JP2743066B2 - Blade structure for gas turbine - Google Patents

Description

Description: TECHNICAL FIELD The present invention relates to a moving blade structure for a gas turbine, and in particular, has excellent heat resistance capable of achieving high efficiency by increasing the temperature of combustion gas. The present invention relates to a moving blade structure for a gas turbine. [Prior Art] As shown in FIG. 16, a conventional blade 1 for a gas turbine has a blade portion 2 for receiving combustion gas and a thick shank portion 4.
And the dovetail portion 6 implanted in the disc-shaped wheel 7
Are integrally formed of a metal material, and a number of rotor blades 1 are implanted around the circumference of the wheel 7 to constitute one gas turbine rotor.
In FIG. 16, reference numeral 8 denotes a shroud assembled to the casing 8A and provided so as to be close to the tip of the blade portion 2 of the moving blade 1. In this conventional rotor blade structure for a turbine, since the entire rotor blade 1 is entirely made of a metal material, the temperature of the combustion gas is reduced to about 800 ° C., which is the allowable heat-resistant temperature of the metal material forming the rotor blade 1. It is necessary to keep below. For this reason,
A large amount of cooling air was required, which in turn reduced the efficiency of the gas turbine. However, there is a limit to the cooling technology of the moving blade 1, and in the case of an air cooling structure, it is difficult to apply the conventional metal moving blade when the temperature of the combustion gas turbine inlet is 1300 ° C. or more. Was. Therefore, as shown in JP-A-54-106714,
A moving blade structure using ceramic having excellent heat resistance for a part of the moving blade has also been proposed. As shown in FIG. 17, a moving blade structure using a part of this ceramic has a moving blade 11 formed of a hollow blade core 12 and a blade skin 14 made of high-strength ceramic or the like.
A gap 15 is formed between the core 12 and the skin 14, and a small hole 16 provided in the core 12 with cooling air supplied in the axial direction (direction of arrow A) of the core hollow portion. Through the gap
The blades 15 are discharged to the outside through the discharge holes 18 at the lower ends of the blades, so that the entire blade 11 is cooled from the inside. [Problems to be Solved by the Invention] In the moving blade structure using a part of the conventional ceramic,
There are the following problems. Although a gap 15 is formed by interposing a fibrous heat-resistant member between the core 12 and the skin 14, the heat-resistant impact strength of the skin 14 is low when the moving blade 11 is cast-molded. Is more likely to occur. The ceramic skin 14 is fixed to the wing core 12 via a fibrous heat-resistant member, but a centrifugal force acting on the skin 14 acts on the fixing portion, particularly when a shroud is not provided on the outer periphery of the wing. However, there is a problem that the strength is not sufficient and the reliability as a moving blade is lacking. Since the blade platform is not covered with the ceramic skin 14 and is directly exposed to the combustion gas, and the wing core 12 covered with the ceramic skin 14 also receives radiant heat from the skin 14, it is made of a metal material. The entire outer peripheral surface of the wing core 12 is required to be cooled, and a large amount of cooling air is required, thereby lowering the thermal efficiency of the gas turbine. SUMMARY OF THE INVENTION The present invention has been made in view of the problems of the related art, and an object of the present invention is to provide a moving blade structure for a gas turbine which is excellent in both heat resistance and mechanical strength. [Means for Solving the Problems] In order to achieve the above object, a moving blade structure for a gas turbine according to the present invention comprises a blade portion to which combustion gas is applied, and a retainer formed in a convex shape at the root of the blade portion. A shank portion connected to the blade root portion having a constricted portion for use, and a dovetail portion protruding downward from the shank portion and implanting into a disk-shaped wheel. The blade root portion and the shank portion are fitted. In a gas turbine moving blade structure in which the wing portion is formed of a ceramic material and the other portion is formed of a metal material, the wing portion is made of a ceramic material, and the shank portion is assembled with a ceramic shank shell. The outer surface of the shank portion is covered with the shank shell, and the mounting surface of the shank portion and the shank shell is filled with a heat insulating material, and the cooling air flow is A passage is formed, and a cooling air supply passage is formed from the dovetail portion through the shank portion to open to the fitting surface and the assembly surface. Further, a wing portion to which the combustion gas is applied, a shank portion connected to the wing root portion formed with a convex constriction portion formed at the root of the wing portion, and a disc-shaped protruding downward from the shank portion. A dovetail portion which is an implant portion to the wheel, wherein the blade root portion and the shank portion are integrally formed by fitting connection, and the wing portion is a ceramic material,
