DE3831192A1 - METHOD FOR PRODUCING SHAPES AND SHELLS, FOUNDRY MODELS, CORE SOCKETS AND THE LIKE, WITH STRUCTURED SURFACE - Google Patents

Description

The invention relates to a method for producing molds and Shells, foundry models, core bushings and the like, also with textured surface, ceramic or other high strength and refractory materials.

It is very expensive to manufacture molds or molded shells that are in their Are structured surface, so for example a leather-like Have structure or with a wood grain on the surface is desired. When such shapes have a long enough life they have to be made of a high-strength material. The usual way to do this is to make an impression of an original model is removed and the surface structure subsequently cutting techniques are brought into shape. this is a elaborate and time-consuming procedure, which is also in most Cases is not automated, so that manual labor is necessary. The same thing applies if the shape should have a very smooth surface.

The object of the present invention is therefore a method of provide the type mentioned above, so that shapes with smoother Surface or with surface structures made with little effort can be, the method can also be largely automated should.

This object is achieved by a method with those specified in claim 1 Process steps solved.

In the method according to the invention, an original model is used that already has the desired surface structures. This original model can be used for Example consist of textiles, plastic, wood, it can have a dermis. It can also be made of wax on which the Structures are applied, if it turns out that this for the Desired surface structure or required for the shape  is. In general, the original model consists of a thermal highly sensitive material. But it can also be made of thermal models insensitive materials such as metal or ceramic.

This original model made of thermally highly sensitive materials is used in first step a layer of a low melting metallic material applied. The selection of the material judges the temperature sensitivity of the underlying master model. You can use tin, bismuth, cadmium, indium, lead, zinc, aluminum, or an alloy of at least two of these substances.

Appropriate techniques to this low melting metal material to be applied to the master model are to be sprayed on or poured on. To the Spraying is a commercially available metal spray gun that is suitable is electrically or gas operated, e.g. an arc, plasma or powder gun, or a melt gun.

The applied self-supporting layer is covered by non-metallic Materials reinforced to an intermediate shape. Either done this by pouring resin, plaster, etc., so that one can massive body, another option is the layer for example to laminate with glass fiber reinforced synthetic resin.

It can also be the low melting metal material in a very thick layer are poured on, so that there is further reinforcement superfluous.

Then the resulting intermediate form is demolded from the master model. The intermediate form now has a metallic side, which is also structured on its surface.

A layer is now made on this metallic side of the intermediate form a high-strength ceramic or other high-melting material brings. Melting here means that the melting point of the material is high compared to the melting point or melting range of the low-melting metallic material. Such materials are for example zinc, aluminum, copper, brass, steel, molybdenum, nickel, Ceramic or an alloy of at least two of these substances, as well  Carbides of these materials.

The high-strength and high-melting material can also be sprayed be applied to the intermediate form. Another one is suitable Metal spray gun or a melt gun as described above. In addition, the flame-arc technique or plasma technique can be used will.

The layer thickness in which the high-strength and high-melting material the intermediate model is applied depends on the later one Application. Layers in thickness from micrometer thicknesses up to to be applied to a few centimeters. In the latter case it will The model is appropriately cooled by cooling coils that have been inserted beforehand.

The high-melting material melts the low-melting material something on its surface. So you get liability for Intermediate model, without the need to use special adhesion promoters. Also the commonly used method of roughening the model surface sandblasting can be omitted. Both methods would also be disadvantageous since it is the surface of the intermediate model in its nature influence and worsen.

If the layer of high-melting material is not self-supporting, it can be reinforced with a metal, a metal Alloy, with casting resin or another plastic or with plaster or Concrete.

Now the layer is made of low-melting metallic material melted. Depending on the material used, this can be done in a water bath Oil bath, in a wax / paraffin bath, in a polyethylene glycol bath, in one Furnace or crucible can be made, or the low-melting Material can be melted inductively. As soon as that low-melting material has flowed away or has been derived, are the remaining reinforcement of the intermediate form and the layer is made high-melting material, which forms the final shape, separated from each other. The final shape can be removed.

In this way, dimensionally accurate molded shells can be produced in a short time  will. Surface structures are reproduced well.

