WO1999037421A1

WO1999037421A1 - Cast part, method for producing a cast part and casting mould

Info

Publication number: WO1999037421A1
Application number: PCT/DE1999/000121
Authority: WO
Inventors: Peter Tiemann
Original assignee: Siemens Aktiengesellschaft
Priority date: 1998-01-23
Filing date: 1999-01-19
Publication date: 1999-07-29
Also published as: EP1049549A1; JP4327351B2; EP1049549B1; JP2002500955A; DE59904037D1

Abstract

The invention relates to a cast part (17) with at least two hollow chambers (18, 19) between which an intermediate wall (21) with a positioning element (12 to 16) is situated. Said positioning element (12 to 16) acts as a spacer for keeping two areas of a casting mould, especially a lost casting mould (1), at a distance from each other, said areas at least partially delimiting a casting area (8). The positioning element (12 to 16) has a geometrical configuration which prevents it from falling out of the intermediate wall (21). The invention also relates to a casting mould (1) and to a method for producing a cast part (17).

Description

description

Casting part, process for producing a casting and casting mold

The invention relates to a positioning element with a surface, an initial region and an end region, which serves to space two casting mold regions, in particular a lost casting mold, these at least partially delimiting a casting region, which casting region can be filled with a casting material. The invention further relates to a casting mold, a casting and a method for producing a casting.

To produce a casting with an inner cavity, it is known from DE 33 12 867 AI to use a casting mold which has an outer shell and a casting core. The outer shell encloses a casting space that defines an outer shape of the casting. To produce the inner cavity, the casting core is arranged in the casting space and is spaced and positioned by a support from the outer shell. As a result, a casting area is formed between the outer shell and the casting core and can be filled with a casting material. If the casting has two adjacent inner cavities, which are separated from one another by an intermediate wall made of the casting material, then two casting cores which are arranged in the casting space are used to produce the inner cavities. The casting cores each have a casting area, the casting areas being spaced apart from one another so that the casting space extends between them to produce the intermediate wall.

The support is designed both for spacing and positioning the casting cores with respect to the outer shell, and for spacing and positioning the casting mold regions. 2 det. It consists of a material that melts when the casting area is poured out and connects to the casting material. The melting can make the support unstable when pouring out the casting area, so that it can no longer reliably prevent the position of the lost casting area from changing.

From US Pat. No. 3,596,703 and US Pat. No. 3,662,816 it is known in each case to use a casting mold for the production of the casting, which mold has posts which hold a casting core for producing an inner cavity in the casting space and which are spaced apart from the outer shell. The mold and the posts are made of a ceramic material. After the casting area has been poured out, the outer shell and the casting core are removed and destroyed in the process. For technical reasons, the posts are removed because they are made of the same material as the outer shell and the cast core. As a result, a casting which can be produced with the casting mold has holes which form an access to the inner cavity. If the inner cavity of the casting is used to guide a cooling fluid, cooling fluid can undesirably emerge from the inner cavity through the holes. It is also known to design the posts as metallic cylindrical pins which protrude into the outer shell and end on the casting core. Because the outer shell and the core are removed and destroyed after the casting is made, they are also referred to as the lost outer shell and core.

In the German magazine "Gießerei-Praxis", No. 18, 1960, the article by Fritz Paschke describes "Experience with core nozzles and their use", pages 327 to 330, so-called double core nozzles, through which a heavy cast core, for example for the Production of thick-walled castings, is trimmed. These double core stubs cause 3 a sliding bearing between an outer shell and the inner casting core. The aim of the double-core nozzle is not only to be able to withstand the high pressure that occurs, but also to withstand the high buoyancy forces that occur during casting.

The object of the invention is to provide a casting mold with a positioning element which is used to space the casting mold regions, in particular lost casting mold regions. Further tasks are to specify a cast part and a method for producing a cast part.

According to the invention, the object directed to the casting mold with positioning element is achieved by a casting mold with a positioning element according to the preamble of patent claim 1, which has a geometrical configuration which, after the casting area has been poured out, is secured against falling out of the casting material conditionally.

A casting mold with at least one casting core or a casting core structure is used to produce a casting with a plurality of adjacent interior cavities or a plurality of interconnected interior cavity regions of an interior cavity. A mold core defines an inner mold area. An outer shell, whether in one part or in several parts, forms an outer mold area. The inner cavities or the inner cavity areas of the casting are separated from one another by an intermediate wall and can be used, for example, to guide a cooling fluid for cooling the casting. In the following, the lost mold areas are referred to as mold areas of a cast core or of a cast core structure which is destroyed and is therefore lost after being used for producing the cast part. One positioning element or several positioning 4 elements serve / serve the fixed positioning (fixation) of cast cores or cast core areas, so that a mutual displacement of these core parts is avoided when pouring.

