JP2002500955A - Casting products, methods for producing castings, and molds - Google Patents

Abstract

SUMMARY OF THE INVENTION The present invention has at least two cavities (18, 19), and positioning elements (12 to 19) used between the cavities, in particular for separating the two mold areas of the consumable mold (1). An intermediate wall (21) with 16) is arranged, wherein the two mold areas relate to a casting (17) at least partially defining a casting area (8). The positioning elements (12-16) have a geometry that prevents them from falling out of the intermediate wall (21). The invention further relates to a method for producing the mold (1) and the casting (17).

Description

DETAILED DESCRIPTION OF THE INVENTION

The present invention relates to a positioning element with a surface, a starting part and a terminal part, used in particular for separating two mold areas of a consumable mold. In that case, the two mold areas at least partially define the casting area, the casting area being filled with casting material. The invention further relates to a mold, a casting and a method for producing a casting.

[0002] It is known from DE 33 12 867 A1 to use a mold having an outer shell and a casting core for producing a casting having an internal cavity. The outer shell surrounds a casting space that defines the outer shape of the casting. To create an internal cavity, a casting core is positioned in the casting space, spaced from the outer shell and positioned by a support member. This forms a casting area between the shell and the casting core, which is filled with the casting material. If the casting has two adjacent internal cavities, which are separated from one another by an intermediate wall of casting material, two casting cores arranged in the casting space are used to create the internal cavities. Is done. The casting cores each have a mold area, the mold areas are spaced apart from each other,
The casting space therefore extends between the mold areas for the creation of intermediate walls.

[0003] Support members are formed for spacing and positioning the casting core with respect to the shell, as well as for spacing and positioning the mold area. The support member is composed of a material that melts and mixes with the casting material when injected into the mold area. The support element becomes unstable during the injection of the mold area due to melting, so that the support element can no longer reliably prevent positional fluctuations of the consumable mold area.

According to US Pat. Nos. 3,596,703 and 3,662,816, a casting core for creating an internal cavity in a casting space is held and separated from an outer shell to produce a casting. It is known to use a mold with struts. The mold and the struts are made of a ceramic material. After being injected into the casting area, the shell and the casting core are removed and broken. The struts are removed together for technical reasons. This is because the struts are made of the same material as the shell and the casting core. This results in a casting that can be manufactured using a mold having holes that form a passage to the internal cavity. If the internal cavity of the casting is used to conduct a cooling fluid, the cooling fluid can undesirably flow out of the internal cavity through the holes. It is also known to form the struts as metal cylindrical pins, which project into the outer shell and terminate at the casting core. Because the shell and the casting core are removed and broken after the manufacture of the casting, they are called consumable shells and consumable casting cores.

[0005] Fritz Paschke's dissertation, "Experience and Use of Core Support and Its Use", published in the German magazine "Gieserai-Praxis" (No. 18, 1960) (pp. 327-330) Describes, for example, a so-called double core support for supporting a heavy casting core in order to produce a thick casting. This double core support then creates a sliding support between the shell and the inner cast core. In this case, the purpose of installing the double core support is to withstand the high pressure generated at that time and to withstand the lift generated at the time of casting.

[0006] It is an object of the present invention to provide a mold with a positioning element which is used for separating a mold area, in particular a consumable mold area. Another object is to provide a casting and a method of manufacturing the casting.

[0007] According to the invention, the problem with a mold having a positioning element is that the casting has a geometry which prevents the casting material from falling out of the casting material after it has been poured into the casting area. Solved by a mold with elements.

[0008] At least one casting core or casting core arrangement for producing a casting with a plurality of adjacent internal cavities or with a plurality of internal cavity areas coupled to one internal cavity to one another. A mold with is used. Each casting core defines an inner mold area. The shell forms an outer mold area, whether of one piece or of multiple pieces. The internal cavities or areas of the internal cavities of the casting are separated from one another by intermediate walls and are used, for example, for conducting a cooling fluid for cooling the casting. In the following, the mold area of a casting core or casting core structure that is broken and discarded after it has been used to produce a casting is referred to as a consumable mold area. One or more positioning elements are used to perform a fixed positioning (fixation) of the casting core or casting core structure, so that these core parts move relative to each other during injection. Be avoided.

[0009] The casting space between the mold areas (especially the consumable mold areas) is used to create intermediate walls. After pouring the casting material into the casting area, the positioning element is surrounded by the casting material between its start and its end. The geometry of the locating element ensures that dropout from the intermediate wall is avoided, so that no holes are formed in the intermediate wall.
At most very little clearance is left between the casting material and the surface of the positioning element. The locating element is held in the intermediate wall by a good geometry, so that when conducting the cooling fluid through the interior cavity area, the cooling fluid only escapes a small amount through the remaining gaps.

