RU53724U1 - COOLED GAS TURBINE SHOULDER BLADE - Google Patents

Abstract

The proposed utility model relates to the field of power engineering, namely turbine engineering, specifically, to the device of cooled nozzle guide vanes of gas turbines for powerful power plants. The task to which the proposed utility model is directed is to reduce the complexity of manufacturing and assembling the device of the cooling blade, increase the efficiency of heat removal, as well as the reliability of the cooled nozzle blade as a whole. To achieve the desired technical result, the thrust elements of the pin located inside the deflector space are made integral with its body in the form of horizontal ribs concentrically arranged along the height of the pin and at equal distance from each other, and the pin is mounted on two floating supports made in the blade body of the blade of which represents the cylindrical end of the pin mounted in a socket on the blade body with a gap, and the upper part of the pin is provided with an opening through which the locking pallet passes EC installed in the eyes and secured with a cotter pin. The proposed device of a cooled nozzle blade allows for a constant-tight fit of the deflector to the stop elements on the inner surface of the blade from the back and trough side, regardless of the angle of rotation of the pin, which makes it possible to obtain a given passage area for cooling air with great accuracy, thereby increasing the heat removal efficiency from the surface of the blade and the reliability of the blade as a whole.

Description

The proposed utility model relates to the field of power engineering, namely turbine engineering, specifically, to the device of cooled nozzle, guide vanes of gas turbines for powerful power plants.

In gas turbines operating at high inlet gas temperatures (1100 ° C and above), various designs of cooled blades are widely used. One of the design options for the blades is the use of hollow blades with thin-walled deflectors installed inside. The cooling of the blade occurs due to the air supplied to the space between the walls of the blade and the deflector. At the same time, the most serious problem that arises when developing a device for cooled gas turbine blades is ensuring reliable heat removal, as well as increasing the maintainability of the structure.

A device for a cooled nozzle blade is known, containing two cavities in each of which a deflector is installed closed along the contour with holes for cooling air to pass through it. During assembly, this deflector is compressed due to the elastic front wall, and in the operating mode it is pressed against the inner surface of the blade body by means of supporting elements made in the form of protrusions on the surface of the deflector from the side of the trough and back and forming channels for the passage of cooling air. (US Patent No. 3806275, 1972).

A disadvantage of the known device is that due to the technological features of the manufacture of the deflector and casting of the blade (the need for significant tolerances on the dimensions of the workpieces), as well as the process of warping the deflector under high temperatures in the operating mode, there is a loose fit of the protrusions on the surface of the deflector to the inner surface of the trough body shoulder blades. As a result, the height of the cooling air inlet channel in the cross section of the blade increases, which leads to an increase in the cross-sectional area of the channel and, accordingly, a decrease in the flow rate of cooling air in the channel and the amount of heat removal, which is the main prerequisite for the subsequent failure of the blade. In addition, a deflector of this design is difficult to assemble and disassemble. The noted circumstances are typical for the design of nozzle blades of large power plants

with a capacity of 60 MW or more, in which the wall thickness of the deflector is 1 mm or more, which necessitates the use of complex equipment and significant difficulties in its installation and dismantling.

The closest device to the proposed one on the basis of essential features and selected as a prototype is a device for a cooled nozzle blade of a gas turbine containing the first and second cavities separated by a transverse partition, a perforated deflector that is placed in the second cavity and made in the profile as open in the front parts of the bracket, with the curvature of the surfaces - from the back of the scapula of less curvature of the back of the scapula, and from the side of the trough - more curvature of the trough of the scapula, a pin equipped thrust elements made in the form of cams for abutment to the deflector, which is located inside the deflector in its middle part, thrust elements for the deflector made on the inner surface of the second cavity of the blade from the side of the trough and back in the form of horizontal ribs so that the cams of the pin abut against a deflector in areas located between the stop elements of the inner surface of the scapula. (RF patent No. 2237811, published in Bull. IZ and PM No. 28-2004).

The invention is the prototype, due to the different curvature of the surfaces of the deflector - from the back of the scapula of less curvature of the back of the scapula, and from the side of the trough - more curvature of the trough of the scapula provides a more snug fit of the stop elements made on the surface of the deflector by means of pin cams, thereby in the cross section of the scapula more precisely, a predetermined area for the passage of cooling air is provided, which increases the cooling efficiency of the nozzle blade. In this case, the assembly and disassembly of the blades with a deflector does not require complex equipment.

However, the reasons that impede the achievement of the desired technical result when using the known device adopted for the prototype include the fact that, in the case of technological violations, the manufacturing accuracy of the mounting seats for the pin relative to the inner walls (supporting elements) of the blade of the pin of the pin does not abut against the deflector when it is turned all at the same time. Therefore, on one side of the inner surface of the blade, the deflector may not be pressed, which in practice leads to a change in the cross-sectional area of the channels and the efficiency of heat removal. Moreover, the non-pressed wall of the deflector will be an additional source of unwanted vibrations, and in case of a breakdown of the pin fixing the pin from turning, the latter can turn around, the deflector will not be pressed,

the performance of the scapula will be impaired.

