KR20190109907A - Protecting device - Google Patents

Abstract

The present invention relates to a protection device, which is provided on a vane to protect the vane when performing laser processing on the vane including an airfoil having a vane cavity formed therein, and a pair of shrouds respectively provided on an upper end and a lower end of the airfoil. The protection device comprises: a protection portion formed in a shape corresponding to the shape of an inner wall of the vane cavity, the protection portion being inserted into the vane cavity so that an outer surface thereof is in contact with the inner wall of the vane cavity and preventing a laser beam irradiated to one side of the airfoil from penetrating to the other side of the airfoil; and a mounting portion provided at one end of the protection portion and mounted on the shroud to fix the protection portion to the inside of the vane cavity. According to the present invention, the protection device is provided with the protection portion inserted into the vane cavity, thereby preventing the laser beam irradiated to the one surface of the airfoil from penetrating to the other surface of the airfoil.

Description

Protective device

The present invention relates to a protection device, and more particularly, to an apparatus installed on the vanes to protect the vanes when performing laser processing on the vanes of the gas turbine.

In general, a gas turbine consists of a compressor, a combustor and a turbine. The compressor is arranged alternately with a plurality of compressor vanes and compressor blades in the compressor casing. The compressor draws in external air through a compressor inlet scroll strut. The sucked air is compressed by the compressor vanes and the compressor blades while passing through the inside of the compressor.

In the turbine, a plurality of turbine vanes and turbine blades are alternately arranged in the turbine casing. The turbine receives the combustion gas generated by the combustor and passes it therein. The combustion gas passing through the inside of the turbine rotates the turbine blades, and the combustion gas passing through the inside of the turbine is discharged to the outside through the turbine diffuser.

Since such a gas turbine does not have a reciprocating mechanism such as a piston of a four-stroke engine, there is no mutual friction portion such as a piston-cylinder, so that consumption of lubricant is extremely low. Therefore, the gas turbine has the advantage that the amplitude, which is a characteristic of the reciprocating machine, is greatly reduced, and the high speed movement is possible to generate a high capacity power.

On the other hand, as related to the turbine vane of the gas turbine, the Republic of Korea Utility Model Registration No. 20-0174662 discloses a gas turbine.

The turbine vane includes an airfoil having a vane cavity formed therein, and a pair of shrouds respectively provided at upper and lower ends of the airfoil. In addition, the air foil is formed with a plurality of vane cooling holes through which compressed air supplied from a compressor is discharged on a surface thereof in order to prevent thermal damage from the high temperature and high pressure combustion gas supplied from the combustor.

In this case, the vane cooling hole is formed by laser processing. In addition, the laser irradiated to one side surface of the airfoil to form the vane cooling hole is limited to pass through the vane cavity inside the airfoil to the opposite side surface of the airfoil. Therefore, according to the conventional vane cooling hole processing method, a large number of unnecessary vane cooling holes are formed on the surface of the air foil, and there is a problem that the processing precision of the vane cooling hole is reduced.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a protection device for preventing the laser irradiated to one surface of the vane from penetrating to the other surface of the vane.

The protection device according to an aspect of the present invention is provided on the vanes during laser processing of a vane including an airfoil having a vane cavity formed therein and a pair of shrouds respectively installed at upper and lower ends of the airfoil. As the protection of the vane, the vane cavity is formed in a shape corresponding to the shape of the inner wall of the vane cavity, the outer surface is inserted into the vane cavity to contact the inner wall of the vane cavity, the laser irradiated to one side of the airfoil is air A protection unit for preventing the other side of the foil from penetrating; And a seating part installed at one end of the protection part and seated on the shroud to fix the protection part in the vane cavity.

The protection part may be formed in a blade shape so as to correspond to the shape of the inner wall of the vane cavity, and may include a protective block disposed so that an outer surface thereof contacts the entire surface of the inner wall of the vane cavity.

The vane is accommodated in the vane cavity, connects the inner side of the pressure side of the airfoil and the inner side of the suction side, and the vane cavity leads the leading edge of the airfoil. and a cavity partition wall partitioning into a first vane cavity on an edge side and a second vane cavity on a trailing edge side, wherein the protection part is inserted into the first vane cavity and has an outer surface of the first vane cavity. The first protective block may contact the inner wall of the cavity, and the second protective block may be inserted into the second vane cavity and the outer surface may contact the inner wall of the second vane cavity.