The other part is a blade structure for a gas turbine made of a metal material, in which a ceramic shank shell is assembled to the shank, so that the outer surface of the shank is covered with the shank shell,
A heat insulating material is filled in an assembling surface of the shank portion and the shank shell, and a cooling air flow passage formed by a groove is formed, and the fitting is performed from the dovetail portion through the shank portion. And a cooling air supply passage opening to the surface and the assembly surface. Further, a wing portion to which the combustion gas is applied, a shank portion connected to the wing root portion formed with a convex constriction portion formed at the root of the wing portion, and a disc-shaped protruding downward from the shank portion. A dovetail portion which is an implant portion to the wheel, wherein the blade root portion and the shank portion are integrally formed by fitting connection, and the wing portion is a ceramic material,
The other part is a blade structure for a gas turbine made of a metal material, in which a ceramic shank shell is assembled to the shank, so that the outer surface of the shank is covered with the shank shell,
The mounting surface of the shank portion and the shank shell is filled with a heat insulating material having air permeability, and a ventilation hole of the heat insulating material serves as the cooling air flow passage, and the shank portion is removed from the dovetail portion. It is characterized in that a cooling air supply passage which passes through the fitting surface and the assembling surface is opened. [Operation] According to the above configuration, the metal shank is insulated and cooled by the cooling air. Further, since the ventilation hole of the heat insulating material serves as the cooling air flow passage, transmission of heat to the metal shank is prevented, and the thermal efficiency of the gas turbine is improved. Further, for example, a structure in which a ceramic blade root portion and a metal shank portion are fixed with a hard ceramic-based adhesive having excellent heat resistance and heat insulation properties, and a tipping force of the blade portion is supported by the shear strength of the adhesive. By doing so, the problem of rattling against loads such as vibrations applied to the moving blades during rotation can be solved, and reliability can be improved. Next, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a diagram showing a first embodiment of the present invention. In this figure, a rotor blade 20 according to the present embodiment has a blade portion 22 made of ceramic and other portions (a shank portion 34 and a dovetail portion 32) integrally formed of metal are fitted and connected. It has a structure. As shown in FIG. 2, the wing portion 22 has a wing body 24 formed in a streamlined shape and a wing root portion formed at the root of the wing body.
26 and are integrally formed. The blade root portion 26 is formed in a convex shape having a constricted portion 26B for retaining, and is fitted and connected to a fitting concave portion 35 formed in the shank portion 34. The fitting connection between the wing portion 22 and the shank portion 34 is performed by inserting the wing root portion 26 in the wing cord direction as shown by a two-dot chain line in FIG. State. Fitting concave portion between convex wing root portion 26 of wing portion 22 and shank portion 34
35 is formed in a shape matching with a small gap 27 (see FIG. 3), and the gap 27 is filled with an adhesive 28 such as Al ₂ O ₃ which is excellent in heat resistance and heat insulation. Then, the blade root portion 26 and the shank portion 34 are fixed. On both sides of the shank portion 34, a pair of shank shells 36 and 37 made of ceramic are assembled via a heat insulating material 29, and the metal shank portion 34 is covered with ceramic shank shells 36 and 37. It has a broken structure. Side grooves 38 are formed in the shank shells 36 and 37, and a heat-resistant fiber member 39 such as a ceramic fiber is wound and mounted along the side grooves 38 so that the shank shells 36 and 37 are attached to the shank portion 34. It is designed to be tied and fastened. According to this embodiment, the following effects can be obtained. First, the wing, which is the part directly exposed to the hot combustion gases
22, and blade root upper end surface, shank shell upper end surface 36A, 37
