EP1127635A1 - Apparatus and method for casting a workpiece and workpiece - Google Patents

Abstract

The invention relates to a device for casting a workpiece, especially a turbine blade with inner cooling, comprising a casting cavity (1) in which casting cores (2) which produce channels (3) that pass through the workpiece are provided. The aim of the invention is to improve a device of this type in such a way that there are no poorly cooled areas present in the workpiece. To this end, the casting cores (2) are placed in the casting cavity (1) in such a way that they rest against each other loosely.

Description

The invention relates to a device for casting a Workpiece, in particular an internally cooled turbine blade, with a casting cavity in which casting cores are present, which create workpiece penetrating channels, as well as a method for casting a workpiece with the features of the generic term of claim 16 and a workpiece with the features the preamble of claim 18.

Hot gas pressurized, internally cooled turbine blades often cooled by a so-called film cooling. At a Film cooling flows cooling air through holes from the inside of the blade profile to the outside. On the outside of the outer wall An air film forms on the blade profile, which is cooling works. The holes are either cast directly or drilled afterwards. For the cast holes cylindrical shaped for the continuous channels Casting cores in the two, the inside and outside of the outside wall forming mold parts attached. It thus arises Bores with a large bore diameter that are right are far apart. So you can find worse everywhere cooled areas between the film cooling holes. This is compensated for by the fact that a larger coolant flow than is actually needed to use this too adequately cool poorly cooled areas.

The object of the present invention is therefore a device for casting a workpiece without badly cooled Propose areas, especially if they are internally cooled Turbine blades are such a possibility sufficient film cooling with low coolant consumption to deliver.

The object is achieved in that casting cores in the casting cavity are placed loosely next to each other.

Due to the loosely lying casting cores, one is depending Casting core size and shape different density packing from Given casting cores. At the contact points of the casting cores poured casting material is displaced. After pouring the core material is chemically removed from the material, for example by leaching. Workpieces penetrating arise Channels that are almost statistically over the area filled with casting cores are distributed, the channel density depending on the casting core size and shape in a predetermined Relation to casting core density. The channels have Openings on both sides of the workpiece, as for the loose casting cores lying on top of each other, at least almost every casting core has a neighbor he touches and he has it turn a neighbor and so on until a related one Casting core touches the other outside of the workpiece.

In this way, high-temperature casting materials for the manufacture of film-cooled turbine blades, however can also be processed for cover plates and heat shields. By choosing a small casting core size and a suitable one The casting core shape becomes a very large number of small channel outlet openings achieved. A channel passing through the workpiece usually has several closely spaced openings as outputs on. With such a workpiece film cooling, all areas of the surface, which is broken by openings in the channels, from Cooling film can be achieved. At the same time, the channel is enforced Workpiece due to the solid casting material a special selection of the casting core size and shape is sufficient firmly, as will be explained in more detail. The production the pouring device is simplified because of the way supported poured cores on each other and therefore not can be attached separately in the surrounding mold walls have to.

Due to the adjacent casting cores, after the Pour suitable channels with a small diameter at the channel opening, if at least two casting cores penetrate a workpiece Create a channel.

When the largest outer dimensions of the casting cores are smaller as the smallest internal dimensions of the casting cavity, it is ensures that at least at every point of the casting cavity two or more casting cores touching one another can be distributed over the cross section of the casting cavity. In this way, very small, branched channel structures, depending on the size, shape and packing density of the Generate casting cores.

Setting up the full mold is essential simplified if the casting cores can be poured into the casting cavity are. Even narrow, angled areas of the mold can be coated with the casting cores in this way.

If the casting cores are approximately circular and / or ellipsoidal they are easy to pour and spread out good in the mold without leaving large, free volumes. The casting cores have a large surface area for production from contact points with other, adjacent casting cores on, so that a high channel density in the cast workpiece given is. With ellipsoidal casting cores, especially elongated channel sections at a high Establish channel density if the points of contact are predominant are due to the greatest dimensions of the ellipsoids.

If the casting cores are approximately the same size, as a result, very even, easily predictable channel structures produce.

