EP0067955A1 - Method of and installation for producing shell moulds - Google Patents

Abstract

1. A method of preparing a shell mould - for foundry use - from a thermally hardenable moulding sand by forming it on a heatable pattern (1) the shaped surface of which is turned downwardly, characterized in that the pattern (1) is heated, until the shell mould has been formed, in a mass of sand (7) fluidized by a rising air stream, that while the shell ist being formed air is fed under pressure through a base plate (11) into an enclosed space, and in that the air egress form the enclosed space through a pattern plate (2) carrying the pattern (1).

Description

The invention relates to a method for producing molding masks for foundry applications from a thermosetting molding sand on a heatable model and to an apparatus for carrying out the method. It refers to all suitable types of sand, the corresponding binders, e.g. in the form of a coating of the individual grains of sand or by a moisture-binding admixture to the sand.

The production of mold masks with thermally curing molding sand according to the so-called croning process is generally known. The methods used hitherto have disadvantages with regard to the freeing of the finished model from the uncured molding sand and from the point of view of unsatisfactory guidance in the curing of pollutants that arise. Furthermore, the great procedural and structural effort is felt to be disadvantageous.

The invention has for its object to simplify and accelerate the manufacturing process and also to offer suitable measures for removing the pollutants. Use in a higher-level production process should also be possible or guaranteed.

The object is mainly achieved by heating the model with the mold surface facing downward in a sand volume fluidized by an increasing air flow until a mold mask is formed. A further contribution to the solution is that air is removed from the interior via a model plate carrying the model during mask formation. A suitable method for this apparatus includes a fluid container with a bottom flask equipped with air supply openings and the fluid container can be lifted final model ^p latte with air outlet openings.

The hanging arrangement of the model in the fluidized sand volume allows the finished molding mask to be lifted up with the model, while the excess, not hardened molding sand remains in its position, in particular in a fluid container. The thickness and strength of the resulting mask can be adjusted in the usual way by the model temperature and the curing time and, moreover, according to the invention by the density of the fluidized sand, which can be regulated as a function of the air flow.

A particular possibility of influencing the mask formation arises if a model plate carrying the model or a bottom piston in a fluid container are brought closer to one another during the mask formation, in particular by lifting the bottom piston. Lowering the model plate and lifting the bottom piston is equivalent in terms of process technology. When the bottom piston can be raised, the model plate can then be designed in a particularly simple manner in the form of a lid on the fluid container.

The fluidization of the sand takes place by blowing air into the bottom area of a fluid container or other device, in particular through openings in the bottom piston, the air being able to escape through openings in the model plate, in particular in the vicinity of the model, through openings of a suitable size. Depending on the model shape, discharge or suction openings can also advantageously be present in the model area itself, in order to accelerate or improve the mask formation. The supply of air continues to take place during the removal of the molding mask and the refilling of the processed sand.

One embodiment which is particularly suitable for solving the task provides a model plate which can be connected in a sealing manner to the container and on which the pollutants can emerge collectively at a single suction opening. In a similar manner, the bottom piston is preferably designed with a compressed air connection opening. Instead of a multiplicity of small openings in the bottom flask which are endangered by sand closure, a bottom flask made of an air-permeable sintered material is preferred according to the invention.

The sand can be refilled with the lid lifted off in the usual way by pouring in from above or, in a preferred automatic manner, by slipping over lateral filler necks in the fluid container. The dumping height is automatically set by the height of the inlet openings in combination with a lowering of the bottom piston. The sand in the fluid container normally remains in a fluidized state. The filler necks are connected to a sand reservoir located higher up via pipes that continuously drop from it.

According to the invention, a cooling channel in the fluid container in the upper area prevents heat transfer from the heated model and the model plate to the fluid container, so that hardening of the sand contained therein is precluded.

The figure shows an embodiment of a device according to the invention.

A model 1 is attached with the mold surface facing downward to a model plate 2 which has air outlet openings 3 in the form of slot nozzles in the vicinity of the model. The model plate 2 has an air suction box 15 with a suction nozzle 16. The model plate 2 serves as a removable, ins Special hinged lid of a fluid container 10, which has a cooling channel 4 in the upper region. Below the model, in the situation shown, there is a free space 5 before the mask formation begins. The fluidized sand volume 7 has automatically increased to the level of filler necks arranged on both sides. The filler neck 6 are connected to a sand reservoir, not shown, via falling channels. The vertically movable bottom piston 11, which is provided with a plurality of air supply openings 17, is sealed off from the fluid container 10 by a sealing lip 12. An overpressure box 9 is built underneath the bottom piston 11, which forms a pressure chamber 8 with it and is supplied via a flexible pressure line 14. The bottom piston 11 with the overpressure box 9 can be moved in height by means of an adjusting device 13, which is not described in more detail, so that the fluidized sand can be moved in a desired manner to the model constantly or periodically to the extent that a density and hardening-controlled form mask is produced.

Claims (16)

1. A process for the production of molds for foundry applications from a thermosetting molding sand on a heatable model, characterized in that the model (1) is heated with the mold surface facing downwards in a sand volume fluidized by an increasing air flow (7) until a mold mask is formed . becomes. 2. The method according to claim 1,
characterized in that before the formation of a mask, an interior space under the model (1) is heaped up with sand while maintaining a free space (5), and that during the formation of the mask the interior space is reduced to one another while its base piston (11) and the model plate (2) are approaching each other. 3. The method according to any one of claims 1 or 2, characterized in that the bed height in the interior is automatically controlled by the entrance height (6) of a sliding sand pillar. 4. The method according to any one of claims 1 to 3, characterized in that the sand volume (7) in the interior is fluidized during the pouring or automatic sliding from the higher sand column. 5. The method according to any one of claims 1 to 4, characterized in that at least during the mask formation, the interior air is supplied with overpressure via its bottom piston (11). 6. The method according to any one of claims 1 to 5, characterized in that air is removed from the interior via a model plate (2) supporting the model during mask formation. 7. Apparatus for carrying out the method according to one of claims 1 to 6, characterized by a fluid container (10) with a bottom with air supply openings (17) and a fluid plate (10) closing, removable model plate (2) with air outlet openings (3). 8. The device according to claim 7, characterized by a within the fluid container (10) vertically movable bottom piston (11). 9. Device according to one of claims 7 or 8, characterized by a vertically movable model plate (2) within the fluid container (10). 10. The device according to one of claims 7 or 8, characterized by a hinged to the fluid container (10) hinged, hinged model plate (2). 11. The device according to one of claims 7 to 10, characterized by a bottom piston (11) made of air-permeable sintered material. 12. The device according to one of claims 7 to 11, characterized by an overpressure box (8) built under the bottom piston (11). 13. Device according to one of claims 7 to 12, characterized by one of the model plate (2) mounted air suction box (15). 14. The device according to any one of claims 7 to 13, characterized by at least one lateral filler neck (6) in the fluid container (10), which is attached at dumping height. 15. Device according to one of claims 7 to 14, characterized by a above the filler neck (6) arranged, by falling channels connected to this sand reservoir. 16. The device according to one of claims 7 to 15, characterized by a in the height of the model plate (2) arranged cooling channel (4) on the fluid container (10).

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