EP0458018A2 - Procédé et dispositif de pulvérisation par flamme à haute vitesse de matériau d'apport réfractaire sous forme de poudre ou de fil pour le revêtement de surfaces - Google Patents

Procédé et dispositif de pulvérisation par flamme à haute vitesse de matériau d'apport réfractaire sous forme de poudre ou de fil pour le revêtement de surfaces Download PDF

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Publication number
EP0458018A2
EP0458018A2 EP91103273A EP91103273A EP0458018A2 EP 0458018 A2 EP0458018 A2 EP 0458018A2 EP 91103273 A EP91103273 A EP 91103273A EP 91103273 A EP91103273 A EP 91103273A EP 0458018 A2 EP0458018 A2 EP 0458018A2
Authority
EP
European Patent Office
Prior art keywords
gas
primary
combustion chamber
injector
channels
Prior art date
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
Granted
Application number
EP91103273A
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German (de)
English (en)
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EP0458018A3 (en
EP0458018B1 (fr
Inventor
Erwin Dieter Hühne
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UTP Schweissmaterial GmbH and Co KG
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UTP Schweissmaterial GmbH and Co KG
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Priority to AT9191103273T priority Critical patent/ATE105596T1/de
Publication of EP0458018A2 publication Critical patent/EP0458018A2/fr
Publication of EP0458018A3 publication Critical patent/EP0458018A3/de
Application granted granted Critical
Publication of EP0458018B1 publication Critical patent/EP0458018B1/fr
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    • BPERFORMING OPERATIONS; TRANSPORTING
    • B05SPRAYING OR ATOMISING IN GENERAL; APPLYING FLUENT MATERIALS TO SURFACES, IN GENERAL
    • B05BSPRAYING APPARATUS; ATOMISING APPARATUS; NOZZLES
    • B05B7/00Spraying apparatus for discharge of liquids or other fluent materials from two or more sources, e.g. of liquid and air, of powder and gas
    • B05B7/16Spraying apparatus for discharge of liquids or other fluent materials from two or more sources, e.g. of liquid and air, of powder and gas incorporating means for heating or cooling the material to be sprayed
    • B05B7/20Spraying apparatus for discharge of liquids or other fluent materials from two or more sources, e.g. of liquid and air, of powder and gas incorporating means for heating or cooling the material to be sprayed by flame or combustion
    • B05B7/201Spraying apparatus for discharge of liquids or other fluent materials from two or more sources, e.g. of liquid and air, of powder and gas incorporating means for heating or cooling the material to be sprayed by flame or combustion downstream of the nozzle
    • CCHEMISTRY; METALLURGY
    • C23COATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; CHEMICAL SURFACE TREATMENT; DIFFUSION TREATMENT OF METALLIC MATERIAL; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL; INHIBITING CORROSION OF METALLIC MATERIAL OR INCRUSTATION IN GENERAL
    • C23CCOATING METALLIC MATERIAL; COATING MATERIAL WITH METALLIC MATERIAL; SURFACE TREATMENT OF METALLIC MATERIAL BY DIFFUSION INTO THE SURFACE, BY CHEMICAL CONVERSION OR SUBSTITUTION; COATING BY VACUUM EVAPORATION, BY SPUTTERING, BY ION IMPLANTATION OR BY CHEMICAL VAPOUR DEPOSITION, IN GENERAL
    • C23C4/00Coating by spraying the coating material in the molten state, e.g. by flame, plasma or electric discharge
    • C23C4/12Coating by spraying the coating material in the molten state, e.g. by flame, plasma or electric discharge characterised by the method of spraying