Of course, the method is also suitable if none Surface structures on the mold are provided. In this case it receives a shape whose surface roughness is much less than that of Molds that are manufactured using cutting methods. Depending on The material used has a high hardness and strength.

The following is an example of the method based on the drawing are explained. It shows:

Fig. 1 shows the flow chart for a method according to the invention, where applicable. alternative options are also shown,

FIG. 2a preparing the intermediate form,

Fig. 2b the manufacture of the final shape and

Fig. 3 shows a device for melting the layer of low-melting metallic material.

Fig. 1 schematically shows the flow chart for a method according to the present invention. One starts from a positive or negative master model made of any material, the method being particularly suitable for thermally very sensitive materials. The intermediate form is produced in two steps, namely first by spraying a layer of low-melting plastic on the master model, then this layer is laminated with synthetic resin. As an alternative to spraying, the material can also be poured on. It then massively covers the original model in the manner of a backing. The lamination of the layer of low-melting metal material can also be replaced by a massive back casting, for example with casting resin, metal, plaster or the like. Then the finished intermediate model is removed from the mold. The next steps deal with making the final shape. A layer of high-strength and high-melting material is sprayed onto the layer of low-melting metal material. This high-strength layer is cast with resin, metal or ceramic material. Now the layer of low-melting metal material is melted, either with direct heat or inductively. The final shape can now be easily separated and removed from the remaining reinforcement of the intermediate shape.

Fig. 2a shows clearly the manufacturing of the intermediate mold in an image sequence. In partial image I, the original model ( 2 ) rests on a carrier ( 1 ). The carrier ( 1 ) extends beyond the original model ( 2 ). Part II shows how the carrier ( 1 ) and master model ( 2 ) are coated with a layer ( 3 ) of low-melting metal material. It is also possible to attach a frame ( 1 a , 1 b ) to the carrier ( 1 ) and to completely fill the resulting cavity with the low-melting material ( 3 a ). This is shown in Figure IIA. Then the next process step, namely the reinforcement of the layer ( 3 ), is omitted. The layer ( 3 ) can be reinforced with a laminate ( 4 ) made of plastic (Fig. III) or back-cast with solid resin, plaster or the like. This is shown in Figure IIIA, where a frame ( 1 a , 1 b ) is again provided on the support, which form a space to be filled with the material to be cast ( 4 a ). The now finished intermediate form, which preferably consists of a layer ( 3 ) made of low-melting metal material and a reinforcement made of laminate ( 4 ), can now be removed from the original model ( 2 ), the original model ( 2 ) remaining on the carrier ( 1 ) .

FIG. 2b shows the production of the final shape. For this purpose, it is favorable to turn the intermediate shape so that it can be stored on two supports ( 6 a , 6 b ) with the laminate side ( 4 ) at rest. The layer ( 5 ) made of high-strength and high-melting material is then applied, preferably sprayed, onto the layer ( 3 ) made of low-melting metal material. In picture V, the intermediate form ( 3 , 4 ) with the layer ( 5 ) made of high-strength material is shown resting on the supports ( 6 a , 6 b ). A frame ( 7 a , 7 b ) can be attached to the supports ( 6 a , 6 b ) in order to - as shown in Figure VI - together with the intermediate form ( 3 , 4 ) and the layer ( 5 ) a space to be backfilled ( 8 ) to be defined. The backing material will also be selected according to whether, for example, the final shape is hermetically loaded or not. If this is not the case, it is also conceivable to foam the space ( 8 ) with polyurethane or another plastic, whereby the final shape becomes low in weight. If temperature resistance is also required for the backing, materials such as zinc, aluminum, bronze, plaster, concrete and the like are more suitable. Finally, Figure VII shows the final shape, consisting of the layer ( 5 ) made of high-strength material, the frame ( 7 a , 7 b ) and the backing ( 8 ). It is not shown here how the intermediate form and the final form are separated.

