EP0673698A1 - Method for the production of moulds - Google Patents

Abstract

The appts. comprises a pattern plate (4), a mould box (3) and a compression unit (1) for pneumatic preliminary compression and mechanical final compression by means of a pressure ram (13). The appts. is characterised by the following features: (a) the pressure ram (13) is elastically deformable at least within the region of its pressure area (13a); (b) a pressure space (15) is located above the pressure ram and is connected to a compressed air supply; and (c) the pressure ram is provided with bores (13d) connecting the mould space (12) above the mould material (6) with the pressure space (15).

Description

The invention relates to a device for producing casting molds, with a model plate provided with a model, with a mold box which can be placed on the model plate for receiving a compressible molding material, in particular molding sand, and with a compression device which can be placed on the mold box, with a pneumatic precompression and at least a stamp for mechanical compression of the molding material.

From EP patent 0 319 453 B1 a method for compressing granular molding material is known, in which compressed air flows through the molding material even during the mechanical post-compression and where ventilation holes for the compressed air are provided in the model plate of the device for this purpose; the air pressure can be kept relatively low in comparison to the previous pneumatic precompression, so that one can speak of a flushing of the molding sand.

Instead, however, it is also possible to operate the pre-compression by means of a compressed air which is exposed to a relatively short-term pressure pulse Vent holes can be omitted if necessary; however, mechanical post-compression can also be associated with constant compressed air purging of the molding material.

In order to obtain a uniform post-compression regardless of the shape of the model, it has long been known from British patent application GB 2 046 644 A to use a larger number of parallel stamps, which according to European patent 0 263 977 B1 are also independent of one another can be displaceable.

An arrangement according to US Pat. No. 3,401,685 pursues the same purpose, irrespective of the type of precompression used, in that the (only) pressure stamp for the mechanical post-compression is elastic. In this way, the higher costs associated with a large number of pressure stamps are avoided, and such a design is undoubtedly closer to uniform post-compression than is possible when using a single rigid pressure stamp. However, the pressure distribution in the molding material is no longer uniform during the pneumatic pre-compression, because the compressed air that is directed around the pressure ram cannot build up a surface pressure of the same level on the entire surface of the molding material, especially if there is an outflow through the molding material and the model plate should. Flawless post-compaction also depends, among other things, on whether it was possible to ensure that the molding material was uniformly compact and independent of the model contour and the contour of the pressure stamp during pre-compaction.

The object of the invention is therefore to design a device of the type specified at the outset in such a way that that with their help and by means of a single pressure ram, both in the pneumatic pre-compression and in the mechanical post-compression, the molding material can be compacted uniformly with an approximately constant surface pressure over the entire surface of the molding material, regardless of the shape of the overmolded model. The device should also make it possible to carry out the pre-compression of the molding material both with a constant pressure gradient of the compressed air with an effective outflow via the ventilation holes and with a brief pressure pulse to which the compressed air is exposed.

According to the invention the object is achieved in that the pressure stamp is elastically deformable at least in the area of its pressure surface, that a pressure chamber is provided in the compression device above the pressure stamp, in which the compressed air supply opens, and that through holes are arranged in the pressure stamp, which one between the Pneumatically connect the surface of the molding material and the mold cavity formed with the pressure chamber. The through holes in the plunger are expediently distributed so that the surface of the molding material is exposed to the same pressure from the compressed air throughout. In this way, the entire configuration of the molding space is exposed to this static pressure of the compressed air, and pressure drops within the molding space and thus, in particular, along the surface of the molding material are largely avoided. On the other hand, the effect of the mechanical post-compression is not affected by the arrangement of the through bores, because the outer shape of the pressure stamp is not impaired and the shape of the models can still be flexibly followed.

On the one hand, it is possible that vent holes for the compressed air are provided in the model plate and the through holes are dimensioned according to the number and cross section are that during the pre-compression there is a uniform flow of the molding material, on the other hand the through holes can be dimensioned in terms of number and cross-section so that during pulsed compressed air feeding into the pressure chamber the air pressure built up there is also instantaneous in the molding space above the surface of the molding material; vent holes for the compressed air can also be provided in the model plate.

The arrangement and dimensioning of the through holes and any ventilation holes can be determined by tests. Of course, it also depends on the type of molding material, the specific geometric conditions and the pressures and forces used.

