The present invention relates to a process for producing a thermal barrier coating having excellent durability, and relates particularly to a process for producing a ceramic layer used as the top coat of a thermal barrier coating.
In recent years, enhancement of the thermal efficiency of thermal power generation has been investigated as a potential energy conservation measure. In order to enhance the electric power generation efficiency of a power-generating gas turbine, increasing the gas inlet temperature has been shown to be effective, and in some cases this temperature is increased to approximately 1500° C. In order to realize a power generation plant that can be operated at this type of higher temperature, the stationary blades and moving blades that constitute the gas turbine, and the walls of the combustor and the like must be formed of heat-resistant members. However, even though the material used for the turbine blades is a heat-resistant metal, it is unable to withstand the types of high temperature mentioned above, and therefore a thermal barrier coating (TBC) is formed by using a deposition process such as thermal spraying to laminate a ceramic layer composed of an oxide ceramic onto the heat-resistant metal substrate, with a metal bonding layer disposed therebetween, thereby protecting the heat-resistant metal substrate from high temperatures. ZrO2-based materials are used for the ceramic layer, and yttria-stabilized zirconia (YSZ), which is ZrO2 that has been partially or totally stabilized by Y2O3, is often used because of its comparatively low thermal conductivity and comparatively high coefficient of thermal expansion compared with other ceramic materials.
Depending on the type of gas turbine, it is thought that the turbine inlet temperature may rise to a temperature exceeding 1500° C. In those cases where the moving blades and stationary blades and the like of a gas turbine are coated with a thermal barrier coating comprising a ceramic layer composed of the above-mentioned YSZ, there is a possibility that portions of the ceramic layer may detach during operation of the gas turbine under severe operating conditions exceeding 1500° C., resulting in a loss of heat resistance. Further, recent trends towards improved environmental friendliness are spurring the development of gas turbines having even higher thermal efficiency, and it is thought that turbine inlet temperatures may reach 1600° C. to 1700° C., with the surface temperature of the turbine blades reaching temperatures as high as 1300° C. Accordingly, even higher levels of heat resistance and thermal barrier properties are now being demanded of thermal barrier coatings.
The above-mentioned problem of detachment of ceramic layers composed of YSZ occurs because the crystal stability of YSZ is unsatisfactory under high-temperature conditions, and because the YSZ lacks satisfactory durability relative to large thermal stress. As a result, materials such as Yb2O3-doped ZrO2 (PTL 1), Dy2O3-doped ZrO2 (PTL 2), Er2O3-doped ZrO2 (PTL 3), and SmYbZr2O7 (PTL 4) have been developed as ceramic layers that exhibit excellent crystal stability under high-temperature conditions and superior thermal durability.
As disclosed in PTL 5, ceramic layers generally employ particles having an average particle size of 10 μm to 100 μm, and are typically deposited by a thermal spraying process.
The thermal barrier properties of a ceramic layer can be improved by introducing pores into the ceramic layer. The porosity within a ceramic layer can be controlled by altering the thermal spraying conditions. However, the upper limit for the porosity that can be obtained using a thermal spraying process is approximately 10%. It is thought that further increasing this porosity would be effective in improving the thermal barrier properties of the ceramic layer.
The present invention has been developed in light of the above circumstances, and has an object of providing a process for producing a thermal barrier coating having an excellent thermal barrier effect and superior durability to thermal cycling, and also providing a turbine member having a thermal barrier coating that has been formed using the production process, and a gas turbine.
In order to achieve the above object, the present invention provides a process for producing a thermal barrier coating, the process comprising forming a metal bonding layer on a heat-resistant alloy substrate, and forming a ceramic layer on the metal bonding layer by thermal spraying of thermal spray particles having a particle size distribution in which the 10% cumulative particle size is not less than 30 μm and not more than 150 μm.
In one aspect of the above invention, the thermal spray particles preferably have a maximum particle size of 150 μm, and preferably comprise not more than 3% of particles having a particle size of 30 μm, and not more than 8% of particles having a particle size of 40 μm.
Conventionally, the formation of ceramic layers has generally been conducted using thermal spray particles having a particle size distribution close to a normal distribution in which the average particle size is within a range from 10 μm to 150 μm, and more typically from 10 μm to 100 μm. In contrast, in the present invention, as specified by the proportion defined above, the proportion of small particles is reduced, and the ceramic layer is formed using spray particles comprising mainly comparatively large particles. Increasing the 10% cumulative particle size for the thermal spray particles means the proportion of small particles contained within the spray particles is reduced. This results in increased porosity within the ceramic layer, and improved thermal barrier properties for the ceramic layer. Moreover, the generation of fine laminar defects within the ceramic layer is also suppressed, enabling the production of a thermal barrier coating with improved durability to thermal cycling.
