EP0554683A1 - Method to change the surface of castings by powder impregnating - Google Patents

Abstract

A description is given of a process for impregnating or embedding hard, wear-resistant phases in surface layers of metal products made by casting a liquid metal. Said process is intended to improve the adhesion between the wear-resistant layer and the metal. It is proposed that at least one sintered-on layer with at least one formed-on peg or protrusion be formed from hard, wear-resistant phases, and that the layer is fixed on a surface of the mould before casting the metal. <IMAGE>

Description

The invention relates to a method for impregnating or embedding hard, wear-resistant phases in surface layers of metal products which are produced by pouring liquid metal.

Various methods are known by means of which metal products, for example made of iron, can be provided with hard, wear-resistant or abrasion-resistant surfaces. The surfaces are coated, for example, by flame spray coating or plasma spray coating. However, a disadvantage of these processes is that the surface layers can flake off during the coating process and when the products are used. There are also high procedural costs.

It is also known from US Pat. No. 4,119,459 to melt carbides into the surface by applying carbide macro particles to a casting model and then casting the workpiece. However, it is difficult to place the carbide macro particles precisely in the desired locations and in the desired distribution pattern.

Also known for the manufacture of iron products are some methods for casting hard surfaces onto the iron workpieces in connection with the use of polystyrene models. Such a method has been described, for example, by Hansen et al, "Application of Cast-On Ferrochrome-Based Hard Surfacings to Polystyrene Pattern Castings", Bureau of Mines Report of Investigations 8942, US Department of the Interior, 1985. In this method, a paste containing an adhesive and the desired hard material, such as. B. tungsten carbide powder, applied to those surfaces of a polystyrene model that correspond to the wear-prone surfaces of the resulting cast. Then a heat-resistant coating is applied to the entire model before the metal is poured off. This process is known as the "Evaporative Pattern Casting" process or EPC process.

However, this process suffers from the lack of adhesion between the wear-resistant layer, which consists for example of tungsten carbide, and the foam model made of polystyrene, which is mainly due to the fact that the almost dry paste does not adequately wet the surface of the foamed synthetic resin. Therefore, the iron sometimes does not penetrate the layer before it solidifies, and instead of having soaked the iron, the carbide flakes off the product. Furthermore, this process is complex and uneconomical and cannot be used effectively in large-scale production.

The mechanical properties of cast iron made by an EPC process are inferior to that of sand or core castings due to the presence of carbon defects. Furthermore, the EPC process requires special precautionary measures to keep small changes in shape during casting.

Various processes are also known from EP-A-0 421 374 and EP-A-0 470 503, by means of which the impregnation of metal surfaces with carbides is improved during the casting process by transferring layers of carbide particles to a foam core or a sand core be the the casting of the workpiece to be manufactured, made of iron or aluminum.

Even though these latter methods have brought about a significant improvement, they are still not entirely satisfactory. For example, the EPC process in a conventional foundry requires the installation of special devices. Furthermore, the cast products can have shape deviations which can be attributed to shape deviations of the foam models. The sand molding method for casting carbides known from the prior art requires carbide balls, which can make the process more expensive. Increased costs can also result from the requirement that the wear-resistant surface be formed flat. In this case, the cast product must be smoothed and a surface layer removed, which corresponds approximately to half the diameter of the spherical particles.

There is therefore still a need for a method for impregnating metal surfaces, in particular iron product surfaces, with a hard, wear-resistant material, by means of which the problems of the known methods mentioned at the outset can be overcome.

The invention remedies this and proposes a method for embedding hard, wear-resistant phases in surface layers of metal products which are produced by pouring liquid metal into casting molds. A flowable mass, which contains wear-resistant material, is shaped in such a way that a disc or layer is formed with preferably a series of pegs, projections, spikes or the like. This layer is sintered and adhered to a surface of the mold before the metal is cast. The projections result in a better bond between the wear-resistant material and the cast one Metal than is the case when using spherical sintered carbide particles.

The teaching of the invention is given by claim 1. Further advantageous refinements and developments of the invention emerge from the subclaims.

Exemplary embodiments and further advantages and advantageous developments and refinements of the invention are described and explained in more detail below with reference to the drawing.

