EP2476864A1 - Bladed disk unit of a turbomachine ad method of manufacture - Google Patents

Abstract

The blade-disc assembly comprises a disc (1) and a blade (2), which is firmly connected to the disc. A weld seam (6) is arranged in a connecting area between the blade and the disc, and completely forms itself in either of the blade or the disc. A solder region or a diffusion region adjoins itself next to the weld seam toward the adjacent blade or disc. The weld seam is located in the disc. The weld seam (0-2.5 mm) is removed from the connected disc or blade or an edge of the blade or disc, in which the disc or blade is located in the weld seam. The weld seam has a thickness of 5-75 mm. The blade-disc assembly comprises a disc (1) and a blade (2), which is firmly connected to the disc. A weld seam (6) is arranged in a connecting area between the blade and the disc, and completely forms itself in either of the blade or the disc. A solder region or a diffusion region adjoins itself next to the weld seam toward the adjacent blade or disc. The weld seam is located in the disc. The weld seam (0-2.5 mm) is removed from the connected disc or blade or an edge of the blade or disc, in which the disc or blade is located in the weld seam. The weld seam has a thickness of 5-75 mm and an I-seam with centering lip. The disc and the blade form a shock at which the disc and the blade area adjacent to each other, where the shock has an abutting surface. The weld seam comprises limiting edges. The abutting surface adjoining the limiting edge of the weld seam is parallel to the abutting surface. An independent claim is included for a method for producing a blade-disc assembly.

Description

FIELD OF THE INVENTION

The present invention relates to a blade-disc unit for a turbomachine with a disc and a plurality of blades, which are materially connected to the disc.

STATE OF THE ART

In the construction of turbomachines, such as gas turbines or aircraft engines, cohesively connected blade-disc units are used, which are also referred to as a so-called blisk, where blisk is an artificial word for the combination of blade and disk. Such blade-disc units, which constitute a rotor for a corresponding gas turbine or an aircraft engine, are characterized in that the blades are cohesively, for example by welding, arranged on the disc. However, since different materials for the blades and the discs are used in the turbine, a direct welding of the blades with the disc is not possible there, as by welding a corresponding change or damage of the disc or blade material could occur, resulting in a not acceptable property profile.

For example, in the turbine of aircraft engines, melt-weldable nickel wrought alloys, such as Inconel 718, are often used, while the blade materials are formed from polycrystalline directionally solidified or single-crystalline nickel casting alloys having a high γ 'content which provides the requisite strength to the blade material. By melting the blade material, this structure would be destroyed and affected accordingly the strength of the blade.

Accordingly, an adapter between the blade and disc is provided in the prior art, wherein the adapter is connected by friction welding to the blade and then the adapter is arranged by a fusion welding to the disc. However, this is very complicated by the additional use of the adapter and the necessary additional welding operations.

DISCLOSURE OF THE INVENTION OBJECT OF THE INVENTION

It is therefore an object of the present invention to provide a method for producing a blade-disc unit (Blisk) and a corresponding blade-disc unit, the method should be easier and more effective to perform, but at the same time ensure that the property profile of the so Blisk produced is not affected.

TECHNICAL SOLUTION

This object is achieved by a method having the features of claim 9 and a blade-disc unit having the features of claim 1. Advantageous embodiments are the subject of the dependent claims.

The invention is based on the idea that a cohesive connection between the disk and the blade can also be achieved if one of the connection partners, ie either disk or blade, is not melted and only a melting of the other connection partner, ie according to the blade or disk , in which a solder joint can be formed by the molten material in the connection region and / or the energy introduced by the melting is sufficient to form, for example, a diffusion connection in the connection region of blade and disk.

Accordingly, the invention provides a weld spaced from the actual connection surface or directly to the connection surface, but only in the range of one of the connection partners provide while the other connection partners, so either disc or blade, are not melted. This means that the term the weld is understood in the sense that an area of one of the components to be joined is melted, so that there is a molten area. For the purposes of the present invention, however, welding seam is not to be understood as meaning that there is a fusion-technical mixing of materials of the components to be joined. Rather, it is just core of the present invention that one of the components to be connected, ie either blade or disc, especially in aircraft engines, the blade is not melted, but only by molten material of the connection partner, so in aircraft engines z. B. the disc is connected via a solder connection or via the heat provided in the melting area via a diffusion connection.

The weld can be introduced into either the disk or the blade, in particular at a distance of 0 to 3 mm, preferably 0 to 2.5 mm from the actual connection surface, that is, for example, the abutment surface of the components to be joined, wherein the weld itself has a thickness of 2 to 100 mm, in particular 5 to 75 mm in the direction transverse to the butt joint may have.

In particular, the disc and the blade can form a butt joint with a centering lip, wherein the weld seam can be formed as an I-seam.