If the diameter of the casting cores is between approximately 0.1 to are approximately 2 mm, in particular with conventional ones Turbine blade wall thicknesses one for optimal film cooling Establish a sufficient number of channels. The casting cores of this kind are therefore neither too small, which may have casting problems would bring itself too big, so that the cooling of the Workpiece is only possible with a high amount of coolant.

If the casting cores have hollows with the casting material are fillable, is sufficient strength of the Workpiece despite its porous structure. The casting cores show a through the hollows compared to theirs Volume large surface area. This is the share in Casting material in the casting workpiece increased.

If the cavity is a hole and through a center of the casting core is particularly good strength of the workpiece also locally in the area of each core, since the casting cores are leached out after casting and each at least one central strut formed by the material remains, which ensures sufficient strength.

If only a predetermined part of the workpiece casting with Casting cores is filled, part of the workpiece can be filled with channels and another be solid. This is particularly so can be used with turbine blades by the casting cores only be filled in the area of the mold that the External walls created. Then only one outer wall is open porous, while the rest of the shovel contains the casting material in its has its original shape. The outer wall can then be cooled by means of a consumption-optimized film cooling.

When the casting cores are compacted with a shaker can be very narrow even with irregular casting cores Channel structures are generated. Uneven fillings the mold can thus be corrected.

This can cause the casting cores to float during casting be prevented that the introduced into the casting cavity Casting cores are held together.

When the casting cores are held together by nets, on the one hand prevents the casting cores from floating during casting and on the other hand possible slags, which accumulate on the casting material are intercepted. To do this, the mesh width must be smaller than the diameter on the other hand, the casting cores are large enough to let through be the slag.

The size of the channels is still adjustable in that the casting cores introduced into the casting cavity subsequently can be coated with a casting-resistant material that adheres to them are. The cast-resistant material adheres to both on the surface, as well as in particular at the points of contact two casting cores. This creates these points of contact reinforced and get a larger diameter, which in turn affects the channel diameter. Farther can through the material applied additional contact points arise if the casting cores are already very close together have, but have not yet touched. About that the coating also improves the casting cores held together and a floating of the casting cores in the Casting material prevented.

When the mold is connected to an evacuation device is, the casting material is poured into even the smallest Cavities in the casting mold, especially between the casting cores drawn. The emergence of cast material-free areas avoided. The casting process is also accelerated. By the Insertion of restraint devices, for example nets, prevents casting cores from being together with the casting material pulled towards the evacuation device.

To a casting process in the sense of the above task improve, it is suggested that casting cores in the casting cavity loosely placed next to each other. In this Processes are easily generated through channels, the dimensions of which can be easily selected by suitable Casting core dimensions can be changed and for their manufacture there is no elaborate preparation of the mold requirement.

When the casting cores inserted into the casting cavity are retrofitted with a cast-resistant material that adheres to them are coated, they are kept in the shape without to have to use complex devices. Depending on The coating process can target the channels several times repeated so as to stop between the cores improve or establish new connections.

To a workpiece in the sense of the above task improve, it is proposed that the workpiece of channels is interspersed with a space lattice. Such a workpiece can by passing cooling air on the other hand adequately cooled even with a low cooling air flow become. Own in the space lattice arrangement the channels, their diameter depending on the shape and the arrangement of the casting cores vary, mostly varied Branches and several openings.

Very good workpiece properties are achieved when practical a quarter of the total area of a workpiece side the area of evenly distributed channel openings is eliminated. On the one hand, there is practically no place on a channel enforced Workpiece side more that is cooled less well because film cooling occurs behind the channel opening well-cooled area that is three times the width of the channel opening is. All areas of the penetrated workpiece side are thus in the presence of a quarter channel opening area evenly cooled. At the same time it has A sufficient workpiece even in the area penetrated by the channel Strength.

If the channel openings have diameters between approximately 0.1 and have approximately 2 mm, optimal cooling is particularly a channel-penetrated outer wall of a conventional, internally cooled turbine blade guaranteed with film cooling.