Definitions

  • the invention relates to a method and an apparatus for high-speed flame spraying of high-melting wire and powder-form filler materials for coating surfaces, in which an all-gas high-speed flame spray gun is used to coat the surfaces with any high-melting wire or powder-form spray filler materials.
  • Two or more gas mixing systems that work independently of one another and can work with different fuel gas-oxygen mixtures are integrated in the device.
  • DE-PS 81 18 99 proposes a device for spraying metallic and non-metallic materials, which can be regarded as the basic principle for high-speed spraying using fuel gas and oxygen.
  • the device is essentially a system consisting of a combustion chamber and an expansion nozzle, with which wire, powder or molten spray additive materials can be sprayed using hydrogen as the main detonating gas.
  • the proposed device therefore only works with one heating or propellant gas, predominantly hydrogen, which is introduced into the combustion chamber according to the compressed gas principle.
  • the ignition of hydrogen is carried out manually according to DE-PS 81 18 99, when exiting the expansion nozzle, electrically by short circuit or by an electric arc.
  • the ignition of hydrogen can take place through the molten heated spray additive, which is brought together through the combustion chamber via an access with the oxyhydrogen gas.
  • the fuel gas according to DE-PS 81 18 99 this is hydrogen, is led into the combustion chamber according to the compressed gas principle, which no longer meets the legal design requirements for oxy-fuel burners and also does not comply with the accident prevention regulation UVV-VGB 15.
  • hydrogen has no additional oxidizing gas, e.g. As oxygen, an insufficient heating power to high-melting spray additives, such as. B. can spray molybdenum, tungsten and oxides.
  • oxygen e.g. As oxygen
  • an insufficient heating power to high-melting spray additives such as. B. can spray molybdenum, tungsten and oxides.
  • hydrogen burns in a reducing manner and is therefore not suitable for spraying metal oxides, since the hydrogen flame extracts oxygen from the spray additive in the molten or plastic state.
  • Another high-speed flame spraying system is known from EP-0 049 915.
  • This high-speed flame spraying system has a water-cooled expansion nozzle which is said to be suitable for spraying wire and powdered filler materials.
  • the heating gas is either hydrogen, propane or MAPP gas with oxygen.
  • the fuel gases used are fed into a large mixing room according to the compressed gas principle and mixed with oxygen.
  • the fuel gas-oxygen mixture enters the water-cooled expansion nozzle through holes, where it is combined with the powder or wire-shaped filler material in the combustion chamber.
  • EP-A1-0 049 915 also has a large number of application-related and safety-related defects.
  • the acetylene-oxygen flame has dominant properties that no other fuel gas-oxygen mixture can achieve. For this reason, it is ideally suited for the thermal spraying of high-melting filler materials.
  • acetylene as a heating gas for operating high-speed flame spraying systems in conjunction with oxygen is problematic due to the specific structure of the acetylene molecule.
  • Acetylene is a chemical compound of carbon and hydrogen. It is a so-called unsaturated hydrocarbon, the molecule of which is full of internal tension that is trying to balance. Acetylene is therefore not a stable substance, but tends to break down into its constituents, namely carbon and hydrogen. For example, if the acetylene is heated to a temperature of around 300 ° C, it is also under pressure, so that once decay has started, it propagates through the entire amount of gas. The energy released in the form of heat is sufficient to bring neighboring acetylene particles to the decay temperature. This process takes place so quickly that compressed acetylene decomposes like a deflagration when decomposition is initiated. This condition occurs e.g. B.
  • oxide-free spray layers such as. B. from Hastelloy, Tribaloy or high-purity nickel can only be produced using the plasma vacuum chamber spraying. This technology is very complicated and extremely costly.
  • the object of the above invention is therefore to provide a method and a device with which operation with acetylene and oxygen is possible without any problems.
  • the present invention is intended to provide a considerable simplification of the coating process and a cost reduction, which at the same time also improves the layer quality with regard to optimization of the adhesive tensile strength of the spray material to the substrate, by means of a significantly higher kinetic Energy of the flame jet is achieved, while at the same time a lower porosity and thus a higher tightness of the spray layer is achieved.
  • the method for high-speed flame spraying of high-melting wire and powder-form filler materials for coating surfaces works by means of at least two gas mixing systems that function independently of one another and with which the wire or powder-form spray additive material introduced into the primary chamber melts from primary heating flames arranged concentrically around a feed channel , accelerated with the resulting high-speed flame and passed through an expansion nozzle into a downstream secondary combustion chamber, the primary high-speed flame at supersonic speed flows through it, along with the melt-plastic filler materials, which flows into an axially centrically expanded, downstream and water-cooled secondary expansion nozzle, so that in the area it flows from , axially and focussing arranged, opening into the secondary combustion chamber secondary combustion
