KR101905759B1 - Temperature measuring apparatus of combustion chamber of gas turbine - Google Patents

Abstract

A combustion chamber temperature measuring apparatus of a gas turbine capable of directly measuring a combustion chamber temperature of a gas turbine and capable of accurately detecting a combustion state and a combustion characteristic of the combustion chamber is disclosed. An apparatus for measuring a combustion chamber temperature of a gas turbine includes an end cover mounted on a combustion chamber of a gas turbine, a fuel nozzle mounted on the end cover, disposed in the combustion chamber, a dummy nozzle and a temperature sensor disposed inside the combustion chamber along the inside of the dummy nozzle and measuring a temperature of the combustion chamber.

Description

TECHNICAL FIELD [0001] The present invention relates to an apparatus for measuring a combustion chamber temperature of a gas turbine,

The present invention relates to an apparatus for measuring the temperature of a combustion chamber of a gas turbine, and more particularly, to an apparatus for measuring a temperature of a combustion chamber of a gas turbine, which can directly measure the temperature of the combustion chamber of the gas turbine, .

The gas turbine means a rotary internal combustion engine that obtains a rotational force by expanding a high-temperature and high-pressure combustion gas to rotate the turbine.

Generally, in order to increase the operating efficiency of the gas turbine, it is necessary to accurately predict and confirm the state of the combustion chamber component of the gas turbine, and the precise state of the combustion chamber component of the gas turbine is determined by detecting the combustion state and combustion characteristics of the combustion chamber Able to know.

As one of the methods for detecting the combustion state and the combustion characteristic of the combustion chamber, there has been proposed a method of detecting the combustion state and the combustion characteristic of the combustion chamber by measuring the temperature of the combustion chamber.

One of the methods of measuring the temperature of the combustion chamber of a gas turbine is to measure the temperature of the exhaust gas that is burned and discharged by the exhaust duct of the gas turbine and calculate the swirl amount proportional to the gas turbine output value as a theoretical value Thereby measuring the temperature of the combustion chamber.

However, the method of detecting the temperature of the combustion chamber by measuring the temperature of the exhaust gas has a problem that it is difficult to accurately determine the ignition state of each combustion chamber while the plurality of combustors are simultaneously operated.

In other words, at the time of initial ignition of the gas turbine, there is a problem that the exhaust gas flow amount changes due to the increase of the rotational speed, so that it is difficult to recognize an accurate temperature for each of a plurality of combustion chambers. There is a problem that it is difficult to know exactly which combustion chamber the ignition failure occurred in, among the plurality of combustion chambers constituting the gas turbine. In addition, even if a fatal nozzle is damaged due to the back flame of the flame due to an unstable combustion state in each combustion chamber, there is a problem that it is difficult to detect it.

On the other hand, an end cover mounted on a combustion chamber of a gas turbine is equipped with a fuel nozzle to which fuel is supplied. In addition, a dummy nozzle, into which a core tube is inserted and an atomizing air is supplied, is inserted into the fuel nozzle.

However, the length of the dummy nozzle inserted into the core tube is always constant, even if the length of the core tube is slightly different due to assembly and manufacturing tolerances for each turbine. Therefore, if a length deviation occurs between the core tube and the dummy nozzle, In other words, if the distance between the core tube and the dummy nozzle tip is not constant, the amount of automassing air may become uneven and the dummy nozzle may be damaged.

Accordingly, in recent years, various studies have been made to directly measure the internal temperature of the combustion chamber and to prevent damage to the components of the combustion chamber, but there is still insufficient development and development thereof is required.

Korean Registered Patent No. 10-0552011 (2006.02.07 Announcement)

An object of the present invention is to provide a gas turbine combustion chamber temperature measuring apparatus capable of directly measuring the temperature of a gas turbine combustion chamber and accurately detecting a combustion state and a combustion characteristic of the combustion chamber.

It is still another object of the present invention to provide a combustion chamber temperature measuring apparatus capable of preventing damage to components of a combustion chamber and improving stability and reliability.

In particular, it is an object of the present invention to provide a combustion chamber temperature measuring apparatus capable of selectively varying the length of a dummy nozzle, and capable of maintaining a constant amount of automilling air by a dummy nozzle.

According to another aspect of the present invention, there is provided an apparatus for measuring the temperature of a combustion chamber of a gas turbine, the apparatus comprising: an end cover mounted on a combustion chamber of a gas turbine; A dummy nozzle inserted into the fuel nozzle, and a temperature sensor disposed inside the combustion chamber along the inside of the dummy nozzle, the temperature sensor measuring the temperature of the combustion chamber do.

Thus, by providing a temperature sensor along the inside of the dummy nozzle and directly measuring the temperature of the combustion chamber, it is possible to obtain an effect of accurately detecting the combustion state and the combustion characteristic of the combustion chamber.

In addition, since the temperature sensor can be individually mounted in each of the plurality of combustion chambers, even if the ignition failure occurs in any one of the plurality of combustion chambers, the combustion chamber in which the ignition failure has occurred, The combustion chamber can be accurately detected.

Further, by directly measuring the temperature of the combustion chamber, it is possible to quickly detect the back flame of the flame according to the unstable combustion state in each combustion chamber, thereby minimizing the damage of the fuel nozzle due to the back flame of the flame.

Further, the dummy nozzle is formed to be selectively adjustable in length within the fuel nozzle along the longitudinal direction of the fuel nozzle.