The vane further includes a pair of edgewalls protruding upward and downward from upper and side shrouds and lower and lower shrouds of the airfoil, respectively, and the seating portion is coupled to one end of the protective part, A protective wall disposed inside and seated on the shroud and protruding in the direction in which the edge wall protrudes from the mounting plate to prevent the laser beam irradiated to one side of the edge wall from penetrating to the other side of the edge wall. It may include.

The protective wall may protrude from an edge of the seating plate, and may be disposed such that an outer surface thereof contacts the inner surface of the edge wall.

The protective part and the seating part may be formed of a polytetra fluoroethylene (PTFE) material.

According to another aspect of the present invention, the vane is provided on the vane during laser processing of the vane including an airfoil having a vane cavity formed therein, and a pair of shrouds respectively provided at upper and lower ends of the airfoil. In order to protect, the vane cavity is formed in a shape corresponding to the shape of the inner wall, the outer surface is inserted into the vane cavity in contact with the inner wall of the vane cavity, the laser irradiated to one side of the air foil is the other of the air foil A protection unit that prevents penetrating to the side; And a protecting part installed on the protecting part, the pressing part pressing the protecting part to the inner wall of the vane cavity.

The protection part may be formed in a blade shape so as to correspond to the shape of the inner wall of the vane cavity, and may include a protective block disposed so that an outer surface thereof contacts the entire surface of the inner wall of the vane cavity.

The pressing unit may include a pressing member inserted into an insertion hole formed in the vertical direction of the protective block to press the protective block to the outside.

The pressing member may include a leading pressing member inserted into a leading edge side of the airfoil of the insertion hole and a trailing edge inserted into a trailing edge side of the airfoil of the insertion hole. It may include a ring pressing member, and a center pressing member inserted between the leading pressing member and the trailing pressing member.

The pressing member may be formed in a blade shape so as to correspond to the shape of the air foil, and an outer surface thereof may be inserted to contact the inner wall of the insertion hole.

The vane is accommodated in the vane cavity, connects the inner side of the pressure side of the airfoil and the inner side of the suction side, and the vane cavity leads the leading edge of the airfoil. and a cavity partition wall partitioning into a first vane cavity on an edge side and a second vane cavity on a trailing edge side, wherein the protection part is inserted into the first vane cavity and has an outer surface of the first vane cavity. The first protective block may contact the inner wall of the cavity, and the second protective block may be inserted into the second vane cavity and the outer surface may contact the inner wall of the second vane cavity.

The pressing unit may include a first pressing member inserted into a first insertion hole formed in the first protective block in the vertical direction and pressing the first protective block outward, and a second insertion formed in the second protective block in the vertical direction. It may include a second pressing member is inserted into each hole, for pressing the second protective block to the outside.

The protection unit may be formed longer than the air foil on the basis of the vertical direction of the air foil.

The protective part may be formed of a resin material.

According to the protection device according to the present invention, by providing a protection portion inserted into the vane cavity, it is possible to prevent the laser irradiated to one surface of the airfoil to penetrate the other surface of the airfoil.

In addition, according to the protection device according to the present invention, by having a seating portion coupled to one end of the protection portion, the protection portion can be easily detached from the vane, the laser irradiated to one surface of the edge wall is the other side of the edge wall It can be prevented from penetrating the surface.

In addition, according to the protection device according to the present invention, by having a pressing portion inserted into the protection portion to press the protection portion to the outside, it is possible to more effectively protect the surface of the airfoil by the protection portion.

1 is a cross-sectional view showing a schematic structure of a gas turbine.
2 and 3 are perspective views illustrating the turbine vane in FIG. 1.
4 to 7 are perspective views showing the protection device according to the first to fourth embodiments of the present invention.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible. Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

Referring to FIG. 1, the gas turbine 1 includes a compressor 2, a combustor 3 and a turbine 4. Based on the flow direction of the gas (compressed air or combustion gas), the compressor 2 is disposed upstream of the gas turbine 1 and the turbine 4 is disposed downstream. The combustor 3 is arranged between the compressor 2 and the turbine 4.

The compressor 2 accommodates the compressor vanes and the compressor rotor inside the compressor casing, and the turbine 4 houses the turbine vanes 100 and the turbine rotor inside the turbine casing. The compressor vanes and the compressor rotor are arranged in a multi-stage along the flow direction of the compressed air, and the turbine vanes 100 and the turbine rotor are also arranged in the multistage along the flow direction of the combustion gas. At this time, the compressor 2 reduces the internal space from the front stage to the rear stage so that the sucked air can be compressed. On the contrary, the turbine 4 burns the combustion air supplied from the combustor 3. It is designed as a structure in which the internal space becomes larger from the front end to the rear end so that the gas can expand.