The task to which the proposed technical solution is directed is to reduce the complexity of manufacturing and assembling a device for a cooled nozzle blade, increase the efficiency of heat removal, maintainability, reliability of a cooled nozzle blade and increase the overhaul life cycle of a nozzle blade as a whole.

To achieve the desired technical result, a device for a cooled nozzle blade of a gas turbine, containing the first and second cavities in the flow direction, separated by a transverse baffle, a perforated deflector placed in the second upstream flow path of the blade cavity and made in the profile in the form of an open bracket in its front part, having a different curvature of the surface from the back and trough of the scapula, a pin located inside the deflector, equipped with thrust elements made integrally with its body and abutting against about the inner surface of the deflector, thrust elements located on the inner surface of the second cavity along the flow of the cavity from the side of the trough and back, made in the form of ribs horizontally located along the cavity and along its profile, so that the thrust elements of the pin abut against the surface of the deflector in areas located between the thrust elements made on the inner surface of the second cavity of the blade, forming channels for the passage of cooling air. In this case, the thrust elements of the pin are made in the form of horizontal ribs concentrically arranged along the height of the pin and at equal distance from each other, while the pin is installed in two supports made in the blade body with the possibility of moving the pin, the lower of which is a socket in the blade body, where the cylindrical end of the pin is inserted with a gap, and the upper part of the pin is provided with an opening through which a finger is installed, installed in the eyes and fixed with a pin against falling out, with the possibility of displacement along the top of the pin finger.

The proposed device is a cooled nozzle blades of a gas turbine, can provide the desired technical result. Thus, the implementation of the thrust elements of the pin at the same time with its body in the form of horizontal ribs concentrically located at equal distance from each other along the height of the pin of the pin provides reliable clamping of the outer surface of the deflector to the thrust elements located on the inner surface of the second cavity of the blade from the side of the trough and back, regardless of the angle of rotation of the pin thus eliminating the possibility of changing the estimated cross-sectional area of the channels for

passage of cooling air during operation. The installation of the pin in the supports made in the body of the blade’s pen with the possibility of its movement enables the pin to self-install inside the deflector during assembly and repair of the blade due to the gap in the lower support, as well as the possibility of shifting the upper part of the pin along the finger that is installed in the eyes and passes through the hole, made in the upper end of the pin, and is fixed with a pin that secures the finger from possible loss. Thus, the proposed device significantly reduces labor costs and increases the convenience of assembly and repair of the blades, and also provides cooling efficiency, reliable operation of the blades and an increase in the overhaul life cycle of the nozzle blade as a whole.

In the study of the above distinguishing features of the proposed device, the applicant has not identified technical solutions to solve the technical problem. The analysis of the prior art, including a search by patent and scientific and technical sources of information, did not reveal technical solutions characterized by features identical or equivalent to the features of the claimed utility model. This made it possible to identify a set of salient features that are significant in relation to the technical result perceived by the applicant and formulated in the utility model patent formula presented below.

Therefore, the claimed technical solution meets the patentability criterion of "novelty" of a utility model.

The proposed device is a cooled nozzle blades of a gas turbine is illustrated in the following figures 1-3. In particular, figure 1 shows a longitudinal section of the nozzle blade, figure 2 is a section in the plane AA of the nozzle blade shown in figure 1, figure 3 is a sectional view in the plane BB of the nozzle blade shown in figure 1 , as well as view B.

The device of the cooled nozzle vane 1 contains two cavities separated by a transverse partition 2, the first cavity 3 in the upstream direction from the input edge 4 of the blade 1 and the second cavity 5 from the output edge 6 of the blade. In the second cavity 5, a perforated deflector 7 is installed, with rows of holes 17, made in the profile in the form of an open in the front (wide) part of the bracket. Thrust elements located on the inner surface of the scapula from the side of the trough 9 and backs 10 of the scapula in the cavity 5 are made in the form of horizontal ribs 8. The space between the ribs 8 located on the inner surface of the scapula from the side of the trough 9

and the backs 10 of the blade in the cavity 5 and the outer surfaces of the deflector 7, form channels 11 for the passage of cooling air. The curvature of the surface of the deflector 7 from the side of the trough of the scapula 9 is greater than the curvature of the surface of the trough 9. The curvature of the surface of the deflector 7 from the side of the back 10 of the scapula is less than the curvature of the back of 10 of the scapula. In the second cavity 5, inside the deflector 7, a pin 14 is installed approximately in its middle part (FIG. 2). On the pin 14 there are thrust elements, which are made integral with his body, in the form of horizontal ribs 15 concentrically arranged along the height of the pin 14 and at an equal distance from each other. The thrust elements 15 of the pin 14 abut against the inner surface of the deflector 7 in the area located between the ribs 8 of the inner surface of the scapula. The pin 14 is mounted in the blade 1 in two supports with the possibility of displacement. At the same time, the lower support of the pin 14 is located in the body of the blade 1 is a socket 13, where the cylindrical end 12 of the pin 14 is inserted with a gap. In the upper part 19, the pin 14 is provided with an opening 18 through which a pin 20 is installed, installed in the eyes 21 and fixed by a pin S -shaped 16 through a hole in the finger, parallel to the shelf of the scapula.