The present invention also provides a turbine member comprising a thermal barrier coating formed using the above production process, and a gas turbine comprising the turbine member.
A thermal barrier coating produced using the present invention combines excellent thermal barrier properties with superior thermal cycling durability, and can therefore be applied to 1600° C. class gas turbine members and the like.
According to the present invention, a ceramic layer having a higher porosity than conventional ceramic layers can be formed, enabling the production of a thermal barrier coating with excellent thermal barrier properties. Further, because fine laminar defects are reduced, the durability of the thermal barrier coating can also be improved.
An embodiment of the present invention is described below.
The metal bonding layer 12 is formed from an MCrAlY alloy (wherein M represents a metal element such as Ni, Co or Fe, or a combination of two or more of these elements) or the like.
Examples of the ceramic layer 13 include YbSZ (ytterbia-stabilized zirconia), YSZ (yttria-stabilized zirconia), SmYbZr2O7, DySZ (dysprosia-stabilized zirconia) and ErSZ (erbia-stabilized zirconia).
The ceramic layer of the present embodiment is formed by atmospheric pressure plasma spraying. The spray particles used are formed on the metal bonding layer with a particle size distribution in which the 10% cumulative particle size is not less than 30 μm and not more than 150 μm.
To obtain the graph of
The particle size distribution of the thermal spray particles was measured using a laser scattering/diffraction particle size distribution analyzer (manufactured by CILAS).
As illustrated in
The thermal spray particles A have been classified using a 44 μm sieve to remove those particles having a small particle size. The spray particles A have a maximum particle size of not more than 150 μm, and comprise not more than 1% of particles having a particle size of 30 μm, and not more than 1% of particles having a particle size of 40 μm. The 10% cumulative particle size of the spray particles A is 42 μm.
The thermal spray particles B have not been classified to remove those particles having a small particle size. Although having a maximum particle size substantially similar to that of the spray particles A, the thermal spray particles B comprise 6% of particles having a particle size of 30 μm, and 10% of particles having a particle size of 40 μm. The 10% cumulative particle size of the spray particles B is 21 μm.
The thermal spray particles A and the thermal spray particles B were used to form ceramic layers on test pieces. The test pieces (the materials for the heat-resistant alloy substrate and the metal bonding layer) and the thermal spray conditions used for the ceramic layer were the same as those used in acquiring the data for
The thermal barrier coating test pieces prepared using the thermal spray particles A and the thermal spray particles B were measured for porosity of the ceramic layer, thermal conductivity, and the value of the above-mentioned ΔT as an indicator of the thermal cycling durability. The results are shown in Table 1.
The porosity was determined by using an image processing method to analyze microscope photographs of a finely polished cross-section of the thermal barrier coating acquired for 5 random fields of view (observation length: approximately 3 mm) using an optical microscope (magnification: 100×). The thermal conductivity was measured using the laser flash method prescribed in JIS R 1611.
The number of thermal cycles (relative value) endured when the above thermal barrier coating test pieces were subjected to a laser thermal cycling test under conditions including a maximum surface heating temperature of 1500° C., a maximum interface temperature of 900° C., a heating time of 3 minutes and a cooling time of 3 minutes are illustrated in
Compared with the ceramic layer formed using the thermal spray particles B, the ceramic layer formed using the thermal spray particles A has increased porosity and a thermal conductivity that is approximately 10% lower. This increase in the porosity within the ceramic layer formed using the thermal spray particles A is due to the removal of the small particles and the resulting increase in the average particle size.
As illustrated in
As illustrated in Table 1 and
Even when a ceramic layer of the thermal spray particles A was formed using different thermal spray conditions (such as a different spray distance), thermal cycling durability that was substantially equivalent to that illustrated in Table 1 and
As described above, by using thermal spray particles in which the number of small particles (for example, particles having a particle size of 40 μm or less) has been dramatically reduced, the porosity of the ceramic layer can be increased, and a thermal barrier coating that exhibits superior thermal barrier properties and excellent thermal cycling durability can be obtained.
Similarly, it has been confirmed that in the cases of YSZ and SmYbZr2O7 and the like, by forming a thermal barrier coating using thermal spray particles from which small particles have been removed in the same manner as that described above, the porosity of the ceramic layer increases and the thermal cycling durability improves.
Number | Date | Country | Kind |
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2009-286659 | Dec 2009 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2010/064691 | 8/30/2010 | WO | 00 | 3/23/2012 |
Publishing Document | Publishing Date | Country | Kind |
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WO2011/074290 | 6/23/2011 | WO | A |
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Number | Date | Country | |
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20130202912 A1 | Aug 2013 | US |