[0010] Preferably, the geometry of the positioning element has a surface contour with at least one local pole between the start and the end. Preferably, the starting portion and the terminal portion each have a large diameter portion. In another advantageous embodiment, the locating element additionally or alternatively has a larger diameter between the start and the end.

In another preferred embodiment, the positioning element is formed from a base material having a higher melting point than the casting material. For example, a nickel-based superalloy or a cobalt-based superalloy is used as a base material. In this case, the base material does not melt when the casting material is poured into the casting range. A change in the position of the casting core (especially the consumable casting core) or a change in the shape of the casting core (especially the consumable casting core) is thereby avoided. Further, the base material is preferably a metal, particularly tungsten.

Preferably, a protective film, particularly an oxide film, is provided on the surface of the positioning element. This makes it at least clearly difficult, if not completely unavoidable, for the casting material to combine with the matrix to form a eutectic, especially by melting of the matrix and by mixing with the casting material.

[0013] Preferably, a positioning element is used to separate the two mold sections (especially the consumable mold section) used in the manufacture of the turbine blade. Furthermore, it is preferred if the mold area, especially the consumable mold area, is used to create at least one internal cavity in the turbine blade.

[0014] Preferably, the starting part and / or the end part of the positioning element each project into the mold area, in particular the consumable mold area. This keeps the positioning element in the mold area and prevents it from slipping off.

A problem with the casting is that the intermediate wall has a positioning element, the positioning element being at least partially surrounded by the casting material and having a geometry that prevents falling out of the casting material. The invention is solved by a casting described in the preamble of the above paragraph, in particular by a turbine blade for a gas turbine. In this case, the casting has locating elements formed by the embodiment relating to the construction of the mold.

The problem with the method of manufacturing a casting is that the casting area, in particular the consumable mold area, is at least partially defined by the casting area, and the casting area has positioning elements which separate the casting areas from one another. It is solved by a method according to the preamble of claim 10 to be arranged. The casting area is filled with a casting material, which after curing of the casting material at least partially surrounds the positioning element. The positioning element has a geometry that prevents falling out of the casting material.

The positioning element, the mold, the casting and the method of manufacturing the casting are described in detail with reference to the exemplary embodiments shown in the drawings.

The drawings schematically show structural and functional features used for description, and are not necessarily to scale. 1 is a cross-sectional view of a mold for a turbine blade, FIG. 2 is a cross-sectional view of a mold, FIG. 3 is a cross-sectional view of a turbine blade of a gas turbine, FIG. 4 is a vertical cross-sectional view of an example of a positioning element, and FIG. FIG. 4 shows a longitudinal section of another example of the element. The reference numerals in all the drawings have the same meaning.

FIG. 1 shows a cross-sectional view of a mold 1 extending along a central axis 24 for manufacturing gas turbine blades. The mold 1 has an outer shell 2 surrounding a casting space 7,
Inside, three casting cores 3, 4, 5 are positioned by a support element 6 and are spaced from the shell 2. The casting cores 3, 4, and 5 are cast in a casting range 8 with respect to the central axis 24.
It is likewise possible to separate the outer shell 2 from the outer shell 2 by a suitable suspension, for example. In this case, the casting cores 3, 4, and 5 have one end fixed and the other end movable. As a result, a casting range 8 is formed between the outer shell 2 and the casting cores 3, 4, and 5. The shell 2 forms an outer mold area. The casting cores 3, 4, 5 respectively form inner mold areas 9.10, 11 which are separated from one another by positioning elements 12-16. The positioning elements 12 to 16 are composed of a base material 35 (see FIG. 4 or 5). The support elements 6 each extend into the shell 2, the positioning elements 13, 14 extend into the mold areas 9, 10, and the positioning elements 16 extend into the mold areas 10, 11.

When producing the casting 17 (see FIG. 3) using the mold 1, the casting area 8 is filled with a molten casting material 23, for example a nickel-based superalloy or a cobalt-based superalloy. The casting material 23 surrounds the support element 6 and the positioning elements 12 to 16 in the casting area 8. After the casting material 23 has hardened, the casting cores 3 to 5 are removed. Positioning element 12 ~
16 has a geometrical shape that prevents the casting material 23 from falling off from the casting material 23 even when the casting material 23 does not melt with the base material 35.

FIG. 2 shows an outer shell 2 and casting cores 3, 4 and 5 arranged therein, with which the casting 1, in particular the mold 1 for producing turbine blades, is strongly simplified. Are shown schematically. Adjacent casting core pairs 3, 4 and 4, 5 each have a positioning element 13
Are fixed to each other. No fixing pins or positioning elements are provided between the shell 2 and the casting cores 3, 4, 5. Rather, the casting cores 3, 4, 5 have a fixed end 42 firmly connected to the shell 2 and at least one open end 43 located opposite the fixed end 42 along the central axis 24. Release side support (slip support) 41
It is movably supported by. Accordingly, when the casting material 23 is poured into the casting area 8 formed between the outer shell 2 and the casting cores 3, 4, and 5, the casting core 3,
It is ensured that the 4, 5 do not move laterally with respect to each other and towards the shell 2.

