CH697912B1 - Cooling circuit to improve turbine performance assets. - Google Patents

Abstract

In a gas turbine with a compressor discharge housing, a refrigeration cycle branches off compressor discharge air to a high pressure seal (HPP) circuit. The refrigeration cycle includes an inlet tube (14) receiving compressor discharge air. One or more cooled cooling air tubes (16) are in fluid communication with the inlet tube via a manifold (18) which distributes the discharge air to the cooled cooling air tubes. A seal (12) is placed upstream of an entrance into the HPP circuit to restrict flow into the HPP circuit, and a second seal is located downstream of the HPP circle on the turbine wheel space to provide the suction and thus the required purge stream air to limit. The circuit serves to reduce the required purge flow in the HPP loop so that a portion of the compressor discharge air may be directed back into the main flow path, thereby improving turbine performance.

Description

The invention relates to a structure and method for improving turbine performance, and more particularly to a refrigeration cycle that branches off compressor discharge air to assist all of the required sweep flow and to cool critical turbine components.

Compressor discharge air exiting behind the high pressure seal (HPP) of a gas turbine is typically returned to the primary gas path via the first front wheel space, between the first stage nozzles and blades. This secondary flow path is referred to as the high pressure seal circuit. This air is used for two purposes: <tb> (1) <sep> is used as purge flow in the first wheel space to prevent hot gas suction; and <tb> (2) <sep> cools critical components in the high pressure seal circuit.

Some of the critical components in the high pressure seal circuit include the compressor anchor bolts, the compressor-turbine connection, the nozzle support ring, and the first-stage wheel.

In some constructions, the flow level in the high pressure seal circuit is higher than the wheel flushing requirements due to component temperature requirements. An ideal solution, therefore, should reduce the total cycle flow to a level that meets the purge requirements, while keeping all critical components in the circuit below the desired temperature requirements. In addition, a preferred solution can handle stifling environmental and turbine operating conditions in a robust manner. Finally, the solution should also be able to be retrofitted to existing systems.

In an existing turbine design by General Electric (the 9H turbine), a high pressure seal circuit uses a bypass system for cooled cooling air. The circuit uses a heat exchanger to cool the discharged compressor discharge air and direct the cooled cooling air upstream of the high pressure seal circuit to not only cool the components of the last stages of the compressor, but also to prevent the flow of one of the last stages from entering the high pressure seal circuit High pressure sealing circle arrives. This system uses a conventional gasket and does not attempt to regulate the purge flow required behind conventional angle vane gaskets. The cooled cooling air can not be regulated.

Brush seals have been implemented in other turbine designs to reduce purge flow. However, there is no need for cooled cooling air due to lower compressor discharge temperatures and consequently lower temperatures in the high pressure seal circuit resulting in corresponding wheel room temperature tolerances.

Brief description of the invention

In an exemplary embodiment, a refrigeration cycle in a gas turbine is used to increase the flow in a high pressure seal (HPP) cycle of the turbine. The refrigeration cycle includes an inlet tube receiving compressor discharge air and at least one cooled cooling air tube in fluid communication with the inlet tube via a manifold. The manifold distributes the compressor discharge air to the at least one cooled cooling air tube. An upstream seal is disposed upstream of an entrance into the high pressure seal circuit, and a downstream seal is disposed downstream of the high pressure seal circle.

In another exemplary embodiment, a method of improving gas turbine performance using a refrigeration cycle by increasing flow in a high pressure seal (HPP) cycle of the turbine includes the steps of receiving the compressor discharge air in an intake manifold; that the compressor discharge air is distributed to a plurality of cooled cooling air pipes; and placing an upstream seal upstream of an entrance into the high pressure seal circuit to regulate the air entering the high pressure seal circuit, and placing a downstream seal downstream of the high pressure seal circle to regulate the need for wheel room scavenging air.

Brief description of the drawings

[0009] <Tb> FIG. 1 <sep> shows the refrigeration cycle of an exemplary embodiment; and <Tb> FIG. 2 <sep> shows the refrigeration cycle of an alternative exemplary embodiment.