  • oxygen channels a negative pressure zone is created and a heating gas mixture with low inflow pressures can be supplied, the radial, axial around the secondary chamber Primary high-speed flame ignites the heating gas mixture, expands and, due to a high flame temperature and an extreme ignition and combustion speed, contributes to the residual melting
  • the primary gas mixture preferably takes place in the intermediate piece designed as an injector gas mixing block and the secondary gas mixture takes place in the primary combustion chamber housing designed as a mixing block for secondary gases.
  • a particularly preferred embodiment of the invention provides that the primary heating gas mixture follows directly in a gas mixing block according to the injector principle in the immediate vicinity of the primary combustion chamber.
  • the primary combustion chamber and / or the expansion nozzle is (are) integrated in the secondary injector gas mixing block.
  • the spray additive material optionally in powder form, and the powder transport gas at room temperature or the powdery spray additive material and / or the powder transport gases preheated.
  • the connection for the spray additives and / or powder transport gases is equipped with water cooling. The cold or preheated spray additive is melted when it is passed through the primary combustion chamber, brought through the secondary combustion chamber by the primary heating flame, melted and accelerated and emerges from the expansion nozzle bore with the secondary flame.
  • the proposed device for carrying out the method is designed as a flame spray gun and consists of a basic device body, operating component connection block with distributor chambers, injector gas mixing block, combustion chamber housing and a central bore for spray additive materials and cooling devices, and starting from the operating component connection block, the secondary gas and secondary heating gas -, Primary gas and primary heating gas ducts are routed separately to a primary combustion gas chamber and a secondary combustion gas chamber, the spray additive duct surrounding the primary gas ducts leading into the primary combustion chamber and the secondary gas ducts via the primary combustion chamber in the direction of the expansion nozzle leading into the secondary combustion chamber.
  • a preferred embodiment is characterized in that the device consists of an operating component connection block, a basic device body, a gas mixing block carrier, an injector gas mixing block, a primary combustion chamber housing with an inner part or central bore body, press screw and union part, as well as a secondary expansion nozzle body and inner screw sleeve and outer screw sleeve.
  • the operating component connection block has at least one cooling water connection, one secondary gas connection, one primary gas connection, one connection for powdered filler materials and / or wire-shaped spray additives, one primary heating gas connection, one secondary heating gas connection and one cooling water return connection, which are channels up to the Continue the face of the operating component connection block or to the distribution chambers arranged there.
  • These channels or the distribution chambers of the operating component connection block correspond to media-like channels of the main body of the device which connects to the operating component connection block.
  • the main body of the device accommodates at least partially surrounding a gas mixing block carrier for secondary gases, an injector gas mixing block for primary gases being arranged in the gas mixing block carrier.
  • a further particularly preferred embodiment consists in the device base body having channels which correspond to the channels or to ring channels arranged on the end face of the operating component connection block.
  • a further embodiment consists in that the channel of the basic device body opens into a cooling water supply channel between the inner screw sleeve and the outer screw sleeve, the cooling water return channel corresponding to the cooling water return channel formed between the basic device body and the compression screw.
  • the gas mixing block carrier is preferably each penetrated by at least one secondary gas and secondary heating gas channel, each of which corresponds on the one hand to the media-like channels of the main body of the device and on the side facing the primary combustion chamber in radial grooves arranged there for secondary heating gas and secondary gas.
  • the injector gas mixing block for primary gases has at least one primary heating gas channel and one primary gas channel, as well as a central bore for spray additive materials, these channels on the one hand corresponding to the media-like channels of the main body of the device and the primary gas channel in a radial annular space between the gas mixing block carrier and the injector gas mixing block or the channel for primary heating gas in an annular space for the oxygen distribution opens, while the central bore leads to the front side of the injector gas mixing block and, starting from the annular space for the oxygen distribution, injector nozzle bores are directed to the injector gap, from where the injector mixing nozzle bores continue to form a radial groove.
