EP0083713A2 - Method of producing a hollow foundry core - Google Patents

Abstract

In a method for producing a hollow foundry core, core halves are first formed on an inner hollow molded part and an outer core box half and then joined together to form a finished foundry core. In order to reduce the manufacturing effort and to improve the dimensional accuracy of foundry cores, the core halves should be formed on a central part and the core halves should be joined together by moving the core box halves together in one operation.

Description

The invention relates to a method for producing a hollow foundry core from two core halves, each core half being formed on an inner hollow molded part and an outer core box half and then the core halves being joined together.

In the production of castings, it is mostly necessary to create recesses or cavities by arranging foundry cores in the foundry mold. These foundry cores should largely disintegrate after casting in order to avoid coring work and not to obstruct the casting shrinkage. In order to achieve this, but also to save on expensive core sand material, foundry cores are recessed on the inside, insofar as their geometric shape and the manufacturing process used permit. For example, it is possible to produce a one-piece foundry core that is hollowed out on the inside by immersing a fixed or movable mandrel in the molding sand during the molding process, which is pulled out of the foundry core after the molding sand has hardened. The disadvantage here is that no foundry core with a uniform wall thickness can be produced in this way and consequently a uniform hardening of the shaped foundry core is not possible. In addition, the finished foundry core has an opening that is used during the later casting process must be closed by other molded parts, otherwise cast iron melt would penetrate into the interior of the core.

Furthermore, in a known method of the type listed in the preamble of claim 1 (DE-OS 17 58 959) a molding of two core halves is provided on two corresponding molding machines, each molding machine being assigned a core box half and a hollow molding part attached to lifting cylinders. In a first step, the two core halves are produced on the molding machine, then the two core box halves are transported to an assembly station together with the core halves remaining in them. In the assembly station, the core box halves are stacked one above the other and pressed together using a pressing tool, so that the respective core halves connect to one another. This process is very complex due to its different operations. On the other hand, the exact alignment of the two core box halves is very difficult, and it cannot be avoided that the dimensional accuracy of the cores suffers, i. H. misalignment can occur between the core halves or pressing together results in an overall height of the foundry core which does not correspond to the desired dimension.

It is therefore an object of the present invention to avoid the difficulties described above and to provide a method and a device with which the production of optimally recessed hollow cores by means of hollow molding parts is possible in a single operation.

This object is achieved in a method of the type in question by the features listed in the characterizing part of claim 1.

Thereafter, in a single operation, which consists of small steps, werden.Bei produced at a machine a complete hollow foundry core little effort for the control of the process is the achievable dimensional accuracy of the casting core is very high, because retain ernkastenhälften the _K throughout the manufacturing process their in alignment. It is only necessary to pivot the center plate, which has hollow-forming parts on both sides, into or out of this alignment at the beginning and after the end of the molding process. In this way, hollow foundry cores can be produced that have a uniform wall thickness and a seamless connection point.

It is also of particular advantage if, as further proposed, before a pivoting of the center plate between the two core box halves, elements of a clamp connection are attached automatically or by hand on both sides of the center plate. When the core box half is subsequently filled, these elements protrude into the core sand and anchor themselves in it during curing. When the core halves are then joined together, the one snaps onto the connecting surface of the one mold half fastened element in the element of the other mold half, and the core halves are immovably attached to each other in this way. However, it is also possible to automatically or manually apply a fast-curing adhesive to at least one of the core halves before joining the core halves.

However, as is proposed in another embodiment of the invention, special profiles can be formed in or on the connecting surface of the core halves directly during the molding process by means of molded parts arranged on the end faces of the central plate. When the core halves are then joined together, these profiles work together in pairs by firmly attaching the core halves to one another.

In a further embodiment of the invention, an apparatus for performing the described method is proposed. Afterwards it is recommended to fix the mold box halves in alignment in a horizontal or vertical plane on hydraulic cylinders. These hydraulic cylinders drive the core box halves on both sides before the core sand is poured in against the center plate, which is pivoted or retracted into alignment via a tool carrier.

Furthermore, special types of clamp connections are proposed for the arrangement in bores on both end faces of the middle plate. It is advantageous if these clamp connections on the principle of _D jerk snap fastener are formed, that is, the one element having a projecting part which engages in the moving together of the mold halves in a correspondingly shaped elastic recess. However, there is also the possibility, according to the principle of the morse taper connection, of arranging an element with an outer cone on the one hand of the middle plate and an element with an inner cone on the other opposite side of the middle plate. In this embodiment, when the core halves are joined together, the element anchored in one core half with an outer cone snaps into the element anchored in the other core half with an inner cone. In this way, the position of the two core halves relative to one another can be precisely fixed.

• _Fig. 1 die beiden auseinander gefahrenen Kernkastenhälften im Teillängsschnitt und die Mittelplatte zu Beginn des Verfahrens,
• Fig. 2 eine Anordnung nach dem Zusammenfahren der Kernkastenhälften am Mittelteil und dem Einschießen oder Einfüllen des Formsandes,
• Fig. 3 eine Anordnung, bei der der fertige Kern nach dem Entfernen der Mittelplatte und dem Zusammenfügen der Kernhälften von einer Kernkastenhälfte gehalten wird und
• _Fig. 4 eine Anordnung nach dem Verschwenken einer Kernkastenhälfte, vor dem Ausstoßen des fertigen Gießereikerns auf eine-Ablage.