In a particularly advantageous embodiment of the invention, the pressure stamp is composed of an at least partially elastically deformable pressure plate and a rigid frame enclosing the pressure plate outside the pressure surface. In this way, the pressure plunger can be conveniently guided in the housing of the device and connected to the piston rod of the pressure piston. The frame of the pressure plate by the frame also ensures that permanent deformations of the pressure plate are avoided because the pressure plate cannot flow under the influence of the possibly high applied pressure force.

A further improvement in the mode of action can be achieved. if the pressure plate consists of several interconnected plate layers transversely to their direction of movement, which in turn can consist of materials of different elasticity, the elasticity of the plate layers expediently increasing in the direction of the printing surface. The printing plate is in one Case can be carried out very dimensionally stable, even if the printing surface is highly elastic.

It is technically possible and particularly advantageous for the mode of operation of the invention if the elasticity of the pressure plate, in particular in the area of its pressure surface, is dimensioned such that during the mechanical re-compression of the molding material the outlets of the through holes which are in contact with the molding material through the pressure plate acting reaction forces are contracted. As a result, the pressure surface of the pressure stamp that actually loads the molding material increases during the post-compression, and the squeezed outlets no longer act as defects in the pressure surface.

In a special way, the device according to the invention for generating a pressure pulse for precompression can be set up in such a way that the pressure chamber consists of two subspaces which are separated from one another by a partition which is fixed to the housing of the compression device and extends transversely to the direction of movement of the pressure stamp, and which means in the partition provided openings are pneumatically connectable to each other, and that the piston rod is guided through the partition, whereby an interruptible pneumatic connection of the two subspaces can be produced, for example, in such a way that the openings in the partition and the through holes offset relative to one another transversely to the direction of movement of the pressure stamp are arranged so that the subspaces are pneumatically separated from one another when the plunger bears against the partition. In this way, a compressed air, possibly with a high air pressure, can be provided in the partial space connected to the compressed air supply, which compressed air only reaches the second partial space above the molding material when the pressure stamp moves away from the partition towards the molding material is moved; the through holes are blocked as long as the pressure stamp is still against the partition. In this way, the molding material can suddenly be exposed to high air pressure.

It is expedient if the material is incompressible for at least one plate layer. Otherwise, a filling frame can be arranged between the compression device and the molding box.

The invention eliminates the disadvantages of the prior art in a surprisingly simple manner and does not require any significant additional effort; on the other hand, it can be used universally in the embodiment described and combines the advantages of the known devices with elastic pressure stamps with the advantages of a uniform pneumatic pre-compression.

Fig. 1

eine erste Ausführung einer erfindungsgemäßen Vorrichtung in geschnittener Vorderansicht während der pneumatischen Vorverdichtung,

Fig. 2

eine dem Schnittverlauf A - A folgende geschnittene Draufsicht zu Fig. 2,

Fig. 3

die Ausführung der Fig. 1 während der mechanischen Nachverdichtung,

Fig. 4

eine zweite Ausführung einer erfindungsgemäßen Vorrichtung in geschnittener Vorderansicht während der pneumatischen Vorverdichtung und

Fig. 5

die Ausführung der Fig. 4 während der mechanischen Nachverdichtung, sämtlich in schematisch vereinfachender Darstellung gezeichnet.

The invention is described below with reference to the drawing of an embodiment. Show it

Fig. 1

a first embodiment of a device according to the invention in a sectional front view during the pneumatic pre-compression,

Fig. 2

3 shows a sectional top view of FIG. 2 following the course of the section A - A,

Fig. 3

1 during the mechanical post-compression,

Fig. 4

a second embodiment of a device according to the invention in a sectional front view during the pneumatic precompression and

Fig. 5

4 during mechanical post-compression, all drawn in a schematically simplified representation.

A device according to the invention initially consists, according to FIG. 1, of a compression device 1 which is placed on a molding box 3 via a filling frame 2. The molding box 3 in turn sits on a model plate 4 on which the models 5 (here two) to be molded are located. The molding box 3 and part of the filling frame 2 are filled with a molding material 6, over the (horizontal) surface 61 of which a molding space 12 is formed in a housing 11 of the compression device 1, which is also delimited by a pressure surface 13a of a pressure stamp 13. The pressure stamp 13 is movable in the housing 11, the filling frame 2 and the molding box 3 in the vertical direction by means of (here four) pressure pistons 14, as far as the molding material 6 permits. Vent holes 41 are provided in the model plate 4, which pneumatically connect the interior of the molding box 3 and thus the molding space 12 to the surroundings of the device. In the

Vent holes 41 inserted screens 42 prevent the passage of molding material 6.