In order to ensure that the connection properties are the same over the entire connection surface, the weld seam can be introduced in particular so that an edge of the weld which delimits it is formed parallel to the butt joint or abutment surface. In a corresponding conical weld, the weld can therefore be slightly tilted according to the opening angle of the welding cone introduced into the material.

In particular, energy beam methods, such as, for example, electron beam welding or laser beam welding, may be used as the welding method, although other suitable welding methods may also be used.

It is also possible to use multiple-jet methods, in which, in addition to the actual energy beam, which leads to the melting of a region of the edge material of a connection partner, one or more additional energy beams are provided heat adjacent areas, in particular the area of the actual butt joint, there to improve the formation of the material connection or facilitate.

In addition, a solder material can be inserted in the joining region, that is to say at the butt joint or the abutment surface between the pane to be joined and the blade, for example in the form of a solder foil of a metallic material, in particular nickel or a nickel alloy, which is heated by the adjacent melting region (Weld) also melts and provides a solder joint.

BRIEF DESCRIPTION OF THE FIGURES

Fig. 1

eine teilweise perspektivische Darstellung einer erfindungsgemäßen Scheiben-Schaufel-Einheit (Blisk);

Fig. 2

einen teilweisen Querschnitt durch eine erfindungsgemäße Blisk im Verbindungsbereich von Scheibe und Schaufel; und in

Fig. 3

eine weiterte Querschnittansicht gemäß der Darstellung aus Figur 2, wobei die Schweißnaht in Querlage ausgebildet ist.

The attached drawings show in

Fig. 1

a partial perspective view of a disc-blade unit (blisk) according to the invention;

Fig. 2

a partial cross section through a blisk according to the invention in the connection region of the disc and blade; and in

Fig. 3

an expanded cross-sectional view as shown FIG. 2 , wherein the weld is formed in a transverse position.

Embodiment

In the FIG. 1 a Blisk invention is shown in partial perspective view. In the FIG. 1 Blisk shown comprises a disc 1, on which a plurality of blades 2 are arranged or can be arranged. The blades 2 have on one side a shroud 4 and on the opposite side a blade root 3, with which they are connected to the disc 1.

For this purpose, a plurality of grooves 5 are formed along the circumference of the cylinder jacket surface of the disc 1, in which the Schaufelfiiße 3 of the blades 2 are inserted.

The FIG. 1 further shows where in the embodiment shown the FIG. 1 the weld is provided to produce by a melting of the disc material a cohesive connection between blades and disc.

As in FIG. 1 is shown, the weld 6 is at a certain distance d from the surface of the disc 2 and the abutting surface between the disc 1 and blades 2. On the disc 1 grooves 5 are formed, which serve to accommodate the blade root 3. The melting of the disc material in the region of the weld seam 6 also causes heating in the connection region between the blade root 3 and the boundary material of the disc 1 in the grooves 5, so that a corresponding cohesive connection is formed there. If there is an inflow of the molten disc material in the connecting region between the disc 1 and blade 2 so a solder joint is formed, in which molten disc material serves as a solder material for connection to the blade root. In this case, the weld seam 6, ie the molten area, can reach as close as possible to the blade root 3 as long as the blade material is not melted or damaged in any other way due to excessive heat input.

In addition, the molten region, that is, the weld 6 can also be introduced at a distance d from the actual abutment surface against which the blade root 3 and the disc abut one another, so that only the disc material heated thereby at the impact surface between the blade root 3 and disc 1 ensures a material connection.

The situation with regard to the position and introduction of the weld 6, ie the melted area, is in the Figures 2 and 3 in sectional views of the connecting portion of the blade 2 and disc 1 on the one hand in the so-called tub position and on the other hand in the transverse position ( Fig. 3 ).

This show the Figures 2 and 3 in that the joint on which the disk 1 and the blade 2 are connected to one another can be designed essentially as a butt joint, wherein a so-called 1-seam with a centering lip 8 can be formed on the stump joint. For this purpose, the thickness of the blade 2 is slightly larger than the thickness D of the disc 1, so that in the region of the centering lip 8, the blade protrudes beyond the disc 1 and forms a contact shoulder.

As the cross-sectional views of Figures 2 and 3 can be clearly seen, the weld 6 is not in the region of the butt joint 7, the disc 1 and blade 2 abut each other, introduced, but slightly offset by the distance d in the direction of the disc material. Although, depending on the choice of material for the disc 1 and the blade 2 also an introduction of the weld 6 in the blade material conceivable, however, the attachment of the weld 6 is selected in the disc 1 in the embodiment shown for a turbine blisk in aircraft engine construction, since the disc material is usually a melt-weldable nickel wrought alloy, such as Inconel 718, while it is in the blade material to polycrystalline, directionally solidified or monocrystalline casting alloys, which are usually not melt-weldable due to their high γ'-share, otherwise cracks may arise and beyond their strength-enhancing γ'-structure is destroyed.