This is explained in connection with the device shown in FIG. 3. The device consists of a tub ( 9 ) which rests on legs ( 10 a , 10 b ) provided with feet ( 11 a , 11 b ). A grid or grate ( 12 ) is accommodated in the tub ( 9 ) at a distance from the tub floor. On the grate ( 12 ) is the ready-to-separate arrangement of intermediate form ( 3 , 4 ), final form ( 5 , 7 a , 7 b , 8 ) and supports ( 6 a , 6 b ). So much oil or water ( 13 ) is now introduced into the tub ( 9 ) that the layer ( 5 ) made of high-strength material and thus also the layer ( 3 ) made of low-melting material are well covered. The liquid ( 13 ) is heated to such an extent that the layer ( 3 ) of low-melting material melts. So whether water or oil is chosen as the liquid ( 13 ) depends on the material of which the layer ( 3 ) consists. The low-melting material can now be directed to the bottom of the trough ( 9 ) by tilting the arrangement, or holes can be provided in the laminate layer ( 4 ) at some points through which the low-melting material can flow in the molten state. The material collecting at the bottom of the tub ( 9 ) can be drained off and used again by means of a tap ( 15 ).

The melting can of course also take place in an oven, or also inductively or through a cast in the back door Copper hose or hot cartridge.

Claims (17)

1. Process for the production of molds and molded shells, foundry models, core bushings and the like, also with a structured surface, made of ceramic or high-strength and high-melting materials, for example metals, metal alloys or ceramic materials, in which

• a) a layer of a low-melting metallic material is applied to an original model made of thermally highly sensitive materials,
• b) this layer is reinforced to an intermediate shape by non-metallic materials,
• c) the intermediate form is demolded from the original model,
• d) a layer of ceramic or a high-strength and high-melting material forming an end shape is applied to the metallic side of the intermediate shape,
• e) the layer of low-melting metallic material is melted and
• f) the final shape of the remaining reinforcement of the intermediate shape is removed.

2. The method according to claim 1, characterized in that the layer of low melting metallic Material is applied in self-supporting strength. 3. The method according to claim 1 or 2, characterized characterized in that the layer of low melting metallic material with a thickness in Micrometer range is applied. 4. The method according to any one of claims 1 to 3, characterized characterized that as a low melting point metallic material tin, bismuth, cadmium, indium,  Lead, zinc or an alloy of at least two of these substances is used. 5. The method according to any one of claims 1 to 4, characterized characterized in that the low-melting metallic Material is sprayed onto the master model. 6. The method according to any one of claims 1 to 4, characterized characterized in that the low-melting metallic Material is poured onto the master model. 7. The method according to any one of claims 1 to 6, characterized characterized in that the layer of ceramic or high-strength and high-melting material on the metallic side of the intermediate form is sprayed on. 8. The method according to any one of claims 1 to 7, characterized characterized in that the layer of ceramic or high-strength and high-melting material in thicknesses up to a few centimeters on the metallic side of the Intermediate form is applied. 9. The method according to any one of claims 1 to 8, characterized characterized in that the layer of ceramic or high-strength and high-melting material in one Thickness in the micrometer range on the metallic side the intermediate form is applied. 10. The method according to any one of claims 1 to 9, characterized characterized that as a high strength and high melting point Material zinc, aluminum, copper, brass, steel, Molybdenum, nickel, ceramic or an alloy at least two of these substances are used. 11. The method according to any one of claims 1 to 10, characterized characterized in that the layer of ceramic or high strength and high melting material after the  Apply to the metallic side of the intermediate form is mechanically reinforced to a final shape. 12. The method according to claim 11, characterized in that the layer of ceramic or high strength and high melting material for reinforcement with a Resin is cast. 13. The method according to claim 11, characterized in that the layer of ceramic or high strength and high melting material for reinforcement with a Metal is poured. 14. The method according to claim 11, characterized in that the layer of ceramic or high strength and high melting material for reinforcement with a ceramic material is poured. 15. The method according to any one of claims 1 to 14, characterized characterized in that the low melting alloy after applying the layer of ceramic or high-strength and high-melting material in an oil bath is melted. 16. The method according to any one of claims 1 to 14, characterized characterized in that the low melting alloy after applying the layer of ceramic or high-strength and high-melting material inductive is melted. 17. The method according to any one of claims 1 to 14, characterized characterized in that the low melting alloy after applying the layer of ceramic or high-strength and high-melting material in a water bath, in a wax / paraffin bath or in one Polyethylene glycol bath is melted.