KR101276760B1 - The Shape of the film cooling hole for cooling gas turbine blades - Google Patents

Abstract

The present invention relates to the shape structure of the membrane cooling hole for cooling the gas turbine blade, and more particularly, to specify the shape of the membrane cooling hole used for the cooling of the gas turbine blade so that the cooling fluid is wider and more effective on the cooling surface. The present invention relates to a shape structure of a membrane cooling hole for cooling of a gas turbine blade, which enables to distribute the gas turbine blade, thereby achieving a significantly improved cooling efficiency compared to the structure of a conventional hole.
According to the present invention, in the shape structure of the film cooling hole for cooling the gas turbine blade, a cylindrical portion having a constant cross-sectional area, and an extension portion connected to an upper end of the cylindrical portion and a central portion of the hole outlet, the cross-sectional area of which is gradually widened, flow direction. And a protrusion formed to protrude from the bottom surface of the expansion pipe.

Description

Shape structure of the film cooling hole for cooling gas turbine blades

The present invention relates to the shape structure of the membrane cooling hole for cooling the gas turbine blade, and more particularly, to specify the shape of the membrane cooling hole used for the cooling of the gas turbine blade so that the cooling fluid is wider and more effective on the cooling surface. The present invention relates to a shape structure of a membrane cooling hole for cooling of a gas turbine blade, which enables to distribute the gas turbine blade, thereby achieving a significantly improved cooling efficiency compared to the structure of a conventional hole.

In general, in order to increase the efficiency and performance of gas turbine engines, gas turbine engines are designed to operate at 1,500 ~ 1700 ^ㅇ C, and the trend is to increase the turbine inlet temperature by 20 ^◦ C annually to increase the thermal efficiency. to be.

Therefore, various cooling techniques have been researched and developed to protect turbine blades from high inlet temperatures. Among them, the film-cooling method sprays the cooling fluid through holes formed at an angle with the blade surface. By forming a film on the blade surface to protect the surface from the hot main flow gas, this method is most commonly used because of the very effective cooling performance.

Since the high-pressure cooling air extracted from the compressor is used for the film cooling, the use of an excessive amount of compressed air reduces the efficiency of the gas turbine, so the necessity of an effective cooling method has emerged. In order to increase the film cooling efficiency, various hole shapes are being developed.

Among them, U.S. Patent Application Publication No. 2008/0031738 discloses a configuration of a bell-shaped film cooling hole. The main technical configuration is an airfoil (22) in fluid communication with a turbine blade cooling circuit, as shown in FIG. A plurality of cooling holes 50 formed on the outer surface of the), the cooling hole 50 includes a metering portion 58 and the diffusion portion 51 opening to the outer surface of the air foil 22 as a whole bell It is characterized by being configured to have a shape to have a high cooling efficiency.

In addition, the shape of the conventional fan-shaped cooling hole 70 shown in FIG. 2 is also characterized in that the cooling hole includes a diffusion portion so that the cooling fluid passing through the cooling hole 70 can be diffused.

However, the shape of the conventional cooling hole 50 shown in FIG. 1 can be expected to some extent the diffusion effect in the longitudinal direction, but the diffusion effect in the width direction is inadequate and the overall diffusion effect of the cooling fluid is reduced, Figure 2 The conventional fan-shaped cooling hole 70-shaped structure shown in Fig. 2 also has a poor diffusion effect in the width direction and the longitudinal direction, resulting in poor cooling performance, and a large number of cooling holes 70 are required as a whole. There was a problem that was much needed.

The present invention has been made to solve the above problems, the object of the present invention is to obtain a significantly improved cooling efficiency compared to the structure of the existing hole by specifying the shape of the film cooling hole used for the cooling of the gas turbine blades. The present invention provides a structure of a film cooling hole for cooling a gas turbine blade.

In addition, the present invention can extend the life of the gas turbine blades due to the improved cooling performance, the use of less cooling fluid and reducing the number of holes can increase the efficiency of the engine blade cooling of the gas turbine blades Another object is to provide a shape structure.

