WO2005019370A2

WO2005019370A2 - Heat-insulation material and arrangement of a heat-insulation layer containing said heat-insulation material

Info

Publication number: WO2005019370A2
Application number: PCT/EP2004/051632
Authority: WO
Inventors: Ulrich Bast; Wolfgang Rossner
Original assignee: Siemens Aktiengesellschaft
Priority date: 2003-08-13
Filing date: 2004-07-28
Publication date: 2005-03-03
Also published as: EP1664231A2; WO2005019370A3; US20060177676A1

Abstract

Said invention relates to a heat-insulation material for a heat-insulation layer (3) for a carrier body (2) for preventing heat transfer between said carrier body and a surrounding area (7) therearound comprising at least one luminous substance which is excitable for emitting luminescent light having a defined emission wavelength and comprises at least one type of metal oxide containing at least one trivalent metal (A). Said invention also relates to an arrangement of at least one heat-insulation layer which contains said heat-insulation material and is applied to the carrier body. The inventive heat-insulation material is characterised in that the metal oxide is embodied in the form of a mixed oxide selected in a perovskite group of total formula AA'O3, and/or of pyrochlore of total formula A2B2O7, wherein A' is the trivalent metal and B is a tetravalent metal. Said heat-insulation layer containing said heat-insulation material is preferably used for a gas turbine.

Description

description

Thermal insulation and arrangement of a thermal insulation layer with the thermal insulation material £

The invention relates to a heat insulation material for a heat insulation layer of a support body for containing heat transfer between the support body and an environment of the support body, the heat insulation material having at least one phosphor which can be excited to emit luminescent light with a specific emission wavelength, and the phosphor at least one metal oxide with at least one trivalent metal A. In addition to the thermal insulation material, an arrangement of at least one thermal insulation layer with the thermal insulation material on a carrier body is specified.

Such a thermal insulation material and such an arrangement are known from EP 1 105 550 B1. The carrier body is a component of a gas turbine. The carrier body is made of a metal. Due to a high temperature of over 1200 ° C. occurring in a gas turbine in the vicinity of the component, the metal of the component can be damaged. To prevent this, a thermal barrier coating (TBC) is applied to the component. The

Thermal insulation layer ensures that there is a reduced heat exchange between the metal carrier body and the environment. As a result, a metal surface of the component heats up less. One occurs on the metal surface of the component

Surface temperature that is lower than the temperature in the vicinity of the component.

The thermal insulation material forms a base material for the thermal insulation layer. The mechanical and thermal

Properties of the thermal insulation layer essentially depend on the properties of the thermal insulation material. The base material the known thermal barrier coating is a metal oxide. The metal oxide is, for example, a zirconium oxide (YSZ) stabilized with yttrium. The thermal conductivity of this thermal insulation material is between 1 W / mK and 3 W / mK. In order to ensure efficient protection of the carrier body, the thickness of the thermal insulation layer is approximately 250 μm. As an alternative to zirconium oxide stabilized with yttrium, a metal oxide in the form of an yttrium aluminum garnet is specified as the thermal insulation material.

In order to firmly connect the thermal insulation layer and the carrier body, a metallic intermediate layer (bond coat) made of a metal alloy is applied to the surface of the component. To improve the connection, a ceramic intermediate layer made of a ceramic material, for example aluminum oxide, can additionally be arranged between the thermal insulation layer and the component.

A so-called thermal luminescence indicator is embedded in the thermal insulation layer. This indicator is a phosphor (luminophore) that can be excited to emit a luminescent light with a specific emission wavelength by excitation with excitation light of a specific excitation wavelength. The excitation light is, for example, UV light. The emission light is, for example, visible light. The phosphor used is a so-called recombination phosphor. The lighting process is caused by electronic transitions between the energy states of the activator. Such a phosphor consists, for example, of a

Solid body with a crystal lattice (host lattice) in which a so-called activator is embedded. The solid is doped with the activator. The activator is involved in the lighting process of the phosphor together with the entire solid. In the known thermal insulation layer, the respective base material of the thermal insulation layer is doped with an activator. There is a thermal barrier coating made of the phosphor. The activator used is a rare earth element. In the case of zirconium oxide stabilized with yttrium, the rare earth element is, for example, europium. The thermal insulation material yttrium aluminum garnet is doped with the rare earth elements dysprosium or terbium.