2 and 3, the turbine vane 100 (hereinafter referred to as “vane”) includes an airfoil 110, a pair of shrouds 120, and a pair of edgewalls 130. A vane cavity 111 is formed in the airfoil 110. The vane cavity 111 is a place where the compressed air supplied from the compressor 2 when the gas turbine 1 operates, the compressed air introduced into the vane cavity 111 is the inner wall of the air foil 110. To cool.

The airfoil 110 may be divided into a pressure surface 112, a suction side 113, a suction side 113, a leading edge 114, and a trailing edge 115. have. The leading edge 114 refers to a portion where the flowing combustion gas hits, and the trailing edge 115 refers to a portion where the combustion gas flowing along the outer surface of the air foil 110 leaves. In addition, the pressure surface 112 refers to a surface of which the pressure of the flowing combustion gas is relatively high and is forced by the flowing combustion gas, and the suction surface 113 has a relatively high pressure of the flowing combustion gas. It means the lower part.

The pair of shrouds 120 are coupled to each end of the air foil 110, and are coupled to an outer shroud 121 coupled to an upper end of the air foil 110 and a lower end of the air foil 110. Inner shroud 122 is included. In addition, the pair of edge walls 130, an inner edge wall protruding downward from the edge of the outer edge wall 131 and the inner shroud 122 protruding upward from the edge of the outer shroud 121 132. The outer edge wall 131 and the outer shroud 121 are installed on an inner wall of the turbine casing to fix the vane 100 to the turbine casing, and the inner edge wall 132 and the inner shroud 122 have a turbine. A sealing housing (not shown) is installed to seal between the disk and the turbine disk.

Referring to FIG. 3, the vane 100 may further include a cavity partition wall 140. The cavity partition wall 140 is accommodated in the vane cavity 111, and has an inner surface of the pressure surface 112 of the air foil 110 and an inside of the suction surface 113 of the air foil 110. It is inserted into the vane cavity 111 to connect the side. Accordingly, the cavity partition wall 140 may include the vane cavity 111 with the first vane cavity 116 on the leading edge 114 side of the airfoil 110 and the trailing edge of the airfoil 110. It divides into the 2nd vane cavity 117 of 115 side. Hereinafter, the vanes of FIG. 2 without the cavity partition wall 140 are referred to as first vanes 101, and the vanes of FIG. 3 including the cavity partition wall 140 are referred to as second vanes 102. do.

On the other hand, the air foil 110, a plurality of vanes discharged from the compressed air supplied from the compressor 2 to the surface in order to prevent thermal damage by the high temperature and high pressure combustion gas supplied from the combustor (3) Cooling holes (not shown) are formed. In this case, the vane cooling hole is formed by laser processing, the laser irradiated to one side surface of the air foil 110 to form the vane cooling hole inevitably the vane cavity (inside the air foil 110) It passes through 111 to penetrate to the opposite surface of the airfoil 110. Therefore, in order to prevent this, in the present invention, when the laser processing of the vane 100, it is provided on the vane 100 to provide a protection device for protecting the vane (100).

Hereinafter, a protection device according to a first embodiment of the present invention will be described in detail with reference to FIG. 4.

Referring to FIG. 4, the protection device 1000 according to the first embodiment of the present invention is installed in the first vane 101 and includes a protection unit 1100 and a seating unit 1200. The protection part 1100 is inserted into the vane cavity 111 to prevent the laser beam irradiated to one surface of the air foil 110 from penetrating to the other surface of the air foil 110.

In this case, the protection unit 1100 may include a protection block 1110. The protective block 1110 is formed in a blade shape, that is, a wing shape so as to correspond to the shape of the inner wall of the vane cavity 111. The protective block 1110 is inserted into the vane cavity 111 so that an outer surface thereof is in contact with the entire surface of the inner wall of the vane cavity 111. If a gap exists between the protective block 1110 and the inner wall of the vane cavity 111, the laser penetrates the surface of one side of the air foil 110 and touches the outer surface of the protective block 1110. Reflected by the protective block 1110 may be penetrated to the other surface of the air foil (110). Therefore, in order to prevent this, the protective block 1110 may be said to be inserted so that the outer surface is in contact with the front surface of the inner wall of the vane cavity (111).

