This application claims priority to German Patent Applications DE102008005479.8, DE102008005480.1, and DE102008005482.8, all filed Jan. 23, 2008, the entirety of which is incorporated by reference herein.
The present invention relates to a gas turbine. More particularly, the present invention relates to a gas turbine with a compressor including at least one row of blades, with the blades having a free end each, with an abradable coating being provided adjacent to the free ends of the blades on an annular casing area and/or an annular drum area.
Modern axial-flow compressors include a rotor with at least one rotor blade row and a casing. The distance between this rotor blade row and the casing should be as small as possible to avoid efficiency losses. Abradable coatings are provided in the casing to avoid damage in the case of collision with the rotor blades. If such collision occurs, areas of the abradable coating will be removed.
Various attempts are known to optimize the gap behavior. Efforts have often been made to adapt the thermal behavior of the casing to that of the rotor by airflows, for example in Specification U.S. Pat. No. 7,086,233. Other solutions aim at minimizing the gap by mechanical methods.
The running gap between the rotor blades and the casing is influenced by various factors:
The latter factor is difficult to control.
With conventional abradable coatings, the gap is set such that, under normal operating conditions, the rotor blades will not, or only to a minimum extent, rub this abradable coating. This ensures a small gap under normal operating conditions. Under extreme operating conditions, the rotor blade may rub these abradable coatings more heavily, removing material therefrom.
Disadvantageously, there is a considerable gap between the rotor blades and the abradable coating even under normal operating conditions, affecting surge limit and efficiency.
It is a broad aspect of the present invention to provide a gas turbine and a method for the blades to rub the coating which, while being simply designed and featuring high efficiency, avoids the disadvantages of the state of the art and shows a high degree of operational safety.
In a first aspect, the present invention accordingly provides a liquid for sealing, with the thickness of the film preferably being in the decimillimeter range only.
Preferably, materials are used which are readily available, for example water produced during combustion or oil required for lubrication.
According to the first aspect, the present invention provides an abradable coating which itself is permeable to liquid, thereby generating, on the surface of the abradable coating, a liquid film which acts towards the free blade ends and optimizes the rubbing characteristics of the blades. Thus, with the free blade ends mating with the liquid film, direct contact with the abradable coating is avoided under certain operating conditions.
The first aspect of the present invention can be described as a gas turbine with a compressor including at least one row of blades, with the blades having a free end each, with an abradable coating being provided adjacent to the free ends of the blades on an annular casing area, with the abradable coating being connected to a liquid supply device and with the abradable coating being provided with liquid passages. In an advantageous development, it is here provided that
A method according to the first aspect of the present invention can be described as a method for the free end areas of the blades of a compressor of a gas turbine to rub the abradable coating, with the end areas being brought into contact with at least one, essentially annular abradable coating of an annular casing area, and with a liquid being applied to a surface of the abradable coating. In an advantageous embodiment, it is here provided that
In a second aspect, the present invention provides for the abradable coating being porous and suitable for the application of an air-hardening material.
The air-hardenable, or air-hardening, material is stored in an annular storage chamber or an annular storage reservoir. When the free ends of the compressor blades contact the surface of the annular casing area or the drum area, the air-hardening material is released and passed through the abradable coating. It travels through the abradable coating into the airflow of the annulus of the rotor (compressor) to harden thereupon.
The second aspect of the present invention can be described as a gas turbine with a compressor including at least one row of blades, with the blades having a free end each, with an abradable coating being provided adjacent to the free ends of the blades on an annular casing area, with the abradable coating being connected to a material supply device which contains air-hardening material, and with the abradable coating being provided with material passages. In an advantageous embodiment, it is here provided that
A method according to the second aspect of the present invention can be described as a method for the free end areas of the blades of a compressor of a gas turbine to rub the abradable coating, with the end areas being brought into contact with at least one, essentially annular abradable coating of an annular casing area, and with an air-hardening material being applicable to a surface of the abradable coating. Here, it is advantageously provided that silicone and/or another hardenable matter is used as air-hardenable material.
In a third aspect, the present invention provides for the abradable coating being porous and suitable for the application of a liquid. A self-healing layer is produced on the surface of the abradable coating by evaporation of the liquid.
The gap between rotor blades and abradable coating is, in accordance with the present invention, set such that the top layer is not damaged under normal operating conditions. If the rotor blades rub the top layer during an extreme maneuver, the top layer will be removed and the basic structure of the abradable coating exposed. Now, the self-healing process will start. Liquid is evaporated until a substance dissolved in the liquid deposits on the damaged surface, thereby reclosing the damaged top layer.