The casting space between the, in particular lost, mold areas serves to produce the intermediate wall. After the casting area has been poured out with the casting material, the positioning element is enclosed by casting material between its starting area and its end area. Due to the geometrical configuration of the positioning element, falling out of the intermediate wall is reliably avoided, so that no holes can arise in the intermediate wall. At most, there is a small gap between the casting material and the surface of the positioning element. Due to the preferred geometric configuration, the positioning element is held in the intermediate wall, and due to the possibly remaining intermediate space, only a small amount of cooling fluid can pass when cooling fluid is guided through the inner cavity regions.

The geometric configuration of the positioning element preferably has a contour of the surface with at least one local extremum between the start region and the end region. The starting region and the end region preferably each have a thickening. In a further preferred embodiment, the positioning element additionally or alternatively has a thickening between the start region and the end region.

In a further preferred embodiment, the positioning element is formed from a base material that has a higher melting point than the cast material. A nickel-based or cobalt-based superalloy is used as the casting material, for example. Melting, melting or melting of the base material when pouring out the casting 5 empires with the casting material is omitted in this case. A change in the position of the, in particular lost, casting cores or the geometry of the, in particular lost, casting core structure is thereby avoided. The base material is further preferably a metal, in particular tungsten.

A protective layer, in particular an oxide layer, is preferably attached to the surface of the positioning element. As a result, a connection of the casting material to the base material, in particular by melting, melting or melting the base material and mixing with the casting material to form a eutectic, is at least significantly more difficult, if not avoided.

The positioning element is preferably used for spacing two, in particular lost, mold regions which are used to produce a turbine blade. The, in particular lost, mold regions are further preferably used to produce at least one inner cavity in the turbine blade.

The start region and / or the end region of the positioning element preferably protrude into a respective, in particular lost, mold region. As a result, the positioning element is held in the mold areas and is secured against slipping.

The object directed to the cast part is achieved by a cast part, in particular a turbine blade for a gas turbine, according to the preamble of patent claim 9, the intermediate wall having a positioning element which is at least partially enclosed by the cast material and has a geometric configuration which a protection against falling out of the casting material. Here, the cast part has a positioning element, which according to the 6 stanchions regarding the design of a mold is formed.

The object directed to a method for producing a cast part is achieved by a method according to the preamble of patent claim 10, wherein, in particular, lost mold areas, a pourable casting area is at least partially limited, in which casting area a positioning element is arranged with which the Mold areas are spaced apart. The casting area is poured out with a casting material which at least partially surrounds the positioning element after solidification. The positioning element has a geometric configuration which prevents it from falling out of the cast material.

The positioning element, the casting mold, the casting and the method for producing a casting are explained in more detail by way of example using the exemplary embodiments shown in the drawing.

They show schematically and partly not to scale, showing the constructive and functional features used for the explanation:

1 shows a casting mold for a turbine blade in a cross section;

2 shows a cross section through a mold

3 shows a turbine blade of a gas turbine in a cross section; F FIIGG 4 4 a positioning element in a longitudinal section; and

5 shows a further positioning element in a longitudinal section.

The reference numerals of all figures have the same meaning in each case. FIG. 1 shows a cross section through a casting mold 1 directed along a main axis 24 for producing a gas turbine blade. The casting mold 1 has an outer shell 2 which surrounds a casting space 7, in which three casting cores 3, 4 and 5 are positioned with the aid of support elements 6 and are spaced apart from the outer shell 2. It is also possible to space the casting cores 3, 4, 5 outside the casting area 8 with respect to the main axis 24 with respect to the outer shell 2 by e.g. B. a suitable suspension. In this case, the casting cores 3, 4, 5 are fixed at one end and movable at the other end. As a result, a casting area 8 is formed between the outer shell 2 and the casting cores 3, 4 and 5. The outer shell 2 forms an outer mold area 40. The cast cores 3, 4 and 5 each form the inner mold areas 9, 10 and 11, which are spaced apart from one another by positioning elements 12 to 16. The positioning elements 12 to 16 are made of a base material 35 (see FIG. 4 or FIG. 5). The support elements 6 each protrude m the outer shell 2 and the positioning elements 13 and 14 protrude into the mold areas 9 and 10 and the positioning element 16 protrudes into the mold areas 10 and 11.

When producing a casting 17 (see FIG. 3) with the casting mold 1, the casting area 8 is melted with a

Cast material 23, for example a nickel-based or cobalt-based superalloy. The casting material 23 encloses the support elements 6 and the positioning elements 12 to 16 in the casting area 8. After the casting material 23 has solidified, the casting cores 3 to 5 are removed. The positioning elements 12 to 16 each have a geometric configuration which prevents them from falling out of the casting material 23, even if the casting material 23 does not fuse with the base material 35. In FIG. 2, a casting mold 2 for producing a casting 17, in particular a turbine blade, with an outer shell 2 and casting cores 3, 4 and 5 arranged therein is greatly simplified and schematized. Adjacent pairs of casting cores 3, 4 and 4, 5 are respectively fixed against each other by positioning elements 14. No fixing pins or positioning elements are provided between the outer shell 2 and the cast cores 3, 4, 5. Rather, the casting cores 3, 4 and 5 are fixedly connected to the outer shell 2 at a fixed end 42 and are movably supported on a loose end 43 opposite the fixed end 42 along the main axis 24 by at least one respective floating bearing (slide bearing) 41 along the main axis 24 . This ensures that when casting material 23 is poured into the casting area 8 formed between the outer shell 2 and the casting cores 3, 4, 5, there is no displacement of the casting cores 3, 4, 5 in the transverse direction with respect to one another and with respect to the outer shell 2.