Fig. 1

zwei Photographien von Mustern eines Chromkarbidpulverschlamms, bevor dieser gesintert wird,

Fig. 2

die elektronenmikroskopische Aufnahme (SEM) der vorgesinterten Oberfläche eines Chromkarbidzapfens,

Fig. 3

zwei elektronenmikroskopische Aufnahmen der Mikrostruktur einer duktilen Eisen-Chromkarbid-Verbundoberfläche und

Fig. 4

die Photographie der geschliffenen und polierten Verbundoberfläche eines Erzeugnisses, das gemäß vorliegender Erfindung gefertigt wurde.

It shows:

Fig. 1

two photographs of samples of a chrome carbide powder slurry before it is sintered,

Fig. 2

the electron micrograph (SEM) of the presintered surface of a chrome carbide pin,

Fig. 3

two electron micrographs of the microstructure of a ductile iron-chromium carbide composite surface and

Fig. 4

the photograph of the ground and polished composite surface of a product made in accordance with the present invention.

The present invention can basically be applied to the casting of any known metal through which a carbide surface can be wetted. Metals that can be used are, for example, iron, aluminum and the like. However Cast iron, especially spheroidal graphite cast iron or gray cast iron is preferred for the most common wear-resistant carbide types, such as, for example, chromium carbide and the like.

According to the present invention, a first step involves forming a thin sheet or plate that contains wear-resistant material. With regard to the choice of the hard, wear-resistant material, the invention can be successfully applied with any hard phase known from the prior art, for example with carbides such as tungsten carbide and chromium carbide or with aluminum compounds and the like. Furthermore, the hard phases can be replaced by powder of any metal, an intermetallic compound or a ceramic material, which is determined by the matrix material (embedding material) used, such as. B. wetting iron or an alloy known from the prior art. For example, aluminum can be used to improve the surface wear resistance of cast iron or nickel by forming intermetallic aluminum compounds. Suitable materials such as nickel or iron can also be used in aluminum casting.

According to a preferred embodiment of the invention, which relates to iron casting, the wear-resistant material can be a metallic binder, e.g. B. from the iron group, preferably cobalt for the use of tungsten carbides or nickel for the use of chromium carbides, etc., included. In particular, particles containing tungsten carbide with a weight fraction of 14 to 17% cobalt are preferred for the casting of ductile iron.

Although the size of the particles is not critical in the practice of the present invention, it becomes fine-grained Particles preferred which have a mesh size of 140/325 (approx. 110 to 50 microns) or finer.

The thin plate is produced by mixing a powder of hard, wear-resistant material with a suitable organic binder, for example a 10% polyvinyl alcohol solution, and a suitable hardener, for example 2-ethylhexyl diphenyl phosphate, phosphate ester hardener (e.g. KRONITEX 3600 from FMC Corporation, USA) or a mixture of these hardeners. The mixture forms a flowable mass with suitable rheological properties so that the mass can be brought into the form of a disk or plate. In this sense, any hardener and / or organic binder that can be processed effectively with a certain hard, wear-resistant material is suitable for carrying out the invention.

A pattern is formed on an outwardly facing surface of the thin plate, which has a structure that allows an improvement in the impregnation of the iron. Any pattern shape that has at least a peg, a peg, a protrusion, or the like that prevents lateral movement of the thin plate during casting is suitable. For example, a hexagonal or waffle-shaped structure can be applied to the surface of the thin plate (FIG. 1). Other suitable patterns include circular, elliptical and similar structures.

In fact, the pegs can take any conceivable shape that gives a desired contour to keep the distance of metal penetration small during casting.

Furthermore, the pattern can be molded by suitable means, for example by using a stamp with the desired pattern is pressed onto the surface of the still flowable, plastic, thin plate.

The thin plate is then dried, for example in an oven at 100 ° C., until it forms a dimensionally stable body. The thin plate is then sintered under suitable conditions so that on the one hand it achieves sufficient porosity and on the other hand it is stable enough to withstand further processing and / or the use of further process steps. For example, the appropriate conditions include a 300 to 360 minute vacuum sintering process at about 1200 to 1250 ° C.

The sintered thin plate described above consists of a porous sinter mixture with partial densifications (Fig. 2).

This partially or sintered thin plate can now be fastened in a known manner on a suitable mold surface, for example on a cast core, so that the patterned surface comes into contact with the cast core. For example, a high-temperature carbon is used here according to an embodiment of the invention. The layer is then z. B. heated in an oven to 100 ° C so that the volatile constituents are expelled from the adhesive and the adhesive cures.