The platform section made of A is made of a ceramic material with excellent heat resistance, while the shank section 34 and the dovetail section 32, which are parts requiring mechanical reliability, are made of a highly tough metal material. The structure has excellent heat resistance and mechanical strength. Next, the fitting concave portion 35 of the shark portion 34 and the wing root portion of the wing portion 22
The mating surface with 26 is filled with a hard and heat-resistant ceramic-based adhesive to connect and connect the two, so that the rotor blades are subject to loads such as vibrations during rotation. It is an extremely reliable connection that does not rattle. Further, the fitting concave portion 35 of the shank portion 34 and the blade root portion 26
By using an adhesive having a low heat conduction property as an adhesive to be filled into the fitting surface of the gas turbine, heat transfer to the shank portion 34 made of metal can be further prevented, and as a result, the heat efficiency of the gas turbine can be reduced. Improvement can be expected. Also, the blade root portion 26 of the ceramic wing portion 22 and the shank portion
Since a heat-resistant adhesive is interposed between the fitting recess 35 and the surface of the fitting recess 35, the working accuracy of the fitting surface is not so much a problem, so that the working of the ceramic blade root 26 is easy. There is also the advantage that there is. FIG. 4 is a view showing a main part of a second embodiment of the present invention. In the second embodiment, the blade root 26 formed at the root of the blade main body 24 of the rotor blade is formed in a streamlined shape similarly to the blade main body 24, and the surface of the blade 22 has a smooth continuous shape. Is the feature. According to the second embodiment, there is no structural (geometric) discontinuity over the entire wing portion 22 and high notch sensitivity of the ceramic (sensitive to stress concentration and the like, causing a substantial reduction in strength). Has the effect of suppressing Further, a pressure difference is generated between the ventral side and the back side of the wing portion 22 due to the flow of the combustion gas, and a tipping force acts on the wing main body 24 due to this pressure difference, but the fitting recess 35 of the shank portion 34 and the wing portion 22 Instead of receiving this force due to the shear deformation of the mating surface with the blade root 26, the blade root
It is designed to receive in all 26 shapes. That is, in the first embodiment, the overturning force is supported only by the shear strength of the adhesive material filled in the fitting surface between the blade root portion 26 and the fitting concave portion 35. In this case, not only the shear strength of the adhesive filled in the fitting surface but also the structural strength of the fitting portion is dominant, so that the fitting structure has high reliability. However, in the case of the second embodiment, it is difficult to insert the blade root portion 26 in the blade code direction, and the shank portion 34 must be divided. FIG. 5 shows a main part of a third embodiment of the present invention. In this embodiment, the blade root portion 26 of the blade portion 22 is formed in a streamlined shape similar to the blade main body 24, and the lower end of the blade root portion 26 is enlarged to increase the contact area of the shank portion 34 with the fitting recess 35. The feature is that the stress generated in the ceramic blade root 26, which is a brittle material, is reduced. Furthermore, in the third embodiment, since the lower end portion of the blade root 26 protrudes in the direction orthogonal to the blade cord direction, the overturning force acting on the blade main body 24 is applied to the protruding load acting surface 26C. In this case, the characteristics of a ceramic material that is strong in compressive force are effectively used. FIG. 6 is a diagram showing a fourth embodiment of the present invention. In the fourth embodiment, the shank shells 36, 37 assembled to the shank portion 34 are divided into two in the blade cord direction (the divided shank is assumed to be 36 ', 37', respectively). In the structure in which the pair of shank shells 36 and 37 are assembled to the shank portion 34 as in the first embodiment, a large thermal stress is generated due to the non-uniform temperature distribution of the shank portion 34 in the blade cord direction. There is a possibility that the shank shells 36 and 37 made of a ceramic material may be adversely affected, but in this embodiment, since the shank shells 36 and 37 are divided in the blade cord direction, the shank portions 34 and 37 are formed. The thermal stress generated by the non-uniform temperature distribution in the blade cord direction is alleviated, and as a result, the strength reliability of the moving blade structure is further improved. FIG. 7 is a view showing a fifth embodiment of the present invention. In the first embodiment, the platform portion of the blade is connected to the upper end surface 26A of the blade root portion 26 and the upper end surfaces 36A of the shank shells 36, 37.
