DE2802103A1 - METHOD OF CASTING USING A VACUUMFORMED COCILLE AND COCILLE THEREFORE - Google Patents

Description

Henkel, Kern, Feiler & Hänzel patent attorneys

Möhlstrasse 37 Mitsubishi Jukogyo Kabushiki Kaisha D-8000 Munich 80

Tokyo, Japan Tel: 89/982085-87

* ^v Telex: 0529802 hnkld

Telegrams: ellipsoid

J Jan. 8, 1978

Process for casting by means of a vacuum-formed mold

and mold therefor

The invention relates to a method for casting by means of a vacuum-formed mold and a mold for carrying out this process.

In a molding method for manufacturing a vacuum-formed mold, an airtight parting material, for example a plastic film, on the surface of a template or a pattern and on the surface of a pouring barrel or channel, a riser and a possibly existing blind riser. After that

coated samples in a predetermined position in an upper and a lower flask provided with an evacuating device connected, has been brought, a binder-free, granular refractory material, e.g. molding sand, filled into the molding boxes. Then the upper and lower sides of the molding boxes containing the molding sand by means of a airtight sealing or separating material tightly closed, after which the interstices in the in the molding boxes Molding sand by means of the evacuation device with an Ubteidrudc

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be applied. The evacuation device can, for example, consist of a device for evacuating the cavities of the molding boxes connected vacuum pump exist. The molding sand is due to the difference in this vacuum application aggregated and compressed between the atmospheric pressure surrounding the pattern and the negative pressure. on In this way, a pattern surface that is complementary to the configuration of the pattern or the template is molded in the molding sand, and the release film is sucked onto the pattern surface. If then the pattern or the template from the molding boxes taken out and the molding sand is kept under a vacuum, a vacuum-formed mold with the same shape as the pattern, which is provided with a sprue barrel, riser, and so on. By subsequent Pouring molten metal into the mold space of the mold is then obtained a cast of the pattern or the template.

In the previous methods of this type, a riser or riser funnel is generally provided in the manner described below in connection with FIG. 1, which feeds molten metal to the casting during cooling and enables its shrinkage. According to Fig. 1, an upper and a separable lower molding box 1 and 1 ^! provided, which are each provided with an evacuation device. ^{Evacuation or suction openings 2 or 2 1} provided in the molding boxes 1, 1 · can be connected to the actual evacuation device (not shown), for example a vacuum pump. 1, evacuation or suction filters 3, 3 ¹ are inserted into the molding boxes. The molding boxes are filled with a granular refractory material 4, for example "with binder-free molding sand, the surfaces of which are coated with an airtight separating material 5, for example. B. be covered in the form of a plastic film. The mold space 6 remaining after the stencil has been removed goes into a pouring run or -Trich-

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ter 7 and risers 8 and 9 over. The particularly deep riser 9 is generally provided when a casting with complex shape is to be cast.

Follow-up or
In addition to the so-called feeding effect during cooling, the risers 8 and 9 prevent deformation of the mold space 6 in this mold by allowing atmospheric air to enter the mold space, even if the airtight foils 5> are affected by the negative pressure applied while covering those corresponding to the pattern Inner surfaces of the mold space 6 are sucked onto these surfaces, melt away under the influence of the heat of the molten metal poured in through the barrel 7.

The previous vacuum-formed mold, however, has the following deficiencies:

1. Since the molten metal as a result of the particularly deep rise during cooling, a much larger volume than the volume supplied to the casting must have the output rate during casting is greatly reduced.

2. As the elongation limit of the airtight plastic film is often exceeded if the stencil surface is covered with only one film, a secondary stencil must be used for the Steiger 9 separately clad with an airtight film and the latter separated and airtight with the Foil cover of the main stencil are connected, which requires a lot of additional work and time and consequently increased manufacturing costs.

3. The deep riser 9 can, depending on its location, sometimes an auxiliary suction pipe 21 or the like. hinder in the molding box 1, so that it becomes necessary to change the structure of the molding box 1.

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- ⁶ - 280210a

The object of the invention is thus to create a casting process using a vacuum-formed mold with riser or riser funnel, with the under extensive or practically complete avoidance of the disadvantages inherent in the previous process, a better way of working is guaranteed.