The seating part 1200 is installed at one end of the protection part 1100 and is mounted on any one of the pair of shrouds 120 to move the protection part 1100 into the vane cavity 111. Place it in a fixed position. In more detail, the seating part 1200 may include a seating plate 1210 and a protective wall 1220. The seating plate 1210 is coupled to one end of the protective block 1110 and is disposed inside the edge wall 130 on the side where the seating plate 1210 is disposed and seated on the shroud 120. . The protective wall 1220 protrudes from the edge of the seating plate 1210 in the direction in which the edge wall 130 protrudes (upper side in FIG. 4). The protective wall 1220 is disposed such that an outer surface thereof contacts the inner surface of the edge wall 130.

Like the air foil 110, the edge wall 130 may be formed with a cooling hole (not shown). Accordingly, the protective wall 1220 may prevent the laser beam irradiated to one side of the edge wall 130 from penetrating to the other side of the edge wall 130 to form a cooling hole of the edge wall 130. .

The protective part 1100 and the seating part 1200 may be made of polytetra fluoroethylene (PTFE) material. Polytetrafluoroethylene is also called Teflon (Teflon), has excellent chemical resistance, and does not change its properties even at high temperatures, and has the characteristics of non-flammability, non-tackiness and wear resistance. When the protective part 1100 and the seating part 1200 are made of such a polytetrafluoroethylene material, the protective part 1100 and the seating part 1200 may be heated by a laser irradiated to one side to prevent thermal deformation or wear. The laser irradiated to the side may be prevented from going through the other side and penetrating the other side of the first vane 101.

Hereinafter, a protection device according to a second embodiment of the present invention will be described in detail with reference to FIG. 5. At this time, only the parts that are different from the protection device according to the first embodiment of the present invention will be described mainly.

Referring to FIG. 5, the protection device 2000 according to the second embodiment of the present invention is installed in the second vane 102 and includes a protection part 2100 and a seating part 2200. The seating portion 2200 includes a seating plate 2210 and a protective wall 2220.

The protection part 2100 includes a first protection block 2110 and a second protection block 2120 installed on the seating plate 2210. The first protective block 2110 is inserted into the first vane cavity 116 of the second vane 102 and is disposed such that an outer surface thereof is in contact with the entire surface of the inner wall of the first vane cavity 116. . The second protective block 2120 is inserted into the second vane cavity 117 of the second vane 102 and is disposed such that an outer surface thereof contacts the entire surface of the inner wall of the second vane cavity 117. .

As such, the protection device 1000 according to the first embodiment of the present invention and the protection device 2000 according to the second embodiment of the present invention include protection parts 1100 and 2100 having different shapes, respectively. In the case of performing the laser processing on the vanes 100 having different internal structures such as the first vane 101 and the second vane 102, the type of protection device 1000 according to the present invention is changed. 2000) can be easily applied.

Hereinafter, a protection device according to a third embodiment of the present invention will be described in detail with reference to FIG. 6.

Referring to FIG. 6, the protection device 3000 according to the third embodiment of the present invention is installed in the first vane 101, and includes a protection unit 3100 and a pressing unit 3200. The protection part 3100 is inserted into the vane cavity 111 to prevent the laser irradiated to one surface of the air foil 110 from penetrating to the other surface of the air foil 110. In this case, the protection unit 3100 may include a protection block 3110. The protective block 3110 is formed in a blade shape, that is, a wing shape so as to correspond to the shape of the inner wall of the vane cavity 111. The protective block 3110 is inserted into the vane cavity 111 so that an outer surface thereof comes into contact with the entire surface of the inner wall of the vane cavity 111.

If a gap exists between the protective block 3110 and the inner wall of the vane cavity 111, the laser penetrates the surface of one side of the air foil 110 and touches the outer surface of the protective block 3110. Reflected by the protective block 3110 may be penetrated to the other surface of the air foil (110). Therefore, in order to prevent this, the protective block 3110 may be said to be inserted so that the outer surface is in contact with the front surface of the inner wall of the vane cavity (111).

The pressing unit 3200 is installed in the protection unit 3100 to press the protection unit 3100 to the inner wall of the vane cavity 111. In more detail, the protective block 3110 may have an insertion hole 3110a penetrating therein in the vertical direction. The pressing unit 3200 may include a pressing member 3210 inserted into the insertion hole 3110a. The pressing member 3210 is inserted into the insertion hole 3110a to press the protective block 3110 outward, so that the outer surface of the protective block 3110 is in close contact with the inner wall of the vane cavity 111. Be sure to

The pressing member 3210 may include a leading pressing member 3211, a trailing pressing member 3212, and a center pressing member 3213. The leading pressing member 3211 is inserted into the leading edge 114 side of the air foil 110 of the insertion hole (3110a). The trailing pressing member 3212 is inserted into a trailing edge 3212 side of the air foil 110 of the insertion hole 3110a. The center urging member 3213 is inserted between the leading urging member 3211 and the trailing urging member 3212.