The proposed device is a cooled nozzle blades of a gas turbine operates as follows:

Cooling air is supplied into the second cavity 5 of the blade 1 through the upper part of the blade body 1. From the rear of the deflector 7, air between the stop elements 15 enters the front of the deflector 7 and then through two rows of holes 17 enters the horizontal channels 11 running along the inner surface of the trough 9 and the back 10 of the scapula and which are formed between the thrust elements located on the inner surface of the trough 9 and the back 10 of the scapula in the form of horizontal ribs 8. Passing through the channels 11, the air cools the trough 9 and the backrest 10 and thereafter is discharged into a slot 22 located in the outlet edge 6 of the blade 1. The surface of the deflector 7 is provided by a pin 14 provided with thrust elements 15 made integral with its body in the form of a pin concentrically located at equal distance from each other along the height of the pin horizontal ribs 15, tightly pressed against the thrust elements 8 located on the inner surface of the cavity 5 of the blade 1, regardless of the angle of rotation of the pin 14 during Assembly of the blade 1, thereby providing a predetermined cross-sectional area of the channels 11 for passage of cooling air. A tight fit of the deflector is ensured, in addition, by performing different curvatures of the surface of the deflector 7 and the inner surface of the trough 9 and the back 10 of the blade 1. In this case, the pin 14 is self-mounted inside the deflector 7 when it is assembled in the optimal position due to

the existing gap in the lower support and the possibility of displacement along the finger 20 located in the upper part 19 of the pin 14 and installed in the eyes 21.

In the first in the direction of flow of the cavity 3 of the blade 1, different cooling schemes can be used. In the above example, a device for a cooled nozzle blade air is supplied to the cavity 3 from the bottom. In the input edge 4 of the blade 1 holes are made for the release of cooling air to the outer surface of the blade.

The proposed design of the blade ensures during operation of the gas turbine a constant tight fit of the deflector surface to the stop elements located on the inner surface of the cavity 5 of the blade 1 from the side of its trough 9 and back 10. This allows for a high accuracy of the specified cross-sectional area of the channels for the passage of cooling air , thereby increasing the efficiency of heat removal from the surface of the scapula. In addition, the proposed design significantly reduces labor costs during assembly and repair of the nozzle blade, and also reduces the cost of manufacturing the blade due to the possibility of expanding the tolerances of the workpiece, which generally increases maintainability, reliability, and the overhaul life cycle of the nozzle blade.

The above information upon the implementation of the proposed device, indicate the following conditions:

- the proposed device in its implementation, is intended for use in turbine construction;

- for the claimed device in the form as described in the independent claim of the utility model formula, the possibility of its implementation using the means and methods described in the application description is confirmed;

- the device, according to the description of the proposed utility model in its implementation, is able to achieve the desired technical result by the applicant, namely, it reduces the complexity of manufacturing and assembling the device of the cooling blade, to increase the efficiency of heat removal, as well as the reliability of the cooled nozzle blade as a whole.

Therefore, the proposed solution meets the patentability criterion of the utility model "industrial applicability".

Claims (1)

Cooled nozzle blade of a gas turbine, containing first and second cavities in the course of flow, separated by a transverse partition, a perforated deflector placed in the second in the course of flow of the cavity of the scapula and made in the form of an open bracket, in its front part having different surface curvature from the back side and troughs of the blade, a pin located inside the deflector, equipped with thrust elements made integral with its body and abutting against the inner surface of the deflector, thrust elements located worn on the inner surface of the second cavity along the flow path from the side of the trough and the back, made in the form of ribs horizontally located along the cavity and along its profile so that the thrust elements of the pin abut against the surface of the deflector in areas located between the thrust elements made on the inner the surface of the second cavity of the scapula, forming channels for the passage of cooling air, characterized in that the thrust elements of the pin are made in the form of concentrically arranged along its height and at equal the distance of the horizontal ribs from each other, while the pin is installed in two supports made in the blade body with the possibility of moving the pin, the lower of which is a socket in the blade body, where the cylindrical end of the pin is inserted with a gap, and the upper part of the pin is provided with an opening, through which passes the finger installed in the eyes and fixed by a pin against falling out, with the possibility of displacement of the upper part of the pin along the finger.