  • the injector gas mixing block is followed by a primary combustion chamber housing in the direction of the expansion nozzle, which houses an inner part with injector gas mixing holes and a hole for the spray additives.
  • the injector gas mixing bores are focussing and / or are arranged axially in the inner part.
  • a radial ring groove for fuel gas, oxygen primary gas, which corresponds to the radial ring groove of the injector gas mixing block, as well as the centrally arranged bore for spray additives of the inner part with the central bore of the injector gas mixing block, are arranged on the end face of the inner part pointing toward the injector gas mixing block.
  • the primary combustion chamber housing has a radial ring groove for secondary heating gas and a radial ring groove for secondary heating oxygen, which correspond to the radial grooves of the gas mixing block carrier of the same media, on the end facing the gas mixing block carrier.
  • Corresponding channels continue from these radial ring grooves, where they meet in a radial ring groove (injector gap), in that the channels insert directly into the radial ring groove or via injector pressure nozzle bores.
  • these channels are at least partially formed by the gap between the primary combustion chamber housing and the union part.
  • the expansion nozzle connects to the secondary combustion chamber.
  • the cooling water channel continues, starting from the connection of the operating component connection block through the device base body, between the inner screw sleeve and the outer screw sleeve up to the radial bore on the expansion nozzle outlet bore and then merges into the cooling water return, in that the cooling water channel extends between the expansion nozzle body and the inner screw water sleeve and passes into a cooling sleeve , from here a cooling water channel leads to the cooling water return connection of the operating component connection block.
  • the primary combustion chamber housing is designed as a secondary gas mixing block.
  • the primary combustion chamber of the combustion chamber housing has a transition expansion nozzle bore.
  • Figure 1 shows the inventive device for high-speed flame spraying, which is designed as a flame spray gun.
  • the device is composed of an operating component connection block 9, an apparatus base body 12, an internal mixing nozzle block / injector gas mixing block for primary gases 13 and gas mixing block carrier 14, a primary combustion chamber housing 29 with a union part 80 and pressure screw 62, expansion nozzle body 39 and a surrounding inner screw sleeve 34 and outer screw sleeve 35 as well an inner part 76 receiving the central bore body 81.
  • a cooling water supply channel 1, a secondary gas channel 2, a primary gas channel 3, a central bore for filler materials (powder or wire) 4, a primary heating gas channel 5, a secondary heating gas channel 6 and a cooling water return channel 7 prevail through the device.
  • the primary gas and the primary heating gas are mixed in the injector gas mixing block for primary gases 13 and enter the primary combustion chamber 28, the wire or powdered spray additive likewise introduced into the primary combustion chamber 28 being melted by the primary heating flames 64 arranged concentrically around the feed channel 4, accelerated with the resulting high-speed flame 65 and passed through a primary expansion nozzle bore 30 into a downstream secondary combustion chamber 32 becomes.
  • the primary high-speed flame 65 at supersonic speed with entrainment of the melt-plastic filler materials, which flows into an axially centrically expanded, downstream and water-cooled secondary expansion nozzle 39 or into its bore 38, so that in the region of radially, axially and / or focussing, in the secondary combustion chamber 32 opening secondary combustion gas oxygen channels 44, 45 a negative pressure zone is created and a heating gas mixture can be supplied with low admixing pressures, the heating gas mixture igniting in the secondary chamber 32 radially, axially around the primary high-speed flame 65, expanding and due to a high flame temperature and an extreme ignition and combustion speed contributes to the residual melting of the spray additives and their additional acceleration.
  • the outer screw sleeve 35 surrounds the inner screw sleeve 34 in such a way that an annular space 36 is formed for the cooling water flow.
  • the inner screw sleeve 34 has an internal thread 83, and can thus be screwed onto the external thread 84 of the device body 12 and sealed by means of an O-ring 19.
  • the external screw sleeve 35 has an external thread 85, which engages in an internal thread 86 of the device body 12 and thus screwed to it.
  • An O-ring 15 is also inserted here for sealing purposes.
  • O-ring seals 41 and 42 are likewise arranged between the outer screw sleeve 35 and the inner screw sleeve 34 and between the inner screw sleeve 34 and the expansion nozzle body 39.
  • a cooling water channel 1c leads through the device base body 12 to the cooling water channel 1b of the operating component connection block 9, which has a connection for the cooling water access 1a.
  • the operating component connection block 9 is fastened to the device base body 12 by means of Allen screws 8 and sealed by means of O-rings 50, which each surround the connection channels 1a to 7a and the screws 8 in a sealing manner.
