RU195437U1 - TURBINE WORKING SHOVEL WITH ASYMMETRIC INTERNAL AND EXTERNAL SURFACES OF BANDAGE SHELF - Google Patents

Abstract

The utility model relates to the field of turbine construction, in particular, to the construction of a high-pressure turbine of a gas turbine engine, which provides cooling of certain parts of its nozzle blades, and can be used in transport and power engineering. turbines. The technical result is achieved by the fact that in a turbine rotor blade with asymmetric inner and outer surfaces of the retaining shelf, the nib, the locking part and the retaining shelf, on the external, in relation to the path gas flow zone, the surfaces of which are inclined scallops to reduce overflow through the radial clearance between the blade and the stator elements, and the surface between the scallops is asymmetrical, i.e. containing a bulge and a cavity , as well as the inner surface of the retaining shelf.

Description

The utility model relates to the field of turbine construction, in particular to the device of a high pressure turbine of a gas turbine engine, which provides cooling of certain parts of its nozzle blades, and can be used in transport and power engineering.

Known turbine blade, described in the work "The influence of the mounting interference on the stress state of the working blades of the turbines of modern aircraft engines" / B.E. Vasiliev, L.A. Maharramova. Engine. 2010, No 4 (10), p. 32-33. This blade is characteristic of modern aircraft engine manufacturing and includes a feather, a lock part and a retaining shelf, on the external (with respect to the path gas flow zone) surface of which there are straight combs to reduce overflow through the radial clearance between the blade and the stator elements forming the flow part.

The described blade has a disadvantage, expressed in the absence of additional measures to reduce aerodynamic losses in the peripheral region of the flow part.

The prototype of the proposed utility model can serve as a working blade, shown in the paper "Development and study of constructive ways to increase efficiency in the end sections of the working blades of a theater of aviation aircraft GTE." Le Thien Zyong, Nesterenko V.G.// International Research Journal. Technical science. Issue No. 1 (67) January 2018, p. 73-84.

This working blade includes a feather, a locking part and a retaining shelf, on the external (with respect to the path gas flow zone) surface of which sloping scallops are installed to reduce overflow through the radial clearance between the blade and the stator elements forming the flow part. The use of inclined scallops allows a higher tightness of the radial clearance and an increased level of efficiency. The disadvantage of the above blades is the lack of measures to reduce losses in the peripheral region of the flow part.

Thus, existing designs of turbine blades with retaining shelves do not allow the use of retaining shelves to reduce losses in the peripheral region of the flow part.

To eliminate the aforementioned drawback, a turbine working blade design is proposed, including a feather, a locking part with an end shelf and a retaining shelf, on the outer surface of which (with respect to the path gas flow zone) sloping scallops are installed to reduce overflow through the radial clearance between the blade and the elements the stator, and the surface between them and the inner surface of the shelf (from the main flow) are asymmetric, i.e. containing bulges and hollows.

The advantage of the proposed utility model is the increase in the efficiency of the turbine stage due to a decrease in the aerodynamic loss due to a decrease in the intensity of the secondary vortex on the inner surface (from the duct gas side) of the retaining shelf and due to an increase in the resistance of the inter-labyrinth space due to the asymmetric profiling of the outer surface of the shelf between the combs the maze.

To eliminate the aforementioned drawback, a turbine working blade design is proposed, including a feather, a locking part with an end shelf and a retaining shelf, on the outer surface of which (with respect to the path gas flow zone) sloping scallops are installed to reduce overflow through the radial clearance between the blade and the elements the stator, and the surface between them and the inner surface of the shelf (from the main flow) are asymmetric, i.e. containing bulges and hollows.

The rotor blades of turbine engines are the most critical parts of the engine, on which its resource and reliability depend, and the efficiency of the entire turbine depends on the perfect design of the blades.

In order to prevent dangerous vibrations of the blade feather and its further failure, a retaining shelf is provided in the design of the blade, which is a bounding surface located perpendicular to the blade feather.

The goal of creating a turbine rotor blade with asymmetric inner and outer surfaces of the retaining shelf is to increase the efficiency level of the turbine stage by reducing the size of the peripheral channel vortex in the working grid, which reduces the uneven flow in the impeller, as well as by increasing the resistance of the labyrinth space and reducing overflow in radial clearance.

The technical result is expressed in the reduction of aerodynamic losses and the corresponding increase in turbine efficiency.

The technical result is achieved by the fact that in a turbine working blade with asymmetric inner and outer surfaces of the retaining shelf containing a feather, a locking part and a retaining shelf, on the outside, in relation to the path of the gas flow, the surfaces of which are inclined scallops to reduce overflow through the radial clearance between the blade and the stator elements, and the surface between the combs is made asymmetric, that is, containing the bulge and cavity, as well as the inner surface of the retaining shelf.

The figure shows the proposed design of the turbine rotor blades with asymmetric inner and outer surfaces of the retaining shelf. The design contains a feather (1), a locking part (2), an end flange with an asymmetric surface (3) and a retaining flange (4), on the external (with respect to the path gas path) surface of which sloping scallops (5) are installed to reduce overflows through the radial clearance between the blade and the stator elements, and the surface between them is asymmetric, i.e. containing bulges and hollows, as well as the inner surface of the retaining shelf.

The principle of operation of the proposed turbine blades with asymmetric surfaces of the retaining shelf is as follows. The inner surface of the retaining shelf and part of the outer surface of the retaining shelf between the inclined scallops are asymmetrical - having hollows and convexities, which contribute to the generation of additional vortex structures, on the outer surface (from the path gas side) helping to reduce the negative influence of the peripheral vortex, and on the inside, to reduce the kinetic loss energy and, as a result, increase the efficiency of the turbine stage

The asymmetry of the surface from the side of the path gas makes it possible to reduce the intensity of the secondary vortices (the size of the channel vortex), as a result of which the unevenness of the flow decreases, the level of losses decreases, and the efficiency increases; from the outside, the asymmetry of the surface increases the resistance level of the labyrinth space, which in turn helps to reduce losses and increase the efficiency of the turbine stage.

Claims (1)

A turbine working blade with an asymmetric inner and outer surfaces of the retaining shelf, containing a feather, a locking part and a retaining shelf, on the outside, in relation to the path of the gas flow, the surfaces of which are inclined scallops to reduce overflow through the radial clearance between the blade and the stator elements, characterized the fact that the surface between the combs is made asymmetric, that is, containing the bulge and hollows, as well as the inner surface of the retaining shelf.

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