METHOD FOR SEPARATING A METAL PART FROM A CERAMIC PART

Abstract

The invention relates to a method for separating a metal part from a ceramic part, which are joined at a connecting face within a modular hybrid component, especially of a gas turbine. The method includes said component being subjected to a reducing atmosphere in a gaseous process at elevated temperatures to dissolve the connection between said metal part and said ceramic part, especially by dissolving the ceramic part itself.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims priority to PCT/EP2013/056112 filed Mar. 22, 2013, which claims priority to European application 12161874.8 filed Mar. 28, 2012, both of which are hereby incorporated in their entireties.

TECHNICAL FIELD

The present invention relates to the processing of hybrid metal/ceramic parts in the field of gas turbine technology. It refers to a method for separating a metal part from a ceramic part according to the preamble of claim 1.

BACKGROUND

Modern, next generation gas turbine hot gas path components consist of more than one material (see for example EP 1 362 983 A2, US 2010/0166551 A1, EP 2 017 433 A2, EP 2 108 785 A2, US 2010/0074759 A1 or U.S. Pat. No. 7,452,189 B2) to adjust the properties of each region of the component to its environment.

Very often those parts consist of ceramic and metal sections to make use of the higher temperature capability of the ceramic where needed and of the strength/and/or toughness of the metal where needed.

After completion of one service interval, the components need to be disassembled and worn pieces need to be replaced. Typically the ceramic part cannot be reworked and will be replaced, while the metal part can be reused or reworked (e.g. crack brazing). Such modular parts are often joined together by brazing (see US 2008/0056888 A1, US 2008/0307793 A1).

Limited information is available on disassembly of modular parts. US 2008/0229567 A1 discloses a process that intends to leach out only a ceramic matrix in which ceramic fibres are embedded and to restore the ceramic afterwards by infiltration. However, the leaching process is not disclosed. In any case, leaching (which generally involves a liquid) is typically a slow process, whereas a gaseous process that is executed at higher temperatures, might have the advantage of the exponential temperature dependence of most chemical reactions, thus providing a faster process.

Furthermore, the leaching process would only be suitable for a local repair of the ceramic part, which is very unlikely considering the brittle behaviour of ceramics and does not take advantages of the modular design of the component, which aims at replacing worn pieces instead of doing repair, which anyway can only cope with limited damages.

Especially, when considering multiple reconditioning or heavy damages of gas turbine parts, a disassembly is unavoidable. Thus, although US 2008/0229567 A1 provides a process that is beneficial for some niche applications, it does not solve the problem of how to efficiently remove the ceramic part from the metallic part.

Another process known in the art for disassembling of brazed parts is de-brazing, i.e. subjecting the component to high temperatures in order to re-melt the braze alloy. However, this requires temperatures exceeding the original braze temperature, since the melting point depressants have diffused during service operation and thus the liquidus temperature of the braze joint has increased.

Therefore, the component, especially low tolerance joints, is prone to thermal deterioration. In addition, the braze alloy is only re-melt but not dissolved, i.e. residues are still attached to the joining surfaces even if the parts can be separated. However, these joining surfaces have complicated geometries and tight tolerances, so that every mechanical cleaning of the joining surfaces risks to modify their geometry beyond the tolerance, especially when low tolerance parts are involved.

SUMMARY

It is an object of the present invention to provide a method, which offers a time efficient one step process for disassembly, cleaning, preparation for repair and joining of a hybrid component, especially for gas turbines, said process being used to separate a ceramic or ceramic composite from a metal, e.g. separating ceramic parts from metallic parts of a modular hybrid gas turbine component.

It is another object of the invention to provide a process, which can be used for the simultaneous cleaning of the metal part and/or ceramic composite part, such that the metal part can be brazed without further cleaning or oxide removal and in case no rework of the metal part is required the part is immediately ready for joining with a new ceramic part.