  • the expansion nozzle body 39 is located within the inner screw sleeve 34 and is screwed onto the internal primary combustion chamber housing 29.
  • annular space 37 for the cooling water return is formed between the expansion nozzle body 39 and the inner screw sleeve 34. This in turn merges into a larger annular space 33, in which the cooling water channel 7d opens out from the basic device body 12 and operating component connection block 9, here the channel 7a.
  • cooling channel 7d is continued through the gap between the device body 12 and the compression screw 62 to the annular space 33.
  • the cooling system therefore takes the following route: Starting from the cooling water connection stub 1 of the operating component block 9, cooling water flows via the cooling water supply duct 1a into the cooling water supply duct 1b of the basic device body via the annular space 36, distributed between the outer screw sleeve 35 and the inner screw sleeve 34 to the radial bores for cooling water 40 (cooling water supply) on the expansion nozzle 39 the annular space 37, the cooling water flows between the expansion nozzle 39 and the inner screw sleeve 34 via the cooling water channel 7d back to the connecting piece 7 for cooling water return.
  • the cooling water supply is shown in broken lines and the cooling water return is shown in dash-dotted lines in FIGS.
  • the secondary gas path is shown here with wavy lines that run obliquely from top left to bottom right and the secondary heating gas path is shown with wavy lines that run diagonally from bottom left to top right.
  • the primary gas path was shown with horizontal wavy lines and the primary heating gas curve with vertical wavy lines, the respective crossing waves representing the mixture.
  • the Spray additive shown dotted.
  • the operating component connection block 9 has, for example, a connection 3a for heating oxygen (primary gas) and a connection 5a for fuel gas H2, propane, etc. (primary heating gas).
  • a channel 3b leads from the connection 3a for heating oxygen (primary gas) through the operating component connection block 9 into an oxygen distribution chamber 11, on the end face 68 of the operating component connection block 9 pointing towards the device connection block 12.
  • the primary heating oxygen channel 3 is formed by the individual channels 3c in the device base body 12 and the channel 3d and in the injector gas mixing block 13.
  • the channel 3c opens into the oxygen distribution chamber 11 and the channel 3d into the annular space 56 for the oxygen distribution in the interior mixing nozzle block or injector gas mixing block 13.
  • a channel 5a leads into the fuel component distribution block 9 within the operating component connection block 9, which also leads to the end face 68 of the operating component connection block 9 is arranged.
  • the channel 5c in the main body 12 leads to the channel 5d, which opens into the annular space 57.
  • the oxygen distribution takes place in the annular space 56, which acts as a pressure compensation chamber.
  • the oxygen flows through the annular groove adjoining the annular space 57 (Injector gap) 57a, in order to then flow through the various injector mixing nozzle bores 59 with the entrained fuel gas from the injector gap (annular space 57a).
  • the fuel gas-oxygen mixture passes through the radial ring groove 22 / 22a via the fuel gas-oxygen mixture bores 47 and 48 into the primary gas combustion chamber 28.
  • Fuel gas (predominantly hydrogen, propane gas or propylene) is fed in at port 5 and passes through the fuel gas distribution chamber (pressure compensation chamber) 10 via the connecting bore 5c / 5d into the radial annular space 57 into the radial annular groove 57a, injector gap, from which the fuel gas is entrained and mixed into the injector mixing bores 59 by the injector action, the oxygen flowing through at supersonic speed.
  • the fuel gas-oxygen primary mixture reaches the primary combustion chamber 28 via the bores 47 and 48.
  • the injector effect in the internal gas mixing block is achieved by a higher inflow pressure of oxygen compared to the fuel gas inflow pressure. If the primary fuel gas / oxygen mixture emerging from the expansion nozzle bore 43 (see FIG. 1) is ignited, the flame strikes back into the primary combustion chamber 28. The fuel gas / oxygen mixture now burns out of the cylindrical combustion chamber bore 30 or 46 as a primary high-speed flame through the secondary combustion chamber 32 into the water-cooled expansion nozzle bore 38. In the opening area of the secondary gas mixture bores 44, 45 arranged concentrically, axially and focusing around the primary combustion chamber bore 46, a vacuum zone is created due to the high flame speed of the primary heating gas flow.
  • Secondary heating oxygen is supplied at the connection 2a and reaches the radial ring groove 63/21 (pressure compensation and distribution ring groove) via the channels 2b, 2c, 2d.
  • the oxygen Via the oxygen connection bores, the oxygen reaches a plurality of injector compressed gas bores 24, in which it is accelerated to supersonic speed and flows through annular groove 25 (injector gap), entrains fuel gas from the annular groove 25 and opens into the opposite axial and / or focusing aligned mixing bores 26 and as fuel gas -Oxygen mixture emerges from the mixing bores 44 and 45.
  • the outflow is positively influenced by the negative pressure zone in the inlet area generated by the primary high-speed flame.