In this embodiment, the upper ends 36A, 37A of the shanks 36, 37 are extended to a position where they come into contact with the wing body 24 of the wing portion 22, and the platform portion of the rotor blade is connected to the shank shell 36. , 37 only at the upper end surfaces 36A, 37A. As in the fourth embodiment, the shank shells 36 and 37 have a structure divided into two in the blade cord direction. According to the fifth embodiment, the influence of the thermal stress generated on the mounting surface of the shank portion 34 and the shank shells 36, 37 can be reduced, and the metal shank portion 34 can be formed by the shank shells 36, 37. The first embodiment (first embodiment)
Since the structure is more securely covered than shown in the figure, it is effective in preventing heat from flowing into the shank portion 34. FIG. 8 shows a sixth embodiment of the present invention. In this embodiment, grooves 40 are formed on both side surfaces of the shank portion 34, while shank shells 36 and 37 assembled to the shank portion 34 are formed with dowels 42 having a size matching the dovetail groove 40. Have been. This shank shell 36,3
7 is assembled to the shank portion 34 by moving the shank shell 36 (37) in the wing cord direction with the end of the dovetail 42 engaged with the dovetail groove 40, as shown in FIG. . A heat insulating material 29 is arranged on the mounting surface of the shank portion 34 and the shank shells 36 and 37, so that the shank shells 36 and 37 are prevented from vibrating. According to the present embodiment, the shank portion 34 and the shank shell 3
6 and 37, and is formed by groove coupling, so that the structure is very firm as compared with the binding and fastening by the fiber member as shown in the first embodiment. FIG. 10 shows a seventh embodiment of the present invention. In the present embodiment, a concave surface 46 is formed on the outer surface of the shank portion 34, while a convex portion (shown in the drawing) that engages with the concave portion 46 is provided on the mounting surfaces of the shank shells 36 and 37 that are mounted on the shank portion 34. The shank shells 36 and 37 are assembled in a state where the concave and convex portions are engaged with each other, and the fiber members 39 are used for binding and fastening. According to the seventh embodiment, the centrifugal force of its own weight acts on the shank shells 36 and 37 by the rotation of the rotor blades. The centrifugal force of the shank shells 36 and 37 is formed on the side surface of the shank portion 34. It is supported by the contact stress acting on the surface of the concave portion 46, and a highly reliable coupling structure is obtained. FIG. 11 is a view showing an eighth embodiment of the present invention. In FIG. 11, the blade is fitted with a blade portion 22 made of ceramic and connected to a shank portion 34 made of metal, and a ceramic shell 3 is formed on the outer surface of the metal shank portion 34.
6,37 are assembled. A wing root portion 26 formed at the root of the wing portion 22 and a fitting concave portion of the shank portion 34
The mating surface with 35 is filled with an adhesive 29 having excellent heat resistance and heat insulation such as Al ₂ O ₃ , and the wing portion 22 and the shank portion 34 are filled.
Is firmly fixed. On the assembly surface of the shank portion 34 and the shank shells 36 and 37, a fiber fiber member 29A excellent in air permeability, heat insulation and heat resistance is interposed,
A heat-resistant fiber member 39 is wound and mounted on a side groove 38 formed on the outer surface of the shank shell, thereby forming the shank shell 3.
6,37 can be securely assembled. As shown in FIGS. 12 and 13, a plurality of grooves 35A for cooling air flow are formed in the inner circumferential surface of the fitting concave portion 35 of the shank portion 34 in the blade cord direction. In the fiber fiber member 29A interposed on the mounting surface of the shank portion 34 and the shank shells 36 and 37, the pores of the fiber function as a cooling air passage. Also, the upper end surface 26A of the wing root portion 26 of the wing portion 22 and the upper end surfaces 36A, 37A of the shank shells 36, 37 are:
As shown in FIG. 11, a cooling air flow passage is formed on the entire outer peripheral surface of the shank portion 34 as shown in FIG. It has become so. As shown in FIG. 11 and FIG. 12, the portion made of metal consisting of the dovetail portion 32 and the shank portion 34 has a tip surface of the dovetail portion 32 and an inner peripheral surface of a fitting recess 35 of the shank portion 34. A plurality of vertical through holes 50 having both ends opened are formed in the groove 35A formed in the direction of the blade cord. Further, a plurality of horizontal through-holes 52 are formed in the blade cord direction while intersecting with these through-holes 50 and opening on both side surfaces of the shank portion 34, and these vertical and horizontal through-holes 50, 52 are provided for cooling air. Is supplied to the outer peripheral surface of the shank portion 34. The lower end of the through hole 50 of the dovetail portion 32 is connected to an air supply passage formed in a disc-shaped wheel (not shown), and as shown in FIG. The cooling air entering the hole 50 is divided into a flow (B ₁ ) passing through the horizontal hole 52 of the shank portion and a flow (B ₂ ) toward the upper end end of the vertical hole 50. entering as shown by reference numeral C ₁ in the fiber member 29A which is interposed between the parts 34 and the shank shell 36,37. A gap 26B is formed in the platform by using the pores of the fiber member having excellent air permeability as an air flow passage.