Detailed description of the invention

With reference to FIG. 1, the system employs a gasket 12, such as a brush seal, adjustable gasket, or the like, to prevent excessive flow from the compressor discharge air and secondary (or bypass) cooled air cooling system, and so on to deliver all the required purge flow and to cool critical components. An adjustable seal may be a seal that is retracted in the course of engine transition conditions to minimize wear or damage to the seal, or a seal that allows adjustment during maintenance to compensate for wear of the seal during operation.

The seal is upstream or adjacent to the entrance in the high pressure sealing circuit before all critical components and arranged in front of the existing honeycomb seal. As already mentioned, the seal may be a conventional brush seal, an adjustable seal with a positioning system or the like.

An inlet pipe 14 is arranged to receive compressor discharge air. Preferably, the circle includes two inlet tubes 14 of about 76,2 mm (3 ") diameter.

Dedicated air in the inlet pipe 14 flows through a manifold 18 to a plurality of cooled cooling air tubes 16. The manifold 18 distributes the discharge air from the inlet tubes 14 to the cooled cooling air tubes 16. The cooled cooling air tubes 16 conduct the Compressor discharge air to the high pressure seal circuit.

In a preferred arrangement, the refrigeration cycle includes twelve cooled cooling air tubes which penetrate the vertical flange of the compressor discharge casing and extend along the strut of the compressor discharge casing at the trailing edges. The cooled cooling air tubes are preferably 19.05 mm or 25.4 mm (3/4 "or 1") in diameter. The positioning above the struts of the compressor discharge housing serves to minimize the aerodynamic influence on the main gas flow. A computer-aided analysis of fluid dynamics has been performed to ensure that the additional piping system has only a negligible impact on the main gas flow. The tubes 16 further penetrate via suitable openings 30 the flange of the inner drum of the Kompressorentladegehäuses.

The circuit preferably additionally includes a cooling source in communication with either the inlet tube 14 or the cooled cooling air tubes 16 or both. In one arrangement, the cooling source includes ambient air that serves to cool the airflow as it flows through the cooled cooling air tubes 16. Alternatively, the cooling source may include a heat exchanger 20 such as a tube-bundle type heat exchanger or the like.

Yet another alternative for the cooling source is an atomizer 22 which brings water droplets into contact with either the compressor discharge air or the cooled cooling air tubes 16 by spraying. The atomizer 22 preferably produces water droplets of microscopic dimension, which are sprayed directly to cool the extracted air. The amount of water required to cool the flow by 65.55 ° C (150 ° F) increases the moisture content of the main gas path stream by only 2%. Locally in the high pressure seal circuit, the specific humidity will typically be four to five times that of the inlet. This higher humidity is generally harmless to the circuit components.

Fig. 2 illustrates an alternative to the heat exchanger 20 or atomizer 22 shown in Fig. 1. Fig. 2 illustrates an ejector 24 which mixes air from the 13th stage of the compressor, or air from another suitable compressor discharge opening, with the compressor discharge air. The 13th stage air is directed to the ejector via suitable tubing 26 or the like. The combination of 13th stage air and compressor discharge air at the ejector outlet has a desired temperature and lower pressure than the compressor discharge air. Since relatively less expensive air from stage 13, more cost effective in the sense that less work has been done to compress and heat that air, is used, additional turbine power can be gained.

The exit temperature and mass flow may be adjusted by a valve 28 interposed between the inlet tube 14 and the cooled cooling air tubes 16. An additional valve may be provided to control the amount of water when using the nebulizer 22. The two valves can be operated either manually or automatically by control signals. Preferably, the valves may be automatically adjusted to the desired mass flow and temperature of the cooled cooling air based on a temperature measurement on the high pressure seal circuit. Such valves can be used to regulate the GKL circuit regardless of the cooling mechanism used. These valves should be controlled based on temperature measurements made in the high pressure seal circuit; these are typically made at multiple positions in the wheelspace, but may also be at any critical locations in the high pressure seal circuit. Temperature measurements can be used to detect both sufficient cooling of the cooling air and hot gas suction into the wheelspace.