  • the fuel gas-oxygen mixture predominantly acetylene-oxygen mixture flowing into the combustion chamber (secondary) 32 ignites at the primary high-speed flame and optimizes the melting process of the spray particles and increases the flame speed and spray particle speed.
  • the operating component connection block 9 has the connection 2a for heating oxygen (secondary gas) and the connection 6a for fuel gas C2, H2 (secondary heating gas), from where the channels 2b and 6b lead through the operating component connection block 9 to the end face 68.
  • a channel 2c leads to channel 2d of the gas mixing block carrier 14 and a channel 6c from channel 6a to channel 6d of the gas mixing block carrier 14.
  • the channel 2d in turn leads into a radial ring groove 63 or 21 and the like Channel 6d into the radial groove 18.
  • radial grooves of the gas mixing block carrier 14 of the same media correspond to the radial grooves of the primary combustion chamber housing 29, as is also the case with the primary system.
  • Heating oxygen flows through the bores 23 of the secondary fuel via the injector pressure nozzle bores 24, which each have a focal position and an axial position, into the radial annular groove 25 (injector gap), from where the mixture then flows through the bores 44 and 45, such as described, continues.
  • a connection 4 is arranged on the operating component connection block 9, from which the channel 4b continues to the end face 68, where it leads into a channel 4c of the main body 12 or corresponds to it.
  • the channel 4d which corresponds to the bore 49 of the central bore body 76, now continues in the injector gas mixing block 13.
  • FIG. 9 shows a section along the line AA indicated in FIG. 1 and FIG. 10 shows a section along the section line BB indicated in FIG. 1.
  • FIG. 9 shows the opening area of the secondary gas flows in plan view.
  • outlet bores 44 for secondary heating gas-oxygen mixture (axial) and the outlet bores 45 for secondary heating gas-oxygen mixture (focusing) can thus be seen in FIG.
  • injector gas mixing bores for primary heating gas-oxygen mixture are used with the reference symbol 47 and such bores (focusing) with the reference symbol 48.
  • the outlet 49 for the spray additives is identified by reference numeral 49 and the central bore body by reference numeral 81.
  • the secondary combustion chamber housing bears the reference symbol 31 and the primary expansion nozzle bore the reference symbol 30, while the outlet bores for secondary heating gas-oxygen mixture (axial) and the reference bores 45 identify these outlet bores (focusing) with the reference symbol 44.
  • the primary flame outlet expansion nozzle bore has the reference symbol 46 and the outlet bore for spray additives is identified by the reference symbol 49.
  • FIG. 4 shows the operating component connection block 9. It has the cooling water supply connection 1 a, the secondary gas connection 2 a, the primary gas connection 3 a, feed channel connection 4 a, primary heating gas connection 5 a, secondary heating gas connection 6 a and cooling water return connection 7a. These each continue with corresponding channels 1b to 7b in the operating component connection block 9, the channels 1b to 7b corresponding to media-like channels 1c to 7c of the main body 12 of the device.
  • the operating component connection block 9 is connected to the device base body 12 by means of screws 8 and sealed by O-rings 50 on its end face 68.
  • FIG. 5 shows the basic device body 12. As already described above, this has the channels 1c to 7c, which correspond to corresponding media-like channels 1b to 7b of the operating component connection block 9.
  • the secondary gas channel 2c and secondary heating gas channel 6c of the device base body 12 lead into channels 2d and 6d of the gas mixing block carrier 14 with the same media, while the primary gas 3c and primary heating gas channels 5c lead into channels 3d, 5d of the injector gas mixing block 13 with the same media.
  • the central loading channel 4c corresponds to the channel 4d of the injector gas mixing block 13.
  • the cooling water supply channel 1c is meanwhile connected to the channel 1d, which is formed between the inner screw sleeve 34 and the outer screw sleeve 35, the outer screw sleeve 35 being screwed onto the internal thread 86 and the inner screw sleeve 34 onto the external thread 84 of the basic device body 12, these of course corresponding threads 83 or 85.
  • the cooling water return duct 7c is connected to the duct 7d, which is formed between the device base body 12 and the compression screw 62.
  • FIG. 6 shows the gas mixing block carrier 14. It receives the injector gas mixing block 13 centrally and has the already described secondary gas 2d and secondary heating gas channels 6d, which correspond to the channels 2c and 6c of the main body 12 of the device.
  • Radial ring grooves 18 for secondary heating gas and 60 for secondary gas are provided on the end face 71 of the gas mixing block 14, the channel 2d opening into the radial ring groove 60 and the channel 6d opening into the radial ring groove 18. These are in turn connected to corresponding radial ring grooves 20 and 21 of the primary combustion chamber housing 29 of the same media.
  • FIG. 7 shows the injector gas mixing block 13 accommodated by the gas mixing block carrier 14, with its channels 3d, 4d and 5d, which, as described above, are connected to the channels 3c, 4c and 5c of the basic device body 12.