From the outside as shown by arrow D. Meanwhile, the flow indicated by the arrow B ₂ penetrates into the groove 35A as shown in the fitting recess 35 inner peripheral surface of the shank portion 34, arrow C ₂
As shown in FIG. 5, the fluid flows along the groove 35A and is discharged to the outside as indicated by an arrow D from a gap 26B also formed in the platform. Other than the above, the first embodiment of the present invention (FIGS. 1 to 3)
Since the structure is the same as that shown in the figure, the same reference numerals are given and the description thereof is omitted. According to the present embodiment, the following effects can be obtained. The wing portion 22 is made of ceramic, is fitted and connected to a metal shank portion 34 via a heat-resistant adhesive 29, and furthermore, the outer peripheral surface of the metal shank portion 34 is made of ceramic through a heat-resistant fiber member 29A. Since it is configured to be covered with the shank shells 36 and 37 composed of, both heat resistance and mechanical strength are excellent. On the outer peripheral surface of the metal shank portion 34, in addition to arranging the fiber member 29A which is a heat insulating material, cooling air is circulated, so that the metal shank portion 34 can be efficiently cooled. As a result, the operation in which the temperature of the combustion gas is increased can be performed, and the efficiency of the turbine can be improved. In the above-described embodiment, the air-permeable fiber member 29A interposed on the mounting surface with the shank shells 36 and 37 is configured as a cooling air flow passage, but as shown in FIG. Mating surface with blade root 26, shank shells 36, 3
7, the fiber member 29A having excellent air permeability, heat insulation and heat resistance, and an adhesive material such as Al ₂ O ₃ having excellent heat resistance are alternately arranged at predetermined intervals in the blade cord direction on the assembly surface with 7, This fiber member 29
A may be configured as a cooling air flow passage.
In this case, there is an advantage that an operation of forming a groove in the shank portion 34 becomes unnecessary. As shown in FIG. 15, grooves 35B corresponding to grooves 35A are also provided on the mounting surface of shank portion 34 with shank shells 36 and 37.
May be formed, and cooling air may flow through these grooves 35A and 35B. In this case, since the adhesive 29 can also be filled on the mounting surfaces of the shank shells 36 and 37,
As a result, the shank shells 36 and 37 can be securely assembled. In each of the above embodiments, the grooves 35A (3
5B) Alternatively, the outer peripheral surface of the shank portion 34 is cooled by disposing the heat-insulating member 29A having a high air permeability, and the gap between the platforms is reduced.
The cooling air is discharged to the outside from 26B, but a groove that is orthogonal to and intersects with the groove 35A (35B) is formed,
The cooling air may be discharged to the outside also from the surface of the shank section 34 facing the stationary blade (not shown). With this configuration, the vertical and horizontal grooves formed on the outer peripheral surface of the shank portion 34 enhance the cooling effect of the shank portion 34 accordingly. Although FIG. 11 and subsequent drawings focus on the cooling air passage, it goes without saying that other structures of the moving blades can be configured as in the above-described embodiments. [Effects of the Invention] As is apparent from the above description, according to the present invention, the metal shank portion can be efficiently cooled and heat shielded by the cooling air or its passage. For example, by fixing the wing portion and the shank portion with a hard ceramic adhesive, and supporting the wing portion with the shear strength of the adhesive, the vibration resistance is further improved, and the heat transfer to the metal shank portion is performed. Can be prevented. Accordingly, a blade for a gas turbine excellent in both heat resistance and mechanical strength can be obtained, the efficiency of the turbine can be remarkably improved, and a highly reliable gas turbine can be operated.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view showing the whole of a first embodiment of the present invention, FIG. 2 is an exploded perspective view of its individual components, and FIG. FIG. 4 is a perspective view of a main part of a second embodiment of the present invention, FIG. 5 is a perspective view of a main part of a third embodiment of the present invention, and FIG. FIG. 7 is a perspective view showing the entire fifth embodiment of the present invention, FIG. 8 is an exploded perspective view showing the sixth embodiment of the present invention, and FIG.
