DE19520149B4 - Apparatus for manufacturing, method for producing and using a coating on a component - Google Patents

Abstract

Apparatus for producing a coating on a component, which delimits an effective zone as substrate with its substrate surface on at least two sides by at least one smooth-walled mold and has an additional material supply, characterized in that at least one laser beam within the effective zone focuses on the substrate surface in a movable manner relative to the substrate is.

Description

Of the Material of a component is subject to other on its surface Influences as in volume, as it causes corrosion, wear and fatigue can come. For this reason, materials are used as gradient materials built or on its surface thermally, chemically or mechanically modified or with a coating material coated. The height of coatings vary in the literature due to application of some atomic layers, z. As in PVD layers, up to several centimeters high buildup welds.

After DE4139421A1 a substrate surface is coated with a sintered layer. For this purpose, a powdered starting material is introduced into a cargo space formed from a tool, sintered by heating and finally machined mechanically.

After DE839415B is a method for producing equipped with carbide teeth tools known in which a mold is attached to the tool body, filled with hard material and solder and heated. The amount of solder is calculated so that a plastering is not necessary, but the drill bit after removal of the mold forming parts is ready for use immediately.

After DE3843647A1 In a thermal coating method, a hard material is applied to the teeth of a cutting tool by means of a coating device, wherein the hard material is melted by means of a gas or plasma jet moved relative to the tooth and dripped into a mold cavity enclosing the tooth to be coated. To eliminate the surface deformation caused by the impacting gas or plasma jet, the hard material layer is reshaped with a stamp.

The proposed device for the production, the method for the production and the use of a coating relate to the thermal coating of a carrier material (substrate), which can be advantageously used for the production of wear and / or corrosion-resistant layers. These can be used advantageously for the production of thermal coatings in the millimeter range (0.1-5 mm). In the coating method, as is customary in laser beam coating, the laser radiation with a suitable intensity of 10 ³ -10 ⁶ W / cm ² focused on the substrate surface and fed a suitable filler material of the active zone. By relative movement between the substrate on the one hand and laser radiation and supply on the other hand can be produced by melting the filler material and / or the substrate coating webs, by their juxtaposition surface coatings arise. As a result of the melting process, the liquid surface assumes a characteristic cross-sectional shape in accordance with the forces acting on it (the force of gravity and the temperature-dependent surface tension and optionally other forces, such as, for example, the centrifugal force). The resulting geometry of the cross-sectional area in a natural way seldom corresponds to the geometry that is required in an application-specific manner, so that considerable rework is sometimes necessary.

The The object of the invention is the realization of a coating device and a coating process for producing smooth-walled, Near-net-like surfaces. The object is achieved by the features specified in the claims 1 and 10 solved.

at inventive use the proposed method and the proposed device can advantageously be largely dispensed with a rework. According to the invention this is achieved in that the Melt in their geometric formation by assisting in two until four directions are obstructed. This disability occurs in one direction through the substrate itself and in one to three others Directions through a smooth-walled mold. From one and / or two of the remaining directions can then be necessary for melting Laser radiation and the filler material are supplied. Thereby arise Coatings smooth-walled on the supported sides and are near-net shape.

There, where the component geometry allows, one can act according to the invention taking advantage of the so-called tub position particularly advantageous coat (Example 2). Good layer qualities as well as sufficient Adherence to the substrate is obtained one with inventive action then, when the width of the coating is chosen so that the ratio of Height too Width is between 1:20 and 5: 1, but preferably between 1: 2 and 2: 1.

For many applications, eg. As in the coating of saw blades, strips, etc., where over the entire width of the component at once the coating should be applied, this can be achieved according to the invention that the melt is supported perpendicular to the feed direction and in the vertical and in the feed direction a support is omitted (example 1 and 2). For other component geometries, it is possible to move the mold relative to the substrate. It is irrelevant according to the invention, whether the substrate is fixed and the mold is moved or vice versa. Especially with moving mold it may be advantageous not to use the mold in one piece but to use a split mold (Example 3). This is advantageous according to the invention if only part of the mold is displaced relative to the substrate, while another part is firmly connected to the substrate. When acting according to the invention, coating heights and widths can advantageously be produced which have a deviation from the desired size of less than 10 percent, preferably 1 percent.

Around an alloying of the mold material by the filler material and / or to prevent the substrate material, it may according to the invention necessary be, the mold especially on the surfaces that melt with contact, to coat with a release agent.

ever after substrate and filler material as well as depending on the supplied energy The laser radiation will become the solidification behavior of the solidifying Form melt differently. This fact can be inventively characterized encounter that one external cooling and / or heating of the mold is provided. This way you can you favor the heat the thermal coating process, preferably over the Mold (cooling) or over remove the substrate (heating of the mold). A discharge of the Heat over the Mold reduces the thermal distortion, a drain on the Substrate improves adhesion between substrate and coating.

at one-step coating and feeding the filler material in powder, wire or paste form, according to the invention, the efficiency, with which the filler material is applied, thereby increasing that the feeder for the Additional material is guided geometrically by the mold. It is advantageous that Achieve efficiencies of 80 percent, preferably more than 95 percent to let. Technically, the proposed method and the proposed device for the production of wear and corrosion protection layers use.