The piston-like pressure stamp 13 has a pressure plate 13b which is clamped in a frame 13c on all sides, in this case the pressure surface 13a located on the pressure plate 13b and acting on the surface 61 of the molding material 6 and also leaving part of the pressure plate 13b itself free. The frame 13c is also used for the axially movable mounting of the pressure plunger 13 in the housing 11 and for attachment to piston rods 14a of the pressure pistons 14 fixedly installed on the housing 11. The piston rods 14a are located above the pressure plunger 13 in a pressure chamber enclosed by the latter and the housing 11 15, which can be connected via a compressed air supply 16 to a compressed air source omitted in the drawing via a shut-off device 17. The flow direction and paths of the compressed air are illustrated in the drawing by direction arrows. The relatively large flow cross section of the compressed air supply 16 compared to the second embodiment described below is intended to make it clear that a compressed air flow that is to be maintained constantly requires a high compressed air throughput under certain circumstances. This flow of compressed air takes place via through bores 13d in the plunger 13, which pneumatically connect the pressure chamber 15 to the mold chamber 12 in an axially parallel manner. In FIG. 2 it can be seen that a multiplicity of through bores 13d approximately equally spaced from one another are arranged; in the same way it can be seen that there are four piston rods 14a which also belong to a total of four pressure pistons 14.

The mold space 12 which is more real in FIG. 1 and the opened shut-off device 17 indicate that the pneumatic precompression of the molding material 6 has started. 3, the shut-off device 17 is closed, and instead the pressure plunger 13 is raised onto the molding material 6 by actuation of the pressure piston 14 for mechanical post-compression of the molding material 6, so that the molding space 12 has disappeared. The elasticity of the pressure plate 13b can be controlled by its design so that the outlets 13e of the through bores 13d facing the molding material 6 are squeezed together under the influence of the reaction force exerted by the molding material 6 and only narrow slits remain. In this way, a relatively undisturbed printing surface 13a; nevertheless, the narrowed outlets 13e suffice to maintain a flow of compressed air even during mechanical post-compression if the shut-off device 17 remains open. The surface 61 of the molding material 6 is now no longer flat, because its shape is influenced by the models 5 when it is compacted approximately in space.

The pressure plate 13b, which is only partially clamped on its circumference in the frame 13c, is also deformed by the reaction force of the molding material 6 in the region of the edges of the pressure surface 13a in the direction of the housing 11, as in FIG. 3 (and also in FIG. 5) is indicated. The axis guidance of the pressure stamp 13 in the housing 11 is thereby improved.

The embodiment of FIGS. 4 and 5, in which the same components as the embodiment of FIGS. 1 to 3 are provided with the same, but in each case simply underlined reference numerals, differs only slightly from the variant of FIGS. 1 to 3 described in detail above ; it is therefore sufficient to state the main changes.

In Fig. 4 it can be seen that the pressure chamber 15 'is divided into two by a partition 18 which is fixedly clamped in the housing 11', in such a way that the compressed air supply 16 'opens into an upper section 15a. The representation of the compressed air supply 16 'and also the shut-off device 17' is intended to symbolically indicate that in this second embodiment, a flow cross-section which is substantially smaller than that of the first is sufficient for the compressed air flowing into the pressure chamber 15 '.

The pressure ram 13 'is still attached to the piston rod 14a' of a (here only) pressure piston 14 'and is initially under its influence on the underside of the partition wall 18, leaving a molding space 12' above the surface 61 'of the molding material 6' .

The partition wall 18 is provided with a number of openings 18a comparable in size to that of the through bores 13d '; however, these are axially offset from the through bores 13d ', so that when the frame 13c abuts the partition 18, the pressure chamber 15' of the molding chamber 12 'is pneumatic is separated; A high pressure potential can form in the subspace 15a, even with compressed air flowing in only moderately quickly from the compressed air supply 16 ', which also loads the pressure ram 13'.

If the pressure plunger 13 'is only slightly removed by the pressure piston 14' from the partition 18 and moved downward at such a pressure potential, a subspace 15b of the pressure space 15 'is created, and the compressed air expanding into the subspace 15b can be accessed via the now accessible Through holes 13d 'suddenly load the molding material 6' and pre-compress in a pulsed manner. The subspace 15b is further enlarged in accordance with FIG. 5 when the mechanical post-compression is initiated by means of the pressure piston 14 ', the course of which does not differ from that of the embodiment in FIGS. 1 to 3; consequently, it is also conceivable here that the shut-off device 17 'shown closed in FIG. 5 is still open and compressed air flows through the molding material 6' during mechanical post-compression.