  • the channel 3d for primary gas leads into an annular space for the oxygen distribution, from there through injector pressure nozzle bores 58 into the injector gap 57a, while the channel 5d leads into the radial annular space 57 for primary heating gas (fuel gas) and from there into the injector gap 57a.
  • the mixture then continues through the injector mixing nozzle bores 59 into the radial ring groove 22a, while the central channel 4d for the spray additive leads to the end face 65 and there passes into the central channel 49 of the central bore body 81.
  • FIG. 8 shows the primary combustion chamber housing 29 with its radial ring grooves 20 for secondary heating gas and 21 for secondary heating oxygen, as well as the internal part 76 accommodated with a central bore body 81.
  • This illustration clearly shows that the Pirmärbrennhuntgepur 29 also fully achieves the secondary gas or heating gas mixture. This takes place in that the gas mixture brought in from the injector gas mixing block 13 flows through the bores 47, 48 into the primary combustion chamber 28 and the secondary gas / heating gas components from the gas mixing block carrier are guided separately into the primary combustion chamber housing 29 and brought together there in the radial ring groove 25 (injector gap) and via the Primary combustion chamber 28 are also guided through the bores 44, 45 into the secondary combustion chamber 32 of the secondary expansion nozzle body 39.
  • FIG. 11 shows a diagram of the flame temperatures of fuel gas-oxygen mixtures
  • FIG. 12 shows the ignition speeds of fuel gas-oxygen mixtures
  • FIG. 13 shows the primary flame lines of fuel gas-oxygen mixtures. From this it can be seen that the acetylene-oxygen flame has dominant properties that cannot be achieved by any other fuel gas-oxygen mixture. For this reason, it is ideally suited for the thermal spraying of high-melting filler materials.
  • the curve of acetylene in accordance with TRG103 of 21.5 to 22.5% acetylene, 71.5 to 73.5% ethylene and 5.0 to 6.0% propylene, compared with a mixture of methyl acetylene and methane, propylene and propane.
  • powder and powder transport gas are supplied at port 4 at room temperature.
  • preheated powder transport gases e.g. B. argon, nitrogen and other gases and preheated powders.
  • the connection 4a is designed with water cooling (cooling water supply and return).
  • the cold or preheated powder-powder transport gas mixture is guided through the central bore 4 and opens into the primary combustion chamber 28 from the nozzle inlet bore 49.
  • the non-preheated powder transport gas mixture is melted by the high-speed flame and guided with the kinetic energy through the secondary combustion chamber, remelted by the enveloping secondary heating flame (acetylene + oxygen flame) and additionally accelerated through the water-cooled expansion nozzle bore 38 and passes on the end face optimally melted from the expansion nozzle bore 43 or in the melt-plastic state with the secondary high-speed flame with multiple sound speeds.
  • the enveloping secondary heating flame acetylene + oxygen flame
  • preheating temperatures can be between 50 and 800 ° C
  • the preheated spray additive is already melted well when the particles are passed through the primary combustion chamber and from the Primary heating flame passes through the secondary combustion chamber, where it is still molten, accelerated, and emerges from the expansion nozzle bore with the secondary flame at the highest possible speed.
  • Preheating powdered filler material and powder transport gas to 50 ° C to 800 ° C before feeding it into the burner has several advantages over cold supply. For example, the low temperature difference between the powder particles and the heating power of the primary flame should be mentioned; As a result, the powder is melted better in the flame with the same dwell time than when it is introduced cold. It is also advantageous, for example, that the preheated powder transport gas cools the primary and secondary flame less than cold powder transport gas; this leads to higher flame heating power and higher flame speeds.
  • Wire-shaped spray filler materials can also be introduced and melted into the primary combustion chamber via the central bore 4 via the connection 4a.
  • the wire feed is controlled depending on the melting point and wire diameter so that a continuous spraying process can take place.
  • FIG. 14 shows a further embodiment variant of the invention.
  • the primary gas mixture takes place in the injector gas mixing block 13, that is to say in an intermediate piece
  • the primary heating gas mixture fuel gas and oxygen
  • the primary heating gas mixture is directly in a gas mixing block 13a according to the injector principle in in the immediate vicinity of the primary combustion chamber 28, that is to say without an intermediate piece.
  • the descriptions made in the exemplary embodiment according to FIG. 1 with regard to the other device and method elements apply to these taking into account the adaptation of the embodiment variant according to FIG. 14, so that a further functional description can be dispensed with, since the embodiment variant 14 is to be assumed to be the general idea of the invention.
  • a method and a device in the form of an all-gas high-speed flame spray burner for coating surfaces with any high-melting wire or powder-form spray additive materials are created which, for example, make operation with acetylene and oxygen possible without problems.

