RU178873U1 - TURBO MACHINE BLADE FROM ALUMINUM ALLOY WITH A STRENGTHENING LAYER CONTAINING ZIRCONIUM - Google Patents

Abstract

The utility model relates to the field of products from nanocrystalline materials and can be used for turbomachine blades to improve their physico-mechanical, corrosion and other practically important operational properties. The blade of an aluminum alloy turbomachine with a hardened surface layer, which consists of two layers: an outer layer with a thickness of 1 to 3 μm, consisting of nanocrystals of an aluminum alloy containing zirconium and located directly under the outer layer of an inner layer with a thickness of 5 to 20 μm, consisting from nanocrystals of aluminum alloy. In this case, the nanocrystals of the aluminum alloy of the outer layer have sizes in the range from 10 to 600 nm, and the nanocrystals of aluminum alloy of the inner layer have sizes in the range from 300 to 900 nm. 1 s.p. f-ly, 1 approx.

Description

The utility model relates to the field of products from nanocrystalline materials and can be used for turbomachine blades to improve their physico-mechanical, corrosion and other practically important operational properties.

A product is known from solid-phase nanostructured materials, consisting of an initial matrix with a layer of nanostructured materials deposited on it [RF patent application No. 2005106650. A method of obtaining solid-phase nanostructured materials and a device for its implementation. IPC С01В 31/00, 2006]. The disadvantage of this method is the inability to obtain products with a nanocrystalline surface layer of the matrix material.

A product is known from bulk nanocrystalline metallic materials obtained by the method of intensive plastic deformation to form [Valiev RZ, Alexandrov IV Nanostructured materials obtained by intense plastic deformation. M .: Logos, 2000.272 s.].

A disadvantage of the known product [Valiev RZ, Alexandrov I.V. Nanostructured materials obtained by intense plastic deformation. M .: Logos, 2000. 272 S.] is the impossibility of obtaining directly in the surface layer of metal parts of a nanocrystalline structure. At the same time, for parts such as turbomachine blades, it is necessary to provide a hardened surface layer of the material [RF patent 2117073. Method for modifying the surface of titanium alloys. IPC С23С 14/48, 1998]. Turbomachine blades operate under conditions of alternating loads, which can lead to surface cracks and destruction of the blades. Therefore, the operational reliability of the blades can be achieved by increasing the physico-mechanical properties of the surface layer of the material of the part. The creation of a nanocrystalline structure in the surface layer of the material, which has higher strength properties compared to conventional non-nanocrystalline alloys, can significantly increase the operational properties of such products. For example, compared with alloys having grain sizes larger than 1 μm, the time to fracture of samples during strength tests is increased by 2-3 times, and the fatigue life by 1-2 orders of magnitude. In addition, it is not always, in particular, for reasons of high cost, it is advisable to create the entire product from bulk nanocrystalline metal or alloy. Even when using bulk nanocrystalline material with relatively large crystals for the manufacture of parts, enhanced performance properties can be obtained by grinding the structure in the surface layer of the material of the part.

A product is known with a nanocrystalline surface layer obtained on the surface of the product using a tunneling microscope. A thin layer of metal is applied to the surface of the product, on which a thin film of water is adsorbed. As a result of electrochemical processes, a layer of several tens of nm is formed on the treated area [Matsumoto K., Sedawa K - Application of Scanning Tunneling Microscopy Nanofabrication process to Single Electron Transistor. - Journ. Vac. Sci. Technol. - 1996, B 14.R. 1331-1335].

The disadvantage of this technical solution is the impossibility of its application in such details as, for example, a turbomachine blade.

The closest technical solution, selected as a prototype, is a product with a nanostructured surface layer obtained by bombarding the surface of the material with heavy ions. (Fleischer R.L., Price R.V. Walker R.M. - Nuclear Tracks in Solids. - Univ. Of California, Berkeley, 1979). Amorphization of the crystal structure occurs in the region of the track with the formation of nanoscale structures oriented along the track.

The disadvantage of the prototype is the heterogeneity of the obtained surface layer of the material of the product, since irradiation of the surface layer with accelerated heavy ions leads to the formation in the material along the ion track of a highly disordered region with a diameter from units to tens of nm. ["Microelectronics". - 1998, v. 27, 1, p. 46-48].

The objective and technical result of this technical solution is to increase the operational properties of aluminum alloy products through the use of a homogeneous nanocrystalline surface layer of the material.

The technical result is achieved by the fact that in the blade of an aluminum alloy turbomachine with a hardened surface layer, in contrast to the prototype, the hardened surface layer consists of two layers: an outer layer with a thickness of 1 to 3 μm, consisting of nanocrystals of an aluminum alloy containing Zr and located directly under the outer layer of the inner layer with a thickness of 5 to 20 μm, consisting of nanocrystals of aluminum alloy. In addition, the following embodiments of the utility model are possible: nanocrystals of the aluminum alloy of the outer layer have sizes in the range from 10 to 600 nm, and nanocrystals of aluminum alloy of the inner layer have sizes in the range from 300 to 900 nm.

The essence of this technical solution lies in the fact that in the surface layer of the material of the product using one of the known methods form a uniform amorphous surface layer. The formation of an amorphous layer allows, on the one hand, to reduce the influence of the initial structure of the product material on the newly formed nanocrystalline structure of the surface layer, and on the other hand, creates the prerequisites for the formation of nanocrystals in the process of subsequent crystallization. As a method for producing an amorphous layer, an ion implantation method can be used. When Zr ions are introduced into the surface layer of an aluminum alloy of an aluminum alloy, an amorphous layer is formed, which, in turn, consists of two layers: an external amorphous layer with a thickness of the order of 1 ... 3 μm containing embedded Zr ions and an inner layer with a thickness of 5 to 20 μm formed as a result the effects of embedded ions (long-range effect, the formation of radiation-induced structural defects). During crystallization of the amorphous surface layer, the size of the nanocrystals will depend on the frequency of the applied load and the time of thermal exposure. Moreover, to quickly fix the processes of the transition of the material from the amorphous to the nanocrystalline state, it is also necessary to control the cooling rate of the product material.

Thus, obtaining an amorphous surface layer of the material of a turbomachine blade with its subsequent transformation by deformation and crystallization into a nanocrystalline surface layer of the product material allows achieving the effect of the proposed technical solution - improving the operational properties of metal and alloy products.

Example. To assess the operational properties of the blades

made of duralumin (D16), made according to the prototype and the proposed technical solution, endurance and cyclic strength tests were carried out at operating temperatures in air.

As a result of the tests, the following results were obtained: the conditional endurance limit (σ _-1 ) of duralumin blades (D16) on average compared to the prototype is:

1) prototype: 120-125 MPa;

2) according to the proposed technical solution: 136-145 MPa.

The conditional endurance limit (σ _-1 ) of aluminum alloys (D1, D16, D16T) on average increases by approximately 13% -16%, which confirms the claimed technical result.

Claims (2)

1. The blade of a turbomachine made of aluminum alloy with a hardened surface layer, characterized in that the hardened surface layer consists of two layers, the outer layer consisting of nanocrystals of an aluminum alloy containing Zr and made from 1 to 3 μm thick, and located directly under the outer the inner layer is made from 5 to 20 microns thick and consists of nanocrystals of aluminum alloy. 2. The blade according to claim 1, characterized in that the nanocrystals of the aluminum alloy of the outer layer have sizes in the range from 10 to 600 nm, and the nanocrystals of aluminum alloy of the inner layer have sizes in the range from 300 to 900 nm.