List of reference numbers

1.1 '

Compression device

11.11 '

casing

12.12 '

Molding space

13.13 '

Pressure stamp

13a, 13a '

Printing area

13b, 13b '

printing plate

13c, 13c '

frame

13d, 13d '

Through hole

13e, 13e '

Outlet

14.14 '

Pressure piston

14a, 14a '

Piston rod

15.15 '

Pressure room

15a

Subspace

15b

Subspace

16.16 '

Compressed air supply

17.17 '

Shut-off device

18th

partition wall

18a

Breakthrough

2.2 '

Filling frame

3.3 '

Molded box

4.4 '

Model plate

41.41 '

Vent hole

42.42 '

Sieve

5.5 '

model

6.6 '

Molding material

61.61 '

surface

Claims (14)

Device for the production of casting molds, with a model plate provided with a model, with a mold box that can be placed on the model plate for receiving a compressible molding material, in particular a molding sand, and with a compression device that can be placed on the mold box, with a pneumatic precompression and at least one pressure stamp for one mechanical post-compression of the molding material,
characterized in that (a) the pressure stamp (13, 13 ') is elastically deformable at least in the area of its pressure surface (13a, 13a'),
(b) a pressure chamber (15, 15 ') is provided in the compression device (1, 1') above the pressure ram (13, 13 '), in which the compressed air supply (16, 16') opens, and
(c) through bores (13d, 13d ') are arranged in the pressure stamp (13,13'), which one between the surface (61,61 ') of the molding material (6,6') and the pressure stamp (13,13 ') Connect the formed mold space (12, 12 ') to the pressure space (15, 15') pneumatically. Device according to claim 1, characterized in that the through bores (13d, 13d ') in the pressure ram (13, 13') are distributed such that the surface (61, 61 ') of the molding material (6, 6') is the same throughout Air pressure is exposed. Apparatus according to claim 1 or 2, characterized in that vent holes (41, 41 ') are provided in the model plate (4,4') for the compressed air and the through holes (13d, 13d ') are dimensioned in number and cross section such that during the precompression has a uniform flow through the molding material (6, 6 '). Apparatus according to claim 1 or 2, characterized in that the through bores (13d, 13d ') are dimensioned in terms of number and cross-section so that the air pressure built up there also without delay during a pulsed compressed air feed into the pressure chamber (15, 15') in the molding space (12, 12 ') above the surface (61, 61') of the molding material (6, 6 '). Device according to claim 4, characterized in that ventilation holes (41, 41 ') for the compressed air are provided in the model plate (4,4'). Device according to one of claims 1 to 5, characterized in that the pressure stamp (13, 13 ') consists of an at least partially elastically deformable pressure plate (13b, 13b') and a pressure plate (13b, 13b ') outside the pressure surface (13a, 13a ') enclosing rigid frame (13c, 13c'). Device according to one of claims 1 to 6, characterized in that the pressure plate (13b, 13b ') consists of several interconnected plate layers transversely to their direction of movement. Device according to claim 7, characterized in that the plate layers each consist of materials of different elasticity. Device according to claim 8, characterized in that the elasticity of the plate layers increases in the direction of the pressure surface (13a, 13a '). Device according to one of claims 1 to 9, characterized in that the elasticity of the pressure plate (13b, 13b '), in particular in the area of its pressure surface (13a, 13a'), is dimensioned such that during the mechanical post-compression of the molding material (6, 6 ') the outlets (13e, 13e') of the through bores (13d, 13d ') which bear against the molding material (6,6') are contracted by the reaction forces acting on the pressure plate (13b, 13b '). Device according to one of claims 4 to 10, characterized in that the pressure chamber (15 ') consists of two partition walls which are fixed to the housing (11') of the compression device (1 ') and extend transversely to the direction of movement of the pressure ram (13') (18) separate compartments (15a, 15b), which can be pneumatically connected to one another by means of openings (18a) provided in the partition (18), and that the piston rod (14a ') is guided through the partition (18). Apparatus according to claim 11, characterized in that the openings (18a) in the partition (18) and the through bores (13d ') are arranged so as to be offset from one another transversely to the direction of movement of the pressure ram (13') such that when the partition (18 ) adjacent plunger (13 ') the subspaces (15a, 15b) are pneumatically separated from each other. Device according to one of claims 8 to 12, characterized in that the material is incompressible for at least one plate layer. Device according to one of claims 1 to 13, characterized in that a filling frame (2,2 ') is arranged between the compression device (1,1') and the molding box (3,3 ').

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