The known thermal barrier coating takes advantage of the fact that an emission property of the luminescent light of the phosphor, for example an emission intensity or an emission decay time, is dependent on the phosphor temperature of the phosphor. Because of this dependence on the temperature of the

Thermal insulation layer closed with the phosphor. So that this connection can be established, the thermal insulation layer is optically accessible for the excitation light in the UV range. At the same time, it is ensured that the luminescent light of the phosphor can be emitted from the thermal insulation layer and detected.

In order to ensure the optical accessibility, for example, only a single thermal insulation layer with the phosphor is arranged on the carrier body. As an alternative solution, a further heat insulation layer is applied to the heat insulation layer, which is transparent to the excitation light and the luminescent light of the phosphor. The luminescent light from the phosphor can pass through the further thermal insulation layer.

Due to specific material properties, for example phase stability or tendency to sinter, it is possible to use a thermal insulation layer made of one of the luminescent thermal insulation materials mentioned

Operating temperature of about 1200 ° C limited. Therefore, these thermal insulation materials are for future gas turbine generations not suitable, in which the operating temperature is increased to increase the efficiency uss.

The object of the present invention is therefore to provide a luminescent thermal insulation material for a thermal insulation layer of a carrier body which is stable beyond a temperature of 1200 ° C.

To solve the problem, a thermal insulation material for a thermal insulation layer of a carrier body to contain a

Heat transfer between the support body and an environment of the support body specified, wherein the thermal insulation material has at least one phosphor that is used to emit

Luminescent light can be excited with a certain emission wavelength, and the phosphor at least one

Has metal oxide with at least one trivalent metal A. The thermal insulation material is characterized in that the metal oxide is a mixed oxide selected from the group perovskite with the formula AAO3 and / or pyrochlore with the formula A2B2O7, where A 'is a trivalent metal and B is a tetravalent metal.

To achieve the object, an arrangement of at least one thermal insulation layer on a support body for containing heat transfer between the support body and an environment of the support body is also specified, the heat insulation layer having the heat insulation material described with the phosphor.

A thermal barrier coating made of a perovskite and / or a pyrochlore (pyrochlore phase) is characterized by a high stability against temperatures of over 1200 ° C. These stable thermal insulation layers have a phosphor. The thermal barrier coating can be single-phase or multi-phase. Single-phase means that a ceramic phase of the thermal insulation layer formed by the thermal insulation material essentially consists only of the phosphor. The The insulating material of the thermal insulation layer is the phosphor. In the case of a multi-phase thermal insulation layer, the thermal insulation material and the phosphor are different. The thermal insulation material contains phosphor particles from the phosphor. The ceramic phase is made up of different materials. The phosphor particles are preferably distributed homogeneously over the thermal barrier coating. In addition, it is advantageous if the thermal insulation material and the phosphor consist of essentially the same type of solid. The phosphor and the thermal insulation material consist of the same metal oxide. The only difference between the two substances is their optical properties. For this purpose, the phosphor is doped, for example.

The phosphor is a recombination phosphor. The

Emission of the luminescent light is preferably based on the presence of an activator. With the help of an activator or several activators, the emission property of the phosphor, for example the emission wavelength and the emission intensity, can be varied relatively easily. In a special embodiment, the phosphor has an activator selected from the group cerium and / or europium and / or dysprosium and / or terbium to excite the emission of luminescent light. Rare earth elements are generally very easy to incorporate into the crystal lattices of perovskites and pyrochlores due to their ionic radii. Activators in the form of rare earth elements are therefore generally suitable. The listed rare earth elements have proven to be particularly good activators.

When an activator is used, its proportion in the phosphor is selected such that the thermal and mechanical properties of the metal oxide of the phosphor are almost unaffected. The mechanical and thermal properties of the metal oxide are retained despite the doping. In a special embodiment, the activator is contained in the phosphor in a proportion of up to 10 mol%. The proportion is preferably less than 2 mol%. For example, the proportion is 1 mol%. It has been shown that this low proportion of the activator is sufficient to achieve a usable emission intensity of the phosphor. The thermal and mechanical stability of one with the

Fluorescent thermal insulation layer is retained.

In a special embodiment, the trivalent metal A and / or the trivalent metal A 'is a rare earth element Re. The trivalent metal A and / or the trivalent metal A 'is in particular a rare earth element selected from the group consisting of lanthanum and / or gadolinium and / or samarium. Other rare earth elements are also conceivable. By using a perovskite and / or a pyrochlorine with rare earth elements, an activator in the form of a rare earth element can be very easily built into the crystal lattice of the perovskite or pyrochlorine due to the similar ionic radii.