The present invention for achieving the above objects,

In the shape structure of the membrane cooling hole for cooling the gas turbine blade, the cylindrical portion having a constant cross-sectional area, the expansion portion connected to the upper end of the cylindrical portion and the central portion of the hole outlet which is gradually widened so as to protrude in the flow direction And at the same time characterized in that it comprises a protrusion formed to project from the bottom of the expansion pipe.

At this time, the film cooling hole is formed to have a slope of 30 ° in the gas turbine blade, when the diameter of the cylindrical portion, D, the length of the cylindrical portion and the expansion portion is characterized in that each of the 3D.

In addition, the expansion portion is characterized in that the tube is expanded so as to have an inclination of 25 ° in both side directions relative to the cylinder.

The protrusion may protrude in a direction in which the bottom portion is extended by 2.5 ° in the hole exit direction based on the cylindrical portion.

According to the present invention, the expansion portion and the protrusions protruding from the expansion portion have an excellent effect of obtaining the cooling efficiency of the gas turbine blades significantly improved compared to the structure of the existing hole.

In addition, according to the present invention, the improved cooling performance can extend the life of the gas turbine blades, increase the efficiency of the engine by using less cooling fluid and reduce the number of holes, as well as the structural stability of the overall gas turbine. It further has an effect to improve.

1 and 2 is a view showing the shape of a conventional film cooling hole.
Figure 3 is a perspective view showing a film cooling hole for cooling the gas turbine blade according to the present invention.
4 is a plan view and a side cross-sectional view of a membrane cooling hole for cooling the gas turbine blade according to the present invention.
5 is a graph showing the film cooling efficiency averaged in the lateral direction on the cooling surface of the conventional fan-shaped hole shown in Figure 2 and the hole shape of the present invention.
6 is a graph showing the film cooling efficiency averaged at the cooling surface of the conventional fan-shaped hole shown in FIG. 2 and the hole shape of the present invention.
7 (a) and 7 (b) show the film cooling efficiency distribution on the cooling surface of the conventional fan-shaped hole shown in FIG. 2 and the hole shape of the present invention.
8 (a) and 8 (b) are diagrams showing a conventional fan-shaped hole shown in FIG. 2 and a velocity vector at the hole-shaped outlet of the present invention;
9 (a) and 9 (b) show a streamline distribution of the conventional fan-shaped hole shown in FIG. 2 and a cooling fluid passing through the hole of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the shape structure of the film cooling hole for cooling the gas turbine blade according to the present invention.

3 is a perspective view showing a membrane cooling hole for cooling the gas turbine blade according to the present invention, Figure 4 is a plan view and a side cross-sectional view of the membrane cooling hole for cooling the gas turbine blade according to the present invention, Figure 5 Fig. 6 is a graph showing the film cooling efficiency averaged laterally from the cooling surface of the conventional fan-shaped hole and the hole shape of the present invention shown in Fig. 6 is shown in the conventional fan-shaped hole shown in Fig. 2 and the hole shape of the present invention. 7 is a graph showing the film cooling efficiency averaged at the cooling surface, and FIGS. 7A and 7B show the distribution of film cooling efficiency at the cooling surface of the conventional fan-shaped hole shown in FIG. 2 and the hole shape of the present invention. 8 (a) and 8 (b) show the conventional fan-shaped hole shown in FIG. 2 and the velocity vector at the hole-shaped outlet of the present invention, and FIGS. ) Is a conventional fan-shaped hole shown in Figure 2 and the present invention A diagram showing a streamline distribution of a cooling fluid passing through a hole.

The present invention is to specify the shape of the membrane cooling holes used for the cooling of the gas turbine blades so that the cooling fluid can be distributed more widely and effectively on the cooling surface to obtain a significantly improved cooling efficiency compared to the structure of the existing holes It relates to the shape structure of the film cooling hole 100 for cooling the gas turbine blade, the configuration is composed of a cylindrical portion 110, expansion tube 120 and the protrusion 130 as shown in FIG.

In more detail, the cylindrical portion 110 serves as an inlet portion in which the cooling fluid flows, and as shown in FIG. 4, when the width of the gas turbine blade 80 is 3D, the diameter is cylindrical. It is made of a phase, and is formed to have a length of 3D to have a slope of 30 ° in the direction of travel of the cooling fluid.