This object is used in a method of casting a vacuum-formed mold with a blind riser solved according to the invention in that the blind riser with a ventilation hole and is provided with a cone element at an appropriate point of its upper part, wherein the molten metal in contact with the cone element in the blind riser during cooling after The casting process remains in the molten state for longer and that an internal pressure within the refractory material of the mold is generated, by which the supply of the molten metal from the blind riser to the casting to compensate for shrinkage losses is favored.

A vacuum-formed mold with blind riser for carrying out this process is characterized in that the blind riser in its upper region has a ventilation hole and a conical element that extends to a point below the Height protrudes downwards, which the molten metal after pouring achieved, and that the arrangement is such that as a result of the contact between the molten metal and the cone element the refractory material of the mold is thermally saturated around the blind riser and consequently the solidification the metal melt in the blind riser is delayed.

The following are preferred exemplary embodiments of the invention in comparison to the prior art with reference to the attached Drawing explained in more detail. Show it:

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-Fig. 1 a schematic representation of a previous Vei »- driving for the production of vacuum-formed molds,

Figure 2 is a schematic partial sectional view of a mold according to a preferred embodiment of the invention and

3, 4, 5 and 6 of FIG. 2 are similar schematic representations of modified embodiments of the invention.

Fig. 1 has already been explained at the beginning.

According to Fig. 2, a granular, binder-free refractory material 4, e.g. molding sand, is filled into the molding boxes, whereby an airtight separating material 5, such as plastic film, is provided as a coating for the surfaces of this material. After the molding sand has been compacted around the coated or lined template, the template is removed, leaving behind the mold space 6. The details of the molding boxes and its components correspond essentially to those in the case of the one previously described in connection with FIG Chill mold, which is why parts corresponding to the parts of FIG. 1 are denoted by the same reference numerals as there.

Following the mold space 6, a blind riser 10 is formed, and at a suitable point in the upper part of this blind climber 10, preferably at its highest point a downwardly projecting conical element 11 is provided, which fulfills the same task and offers the same advantages like the previously usual atmospheric pressure core, i.e. a so-called "William's" core.

The blind riser 10 is provided with a ventilation hole 12 connected to the outside air, whereby loading

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vent hole 12 and control element 11 to the in Fig. 2 The manner shown are arranged and formed in a molding box, which is equipped with an evacuation device of the in Connection with Fig. 1 described type is provided.

When a pouring run, not shown in FIG. 2, molten metal is poured into the mold space 6 of the vacuum-formed mold described, mold space 6, blind riser 10 and ventilation hole 12 filled with the melt. When the casting begins to cool in the mold space and therefore shrinks, the melt contained in the blind riser 10 flows to the casting. Here the tip of the is at the top of the Blind riser 10 provided conical element 11 so sharp that the molding material, e.g. molding sand, by the heat of the Molten metal is thermally saturated. When the casting begins to solidify, the metal therefore remains around the conical element 11 around in the molten state, and since the molding sand is subjected to an internal pressure of the order of -400 mm Hg is, there is a pressure feed of the molten metal to the casting instead. As a result, forms over the lost Head in the Steiger 10 gradually a cooling and shrinking cavity, the volume of which finally decreases to a Size increased according to the total shrink volume. In this way, a flawless casting is formed in the mold space 6, which has no defects such as shrinkage voids. When the molten metal is poured into the mold space 6, the airtight separating film 5 covering the inner surfaces melts under the heat of the molten metal, so that the pressure difference existing across the film between the molding sand 4 and the mold space 6 is compensated and as a result normally no deformation of the mold space 6 occurs. However, since the mold space 6 is subjected to atmospheric pressure via the ventilation hole 12 and the blind riser 10, the said pressure difference can be retained, so that the possibility of deformation of the mold space 6 is largely possible is avoided.