To further explain the invention, reference is made to the drawing, in which an exemplary embodiment is shown in simplified form. One of the method steps is schematically explained in each of the figures. Show it:

• _F ig. 1 the two separated core box halves in the partial longitudinal section and the middle plate at the beginning of the process,
• 2 shows an arrangement after moving together the core box halves on the middle part and shooting in or filling in the molding sand,
• Fig. 3 shows an arrangement in which the finished core is held by a core box half after removing the central plate and assembling the core halves and
• _F ig. 4 shows an arrangement after swiveling a core box half before ejecting the finished foundry core onto a tray.

1 to 4, 1 and 2 denote two core box halves which together serve to form the outer contour of the foundry core to be produced. These two core box halves 1 and 2 are each attached to the ends of piston rods 3 and 4 hydraulic cylinders, not shown. Furthermore, 5 denotes a central plate, which is fastened to a tool carrier, also not shown, and on the end faces of which a hollow molding part 6 or 7 is arranged. In addition, the center plate 5 has on its one end face a plurality of projections 8 which are arranged around the hollow shaping part 6 and which serve to receive elements 9 of a clamp connection 10. Recesses 8 are provided opposite the projection 8 on the other end face of the middle plate 10 for receiving elements 11 of the clamp connection.

In Fig. 1 the arrangement is shown in its basic position, i. H. the two core box halves 1 and 2 are moved apart via the piston rods 3 and 4 and the middle plate 5, which is already equipped with the elements 9 and 11 of the clamp connection, has not yet been pivoted between the two core box halves 1 and 2.

2, the tool holder has already pivoted the middle plate 5 between the two core box halves 1 and 2, the core box halves 1 and 2 have been moved together via the piston rods 3 and 4, so that they enclose the hollow forming parts 6 and 7 and their ends on Middle part 5. In addition, the molding sand in.den space between core box half, _H ohlformungsteil 6 and middle part of FIG. 2 is already 5 on the one hand and the core box half 2, hollow shaping part 7 and the middle part 5 on the other hand introduced.

Fig. 3 shows the arrangement in a state of the method, in which after the moving apart of the core box halves together with hardened core halves, the middle plate 5 between the core box halves 1 and 2 was pivoted out, the core halves 13 and 14 on the elements 9 and 11 of the Clamping connection 10 have been put together by moving the core box halves 1 and 2 together and has lifted a core box half 1 from the finished foundry core. The core box half 2 holds the finished foundry core produced from the core halves 13 and 14 and pivots it, as can be seen in FIG. 4, in order to release it after being placed on a shelf 15 or a conveyor belt. The finished foundry core is thus available for use in a casting mold.

The method can be used in all known, mechanical, cold and hot core manufacturing processes.

Claims (10)

1. A process for producing a hollow foundry core from two core halves, each core half being formed on an inner hollow molded part and an outer core box half and then the core halves being joined together, characterized by the following process steps: a) swiveling or retracting a hollow plate (5 and 7) having a central plate (5) on both sides between the core box halves 1 and 2, which are held at a distance from one another; b) moving the core box halves (1 and 2) together until they enclose the hollow shaping parts (6 and 7) and lie against the middle plate (5); c) shooting in or pouring the molding sand into the core box halves (1 and 2) and curing the molding sand by gassing and / or heating the core box halves (1 and 2) and / or the central plate (5); d) moving apart the core box halves (1 and 2) together with the respectively shaped core halves (13 and 14) and pivoting out or extending the middle plate (5) with hollow forming parts (6 and 7) from the space between the core box halves (1 and 2); e) joining the core halves (13 and 14) together by moving the core box halves (1 and 2); f) transporting the finished core after ejection from a core box half (1) by means of the other ernkastenhälfte _K (2) to a tray (15) or _F OER derband and then ejected from the core box half (2). 2. The method according to claim 1, characterized in that before the pivoting of the central plate (5) between the two core box halves (1 and 2) on both end faces of the central plate (5) in pairs interacting elements (9 and 11) of clamp connections (10) are arranged become anchored in the later brought in and hardened molding sand and after moving the core halves (13 and 14) firmly attach them to each other. 3. The method according to claim 1, characterized in that by means of molded parts provided on the end faces of the central plate (5) in each case in or on the connecting surfaces of the core halves (13 and 14), interacting elements of clamping connections are formed from molding sand, which are used for immovable fastening serve the core halves (13 and 14) together. 4. The method according to any one of the preceding claims, characterized in that a quick-curing adhesive is applied to the connecting surface of at least one of the core halves (13 or 14) before joining the core halves (13 and 14). 5. The method according to any one of the preceding claims, characterized in that the two core box halves (1 and 2) for shaping and assembling the core are moved in the horizontal direction; while a core box half (2) is pivoted by 90 ⁰ to transport the core. 6. Device for performing the method according to any one of the preceding claims, characterized in that the mold box halves (1 and 2) are aligned in a horizontal or vertical plane in alignment with _H -draulic or pneumatic cylinders (3 and 4). 7. Device according to one of the preceding claims, characterized in that the central plate (5) on its two end faces opposite and aligned recesses (12) or projections (8), in or on each of the paired elements (9 and 11) the clamp connection (10) can be plugged in. 8. Device according to one of the preceding claims, characterized in that the clamping connections (10) are designed according to the principle of the snap fastener. 9. Device according to one of claims 1-7, characterized in that the clamping connections (10) on the one hand have an element with an outer cone and on the other hand an element with an inner cone. 10. Device according to one of the preceding claims, characterized in that a spray device is arranged on the tool carrier, which is pivotable between the core halves (13 and 14) and is used to apply an adhesive.

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