It is a further object of the invention to provide a process, which can be used as a batch process, not a single piece process, and which allows economic ceramic removal for entire sets in very short time.

These and other objects are obtained by a method according to claim 1.

The inventive method is for separating a metal part from a ceramic part, which are joined at a connecting face within a hybrid component, especially of a gas turbine. It is characterized in that said hybrid component is subjected to an inert/reducing atmosphere in a gaseous process at elevated temperatures to dissolve the connection between said metal part and said ceramic part.

According to an embodiment of the invention said reducing atmosphere contains halogens as reactive species.

Specifically, said halogens have a higher electronegativity than oxygen, on either Pauling Scale, Mulliken Scale or Allred-Rochow Scale.

More specifically, said halogens comprise F.

Alternatively, said halogens comprise Cl.

According to another embodiment of the invention said ceramic part itself is dissolved or disintegrated as a whole.

Specifically, said ceramic part is a partially or fully stabilized ceramic, whereby, during the process, the stabilizing phase is removed by phase change from the ceramic, such that the entire ceramic destabilizes and is readily removed or spalls of, as soon as the content of the stabilizing phase decreases below a stability limit, especially during a temperature change, when being cooled down from reaction temperature.

More specifically, said ceramic part is a partially or fully stabilized oxide ceramic.

Especially, said partially or fully stabilized oxide ceramic is zirconia stabilized with a rare earth or an alkaline earth element or combinations thereof.

Preferably, said rare earth or alkaline earth element is one of Sc, Y, Sm, Mg, Ca, Ce, Ta or Sr.

According to another embodiment of the invention, said ceramic part contains an alkali silicate, alkali borosilicate, earth alkali silicate, earth alkali borosilicate or any of those compounds with the addition of a semimetal or metalloid, and that, during the process, the halogen attacks the Si containing phase, which results in dissolution and removal of the entire ceramic.

According to a further embodiment of the invention a joint layer is disposed between said metal part and said ceramic part, and that said halogen attacks said joint layer, such that said metal part and said ceramic part are separated from each other.

Specifically, said joint layer comprises a braze alloy and/or a mineral glue or a high temperature resistant cement.

According to another embodiment of the invention, said hybrid component is put in a reactor, which is heated to more than 850° C., preferably to more than 1000° C. but not more than 1150° C.

According to a further embodiment of the invention said process is conducted as a batch process to allow economic ceramic-metal separation for entire sets in very short time.

According to a just another embodiment of the invention the metal part and/or ceramic composite part is simultaneously cleaned in said process, such that it can be brazed without further cleaning or oxide removal and, in case no rework of the metal part is required, is immediately ready for joining with a new ceramic part, and/or the ceramic composite part cane be re-used.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention is now to be explained more closely by means of different embodiments and with reference to the attached drawings.

FIG. 1 shows different steps in a method for removing the ceramic part from a hybrid metal/ceramic component in a pulsed process in a reactor according to an embodiment of the invention; and;

FIG. 2 shows different steps in a method for separating the ceramic part from the metal part of a hybrid metal/ceramic component in a pulsed process in a reactor according to another embodiment of the invention.

DETAILED DESCRIPTION

FIG. 1 shows different steps in a method for removing the ceramic part from a hybrid metal/ceramic component in a pulsed process in a reactor according to an embodiment of the invention.

The process starts with a (simplified exemplary) hybrid component 10, which comprises a metal part 11 and a ceramic part 12, which are jointly connected at a connecting face 13 (FIG. 1(a)).

The hybrid component 10 is put into a reactor 15, which can be heated by means of a heater 14 (FIG. 2(b)). The inner space 24 of the reactor 15 can be filled with one or more gases through a gas supply line 18, which can be closed by means of valve 16. On the other hand, the inner space 24 can be pumped out or evacuated by means of pump 17 through a pumping line 19.

When the process begins at a low temperature T1 (e.g. room temperature), the reactor 15 is heated up to an elevated temperature T2, which is substantially higher than the temperature T1 (FIG. 1(c)).