A further application aims to produce moldings, wherein on a substrate the outer contour later Form part is produced by successive laying of individual tracks (Example 4). The core of the molding can in a second step be filled by the same or foreign material. This has the technical Advantage that it is possible Manufacture first parts of metal with high density, without this a form is necessary (rapid prototyping). When acting according to the invention results from it In addition, the advantage that molded parts made of non-pourable Materials are produced. This includes such materials, where a component must not melt, or such where there is a reaction between the components of the material comes.

embodiments

Example 1 Support of the Melt perpendicular to the Feed Direction and in the Lane on the Example of a Rotationally Symmetric Component ( 1 and 2 ).

The 1 and 2 show the coating of a rotationally symmetrical component, here a saw blade, wherein the melt perpendicular to the feed rate, which may be between 0.1 and 1 m / min, is supported by a smooth-walled mold and in the vertical of the component itself. A pulsed Nd: YAG laser (pulse repetition frequency: 200 to 250 Hz, pulse power: 5 to 7 kW, pulse length: 0.7 to 1 ms) with an average output power of 1 to 1.2 kW and a focal spot diameter of about 4 mm (round focal spot, power density: 5 × 10 ³ to 1 × 10 ⁴ W / cm ² ) led to the about 1 to 3 mm wide substrate. Simultaneously, a pneumatic supply of powdery filler material at a mass rate of 0.1 to 0.5 g / s, wherein argon is used as a conveying gas with a flow rate of 4 l / min. The filler material consists of a bronze (in this case CuSn 20), to which hard substances with a proportion of up to 20% by volume were added. In the case of a pure bronze coating, the coating material melts in the zone of action of the laser beam and forms a firmly adhering, near-net shape layer on the substrate. In the case of hard material-containing filler materials, the hard materials are unmelted or undisturbed and distributed evenly distributed in the bronze matrix. Due to the guidance of the additional material supply (powder nozzle) and the subsidized additional material (powder jet), coating efficiencies of more than 80 percent result. The coating height reaches between 0.1 and 5 mm, depending on the combination of powder mass rate and feed rate. This results in height to width ratios between 1:20 to 5: 1. The smooth-walled mold results in contour deviations that amount to less than 3 percent of the coating height. The resulting layer is a wear-resistant layer in the above sense.

Example 2: Supporting the melt vertically to the feed direction and in the vertical, using the example of a plane component

The 3 . 4 and 5 show the coating of a planar member, here a bar, wherein the melt perpendicular to the feed rate, which can be between 0.1 and 1 m / min, is supported by a smooth-walled mold and in the vertical of the component itself. A pulsed Nd: YAG laser (pulse repetition frequency: 200 to 250 Hz, Pulse power: 5 to 7 kW, pulse length: 0.7 to 1 ms) with an average output power of 1 to 1.2 kW and a focal spot diameter of about 4 mm (round focal spot, power density: 5 × 10 ³ to 1 × 10 ⁴ W / cm ² ) on the approximately 1 to 3 mm wide substrate. Simultaneously, a pneumatic supply of powdery filler material at a mass rate of 0.1 to 0.5 g / s, wherein argon is used as a conveying gas with a flow rate of 4 l / min. The additional material consists of a bronze (in this case CuSn 20), to which hard materials with a proportion of 12.5 volume percent were added. In the case of a pure bronze coating, the coating material melts in the zone of action of the laser beam and forms a firmly adhering, near-net shape layer on the substrate. In the case of hard material-containing filler materials, the hard materials are unmelted or undisturbed and distributed evenly distributed in the bronze matrix. Due to the guidance of the additional material supply (powder nozzle) and the subsidized additional material (powder jet), coating efficiencies of more than 80 percent result. The coating height reaches between 0.1 and 5 mm, depending on the combination of powder mass rate and feed rate. This results in height to width ratios between 1:20 to 5: 1. The smooth-walled mold results in contour deviations that amount to less than 1 percent of the coating height. The resulting layer is a wear-resistant layer in the above sense.