The weld 6 can be introduced by appropriate energy beams, such as electron beams or laser beams, although other suitable welding methods can be used.

The shape of the weld seam 6, that is to say of the molten area, is generally conical in cross-section, that is to say with flanks converging toward or apart from one another, which delimit the weld seam 6. Advantageously, therefore, the weld 6 is introduced so that the flank, so the edge region of the weld 6, which is adjacent to the connection region, ie in the present case adjacent to the blade 2, as parallel as possible to the butt joint or the impact surface formed thereby extends to prevent in that due to the conical configuration over the cross-section of the material-locking connection, different connection conditions exist due to the different distance between the melted area and the component to be connected. If, therefore, with the welding method no weld 6 can be generated, having parallel flanks, the electron or laser beam 9, with which the weld 6 is introduced so tilted relative to the butt joint 7 or the surface of the components to be connected, that the Butt joint 7 adjacent edge of the weld 6 is formed parallel to the butt joint or abutment surface. This can be done, for example, in a simple form in that the components are tilted correspondingly by the angle θ with respect to the electron or laser beam, which corresponds to the opening angle of the conical weld seam.

The thickness D of the disc material can in this case be selected so that welding defects caused, for example, by a "nail head" in the region of the jet entrance are in the allowance a ₁ , while welding defects which lie in the region of the weld root are are in a measure a ₂ , so that overall no impairment of the required strength values for the disc 1 is to be feared.

The distance d of the weld 6 from the butt joint 7 can be chosen to be different, depending on the material combinations used for the disc 1 and the blade. 2

In addition, in the region of the butt joint, a solder material, for example in the form of a solder foil of a metallic material, such as, in particular, nickel or a nickel alloy, which melts upon introduction of the radiant energy to produce the weld 6 and forms a corresponding solder joint, can be arranged.

If, in the region of the butt joint, it is not immediately possible to melt the disk material or an additionally introduced solder material, then the integral connection is effected by diffusion bonding directly at the butt joint.

To support the heating, in particular in the area of the butt joint, additional energy beams can be used parallel to the electron or laser beam 9, which are directed directly to the region of the butt joint 7 and provide additional heating there, but without melting the material and in particular the material To guide blade material.

Although the present invention has been described in detail with reference to the embodiment, it will be understood by those skilled in the art that the present invention is not limited to this embodiment, but rather modifications are possible in the manner that individual features omitted or other combinations of features are made as long as the scope of protection of the appended claims is not abandoned. In particular, the present invention claims the combination of all presented individual features of the subject invention.

Claims (13)

Blade-disc unit for a turbomachine with a disc and a plurality of blades, which are materially connected to the disc,
characterized in that
in the connection region between the blade (2) and the disc (1) a weld seam (6) is arranged, which is located completely in either the blade or the disc. Blade-disc unit according to claim 1,
characterized in that
next to the weld seam (6) in the direction of the adjacent blade or disc, a solder region or diffusion region connects. Blade-disc unit according to claim 1 or 2,
characterized in that
the weld (6) is in the disc (1). Blade-disc unit according to one of the preceding claims,
characterized in that
the weld (6) is removed from 0 to 3 mm, in particular 0 to 2.5 mm, from the connected disk or blade or the edge of the blade or disk in which the weld is located. Blade-disc unit according to one of the preceding claims,
characterized in that
the weld seam (6) has a thickness of 2 to 100 mm, in particular 5 to 75 mm. Blade-disc unit according to one of the preceding claims,
characterized in that
the weld (6) is an I-seam with centering lip. Blade-disc unit according to one of the preceding claims,
characterized in that
The disc (1) and blade (2) form a butt against which the disc and blade abut each other, the butt having a butting surface, and the weld includes the weld delimiting edges, and wherein the butting surface adjacent edge of the weld is substantially parallel to the butting surface is. Blade-disc unit according to one of the preceding claims,
characterized in that
the blade-disc unit is a turbine blisk for an aircraft engine. Method for producing a blade-disk unit for a turbomachine with a disk and a plurality of blades, which are materially connected to the disk, comprising the steps: Arranging at least one blade (2) on a disc (1), Melting of an edge region (6) of the blade or disk, which is adjacent to the disk or blade to be connected, - Connecting the blade and disc through the molten material of either blade or disc or by heat from the molten area. Method according to claim 9,
characterized in that
the melting by means of energy beam method, in particular electron beam or laser beam welding process takes place. Method according to one of claims 9 or 10,
characterized in that
a multi-beam method is used, wherein at least one energy beam is used in addition to the energy beam for the melting, which heats adjacent areas, in particular the joint area. Method according to one of claims 9 to 11,
characterized in that
in the joint area between the disk and blade a solder material is inserted. Method according to claim 12,
characterized in that
the solder material is arranged as a foil between the disc and the blade.

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