The cooled cooling air pipes 16 supply the cooling air to various positions relative to the high pressure sealing circuit. As shown in Figures 1 and 2, it is preferable to have openings 30 in the inner drum to supply cooled cooling air to the anchor bolts and the turbine connecting flange to the compressor in the turbine. The remaining part of the GKL is led directly into the first front wheel space.

The system and method described herein attempt to conserve the amount of compressor discharge air required in the high pressure seal circuit and to redirect it back into the main flow path to improve turbine performance. This can be achieved in a robust manner by introducing a secondary flow system to bring cooled cooling air into the circuit. The amount of total flow required in the circuit is dictated by the purge cycle demand. The difference between the wheel purge requirement and the current flow is sufficient to justify the implementation of the secondary circuit for cooled cooling air. A seal limits the air entering the high pressure seal circuit to the minimum possible so that as much of the required purge air is supplied by the cooled cooling air circuit. An improved seal on the wheel space by means of wearable angle wing seals reduces the amount of purging air required. The mixture of compressor discharge air and cooled cooling air should be sufficient to prevent hot gas suction into the wheel space while at the same time maintaining the critical components in the circuit below certain temperature limits.

Although the invention has been described in conjunction with what is presently believed to be the most practical and preferred embodiments, it is to be understood that the invention is not to be limited to the disclosed embodiments, but to the contrary, various modifications and equivalents of the order and the scope of the appended claims.

Claims (10)

A refrigeration cycle in a gas turbine for increasing the flow in a high pressure sealing circuit of the gas turbine, the refrigeration cycle comprising: an inlet pipe (14) receiving compressor discharge air; at least one cooled cooling air tube (16) in fluid communication with the inlet tube (14) via a manifold (18), the manifold (18) distributing the compressor discharge air to the at least one cooled cooling air tube (16); an upstream seal disposed upstream of an entrance into the high pressure seal circuit; and a downstream seal disposed downstream of the high pressure seal circle. The refrigeration cycle of claim 1, further comprising a cooling source (20, 22, 24) in communication with the at least one cooled cooling air tube (16). 3. Cooling circuit according to claim 2, wherein the cooling source (20, 22, 24) comprises ambient air. 4. Cooling circuit according to claim 2, wherein the cooling source (20, 22, 24) comprises a heat exchanger (20). The refrigeration circuit of claim 2, wherein the cooling source (20, 22, 24) comprises an atomizer (22) for spraying water droplets with either the compressor discharge air or the at least one cooled cooling air pipe (16) by spraying. 6. The cooling circuit of claim 2, wherein the cooling source (20, 22, 24) comprises an ejector (24) which mixes air from at least two compressor stages including the Kompressorentladeluft. A refrigeration cycle according to any one of the preceding claims, wherein the at least one cooled cooling air duct (16) penetrates a vertical flange of the compressor discharge casing and extends along trailing edges of a strut of the compressor discharge casing. The refrigeration cycle of any one of the preceding claims, further comprising a valve (28) interposed between the inlet tube (14) and the at least one cooled cooling air tube (16), the valve (28) having the mass flow and a temperature of the compressor discharge air the basis of a temperature of the high pressure sealing circle sets. The refrigeration cycle of any one of the preceding claims, further comprising openings (30) in an inner drum for allowing cooled cooling air from the at least one cooled cooling air pipe (16) to include at least one of an anchor bolt and a flange of the gas turbine engine connection reached the compressor in the gas turbine. 10. A method of improving turbine performance using a refrigeration cycle by increasing flow in a high pressure seal circuit of the gas turbine, the method comprising the steps of: that compressor discharge air is received in an inlet pipe (14); that the compressor discharge air is distributed to a plurality of cooled cooling air pipes (16); and placing an upstream seal upstream of an entrance into the high pressure seal circuit to regulate the air entering the high pressure seal circuit; and placing a downstream seal downstream of the high pressure seal circuit to regulate the need for wheel room scavenging air.