The third aspect of the present invention can be described as a gas turbine with a compressor including at least one row of blades, with the blades having a free end each, with an abradable coating being provided adjacent to the free ends of the blades on an annular casing area, with the abradable coating being connected to a liquid supply device, with the abradable coating being provided with liquid passages, and with the blade-facing topmost layer of the abradable coating being of liquid-impermeable material. Here, it is advantageously provided that
A method according to the third aspect of the present invention can be described as a method for the free end areas of the blades of a compressor of a gas turbine to rub the abradable coating, with the end areas being brought into contact with at least one, essentially annular abradable coating of an annular casing area, and with a blade-facing topmost layer being restored by evaporation of a liquid. Here it is advantageously provided that
The present invention is more fully described in light of the accompanying drawings showing three embodiments. In the drawings,
Free blade ends 16 of the rotor blades 11 and stator blades 18 mate, with minimum clearance, with the wall of a casing 9 or the rotor drum, respectively. In accordance with the present invention, an abradable coating 6 is here provided to enable the distance of the free blade ends to the surface of the casing 9 or the drum area 13, respectively, to be set by rubbing the coating.
The liquid is supplied via at least one feed tube 109 (
In accordance with the present invention, the base layer of the abradable coating 106 preferably is a porous, hygroscopic basic material or has capillaries to enable the liquid to exit at the surface. For positive adherence of the liquid to the surface 115, the latter should have properties which enlarge its surface area, e.g. be rough or grainy (see
In order to avoid excessive accumulation of liquid in the bottom area of the engine, a scavenge device is preferably provided there (
In an advantageous development, the present invention provides for an electrically conductive liquid to be used (for example the atoms/molecules of the liquid are electrically conductive, or addition of electrically conductive matter to an otherwise non-conductive liquid). In this case, adherence of the particles to the surface 115 can be promoted by electrical forces. An electrically conductive layer is additionally provided in the abradable coating 106 or, respectively, the abradable coating 106 itself is an electrically conductive material. This electrically conductive material is covered with an insulating layer to avoid direct contact with the electrically conductive liquid. A voltage is now applied to the electrically conductive layer. The particles of the liquid are attracted by the voltage, thereby improving their adherence to the surface.
The gap behavior of an engine is difficult to control. The present invention enables the rotor blades to run into the liquid under extreme operating conditions. Other than a firm abradable coating, the liquid can be continually replaced, thereby enabling a uniform and optimized gap to be set.
In accordance with a second embodiment of the gas turbine (
An abradable coating 206 is applied to an abradable coating carrier 204. The air-hardening material (hardening substance) can reach the abradable coating 206 via holes/openings 207 in the abradable coating carrier 204.
In accordance with the present invention, the base layer of the abradable coating 206 is a porous basic material or has minute tubes. A topmost layer 208 of the abradable coating 206, which faces the free blade ends 216, is impermeable to air and protects the air hardening material from exposure to air in the compressor. By use of a feed tube 217, pressurized air can be fed through the casing 209 into a chamber 210 and exert a pressure on the wall of the storage reservoir 202.
In accordance with the present invention, a gap between the rotor blades 11 (
The self-healing process provided by the present invention will now start. With a portion of the air impermeable layer worn through, exposing the permeable layer underneath, the air-hardening material (hardening substance), will be forced through the porous/permeable layer of the abradable coating 206 at this location of damage, come into contact with atmospheric oxygen of the compressor 12 and harden in the process, again sealing the air impermeable layer.
On a gas turbine according to the third embodiment (
However, the substances used according to the present invention can also be carried as stock or obtained from the ambient air.
In accordance with the present invention, carbon dioxide is dissolved in water, producing carbonic acid. The colder the water and the higher the pressure, the more carbon dioxide is soluble. Accordingly, the present invention also provides for setting up a circuit with pump and cooling of the water.
Lime is required in the subsequent process. In accordance with the present invention, the weakly carbonic-acidic water is fed over the lime, thereby converting the lime to water-soluble calcium hydrogen carbonate. The water, which contains calcium hydrogen carbonate, is now fed via a feed tube 317 on the casing 309. A chamber 310 provides for even distribution of the liquid. The abradable coating carrier 304 is here also used to the seal the chamber 310 against the annulus 5 (
In accordance with the present invention, the gap between the rotor blades 11 and the abradable coating 306 is set such that the top layer 308 is not damaged under normal operating conditions. If the top layer 308 is rubbed by the rotor blades 11 in an extreme maneuver, it will be worn off and the basic structure of the abradable coating 306 exposed. The self-healing process will now start. Water will be evaporated until a layer of lime deposits on the damaged surface, thereby reclosing the damaged top layer 308.
In accordance with the present invention, the base layer of the abradable coating 306 is of porous basic material or has minute tubes (capillaries).
In order to avoid excessive accumulation of liquid in the bottom area of the engine, a scavenge device is preferably provided there (
The gap behavior of an engine is difficult to control. The present invention provides for self-regeneration of the abradable coating and at least partial restoration of the running gap.
Number | Date | Country | Kind |
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10 2008 005 479 | Jan 2008 | DE | national |
10 2008 005 480 | Jan 2008 | DE | national |
10 2008 005 482 | Jan 2008 | DE | national |
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