One of the trivalent metals A and A "of the perovskite is a main group or subgroup element. The tetravalent metal B of the pyrochlor is also a main or subgroup element. In both cases, mixtures of different main and subgroup elements can be provided. Due to the different ionic radii, the Rare earth elements and the main or subgroup elements preferably occupy different places in the perovskite or pyrochlore crystal lattice. Aluminum has proven to be particularly advantageous as a trivalent main group element In a special embodiment, the perovskite is therefore a rare earth alumina, the overall formula is ReAlθ3, where Re stands for a rare earth element, and the rare earth aluminate is preferably a gadolinium-lanthanum aluminate The empirical formula is, for example, Gdg _f 25 ^La 0, 75 ^Al0 3 • ^In particular, the tetravalent metal B of pyrochlorine is that

Sub-group elements hafnium and / or titanium and / or

Zirconium used. The pyrochlore is therefore preferably selected from the group of rare earth titanate and / or side earth hafnate and / or rare earth zirconate. In particular that is

Rare earth zirconate from the group Gadolinium zirconate and / or

Samarium zirconate selected. The preferred empirical formulas are Gd2Zr2θ ₇ and Sm2Zr2θ7. The rare earth hafnate is preferably lanthanum hafnate. The empirical formula is La2Hf2O7.

The phosphor is excited optically to emit luminescent light. The phosphor is illuminated with excitation light of a specific excitation wavelength. By absorbing the excitation light, the phosphor is excited to emit luminescent light. The excitation light is, for example, UV light and the luminescent light is low-energy, visible light.

The excitation of the phosphor with excitation light is suitable for checking a state of a thermal insulation layer with the phosphor that is optically accessible for the excitation light and the luminescent light. For this purpose, for example, only the thermal barrier coating with the phosphor is applied to the carrier body.

In a special embodiment with regard to the arrangement of thermal insulation layer on the carrier body, at least one further thermal insulation layer is present which is essentially free of the phosphor. Essentially free means that a luminescent light that cannot be evaluated cannot be detected due to a very small proportion of the phosphor. The further heat insulation layer can be arranged between the carrier body and the heat insulation layer with the phosphor. The outermost thermal insulation layer is formed by the thermal insulation layer with the phosphor. A transmission property of the further thermal insulation layer with respect to the luminescent light and / or the excitation light does not matter. The thermal insulation layer with the phosphor is optically accessible. Such a solution is advantageous, for example, for a thermal insulation layer made from a pyrochlore. In order to achieve a firm connection between the thermal insulation layer and a metallic intermediate layer applied to the carrier body, a further thermal insulation layer made of a zirconium oxide stabilized with yttrium is applied directly to the metallic intermediate layer. The heat insulation layer with the phosphor is applied over this further heat insulation layer.

The further thermal barrier coating can, however, also be transparent to the excitation light and the luminescent light of the phosphor. The excitation light and the luminescent light can pass through the further thermal insulation layer. In such a solution, the heat insulation layer can be arranged between the further heat insulation layer and the carrier body. Due to the transmission property of the further thermal insulation layer, the thermal insulation layer with the phosphor is constantly optically accessible. In this way, as in the cases in which either only the thermal barrier layer with the phosphor is present or the thermal barrier layer with the phosphor forms the outermost thermal barrier layer of a multilayer structure, a state of the thermal barrier layer can be determined by observing one of the emission properties of the luminescent light. For example, the temperature of the thermal barrier coating can be inferred.

The further is in a special embodiment

Thermal insulation layer for the excitation light to excite the emission of the luminescent light of the phosphor and / or for the luminescent light of the phosphor opaque. The excitation light and / or the luminescent light can through the further thermal insulation layer due to the transmission or

Absorption properties of the further thermal insulation layer do not pass through or only to a small extent. In a In a special embodiment, the heat insulation layer is arranged between the support body and the further heat insulation layer in such a way that the excitation light of the phosphor and / or the luminescent light of the phosphor can essentially only get into the surroundings of the support body through openings in the further heat insulation layer. Such openings are, for example, cracks or gaps in the further thermal insulation layer. An opening is also conceivable, which has been created by erosion (removal) of further thermal insulation material from the further thermal insulation layer. These openings can easily be made visible. The visualization succeeds by illuminating the arrangement with the excitation light. At the points where the UV light reaches the thermal insulation layer with the phosphor through the openings, the phosphor is excited to emit the luminescent light. The luminescent light again reaches the surroundings of the carrier body through the openings and can be detected there. Due to the openings, a luminescent light appears that clearly stands out from the background.