The high temperature adhesive must have a flow temperature that is higher than the casting temperature of the metal. In principle, any adhesive in this regard is suitable, but an inorganic high-temperature adhesive is particularly preferred. For example, according to an embodiment of the invention for processing ductile iron, a binder is proposed which contains a high-temperature ceramic adhesive, e.g. B. a high temperature binder, which is available from Aremco Products, Inc., USA under the trade name Ceramabond 569 is sold and contains, for example, oxides of aluminum, silicon and potassium in an aqueous colloidal suspension which has a maximum service temperature of approximately 1650 ° C.

At this temperature, the liquid metal flows around the layer of hard, wear-resistant material, whereby any of the known casting methods, for example gravity casting, pressure die casting, vacuum casting or the like, can be used. However, gravity-based casting is preferred because of its ease of handling.

If a suitable casting process is used, the wear-resistant material partially dissolves in the casting metal and separates there as an integral part. For example, chrome carbide partially dissolves in molten iron and solidifies again there. The microstructure of such a composite is shown in Fig. 3, which also shows that the composite is bonded to the iron substrate in such a way that it cannot be easily detached therefrom.

Finally, the product can be subjected to any known post-processing. Fig. 4 shows the ground surface of a composite in which the iron "network" surrounding the composite spigot is clearly visible.

The method according to the invention can be used to produce metal products which cover a wide range of applications. The method can also be used with a large number of metals and their alloys.

In the special case of iron, a metallurgical reaction also occurs, through which the iron-carbide bond is further strengthened. This reaction can be supported by choosing suitable patterns of the thin plate.

Considerable process costs can be saved by using the method according to the invention. In particular, the surface conversion can already be carried out successfully during the casting process and requires neither subsequent soldering or welding, nor additional casting devices, such as may be associated with a dissolving foam core (EPC process) during casting. In particular, the process according to the invention can be used without difficulty in known sand molding processes.

An exemplary embodiment is given below for a more detailed description of the present invention and further advantages.

Example:

A fine chrome carbide powder (mesh size 140/325 or finer) is mixed with a 10% aqueous solution of polyvinyl alcohol and 2-ethylhexyl diphenyl phosphate or KRONITEX 3600 to form a flowable mass with adequate rheological properties, which form slices or thin Drain or roll out the plates. A pattern with a hexagonal structure is then embossed on the plate, as shown in FIG. 1. The thin plate is then dried in an oven in air at 100 ° C. and then sintered in a vacuum at 1200 to 1250 ° C. for 300 to 360 minutes.

The carbide plate is attached to a sand core with the Ceramabond 569 adhesive from Aremco. The sand core and the carbide plate are tempered in an oven at 100 ° C. for 60 to 120 minutes in order to drive volatile constituents out of the binder and to set the adhesive. Now it will liquid iron is poured around the carbide plate by means of a conventional casting process, so that the metal plate solidifies the carbide plate with the metal surface.

Claims (9)

Process for impregnating metal products which are produced by pouring liquid metal into casting molds with hard, wear-resistant surface layers, characterized in that at least one sintered layer with at least one molded peg, projection or the like is formed from hard, wear-resistant phases, and in that the Location before casting the metal is tacked to a surface of the mold. Method according to claim 1, characterized in that a layer with projections arranged in a hexagonal pattern is formed by casting or embossing. A method according to claim 1 or 2, characterized in that the casting mold contains a sand core and the layer is attached to the surface of the sand core by means of a high-temperature adhesive, preferably a high-temperature ceramic adhesive. Method according to one of claims 1 to 3, characterized in that a powder of wear-resistant material, an organic binder and at least one hardener are mixed and that the layer is produced from the mixture. Method according to claim 4, characterized in that the layer is produced by pouring off the mixture. Method according to one of claims 1 to 5, characterized in that the metal of the metal product is iron, in particular ductile iron. Method according to one of claims 1 to 5, characterized in that the metal of the metal product is aluminum. Method according to one of claims 1 to 7, characterized in that the hard, wear-resistant material contains at least one carbide, in particular a chromium carbide. Method according to one of claims 1 to 8, characterized in that the hard, wear-resistant material contains intermetallic nickel or iron aluminide.

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