FIG. 3 shows a cross section through a casting 17 that can be produced with the casting mold 8, in particular a turbine blade 17. The turbine blade 17 has three cavities 18 to 20. These are defined in the manufacture of the casting 17 by the casting cores 3, 4 and 5. Between the cavities 18 and 19 as well as 19 and 20 there is an intermediate wall 21 and 22. In the intermediate wall 21 the positioning elements 12 to 14 are attached, which due to their geometrical configuration cannot fall out of the intermediate wall 21 formed with the casting material 23 . The intermediate wall 22 has the positioning elements 15 and 16, which likewise cannot fall out of the cast material 23 due to their geometric configuration (with a kink, with a hole).

FIG. 4 shows the positioning element 14 in an enlarged view. It is essentially cylindrical 9 with an initial region 25, an end region 26 and a surface 27 with a surface contour 28. The surface contour 28 has a local extremum 29 between the start region 25 and the end region 26, a maximum 29 due to a thickening 30 provided between the start region 25 and the end region 26. As a result, the positioning element 14 is secured against falling out of the casting material 23 after being encased with a casting material 23 between the starting area 25 and the starting area 26.

FIG. 5 shows an enlarged representation of the positioning element 13, which has a thickening 31 and 32 at its end region 25 and at its starting region 26. As a result, the surface contour 28 has a local extremum 33, a minimum, between the start region 25 and the end region 26.

The invention is characterized by a positioning element with an initial region and an end region, which positioning element has a geometrical configuration which, after enclosing the positioning element between the initial region and the end region with a casting material, prevents it from falling out of the casting material. The positioning element is used to fix two inner mold areas (casting cores, casting core areas) against each other.

Claims

10 patent claims

1. casting mold (1), in particular for producing a turbine blade (17) which has an outer casting mold region (40) which surrounds at least two inner casting mold regions (9, 10, 11), which are defined by a positioning element (12 to 16) are spaced from one another and at least partially delimit a casting area (8) formed thereby, which casting area (8) can be poured out with a casting material (23), characterized in that the positioning element (12 to 16) after pouring out with the casting material (31 ) is at least partially enclosed by the latter and has a geometrical configuration, which prevents it from falling out of the cast material (23).

2. Casting mold (1) according to claim 1, characterized in that the positioning element (12 to 16) has a geometric configuration with a contour (28) of the surface, the contour (28) between the start region (25) and the end region (26) has at least one local extremum (29).

3. Casting mold (1) according to one of the preceding claims, that the starting area (25) and the end area (26) of the positioning element (12 to 16) each have a thickening (31, 32).

4. Casting mold (1) according to claim 2, dadurchg ek indicates that the positioning element (12 to 16) has a thickening (30) between the start region (25) and the end region (26). 11

5. Casting mold (1) according to one of the preceding claims, d a d u r c h g e k e n n z e i c h n e t that the positioning element (12 to 16) is formed from a base material (35), and the base material (35) has a higher melting point than the casting material (23).

6. casting mold (1) according to claim 5, d a d u r c h g ek e n n z e i c h n e t that the basic material (35) of the positioning element (12 to 16) is tungsten.

7. casting mold (l) according to claim 6, d a d u r c h g ek e n n e e c h n e t that on the surface (27) of the positioning element (12 to 16) a protective layer, in particular an oxide layer, is attached.

8. Casting mold (1) according to one of the preceding claims, characterized in that the positioning element (12 to 16) has a start region (25) and an end region (26), the start region (25) and / or the end region (26) in protrude / protrude a respective mold area (9, 10).

9. Cast part (17), in particular a turbine blade (17), which has at least two cavities (18, 19), between which an intermediate wall (21) made of a cast material (23) is arranged, the intermediate wall (21) being a positioning element ( 12 to 16), which is at least partially enclosed by the casting material (31) and has a geometric configuration that requires protection against falling out of the casting material (31).

10. A method for producing a cast part (17), in particular a turbine blade (17), characterized in that casting areas (9, 10, 11, 40) have a pourable casting area (8) at least partially 12

is limited in which casting area (8) a positioning element (12 to 16) is arranged, with which two inner mold areas (9, 10, 11) are spaced apart, the casting area (8) being poured out with a casting material (23) and after the casting material (23) has solidified, the positioning element (12 to 16) at least partially surrounds it, the positioning element (12 to 16) having a geometric configuration which prevents it from falling out of the casting material (23).