In this case, the pressing member 3210, the center pressing member 3213 presses the leading pressing member 3211 and the trailing pressing member 3212 to both sides, respectively, the leading pressing member 3211 and the trail The ring pressing member 3212 is also configured to press the center pressing member 3213 to the center side, so that the leading pressing member 3211, the trailing pressing member 3212 and the center pressing member 3213 are evenly protected. It is possible to press the block 3110 to the outside.

Meanwhile, although not shown in FIG. 6, the pressing member 3210 is not a structure divided into a leading pressing member 3211, a trailing pressing member 3212 and a center pressing member 3213 as described above. As a whole, an outer surface of the outer surface may be a member of a airfoil contacting the inner surface of the insertion hole 3110a. In this case, the pressing member 3210 is evenly applied to the outside of the protective block 3110.

The protection unit 3100 may be formed longer than the air foil 110 based on the up and down direction of the air foil 110. That is, the protection part 3100 may be formed to maintain a state in which at least one of the upper part and the lower part protrudes to the outside of the vane cavity 111 even though the protection part 3100 is inserted to fill all of the inside of the vane cavity 111. have. In this case, when all the laser processing is completed for the vane 100 to separate the protection device 3000 from the vane 100, the protection part protruding to the outside of the vane cavity 111 ( By pushing or pulling one end of the 3100, the protection device 3000 can be easily separated from the vane 100.

In addition, the protective part 3100 may be made of a resin material. Resin is an amorphous solid or semisolid composed of organic compounds and derivatives thereof, and is largely divided into natural resins and synthetic resins. Among them, natural resins are classified into balms which represent liquid phase by a large amount of essential oils, rubber resins with coexisting rubber, and fossil resins that exist in fossil state. After being molded once, it is classified as a thermosetting resin that does not deform even under heat or pressure. The protection part 3100 is pressed by the pressing part 3200 to be pressed to some extent to be in close contact with the inner wall of the vane cavity 111, the processability and elasticity, such as rubber resin, thermosetting resin, etc. It can be made of good resin material.

Hereinafter, a protection device according to a fourth embodiment of the present invention will be described in detail with reference to FIG. 7. At this time, only the parts that are different from the protection device according to the third embodiment of the present invention will be described mainly.

 The protection device 4000 according to the fourth embodiment of the present invention, which is installed on the second vane 102, includes a protection part 4100 and a pressing part 4200. The protection part 4100 is inserted into the vane cavity 111 to prevent the laser irradiated to one surface of the air foil 110 from penetrating to the other side of the air foil 110.

In this case, the protection unit 4100 may include a first protection block 4110 and a second protection block 4120. The first protective block 4110 is inserted into the first vane cavity 116 and is disposed such that an outer surface thereof contacts the inner wall of the first vane cavity 116. The second protective block 4120 is inserted into the second vane cavity 117 and is disposed such that an outer surface thereof is in contact with an inner wall of the second vane cavity 117.

The pressing unit 4200 may include a first pressurizing member 4210 and a second pressurizing member 4220. The first pressing member 4210 is inserted into the first insertion hole 4110a formed in the first protective block 4110 in the vertical direction to press the first protective block 4110 outward. The second pressing member 4220 is inserted into a second insertion hole 4120a formed in the second protective block 4120 in the vertical direction to press the second protective block 4120 outward.

In this case, the first protective block 4210 and the second pressing member 4220 respectively provided in the first protective block 4110 and the second protective block 4120 are each independently the first protective block. By pressing the 4110 and the second protective block 4120, the first protective block 4110 and the second protective block 4120 to press the protective part 4100 more uniformly and efficiently to the The protection unit 4100 may be in close contact with the inside of the air foil 110.

In addition, as described above, the protection device 3000 according to the third embodiment of the present invention and the protection device 4000 according to the fourth embodiment of the present invention respectively have different protection shapes 3100 and 4100 and a pressing unit ( By including 3200, 4200, even when the laser processing is performed on the vanes having a different internal structure, such as the first vane 101 and the second vane 102, the type is changed to the present invention According to the protection device (3000,4000) can be easily applied.