Example 3: Support of the melt with a divided mold on the example of a planar component

The 6 and 7 show the coating of a planar component, here a strip, wherein the melt is supported with a split mold. Perpendicular to the feed rate, which may be between 0.1 and 1 m / min, the melt is supported by a smooth-walled first mold part and in the vertical of the part itself. Perpendicular to the first mold part, the second part of the smooth-walled mold supports the melt on the upper side, whereby the final contour is achieved in another direction. While the first mold part, which supports the melt, is fixedly connected to the substrate, the second mold part is connected to the laser and the filler feed (powder nozzle). A pulsed Nd: YAG laser (pulse repetition frequency: 200 to 250 Hz, pulse power: 5 to 7 kW, pulse length: 0.7 to 1 ms) with an average output power of 1 to 1.2 kW and a focal spot diameter of about 4 mm (round focal spot, power density: 5 × 10 ³ to 1 × 10 ⁴ W / cm ² ) led to the about 1 to 3 mm wide substrate. Simultaneously, a pneumatic supply of powdery filler material at a mass rate of 0.1 to 0.5 g / s, wherein argon is used as a conveying gas with a flow rate of 4 l / min. The additional material consists of a bronze (here CuSn 20), to which hard substances with a share of 12.5 volume percent was added. In the case of a pure bronze coating, the coating material melts in the zone of action of the laser beam and forms a firmly adhering, near-net shape layer on the substrate. In the case of hard material-containing filler materials, the hard materials are unmelted or undisturbed and distributed evenly distributed in the bronze matrix. Due to the guidance of the additional material supply (powder nozzle) and the subsidized additional material (powder jet), coating efficiencies of more than 80 percent result. The coating height reaches between 0.1 and 5 mm, depending on the combination of powder mass rate and feed rate. This results in height to width ratios between 1:20 to 5: 1. The smooth-walled mold results in contour deviations that amount to less than 1 percent of the coating height. The resulting layer is a wear-resistant layer in the above sense.

Example 4: Support of the melt for the production of moldings

The 8th . 9 and 10 show the production of moldings, wherein a mold, which is firmly connected to the laser beam and the filler inlet (powder nozzle), supports the melt. By moving the laser beam, additional material supply and mold in the xy plane, a trace is created. By repeatedly stacking tracks at a speed of 0.1 to 1 m / min, a molded part is formed. A pulsed Nd: YAG laser (pulse repetition frequency: 200 to 250 Hz, pulse power: 5 to 7 kW, pulse length: 0.7 to 1 ms) with an average output power of 1 to 1.2 kW and a focal spot diameter of about 4 mm (round focal spot, power density: 5 × 10 ³ to 1 × 10 ⁴ W / cm ² ) guided on the substrate. The distance between the two mold parts is 1 to 3 mm. Simultaneously, a pneumatic supply of powdery filler material at a mass rate of 0.1 to 0.5 g / s, wherein argon is used as a conveying gas with a flow rate of 4 l / min. The additional material consists of a bronze (here CuAl 10) or other meltable with the laser beam materials. The coating material melts in the zone of action of the laser beam and forms a free-standing in 5 directions, near-net shape molding, which adheres to the substrate in the 6th direction. Due to the guidance of the additional material supply (powder nozzle) and the subsidized filler material (powder jet), coating efficiencies of more than 80 percent result. The ratio of coating height to width must be about 1:10 in order to achieve a contour close to the final contour.

Claims (14)

Apparatus for producing a coating on a component, which delimits an effective zone as substrate with its substrate surface on at least two sides by at least one smooth-walled mold and has an additional material supply, characterized in that at least one laser beam within the effective zone focuses on the substrate surface in a movable manner relative to the substrate is. Device according to claim 1, characterized in that that the substrate surface is oriented in the vertical. Device according to one of claims 1 or 2, characterized that the active zone is open in the feed direction. Device according to one of claims 1 to 3, characterized that the mold is divided into mold parts. Device according to claim 4, characterized in that that at least one mold part parallel to a feed direction runs. Device according to one of claims 1 to 5, characterized that at least one mold or a Kokillenenteil the laser beam and the additional material supply is allocated spatially fixed. Process for the preparation of a coating a component, which in a first step with its substrate surface at least two sides through at least one smooth-walled mold to an active zone is limited, in a second step, a filler material added is melted in a third step and in a fourth Step to a coating on the substrate solidifies, characterized characterized in that the melting in the third step by at least one within the effective zone focused on the substrate surface and takes place relative to the substrate moving laser beam. Method according to claim 7, characterized in that that the mold cooled or heated. Method according to claim 7 or 8, characterized that the filler material is supplied in powder form. Method according to one of claims 7 to 9, characterized that the ratio a coating height to a coating width in the range of 1:20 to 5: 1, optionally in Range 1: 2 to 2: 1. Method according to claim 10, characterized in that that the coating height in the range between 0.1 and 5 millimeters and a maximum Contour deviation less than 10%, optionally less than 1%, of the coating height. Method according to one of claims 7 to 11, characterized that the mold is coated with a release agent. Use of a method according to one the claims 7 to 12 produced coating as a wear and / or Corrosion protection layer. Use of a method according to one the claims 7 to 12 produced coating for the production of a molding, in a fifth Step from the coating the substrate is removed.