Then, a first inert/reducing atmosphere A1 containing hydrogen (H₂) is established in the inner space 24 of the reactor 15 by introducing gas through gas supply line 18 (FIG. 1(d)).

By introducing a reactive halogen, e.g. F, in form of an HF gas, through gas supply line 18, a second reducing atmosphere A2 is established, which begins to destabilize the ceramic part 12 of the hybrid component 10 (FIG. 1(e)).The reactor 15 is operated in a pulsed mode, i.e. the reaction products are removed from the reactor 15 by pumping out the gas with pump 17 (FIG. 1(f)) and supplying fresh gas afterwards through gas supply line 18 (FIG. 1(g)). Several of such cycles (FIG. 1(f)→FIG. 1(g)→FIG. 1(f)→FIG. 1(g)) are done, until the ceramic part 12 is completely removed and the surface of the metal part 11 cleaned (FIG. 1(h)). In the following, some examples of the method according to the invention will be explained.

1. Example

Disassembly of a modular hybrid part, having a ceramic airfoil fabricated from yttria stabilized zirconia (YSZ) brazed to a load-carrying spar fabricated from an SX superalloy:

• • Aim: A set of modular hybrid parts shall be reconditioned, the ceramic portion requires replacement due to foreign object damage (FOD). The expensive metal part, which consists of an SX superalloy can be used for another service cycle;
  • Process: the parts are put in a reactor 15, which is heated to more than 850° C., preferably to more than 1000° C. but not more than 1150° C. To achieve a reducing atmosphere the reactor 15 is flooded with H₂. As reactive halogen, F is introduced as HF gas. The reactor 15 is operated in a pulsed mode, i.e. the reaction products are removed from the reactor 15 by pumping out the gas and supplying fresh gas afterwards. Several of such cycles are done;
  • Result: The gas readily destabilizes the YSZ, which disintegrates, the braze alloy interface is attacked and cleaned on the surface as well. Thus the complex-shaped joining surface of the metallic part with its tight tolerances is preserved without the need for further (mechanical) cleaning and is ready for being brazed to a new ceramic part. Additionally, the metal parts are simultaneously cleaned by this treatment, thus the cracks can be repaired without further preparation.

2. Example

Disassembly of a modular hybrid part, fabricated from a DS superalloy, with a ceramic portion on the pressure side of the trailing edge (cut-back trailing edge, e.g. shown in document WO 2010/028913 A1) fabricated from YSZ:

• • Aim: preserve the expensive DS component and replace only the worn trailing edge insert;
  • Process: the parts are put in a reactor 15, which is heated to more than 850° C., preferably to more than 1000° C. but not more than 1150° C. To achieve a reducing atmosphere the reactor 15 is flooded with H₂. As reactive halogen, F is introduced as HF gas. The reactor 15 is operated in a pulsed mode, i.e. the reaction products are removed from the reactor 15 by pumping out the gas and supplying fresh gas afterwards. Several of such cycles are done;
  • Result: the YSZ insert from the pressure side of the trailing edge is readily dissolved, the rest of the component is preserved and the surface is clean and ready for brazing a new insert into the trailing edge. Considering the fragile nature of the small joining surface, any mechanical cleaning process is prohibitive.

3. Example

Disassembly of a modular hybrid part, having a ceramic airfoil fabricated from YSZ which is attached to the root section using a bi-cast process, i.e. the parts are interlocked:

• • Aim: preserve the precision-machined root section and replace the airfoil, which was damaged by FOD;
  • Process: the parts are put in a reactor 15, which is heated to more than 850° C., preferably to more than 1000° C. but not more than 1150° C. To achieve a reducing atmosphere the reactor 15 is flooded with H₂. As reactive halogen, F is introduced as HF gas. The reactor 15 is operated in a pulsed mode, i.e. the reaction products are removed from the reactor 15 by pumping out the gas and supplying fresh gas afterwards. Several of such cycles are done;
  • Result: the YSZ is readily de-stabilized and disintegrated. Thus is can be removed from the interlocking features of the root. A replacement airfoil can be brazed to the cleaned root.