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In the modified embodiment shown in FIG According to the invention, an atmospheric pressure core or William's core 15 in a suitable position is highest Point of the blind riser 10 arranged. After the ventilation hole 12 is formed separately and with an airtight Release film has been coated, this film is covered with the help of an adhesive strip 14 with the blind riser 10 airtight film connected. When using a separate atmospheric pressure core or cone 13 of Art according to FIG. 3 there is the advantage that there is only a small risk of deformation at this point. Of the Namely, atmospheric pressure core 13 itself is not subject to deformation because it is made of sand with a binding agent, e.g. Oil sand or COp sand.

In the further modified embodiment according to FIG. 4, the atmospheric pressure core or cone 13 is in the blind riser 10 arranged at the lower end of the ventilation hole 12 and aligned with the latter by means of an auxiliary tube 16. The ventilation hole itself is formed by a pipe 15, which is connected to the auxiliary pipe 16 by means of an adhesive strip or tape 17. Since in this embodiment the molten metal does not enter the pipe 15, is the advantage of a corresponding increase in the output achieved during casting. Since there is still no possibility there is for the molten metal to flow over the ventilation hole onto the surface of the molding box and thereby melting the airtight release film covering the surface thereof, becomes advantageous ensures that the negative pressure acting on the molding sand is not subject to fluctuations.

Another modification is shown in FIG which the volume of the blind riser and therefore also the atmospheric pressure core 13 are small. This core or that

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Cone element 13 is arranged similarly to FIG. 4, but no auxiliary pipe 16 is provided. After the arrangement of the cone element 13 on the top of the blind riser this at the same time clad or covered with the cladding of the stencil surface with an airtight separating film. The pipe 15 for admitting atmospheric air is after the separating film has been cut out accordingly, arranged or inserted on the upper side of the conical element 13, whereupon these parts are connected to one another with the aid of an adhesive strip 18.

In the further modification according to FIG. 6, there is an atmospheric pressure core or cone element 13 similar to that of FIG. With a projection or sprue 19 for placing the lower End of the tube 15 provided. This has the advantage that deformation is prevented after the molding sand has been filled does not have to be left exclusively to the adhesive strip 18 in the molding box.

When using the method according to the invention, the molten metal feed is used from the blind climber obviously highly effective. A sufficient supply of melt can thereby be achieved with a blind riser of small volume can be expected without the possibility of overflowing the molten metal through the ventilation hole. This offers the practical advantage that not only the application of the Castings is improved, but also a low likelihood of producing a casting with There are casting defects.

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Claims (5)

Henkel, Kern, Feiler & Hänzel Patentanwälte 280210 Möhlstrasse 37 Mitsubishi Jukogyo Kabushiki Kaisha D-8000 Munich 80 Tokyo, Japan Te!.: 089 / 982085-87 Telex: 0529802 hnkl d Telegrams: ellipsoid J Jan. 8, 1978 Claims 1. Method of casting using a vacuum formed Mold with a blind riser, characterized in that the blind riser with a ventilation hole and is provided with a cone element at an appropriate point on its upper part, the one in the blind climber metal melt in contact with the cone element during cooling after the casting process remains in the molten state longer, and that an internal pressure within the refractory material of the mold is generated by the feeding of the molten metal from the blind riser to the casting to compensate for Shrinkage losses is favored. 2. Vacuum-formed mold with a blind riser, characterized in that the blind riser (10) in its upper Area has a ventilation hole (12) and a conical element (11; 13), which up to a point below the height protrudes downward ", which the molten metal reaches after pouring, and that the arrangement is made is that due to the contact between the molten metal and the conical element (11; 13) the refractory material (4) the mold around the blind riser (10) is thermally 809884/0581 Ke / Bl / ro ORIGINAL INSPECTED becomes saturated and consequently the solidification of the molten metal in the blind riser is delayed. 3. Mold according to claim 2, characterized in that the ventilation hole is arranged at a distance from the conical element is. 4. Mold according to claim 2, characterized in that the conical element is aligned with the ventilation hole Core is. 5. Mold according to claim 4, characterized in that the core is provided with a sprue (19) and that a die Auxiliary tube (15) forming a ventilation hole through the mold is passed through and placed on the sprue. 6. Mold according to one of Claims 2 to 5, characterized in that that the cone element is an "atmospheric pressure core." S09884 / OS81