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  • Chemical & Material Sciences (AREA)
  • Engineering & Computer Science (AREA)
  • Combustion & Propulsion (AREA)
  • Physics & Mathematics (AREA)
  • Plasma & Fusion (AREA)
  • Chemical Kinetics & Catalysis (AREA)
  • Materials Engineering (AREA)
  • Mechanical Engineering (AREA)
  • Metallurgy (AREA)
  • Organic Chemistry (AREA)
  • Nozzles (AREA)
  • Coating By Spraying Or Casting (AREA)
EP91103273A 1990-05-22 1991-03-05 Procédé et dispositif de pulvérisation par flamme à haute vitesse de matériau d'apport réfractaire sous forme de poudre ou de fil pour le revêtement de surfaces Expired - Lifetime EP0458018B1 (fr)

Priority Applications (1)

Application Number Priority Date Filing Date Title
AT9191103273T ATE105596T1 (de) 1990-05-22 1991-03-05 Verfahren und vorrichtung zum hochgeschwindigkeitsflammspritzen von hochschmelzenden draht- und pulverfoermigen zusatzwerkstoffen zum beschichten von oberflaechen.

Applications Claiming Priority (2)

Application Number Priority Date Filing Date Title
DE4016412 1990-05-22
DE4016412A DE4016412A1 (de) 1990-05-22 1990-05-22 Verfahren und vorrichtung zum hochgeschwindigkeitsflammspritzen von hochschmelzenden draht- und pulverfoermigen zusatzwerkstoffen zum beschichten von oberflaechen

Publications (3)

Publication Number Publication Date
EP0458018A2 true EP0458018A2 (fr) 1991-11-27
EP0458018A3 EP0458018A3 (en) 1992-01-22
EP0458018B1 EP0458018B1 (fr) 1994-05-11

Family

ID=6406924

Family Applications (1)

Application Number Title Priority Date Filing Date
EP91103273A Expired - Lifetime EP0458018B1 (fr) 1990-05-22 1991-03-05 Procédé et dispositif de pulvérisation par flamme à haute vitesse de matériau d'apport réfractaire sous forme de poudre ou de fil pour le revêtement de surfaces

Country Status (5)

Country Link
EP (1) EP0458018B1 (fr)
JP (1) JPH07102358A (fr)
AT (1) ATE105596T1 (fr)
CA (1) CA2043024A1 (fr)
DE (2) DE4016412A1 (fr)

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0599166A1 (fr) * 1992-11-27 1994-06-01 Franz Künzli Ag Injecteur-embouchure pour chalumeaux
GB2281233A (en) * 1993-08-09 1995-03-01 William Hopkins Apparatus for and methods of producing a particulate spray
CN1119431C (zh) * 2000-08-10 2003-08-27 沈阳航空工业学院 超音速火焰熔滴喷涂方法
CH702999A1 (de) * 2010-04-29 2011-10-31 Amt Ag Vorrichtung zur Beschichtung von Substraten mittels Hochgeschwindigkeitsflammspritzen.

Families Citing this family (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE4219992C3 (de) * 1991-12-23 1996-08-01 Osu Maschinenbau Gmbh Thermisches Spritzverfahren und Spritz- und Beschleunigungsdüse zur Erzeugung von Metallschichten
DE4418437C2 (de) * 1994-05-26 1996-10-24 Linde Ag Verfahren und Vorrichtung zum autogenen Flammspritzen
DE4429142B4 (de) * 1994-08-17 2004-11-18 Matthäus Götz Düsenspritzkopf zum Hochgeschwindigkeitsflammspritzen so wie Verfahren zur Verarbeitung von Beschichtungspulvern
JP4626945B2 (ja) * 2004-07-06 2011-02-09 第一高周波工業株式会社 サーメット溶射皮膜形成部材およびその製造方法
CN113512447B (zh) * 2021-04-07 2023-11-10 北京航化节能环保技术有限公司 一种全预混喷嘴装置、气化炉、气化方法及喷嘴加工方法

Family Cites Families (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
DE811899C (de) * 1949-06-05 1951-08-23 Deutsche Edelstahlwerke Ag Vorrichtung zum Verspruehen von metallischen und nichtmetallischen Werkstoffen
US4416421A (en) * 1980-10-09 1983-11-22 Browning Engineering Corporation Highly concentrated supersonic liquified material flame spray method and apparatus
US4869936A (en) * 1987-12-28 1989-09-26 Amoco Corporation Apparatus and process for producing high density thermal spray coatings
US5019686A (en) * 1988-09-20 1991-05-28 Alloy Metals, Inc. High-velocity flame spray apparatus and method of forming materials

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
EP0599166A1 (fr) * 1992-11-27 1994-06-01 Franz Künzli Ag Injecteur-embouchure pour chalumeaux
US5535953A (en) * 1992-11-27 1996-07-16 Huehne; Erwin Injector tip for burning aggregates
GB2281233A (en) * 1993-08-09 1995-03-01 William Hopkins Apparatus for and methods of producing a particulate spray
GB2281233B (en) * 1993-08-09 1998-02-25 William Hopkins Apparatus for and methods of producing a particulate spray
CN1119431C (zh) * 2000-08-10 2003-08-27 沈阳航空工业学院 超音速火焰熔滴喷涂方法
CH702999A1 (de) * 2010-04-29 2011-10-31 Amt Ag Vorrichtung zur Beschichtung von Substraten mittels Hochgeschwindigkeitsflammspritzen.
EP2383361A1 (fr) 2010-04-29 2011-11-02 Amt Ag Dispositif de revêtement de substrats à l'aide de seringues d'injection à la flamme grande vitesse
US9032903B2 (en) 2010-04-29 2015-05-19 Amt Ag Device for coating substrates by means of high-velocity flame spraying

Also Published As

Publication number Publication date
DE59101597D1 (de) 1994-06-16
EP0458018A3 (en) 1992-01-22
DE4016412A1 (de) 1991-11-28
DE4016412C2 (fr) 1992-09-03
EP0458018B1 (fr) 1994-05-11
JPH07102358A (ja) 1995-04-18
CA2043024A1 (fr) 1991-11-23
ATE105596T1 (de) 1994-05-15

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