batchf especially with spray powdersf plays a fundamental role in ensuring a uniform quality for the i�nished coating. cor this reasonf it is recommended that manufacturingf supply and distribution be assessed and monitored by a suitable quality-management system. aetails concerning such a procedure are described in bk kljq4.q dases for sprayingfndustrial gases are used in all thermal spraying processes. aepending on the spraying processf these gases or their mixtures are employed as a fuelf combustion acceleratorf plasma gasf shroud gasf propelling or atomizing gasf powder-feed gasf or for cooling the part to be coated or even the spray gun.qhe physical and chemical characteristics of the industrial gases used for thermal spraying differ quite markedly from each other. maying attention to these parametersf a gas or gas mixturef which fuli�ls the process and material requirementsf can be selected for any thermal spray application.qhe following gases are mainly usedt— as a fuel gast acetylene bClelcf propane bCmercf propylene bCmepcf ethene bCle4cf hydrogen belcf natural gas;— as a plasma gast argon bArcf helium beecf hydrogen belcf nitrogen bklc and their mixtures;— as a combustion acceleratort oxygen bllc;— as a shroud gast argon bArcf nitrogen bklc;— as a propelling or atomizing gast compressed airf nitrogen bklcf argon bArc;— as a powder-feed gast argon bArcf nitrogen bklc;— for coolingt compressed airf carbon dioxide bCllc.aepending on the spraying process and the purpose of the applicationf varying high-purity levels are demanded of the gases. qhe gas producer is responsible for the gas purity whose level shall then be maintained at the user’s premises during the i�lling processf transport and withdrawalf and in the pipeline system.fn generalf it is sufi�cient to indicate the purity of the gases used in thermal spraying with numerical values according to the number of “nines” before and after the point b4fp = ssfssp Bc. qypical gas purities for thermal spraying aret—bthenemfo—lxygenmfo—eydrogenmfj—kitrogen4fp—Argon4fp—eelium4fpfpl klpq9:lMkkbbc n © fpl ljkk – All rights reservedkSIST FprEN ISO 12679:2015



cor plasma spraying in particularf the purity of the gases has a big inl�uence on the lifetime of the nozzle electrode system.r iiquid fuels for sprayingfn several applicationsf the high-velocity l�ame spraying process is applied using liquid fuelsf e.g. kerosenef k-parafi�nf test benzene or petroleum. A low sulfur content has to be kept due to environmental reasons. clash pointf evaporation point and purity have to be consideredf as well as additional instructions from the equipment supplier.9 ppray equipment9.k deneralqhe thermal spray equipment includes the spray device with all the electrical and gas supply and regulating equipmentf possibly the handling systemf plus the peripheral installations such as exhaust and i�lter systemsf spray booth and soundprooi�ng. jodern installations often include additional equipment for monitoring spray parameters and motion sequences by means of video cameras.9.l ppray deviceqhe spray device is dei�ned in fpl k4skq as the equipment required for thermal spraying.duidelines can be found in fpl k4lmk for the qualii�cation of the spraying installation including the transport system for the spray material. fpl k4lmk can also be consulted when monitoring the state of the thermal spraying installation.9.m Mechanical equipmentf rotating devicesf handling systemsf robotsfn addition to the spray parameters for melting and melting off and for the transport of the spray materialf the distancef setting angle and relative motion between the gun and workpiece have a decisive inl�uence on the quality of the spray coating. fn order to maintain these parameters as closely as possiblef a mechanized spraying process should be used wherever possible rather than a manual one.A handling system should fuli�l the following requirementst— capable of movementsf speed and positioning with accuracy values appropriate to the application;— sufi�cient static and dynamic loading capacity;— stabilization of spray distance;— non-susceptibility of control and regulation systems to inl�uences from spray operationf for examplef when igniting the plasma burnerf and in relation to spray dust and heat from the l�amef arc or plasma jet;— simple and straightforward setting and programming of the handling system or rotating device.9.n bssential auxiliary equipmentAuxiliary equipment essential for thermal spraying includes equipment for cooling the burner system and possibly the energy supplyf toof for cooling the workpiece andior the coatingf for detectingf removing by suction and transporting the spray dustf collecting the spray dust in a suitable i�lter system whichf at the same timef releases the exhaust air mixed with the combustion or plasma gas residue into the atmospheref safely and in compliance with environmental regulations. qhe spray booth and sound-proof chamber are also essential components of the auxiliary equipment.qhe peripheral equipmentf especially for detecting and removing the spray dustf can also inl�uence the quality of the spray coating by acting upon the spray jet and the safe discharge of rebounded spray particles. cor this reasonf this equipment should always be kept in good working order.fpl klpq9:lMkkbbc © fpl ljkk – All rights reserved okSIST FprEN ISO 12679:2015



bvery spraying process produces a typical sound pressure level. auring plasma processes and the various eslc processesf the A-weighted sound pressure level can reach values of more than klo dBbAcf making sound-prooi�ng measures with a considerable sound pressure level reduction potential necessary. As a rulef dust build-up generally occurs in addition to the sound pressure levels; spray booths should offer good sound absorptioniinsulation and also be able to prevent dust deposits as far as possible. As these conditions contradict each other to a certain extentf priorities shall be set concerning the design. cor mechanized sprayingf non-absorbingf smooth walls can be used. cor manual sprayingf sound-absorbingf open-pored inner walls and ceilings are to be preferred.auring the spraying processf particle-loaded smoke and gas currents result from the spray materialsf gases and ambient ai
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