Therefore, the cooling fluid supplied from the lower portion of the blade 80 is introduced into the cylindrical portion 110 with a narrow diameter and the flow velocity thereof is increased.

Next, the expansion part 120 is connected to the upper portion of the cylindrical portion 110 so that its cross-sectional area is gradually widened so that the cooling fluid flowing from the cylindrical portion 110 can be spread widely when discharged through the outlet portion of the range of cooling It is to serve to expand the, it is expanded to have an inclination of 25 ° in both lateral directions when the cylindrical portion 110 relative to the base, the overall length is configured to be 3D.

Next, the protrusion 130 is formed on the bottom surface of the expansion pipe 120 to protrude in the advancing direction of the cooling fluid, and serves to distribute the cooling fluid evenly on the surface of the blade 80.

That is, as shown in FIG. 4, the protrusion 130 is formed to protrude in the direction in which the bottom portion is extended by 2.5 ° in the exit direction of the hole 100 with respect to the cylindrical part 110, and thus the expansion part 120 is formed. By allowing the cooling fluid to pass through a wide distribution in the longitudinal direction it is possible to achieve a more efficient cooling of the blade (80).

In order to evaluate the cooling performance of the film cooling hole 100 having the above-described features, numerical analysis of the flow field and the film cooling was performed.

To solve the three-dimensional Reynolds-averaged Navier-Stokes equation, ANSYS CFX-11.0, a commercial computational fluid dynamics code, was used, and a hexahedral lattice and shear stress transport turbulence model was used.

The working fluid is air (ideal gas, air). As boundary conditions, heat insulation and adhesion conditions are applied to the walls, and flow conditions are applied to the inlet of the cooling fluid supply passage. A high pressure condition (100,400 Pa) was applied to the inlet of the main passage and a static pressure condition (93,500 Pa) to the outlet. The Mach number of the hot gas was 0.3, and the temperature of the hot gas and the cooling fluid was 540K and 310K, respectively.

) 및 분사율(M)은 각각 다음과 같이 정의된다.The cooling performance on the film cooling surface was evaluated by calculating the film cooling efficiency averaged in the lateral direction and the area according to the change of the injection rate (M).

) And injection rate M are respectively defined as follows.

(1)

(One)

(2)

(2)

는 단열벽면온도를 의미하며,

와

는 각각 주유동과 냉각유체의 분사온도를 나타낸다. 또한

와

는 각각 냉각 유체가 분사되는 지점에서 측정한 냉각유체의 밀도와 속도를 나타내며,

와

는 고온가스의 입구부근에서 측정한 밀도와 속도를 의미한다. 그리고, D는 본 발명에 따른 막냉각 홀(100)의 원통부(100) 직경이고,

와

는 각각 냉각 유체가 분사되는 지점으로부터의

방향, 즉 분사방향 및

방향, 즉 측면방향으로부터의 거리를 나타낸다.here

Means the insulation wall temperature,

Wow

Are the injection temperatures of the main and cooling fluids, respectively. Also

Wow

Represents the density and velocity of the cooling fluid, respectively, measured at the point where the cooling fluid is injected,

Wow

Is the density and velocity measured near the inlet of hot gas. And, D is the diameter of the cylindrical portion 100 of the film cooling hole 100 according to the present invention,

Wow

From the point where the cooling fluid is injected

Direction, that is, injection direction and

Direction, that is, distance from the lateral direction.

)을 나타낸 것으로, 팬 형상 홀(70)의 수치해석결과는 실험결과와 좋은 일치성을 보여주며, 본 발명에 따른 막냉각 홀(100)은 팬 형상 홀(70)과 비교하여 분사율이 0.5일 때는 막냉각 효율(

)이 미세하게 증가하였으나 분사율이 2.5일 때는 월등하게 높은 막냉각 효율(

)을 보임을 확인할 수 있다.5 is a film cooling efficiency averaged in the lateral direction on the cooling surface of the conventional fan-shaped hole 70 and the film cooling hole 100 of the present invention shown in FIG.

The numerical analysis results of the fan-shaped hole 70 shows good agreement with the experimental results, and the film cooling hole 100 according to the present invention has a spray rate of 0.5 compared with the fan-shaped hole 70. Film cooling efficiency

) Increased slightly but the injection rate was 2.5

Can be seen.