Fig.1a, b Schnitte durch Teile einer schematischen Gießform einer Turbinenschaufel,

Fig.2a, b, c perspektivische Ansichten verschiedener Gießkerne und

Fig.3 einen Schnitt durch einen Teil einer kanaldurchsetzten Außenwand einer Turbinenschaufel.

An exemplary embodiment of the invention is given in the figures. Show it:

1a, b sections through parts of a schematic casting mold of a turbine blade,

Fig. 2a, b, c perspective views of different casting cores and

3 shows a section through part of a channel-penetrated outer wall of a turbine blade.

1a shows a section through part of a schematic Casting mold 10 of a turbine blade. A casting cavity 1 is used to produce an outer wall 14 of an internally cooled Turbine blade as shown in Fig.3. Through the outside wall 14, the coolant is thus flowed through from a coolant Interior transported out that the Outside 15 is covered by a coolant film and thus is cooled. To generate such channels 3 is located in the casting cavity 1 a large number of casting cores 2, which in the casting cavity 1 are loosely inserted. The casting cores 2 are for the sake of simplicity of illustration all elliptical in section in the same size without further Formations or hollows shown. Detailed representations the casting cores 2 can be found in FIGS. 2a, b, c.

Because the casting cores 2 largely touch each other, arise after casting and subsequent chemical Removal of the casting cores 2 channels through the workpiece 3, as shown schematically in Figure 3. The casting cores 2 are used to prevent floating or bringing in other workpiece areas by means of a device, for example a network 8 held together. The casting cores 2 have approximately the same size and in the exemplary embodiment ellipsoidal, almost spherical shape and are very close together. They can be poured into the mold 10 which makes manufacturing easier. For compression it is possible to attach a shaker that works under effect gravity arranges the casting cores 2 even closer. The Casting cores 2 are preferably made from a conventional casting core ceramic made so that after the casting process can be leached out of the workpiece, provided they connect to the outside 15 of the workpiece. Inside Casting cores 2 which are completely surrounded by casting material, can remain in the casting blank. However, it is extreme unlikely that casting cores 2 any other Touch casting cores 2. Because only one contact point per Casting core 2 is usually sufficient, a connection to any one Place one side of the outer wall up to the other Page to get as schematically by the dashed line indicated in Fig.1a, b. Thus, after leaching widely branched channel systems that lead through of the coolant. The channel width 16 can by subsequent stronger etching can be enlarged.

1b shows schematically arranged in a casting cavity 1 Casting cores 2 which after filling in the mold 10 with a pour-resistant material, for example a thin liquid Ceramics adhering to the surface 21 of the casting cores 2, encased and pourable by drying and / or heating have been coated. Through this subsequent wrapping 22 become contact surfaces of existing connection points 11 between the casting cores 2 enlarged and possibly additional Contact points 18 with the outer sides of the casting cavity 1 or another casting core 2 created. Thus the number the resulting channels 3 enlarged. Because the adhesive Envelope 22 in the areas of the joints 11 rather thicker than others due to surface tension Areas is formed, the channel width becomes 16 evened out. The ceramic material used for wrapping serves, is subsequently made together with the casting cores 2 leached the casting workpiece 20.

2a, b, c show perspective views of various Casting cores 2. The casting cores 2 have hollows. In 2a, the cavity runs in the form of a central bore 19 through the center 7 of an almost spherical casting core 2. This hole 19 is made during casting with casting material filled up and when the surrounding casting core 2 after the casting is removed by leaching remains a central one Casting material struts are available for strength in this Area contributes significantly. At the same time, through the introduction of the cavity the casting core volume in favor of the casting material volume decreased.

Fig. 2b shows an ellipsoidal, almost disc-like casting core 2 with an almost central bore 19, but at one Side has an additional opening, which creates a side open ring is created. In this way, casting material penetrate more easily into the cavity in the form of the bore 19 and it is an additional stabilizing side strut made from casting material.

2c shows a spherical casting core 2 with three central ones Bores 19, which meet in the center 7 of the casting core 2. Casting material can thus enter the casting core from the three sides 2 penetrate, which in this way has a very large surface area and has a very small volume and thus the Stability of the workpiece 20 increased.