1000,2000,3000,4000: Protective device 1100,2100,3100,4100: Protective part
1200,2200: Mounting part 3200,4200: Pressing part

Claims (15)

In the protection of the vane to protect the vane during the laser processing of the vane including an airfoil having a vane cavity formed therein and a pair of shrouds respectively provided at the upper end and the lower end of the airfoil,
Is formed in a shape corresponding to the shape of the inner wall of the vane cavity, the outer surface is inserted into the vane cavity to contact the inner wall of the vane cavity, the laser irradiated to one side of the airfoil penetrates to the other side of the airfoil Protection to prevent; And
A protection unit installed at one end of the protection unit, the mounting unit being fixed to the shroud to fix the protection unit inside the vane cavity. The method according to claim 1,
The protection unit,
The vane cavity is formed in a blade shape so as to correspond to the shape of the inner wall, the protective device including a protective block disposed so that the outer surface is in contact with the entire surface of the inner wall of the vane cavity. The method according to claim 1,
The vane is,
The vane cavity is accommodated in the vane cavity, and connects the inner side of the pressure side of the airfoil and the inner side of the suction side, and the vane cavity is connected to the leading edge side of the airfoil. And a cavity partition wall partitioning into a first vane cavity and a second vane cavity on a trailing edge side.
The protection unit,
A first protective block inserted into the first vane cavity and having an outer surface in contact with the inner wall of the first vane cavity, and a second protective block inserted into the second vane cavity and having an outer surface in contact with the inner wall of the second vane cavity. Protection. The method according to claim 1,
The vane is,
The air foil further comprises a pair of edge walls protruding upward and downward from the upper and lower side shrouds, respectively,
The seating portion,
A laser beam coupled to one end of the protective part and disposed inside the edge wall and seated on the shroud, and protruding in a direction in which the edge wall protrudes from the seating plate and irradiated to one side of the edge wall. And a protective wall preventing the penetrating the other side of the edge wall. The method according to claim 4,
The protective wall,
A protective device protruding from the edge of the seating plate, the outer surface is in contact with the inner surface of the edge wall. The method according to any one of claims 1 to 5,
The protective part and the seating part,
Protective device formed of polytetra fluoroethylene (PTFE) material. In the protection of the vane to protect the vane during the laser processing of the vane including an airfoil having a vane cavity formed therein and a pair of shrouds respectively provided at the upper end and the lower end of the airfoil,
Is formed in a shape corresponding to the shape of the inner wall of the vane cavity, the outer surface is inserted into the vane cavity to contact the inner wall of the vane cavity, the laser irradiated to one side of the airfoil penetrates to the other side of the airfoil Protection to prevent; And
A protection unit installed in the protection unit and configured to press the protection unit to the inner wall of the vane cavity. The method according to claim 7,
The protection unit,
The vane cavity is formed in a blade shape so as to correspond to the shape of the inner wall, the protective device including a protective block disposed so that the outer surface is in contact with the entire surface of the inner wall of the vane cavity. The method according to claim 8,
The pressing unit,
And a pressing member inserted into an insertion hole formed in the vertical direction of the protective block to press the protective block to the outside. The method according to claim 9,
The pressing member,
A leading pressing member inserted into a leading edge side of the insertion hole of the insertion hole, and a trailing pressing member inserted into a trailing edge side of the air foil among the insertion holes; And a center pressing member inserted between the leading pressing member and the trailing pressing member. The method according to claim 9,
The pressing member,
A protective device is formed in the airfoil so as to correspond to the shape of the air foil, the outer surface is inserted so as to contact the inner wall of the insertion hole. The method according to claim 7,
The vane is,
The vane cavity is accommodated in the vane cavity, and connects the inner side of the pressure side of the airfoil and the inner side of the suction side, and the vane cavity is connected to the leading edge side of the airfoil. And a cavity partition wall partitioning into a first vane cavity and a second vane cavity on a trailing edge side.
The protection unit,
A first protective block inserted into the first vane cavity and having an outer surface in contact with the inner wall of the first vane cavity, and a second protective block inserted into the second vane cavity and having an outer surface in contact with the inner wall of the second vane cavity. Protection. The method according to claim 12,
The pressing unit,
A first pressing member inserted into a first insertion hole vertically formed in the first protective block to press the first protective block outward, and a second insertion hole formed vertically in the second protective block; And a second pressing member pressurizing the second protective block to the outside. The method according to any one of claims 7 to 13,
The protection unit,
Protective device formed longer than the air foil on the basis of the vertical direction of the air foil. The method according to any one of claims 7 to 13,
The protection unit,
Protective device made of resin.

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