)을 나타낸 것으로, 본 발명에 따른 막냉각 홀(100)은 팬 형상 홀(70)과 비교하였을 때 높은 막냉각 효율(

)을 보이는 것을 확인할 수 있고, 특히 분사율이 증가함에 따라 기존에 사용되어지는 팬 형상 홀(70)과 비교하여 월등히 높은 막냉각 효율(

)을 보임을 알 수 있다.FIG. 6 shows the film cooling efficiency averaged at the cooling surface of the conventional fan-shaped hole 70 shown in FIG. 2 and the shape of the film cooling hole 100 of the present invention.

), The film cooling hole 100 according to the present invention has a high film cooling efficiency (compared with the fan-shaped hole 70).

), Especially as the injection rate increases, the film cooling efficiency (higher than the conventional fan-shaped hole 70) is significantly higher (

Can be seen.

7 (a) and 7 (b) show the film cooling efficiency at the cooling surface of the conventional fan-shaped hole 70 shown in FIG. 2 and the shape of the hole 100 of the present invention when the injection rates are 1.5 and 2.5. Compared with the conventional fan-shaped hole 70, the film cooling hole 100 according to the present invention shows the distribution of cooling fluid evenly and widely on the surface, and shows an extremely effective cooling efficiency. It can be seen that as the injection rate increases.

8 (a) and 8 (b) and 9 (a) and 9 (b) are velocity vectors at the exit shape of the conventional fan shape hole 70 shown in FIG. 2 and the hole 100 of the present invention, and It shows a streamline distribution of the cooling fluid, the conventional fan-shaped hole 70 shows a low film cooling efficiency in the central portion of the cooling surface, the cooling fluid is distributed in a narrow region, the film cooling hole 100 according to the present invention In the case of not only shows high cooling efficiency in the central part, but also shows that the cooling fluid is evenly distributed over the entire surface.

Therefore, according to the shape structure of the film cooling hole 100 for cooling the gas turbine blade according to the present invention, the structure of the existing hole by the expansion portion 120 and the protrusions 130 protruding from the expansion portion 120 Not only can the cooling efficiency of the gas turbine blade 80 be significantly improved compared to that of the gas turbine blade 80, and thus, the cooling performance of the gas turbine blade can be extended due to the improved cooling performance. By reducing the number of installation) can increase the efficiency of the engine and at the same time have various advantages, such as to improve the structural stability of the overall gas turbine.

Although the above embodiments have been described with respect to the most preferred examples of the present invention, it is not limited to the above embodiments, and it will be apparent to those skilled in the art that various modifications are possible without departing from the technical spirit of the present invention.

The present invention relates to the shape structure of the membrane cooling hole for cooling the gas turbine blade, and more particularly, to specify the shape of the membrane cooling hole used for the cooling of the gas turbine blade so that the cooling fluid is wider and more effective on the cooling surface. The present invention relates to a shape structure of a membrane cooling hole for cooling of a gas turbine blade, which enables to distribute the gas turbine blade, thereby achieving a significantly improved cooling efficiency compared to the structure of a conventional hole.

100: film cooling hole 110: cylindrical portion
120: expansion pipe 130: protrusion

Claims (4)

In the shape structure of the film cooling hole for cooling the gas turbine blade,
A cylindrical section having a constant cross-sectional area,
An expansion part connected to the upper end of the cylindrical part, the cross section being gradually wider;
The central portion of the hole exit is configured to include a protrusion formed to protrude from the bottom of the expansion pipe while at the same time protruding in the flow direction,
The film cooling hole is formed to have a slope of 30 ° to the gas turbine blade, when the diameter of the cylindrical portion is D, the length of the cylindrical portion and the expansion portion is 3D, respectively,
The expansion pipe is expanded so as to have an inclination of 25 ° in both lateral directions with respect to the cylindrical portion,
The protrusion is formed in the shape of the film cooling hole for cooling the gas turbine blades, characterized in that the bottom portion protrudes in a direction extending by 2.5 ° in the hole exit direction based on the cylindrical portion.
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