FIG. 3 shows a cross-sectional view of a casting 17, in particular a turbine blade 17, which can be manufactured using the mold 1. The turbine blade 17 has three cavities 18 to 20. These are defined by the casting cores 3, 4, and 5 when the casting 17 is manufactured. Intermediate walls 21, 22 are present between the cavities 18, 19 and between the cavities 19.20, respectively. The intermediate wall 21 is provided with positioning elements 12 to 14 which do not fall off from the intermediate wall 21 formed with the casting material 23 on the basis of its geometry. Intermediate wall 2
2 has positioning elements 15, 16 which likewise do not fall off the intermediate wall 23 based on their geometry (with folds, holes).

FIG. 4 shows the positioning element 14 in an enlarged manner. This positioning element is formed substantially cylindrical by a starting part 25, an end part 26 and a surface 27 having a surface contour 28. The surface contour 28 forms a local pole part 29 between the start part 25 and the end part 26 (that is, a maximum part formed by the large diameter part 30 provided between the start part 25 and the end part 26). Have. This prevents the positioning element 14 from falling out of the casting material 23 after being surrounded by the casting material 23 between the starting part 25 and the terminal part 26.

FIG. 5 shows the positioning element 13 in an enlarged manner. This positioning element has large diameter parts 31 and 32 at the start part 25 and the end part 26, respectively. Thereby, the surface contour 28 between the starting part 25 and the terminal part 26 has a local pole part (that is, a minimum part) 33.

The invention features a locating element having a starting portion and a terminating portion, the locating element having a geometry that prevents falling out of the casting material after being surrounded by the casting material between the starting portion and the terminating portion. I do. The positioning element is used to fix the two mold areas (cast core, cast core area) to each other.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of a mold for a turbine blade.

FIG. 2 is a cross-sectional view of a mold.

FIG. 3 is a sectional view of a turbine blade of a gas turbine.

FIG. 4 is a longitudinal sectional view of an example of a positioning element.

FIG. 5 is a longitudinal sectional view of another example of a positioning element.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Mold 2 Outer shell 3,4,5 Casting core 6 Supporting element 7 Casting space 8 Casting range 9,10,11 Inner mold range 12-16 Positioning element 17 Casting product 23 Casting material 24 Center axis 35 Base material

Claims (10)

[Claims] 1. An outer mold area (40) surrounding at least two inner mold areas (9, 10, 11), the inner mold areas being separated from one another by positioning elements (12-16) and formed thereby. The casting area (8) is at least partially defined and the casting area (8) is filled with the casting material (23), in particular in the mold (1) for producing turbine blades (17). (12-16)
(1) characterized in that it has a geometry which is at least partially surrounded by the casting material (23) after the casting material (23) has been poured and which prevents it from falling out of the casting material (23). 2. A positioning element (12-16) comprising a starting part (25) and a terminating part (12).
26) with at least one local pole (29).
The mold (1) according to claim 1, characterized in that it has a geometry with (1). 3. The start (25) and the end (25) of the positioning elements (12-16).
26) Each of the (26) has a large diameter portion (31, 32).
Or the template (1) according to 2. 4. A positioning element (12-16) comprising a starting part (25) and an end part (2).
The mold (1) according to claim 2, characterized in that it has a large-diameter portion (30) between the mold (6). 5. The positioning element (12-16) is formed from a base material (35),
The mold (1) according to one of the claims 1 to 4, characterized in that the base material (35) has a higher melting point than the casting material (23). 6. The mold (1) according to claim 5, wherein the base material (35) of the positioning elements (12-16) is tungsten. 7. The mold (1) according to claim 6, characterized in that a protective film, in particular an oxide film, is provided on the surface (27) of the positioning element (12-16). 8. A positioning element (12-16) comprising a starting part (25) and a terminating part (2).
6), wherein the starting part (25) and / or the end part (26) extend into the respective mold area (9, 10). The described mold (1). 9. An intermediate wall (21) comprising at least two cavities (18, 19) and comprising a casting material (23) arranged between the cavities, the intermediate wall (21) being located by a positioning element (12-16). And the positioning element is at least partially at the casting material (2
A casting (17), in particular a turbine blade (17), which is surrounded by 3) and has a geometry which prevents it from falling out of the casting material (23). 10. An injectable casting zone (8) is at least partially defined by means of a mold zone (9, 10, 11, 40), the casting zone (8) comprising two inner mold zones (9). , 10, 11) are arranged to separate the casting material (23) from the casting area (8), and the casting material (23) is positioned after the casting material (23) has hardened. A casting (17), characterized by at least partially surrounding the element (12-16), wherein the locating element (12-16) has a geometry that prevents it from falling out of the casting material (23); Especially turbine blades (
17) The manufacturing method.