In the way described, the thermal insulation layer of a carrier body used in the device can be checked in a simple and safe manner during a break in operation of a device. The device is, for example, a gas turbine. The carrier body is, for example, a turbine blade of the gas turbine. The multilayer structure with the thermal insulation layers is located on the turbine blade. By illuminating the turbine blade and observing the luminescent light of the phosphor, those points of the further, outermost thermal insulation layer that have openings become visible.

However, it is also conceivable for the state of the thermal barrier coating to be checked during operation of the device. For this purpose, for example, a combustion chamber of the gas turbine described above, in which the turbine blades are used, has a window provided, through which the luminescence of the phosphor can be observed. The occurrence of luminescent light is an indication that the further, outermost thermal insulation layer of at least one turbine blade has a crack or a gap or is eroded.

Another advantage of the arrangement described is that thermal insulation material is also removed with the phosphor as a result of advanced erosion. The fluorescent substance can be detected in an exhaust gas of the gas turbine by means of appropriate detectors. This is a sign that erosion has progressed to the thermal insulation layer with the phosphor.

In a special embodiment, the carrier body is a component of an internal combustion engine. The internal combustion engine is, for example, a diesel engine. In a special embodiment, the internal combustion engine is a gas turbine. The carrier body can be a tile with which a combustion chamber of the gas turbine is lined. In particular, the carrier body is a turbine blade of the gas turbine. It is conceivable that the different carrier bodies are provided with heat-insulating layers with phosphors that emit different luminescent light. This makes it easy to determine the component that is damaged.

Any coating method can be carried out to apply the various layers, in particular the thermal insulation layer and the further thermal insulation layer. The coating process is particularly a

Plasma spraying process. The coating process can also be a vapor deposition process, for example PVD (Physical Vapor Deposition) or CVD (Chemical Vapor Deposition). With the help of the procedures mentioned Thermal insulation layers with layer thicknesses of 50 μm to 600 μm and more applied.

In summary, the following special advantages result from the invention:

- The materials used are stable at temperatures above 1200 ° C. This makes them particularly suitable for use in internal combustion engines, for example in a gas turbine.

- The mixed oxides used are specifically doped with activators. Thereby thermally and mechanically stable thermal insulation layers with luminescent phosphors are obtained even at temperatures of over 1200 ° C, with the aid of which the condition of the thermal insulation layers can be checked in a simple manner during operation or during breaks in operation of the carrier body.

Using several exemplary embodiments and the associated

Figures, the invention is explained in more detail below. The figures are schematic and do not represent true-to-scale illustrations.

Figures 1 to 3 each show a section of a lateral cross section of an arrangement of a heat insulation layer made of a heat insulation material with a phosphor from the side.

The arrangement 1 consists of a carrier body 2 on which a thermal insulation layer 3 is arranged (FIG. 1). The carrier body 2 is a turbine blade of a gas turbine. The turbine blade is made of a metal. Temperatures of over 1200 ° C. can occur in the combustion chamber of the gas turbine, which represents the surroundings 7 of the carrier body 2, during operation of the gas turbine. In order to prevent the surface 8 of the carrier body 2 from overheating, the thermal insulation layer 3 available. The thermal barrier coating 3 serves to contain heat transfer between the carrier body 2 and the surroundings 7 of the carrier body 2.

A metallic intermediate layer 4 (bond coat) made of a metal alloy is applied between the thermal insulation layer 3 and the carrier body 2. The thermal insulation layer 3, the intermediate layer 4 and optionally the further thermal insulation layer 5 are applied to the surface 8 of the carrier body 2 with the aid of a plasma spraying process.

Example 1 :

The heat insulation material of the heat insulation layer 3 is a metal oxide in the form of a rare earth aluminate with the formula

Gdg 25 ^ ^a 0 75 ^ 103. According to a first embodiment, the rare earth aluminate is mixed with 1 mol% EU2O3. The

Rare earth aluminate has the activator europium with a share of 1 mol%. Excitation of the phosphor with UV light results in a red luminescent light with an emission maximum at approximately 610 nm. The excitation wavelength is, for example, 254 nm.