In order to ensure that the entire surfaces of the casting cores 2 and all areas of the mold 10 are filled with casting material are, the mold 10 is attached to an evacuation device connected, which is not shown. In this way the casting material through the mold 10 in all narrowest areas of the mold 10 drawn between the casting cores 2.

3 shows a section through an outer wall penetrated by a channel 14 of a turbine blade. The casting cores 2 are from the Workpiece 20 has been leached and the voids left behind are connected at the contact points 11 of the casting cores 2, whereby through the outer wall 14 between the inside 17 and outside 15 extending channels 3 have arisen. The Channels 3 in Figure 3 are simplified for reasons of clarity shown schematically. In principle, they are narrower and have more branches and openings 6. The canals 3 have different lengths and branches and are, depending on the choice of size and shape of the casting cores 2, on their openings 6 on the outside 15 very closely arranged. This way, film cooling can cover any area of the outside 15 reach the outer wall 14 of the turbine blade and it is sufficient even with a small amount of coolant Cooling of the outer wall 14 ensured.

Claims (20)

Device for casting a workpiece, in particular one internally cooled turbine blade, with a casting cavity (1), in which casting cores (2) are present, the Generate workpiece penetrating channels (3), characterized in that that the casting cores (2) in the casting cavity (1) are placed loosely next to each other. Device according to claim 1, characterized in that at least two casting cores (2) penetrating a workpiece Create channel (3) lying next to each other. Device according to one of claims 1 or 2, characterized in that that the largest outer dimensions of the casting cores (2) smaller than the smallest inside dimensions of the Casting cavity (1) are. Device according to one of claims 1 to 3, characterized in that that the casting cores (2) in the casting cavity (1) are pourable. Device according to one of claims 1 to 4, characterized in that that the casting cores (2) are approximately spherical and / or are ellipsoidal. Device according to one of claims 1 to 5, characterized in that that the casting cores (2) are approximately the same size are. Device according to one of claims 1 to 6, characterized in that that diameter (5) of the casting cores (2) between approximately 0.1 to approximately 2 mm. Device according to one of claims 1 to 7, characterized in that that the casting cores (2) have hollows, which can be filled with casting material. Device according to one of claims 1 to 8, characterized in that that the cavity is a bore (19), which runs through a center (7) of the casting core (2). Device according to one of claims 1 to 9, characterized in that that only a predetermined part of the Workpiece casting mold (10) is filled with casting cores (2). Device according to one of claims 1 to 10, characterized in that that the casting cores (2) with a shaker be compressed. Device according to one of claims 1 to 11, characterized in that that the introduced into the casting cavity (1) Casting cores (2) are held together. Device according to one of claims 1 to 12, characterized in that that the casting cores (2) held together by nets (8) are. Device according to one of claims 1 to 13, characterized in that that the introduced into the casting cavity (1) Casting cores (2) subsequently with an adhering, pour-resistant material (9) can be coated. Device according to one of claims 1 to 14, characterized is that the mold (10) to an evacuation device connected. Method for casting a workpiece, especially one internally cooled turbine blade, with the casting cores (2) in a casting cavity (1) are used, the workpiece penetrating Generate channels (3), especially with the Features of one or more of claims 1 to 15, characterized characterized in that the casting cores (2) into the casting cavity (1) placed loosely next to each other. A method according to claim 16, characterized in that the casting cores (2) introduced into the casting cavity (1) subsequently with a casting-resistant adhesive on them Material to be coated. Workpiece with channels penetrating the workpiece, in particular internally cooled turbine blade, in particular manufactured by a method according to any one of claims 16 or 17 with a device according to one of claims 1 to 15, characterized in that the workpiece (20) from the channels (3) is interspersed with a space lattice. Workpiece according to claim 18, characterized in that practically a quarter of the total area of a workpiece side on the surface of evenly distributed channel openings (6) does not apply. Workpiece according to claim 18 or 19, characterized in that that the channel openings (6) diameter (9) between have approximately 0.1 and approximately 2 mm.

Images