4. Example

Disassembly of a modular hybrid part, having a ceramic section fabricated from a ceramic matrix composite (CMC) comprising SiN fibres in a water-glass based matrix, which is attached using a mineral glue to a complex shaped superalloy section that includes channels for instrumentation and was build employing selective laser melting:

• • Aim: remove worn section but preserve expensive instrumented platform;
  • Process: the parts are put in a reactor 15, which is heated to more than 850° C., preferably to more than 1000° C. but not more than 1150° C. To achieve a reducing atmosphere the reactor 15 is flooded with H₂. As reactive halogen, F is introduced as HF gas. The reactor 15 is operated in a pulsed mode, i.e. the reaction products are removed from the reactor 15 by pumping out the gas and supplying fresh gas afterwards. Several of such cycles are done;
  • Result: while the ceramic SiN fibres resist the HF attack, the water-glass based matrix is strongly attacked, thus the CMC is readily removed from the expensive platform, which is cleaned at the same time and can be reused.

FIG. 2 shows different steps in a method for separating the ceramic part from the metal part of a hybrid metal/ceramic component in a pulsed process in a reactor according to another embodiment of the invention.

The process starts with a component 20, which comprises a metal part 21, which is joined with a ceramic part 22 by means of a joint layer 23 (FIG. 2(a)).

The component 20 is put into a reactor 15, which can be heated by means of a heater 14 (FIG. 2(b)). The inner space 24 of the reactor 15 can be filled with one or more gases through a gas supply line 18, which can be closed by means of valve 16. On the other hand, in the inner space 16 can be pumped out or evacuated by means of pump 17 through a pumping line 19.

The reactor 15 is heated up to a temperature T2, which is substantially higher than room temperature (FIG. 2(a)).

By introducing hydrogen and a reactive halogen, e.g. F, in form of an HF gas, through gas supply line 18, a reducing atmosphere A2 is established, which begins to destabilize the joint layer 23 of the component 20 (FIG. 2(a)).

The reactor 15 is operated in a pulsed mode, i.e. the reaction products are removed from the reactor 15 by pumping out the gas with pump 17 (FIG. 2(b)) and supplying fresh gas afterwards through gas supply line 18 (FIG. 2(c)). Several of such cycles (FIG. 2(b)→FIG. 2(c)→FIG. 2(b)→FIG. 2(c)) are done, until the joint layer 23 is completely removed and both parts 21, 22 are separated and the surface of metal part 21 cleaned (FIG. 2(d)).

5. Example

Disassembly of a modular hybrid part, having a ceramic airfoil fabricated from Al₂O₃ that is attached to the root section using a buffer layer (joint layer) which consists of porous YSZ:

• • Aim: preserve the precision-machined root section and replaced worn airfoil;
  • Process: the parts are put in a reactor 15, which is heated to more than 850° C., preferably to more than 1000° C. but not more than 1150° C. To achieve a reducing atmosphere the reactor 15 is flooded with H₂. As reactive halogen, F is introduced as HF gas. The reactor 15 is operated in a pulsed mode, i.e. the reaction products are removed from the reactor 15 by pumping out the gas and supplying fresh gas afterwards. Several of such cycles are done;
  • Result: In this case the airfoil, which consists of Al₂O₃ is only slowly attacked by the HF gas. However the porous buffer layer, which is fabricated from porous YSZ, dissolves readily in the HF gas, thus the Al₂O₃ airfoil can be easily detached from the metallic root section.