According to an alternative embodiment, the rare earth aluminate is doped with 1 mol% terbium. The result is a phosphor with green luminescent light with an emission wavelength at 544 nm.

Example 2:

In contrast to the previous example, there is a

Multi-layer structure of the thermal barrier layer 3 and another

Thermal insulation layer 5 on the carrier body 2 before (Figure 2). The

Thermal insulation layer 3 consists of a pyrochlore. Pyrochlore is a gadolinium zirconate with the empirical formula Gd2Zr2Ü7. To the

The phosphor is produced with 1 mol% of the pyrochlore. E 2O3 added. The gadolinium zirconate has the activator

Europium with a share of 1 mol%.

To improve the adhesion to the carrier body 2, a further heat insulation layer 5 is present between the bond coat layer 4 and the heat insulation layer 3 with the phosphor. The further thermal insulation layer 5 consists of zirconium oxide, which is stabilized with yttrium.

Example 3:

There is also a multilayer structure (FIG. 3). In contrast to the previous example, the heat insulation layer 3 with the phosphor is arranged between the further heat insulation layer 5 and the carrier body 5. The further thermal insulation layer 5 is opaque for the excitation light and / or the luminescent light of the phosphor. The luminescent light of the phosphor in the vicinity of the carrier body can only be detected if the further thermal insulation layer 5 has an opening 6.

Claims

claims

1. Thermal insulation material for a thermal insulation layer (3) of a support body (2) for containing heat transfer between the support body (2) and an environment (7) of the support body (2), the heat insulation material having at least one phosphor which is used to emit luminescent light a certain emission wavelength can be excited, and the phosphor has at least one metal oxide with at least one trivalent metal A, characterized in that the metal oxide is a mixed oxide selected from the group perovskite with the formula AAO3 and / or pyrochlore with the formula A2B2O7, where A 'is a trivalent metal and B is a tetravalent metal.

2. Thermal insulation material according to claim 1, wherein the phosphor has an activator selected from the group cerium and / or europium and / or dysprosium and / or terbium to excite the emission of the luminescent light.

3. Thermal insulation material according to claim 2, wherein the activator is contained in a proportion of up to 10 mol% in the phosphor.

4. Thermal insulation material according to one of claims 1 to 3, wherein the trivalent metal A and / or the trivalent metal A 'is a rare earth element Re.

5. Thermal insulation material according to claim 4, wherein the trivalent metal A and / or the trivalent metal A 'is a rare earth element selected from the group consisting of lanthanum and / or gadolinium and / or samarium.

6. Thermal insulation material according to one of claims 1 to 5, wherein the perovskite is a rare earth aluminate.

7. Thermal insulation material according to claim 6, wherein the empirical formula 5 of the rare earth aluminate Gdn 25 is ^La 0 75AIO3.

8. Thermal insulation material according to one of claims 1 to 5, wherein the pyrochlore is selected from the group of rare earth hafnate and / or rare earth titanate and / or rare earth zirconate

10 is.

9. Thermal insulation material according to claim 8, wherein the rare earth zirconate is selected from the group gadolinium zirconate and / or samarium zirconate.

15 10. Thermal insulation material according to claim 8, wherein the rare earth hafnate is lanthanum hafnate.

11. Arrangement of at least one thermal barrier coating (3) on 20. a carrier body (2) for containing heat transfer between the carrier body (2) and an environment (7) of the carrier body (2), wherein the thermal barrier coating is a thermal insulation material according to one of claims 1 to 10 has. 25

12. The arrangement according to claim 11, wherein at least one further heat insulation layer (5) is present which is substantially free of the phosphor.

13. The arrangement according to claim 12, wherein the further thermal barrier coating (5) for the excitation light for exciting the emission of luminescent light and / or for the luminescent light of the phosphor is essentially opaque.

35 14. Arrangement according to claim 13, wherein the thermal barrier coating (3) between the carrier body (2) and the further Thermal insulation layer (5) is arranged in such a way that the luminescent light of the phosphor can only reach the surroundings (7) of the carrier body (2) only through openings (6) of the further thermal insulation layer (5).

15. Arrangement according to one of claims 11 to 14, wherein the carrier body is a component of an internal combustion engine.

16. The arrangement according to claim 15, wherein the internal combustion engine is a gas turbine.