FIG. 10 is a perspective view showing the whole thereof, FIG. 10 is a perspective view showing a main part of a seventh embodiment of the present invention, FIG. 11 is a longitudinal sectional view of an eighth embodiment of the present invention, and FIG. FIG. 13 is a perspective view of the main part, and FIG.
FIG. 14 is a cross-sectional view taken along line XIII-XIII shown in FIG. 14, FIG. 14 is a cross-sectional view of a main part of another embodiment of the present invention, FIG. 15 is a cross-sectional view of another main part of the present invention, and FIG. FIG. 17 is a perspective view showing a state where a turbine rotor is constructed by assembling a moving blade of the present invention into a wheel, and FIG. 17 is a longitudinal sectional view of another conventional moving blade. 20… moving blade, 22… wing part, 24… wing body, 26… wing root part, 28… adhesive, 29,29A… insulation material, 32… debutir part, 34… shank part, 36,37: Shank shell, 38: Side groove, 39: Heat-resistant fiber material, 50,52: Through hole.

Claims (1)

(57) [Claims] A wing part to which the combustion gas is applied, a shank part connected to the wing root part having a convex constriction formed at the root of the wing part, and a disk-shaped wheel protruding downward from the shank part. The blade root portion and the shank portion are integrally formed by fitting and connection, and the wing portion is made of a ceramic material, and the other portions are made of a metal material. In the turbine rotor blade structure, by attaching a ceramic shank shell to the shank portion, an outer surface of the shank portion is covered with the shank shell, and an assembling surface of the shank portion and the shank shell is provided. Is filled with a heat insulating material, and a cooling air flow passage is formed. The fitting surface and the assembling pass through the shank portion from the dovetail portion. A moving blade structure for a gas turbine, characterized in that a cooling air supply passage opening in the surface is formed. 2. A wing part to which the combustion gas is applied, a shank part connected to the wing root part having a convex constriction formed at the root of the wing part, and a disk-shaped wheel protruding downward from the shank part. The blade root portion and the shank portion are integrally formed by fitting connection, the wing portion is made of a ceramic material, and the other portions are made of a metal material. In the turbine rotor blade structure, by attaching a ceramic shank shell to the shank portion, an outer surface of the shank portion is covered with the shank shell, and an assembling surface of the shank portion and the shank shell is provided. Is filled with a heat insulating material, and a cooling air flow passage constituted by a groove is formed, and the cooling air flow passage is formed from the dovetail portion through the shank portion. A moving blade structure for a gas turbine, wherein a cooling air supply passage is formed in the fitting surface and the mounting surface. 3. A wing part to which the combustion gas is applied, a shank part connected to a wing root part having a convex constriction formed at the root of the wing part and connected to a wing root part, and a disk-shaped wheel protruding downward from the shank part. The blade root portion and the shank portion are integrally formed by fitting connection, the wing portion is made of a ceramic material, and the other portions are made of a metal material. In the turbine rotor blade structure, by attaching a ceramic shank shell to the shank portion, an outer surface of the shank portion is covered with the shank shell, and an assembling surface of the shank portion and the shank shell is provided. Is filled with a heat-insulating material having air permeability, and the ventilation hole of the heat-insulating material serves as the cooling air flow passage, and the shank extends from the dovetail portion. A cooling air supply passage which is opened through said portion to said fitting surface and said assembling surface. 4. A small gap between the blade root portion and the shank portion is filled and fixed with a hard ceramic adhesive having excellent heat resistance and heat insulation, and the overturning force of the blade main body due to the shear strength of the adhesive. The moving blade structure for a gas turbine according to claim 1, wherein the moving blade structure is a structure for supporting the moving blade.