So the method offers a time efficient one step process for disassembly, cleaning, preparation for repair and joining of a hybrid metal/ceramic component, with the following characteristics:

• • Said process is used to separate a ceramic from a metal, e.g. separating ceramic parts from metallic parts of a modular hybrid gas turbine component.
  • The halogen attacks preferably the stabilizing phase within the ceramic body or section, thus after dissolving only a few percent of the ceramic, the amount of the stabilizing phase has decreased below the stability limit and the entire ceramic disintegrates. This enables a very efficient removal of the ceramic with a minimum of reactive species.
  • The halogen attacks and cleans the braze alloy/ceramic interface.
  • Said braze alloy attacks the mineral glue or cement used for joining ceramic and metallic parts together.
  • The process is a batch process, not a single piece process, which allows economic ceramic removal for entire sets in very short time.
  • A benefit is the simultaneous cleaning of the metal part, thus the metal part can be brazed without further cleaning or oxide removal and in case no rework of the metal part is required the part is immediately ready for joining with a new ceramic part. So the process offers a time efficient one step process for disassembly, cleaning, preparation for repair and joining.

Further examples of the method according to the invention relate to:

• • Abradables (conservation, cleaning of BC);
  • Preservation of a specific metallic surface texture;
  • Top layer from ceramic multi-layer coating (sacrificial surface sealing, EBC)
  • Cleaning of clogged effusion/transpiration cooling holes.

Claims

1. A method for separating a metal part from a ceramic part, which are joined at a connecting face within a modular hybrid component, especially of a gas turbine; the method comprising; said modular hybrid component is subjected to an inert/reducing atmosphere in a gaseous process at elevated temperatures to dissolve the connection between said metal part and said ceramic part.

2. The method according to claim 1, wherein said reducing atmosphere contains halogens as reactive species.

3. The method according to claim 2, wherein said halogens have a higher electronegativity than oxygen, on either Pauling Scale, Mulliken Scale or Allred-Rochow Scale.

4. The method according to claim 3, wherein said halogens comprise F.

5. The method according to claim 3, wherein said halogens comprise Cl.

6. The method according to claim 1, wherein said ceramic part itself is dissolved or disintegrated as a whole.

7. The method according to claim 6, wherein said ceramic part is a partially or fully stabilized ceramic, whereby, during the process, the stabilizing phase is removed by phase change from the ceramic, such that the entire ceramic destabilizes and is readily removed or spalls of, as soon as the content of the stabilizing phase decreases below a stability limit.

8. The method according to claim 7, wherein said ceramic part is a partially or fully stabilized oxide ceramic.

9. The method according to claim 8, wherein said partially or fully stabilized oxide ceramic is zirconia stabilized with a rare earth or an alkaline earth element or combinations thereof.

10. The method according to claim 9, wherein said rare earth or alkaline earth element is one of Sc, Y, Sm, Mg, Ca, Ce, Ta or Sr.

11. The method according to claim 6, wherein said ceramic part contains an alkali silicate, alkali borosilicate, earth alkali silicate, earth alkali borosilicate or any of those compounds with the addition of a semimetal or metalloid, and that, during the process, the halogen attacks the Si containing phase, which results in dissolution and removal of the entire ceramic.

12. The method according to claim 1, wherein a joint layer is disposed between said metal part and said ceramic part, and that said halogen attacks said joint layer, such that said metal part and said ceramic part are separated from each other.

13. The method according to claim 12, wherein said joint layer comprises a braze alloy and/or a mineral glue or cement.

14. The method according to claim 1, wherein said hybrid component is put in a reactor, which is heated to more than 850° C., preferably to more than 1000° C. but not more than 1150° C.

15. The method according to claim 1, wherein said process is conducted as a batch process to allow economic ceramic-metal separation for entire sets in very short time.

16. The method according to claim 1, wherein the metal part and/or ceramic composite part is simultaneously cleaned in said process, such that it can be brazed without further cleaning or oxide removal and, in case no rework of the metal part is required, is immediately ready for joining with a new ceramic part, and/or the ceramic composite part can be re-used.