Since the length of the dummy nozzle can be selectively varied, the length of the dummy nozzle can be adjusted to match the length of the core tube (without any length deviation) even if a length deviation occurs between the core tube and the dummy nozzle. It is possible to obtain an effect of uniformly maintaining the micromilling air amount in a predetermined setting range.

Further, if the amount of automizing air by the dummy nozzle differs from the intended setting range, the dummy nozzle may be burned out. However, in the present invention, since the amount of automizing air by the dummy nozzle can be uniformly maintained in the predetermined setting range , It is possible to prevent the dummy nozzle from being burned and damaged in advance.

More specifically, the dummy nozzle includes a nozzle flange fixed to the end cover, and a nozzle pipe movably coupled to the nozzle flange along the longitudinal direction of the fuel nozzle and inserted into the interior of the fuel nozzle, The length of the dummy nozzle can be adjusted by moving the nozzle pipe with respect to the nozzle flange.

And a restricting portion for restricting the disposition position of the nozzle pipe relative to the nozzle flange.

Here, the restraint means restraint means for restraining the arrangement state of the nozzle pipe with respect to the nozzle flange without flowing, and the present invention is not limited or limited by the kind and structure of the restraint portion. For example, the restricting portion includes a first screw portion formed on one of the nozzle flange and the nozzle pipe, and a second screw portion formed on the other one of the nozzle flange and the nozzle pipe and fastened to the first screw portion. In some cases, the restricting portion may be composed of a combination of the restricting protrusion and the restricting groove, or may include a separate restricting member capable of fastening or coupling the nozzle pipe with respect to the nozzle flange.

Preferably, the nozzle pipe includes a pipe body inserted into the interior of the fuel nozzle, and a nozzle tip coupled to the tip of the pipe body and exposed to the combustion chamber.

In this way, since the nozzle pipe is constituted by two parts (pipe body, nozzle tip) separable from each other, it is possible to separate and replace only the nozzle tip from the pipe body without replacing the pipe body during maintenance and repair of the nozzle pipe It is possible to provide ease of maintenance and repair, and maintenance cost can be reduced.

Further, the dummy nozzle may include a closing member coupled to one end of the nozzle pipe outside the end cover. At this time, the closing member may be formed with a receiving portion for receiving one end of the nozzle pipe. In addition, a washer may be interposed between the nozzle flange and the closing member.

The temperature sensor is disposed along the inside of the nozzle pipe. By forming a cooling hole for cooling the temperature sensor on the nozzle pipe, it is possible to obtain an effect of preventing the temperature sensor from being overheated to a certain degree.

According to another aspect of the present invention, there is provided an apparatus for measuring the temperature of a combustion chamber of a gas turbine, the apparatus comprising: an end cover mounted on a combustion chamber of a gas turbine; A dummy nozzle inserted into the fuel nozzle, and a temperature sensor disposed inside the combustion chamber along the inside of the dummy nozzle, the temperature sensor measuring the temperature of the combustion chamber do.

Thus, by providing a temperature sensor along the inside of the dummy nozzle and directly measuring the temperature of the combustion chamber, it is possible to obtain an effect of accurately detecting the combustion state and the combustion characteristic of the combustion chamber.

In addition, since the temperature sensor can be individually mounted in each of the plurality of combustion chambers, even if the ignition failure occurs in any one of the plurality of combustion chambers, the combustion chamber in which the ignition failure has occurred, The combustion chamber can be accurately detected.

Further, by directly measuring the temperature of the combustion chamber, it is possible to quickly detect the back flame of the flame according to the unstable combustion state in each combustion chamber, thereby minimizing the damage of the fuel nozzle due to the back flame of the flame.

Further, the dummy nozzle is formed to be selectively adjustable in length within the fuel nozzle along the longitudinal direction of the fuel nozzle.

Since the length of the dummy nozzle can be selectively varied, the length of the dummy nozzle can be adjusted to match the length of the core tube (without any length deviation) even if a length deviation occurs between the core tube and the dummy nozzle. It is possible to obtain an effect of uniformly maintaining the micromilling air amount in a predetermined setting range.

Further, if the set range of the automizing air amount by the dummy nozzle is different, the dummy nozzle may be burned out. In the present invention, however, the amount of the automizing air by the dummy nozzle can be uniformly maintained in the predetermined setting range , It is possible to prevent the dummy nozzle from being burned and damaged in advance.

More specifically, the dummy nozzle includes a nozzle flange fixed to the end cover, and a nozzle pipe movably coupled to the nozzle flange along the longitudinal direction of the fuel nozzle and inserted into the interior of the fuel nozzle, The length of the dummy nozzle can be adjusted by moving the nozzle pipe with respect to the nozzle flange.

And a restricting portion for restricting the disposition position of the nozzle pipe relative to the nozzle flange.

Here, the restraint means restraint means for restraining the arrangement state of the nozzle pipe with respect to the nozzle flange without flowing, and the present invention is not limited or limited by the kind and structure of the restraint portion. For example, the restricting portion includes a first screw portion formed on one of the nozzle flange and the nozzle pipe, and a second screw portion formed on the other one of the nozzle flange and the nozzle pipe and fastened to the first screw portion. In some cases, the restricting portion may be composed of a combination of the restricting protrusion and the restricting groove, or may include a separate restricting member capable of fastening or coupling the nozzle pipe with respect to the nozzle flange.

Preferably, the nozzle pipe includes a pipe body inserted into the interior of the fuel nozzle, and a nozzle tip coupled to the tip of the pipe body and exposed to the combustion chamber.

In this way, since the nozzle pipe is constituted by two parts (pipe body, nozzle tip) separable from each other, it is possible to separate and replace only the nozzle tip from the pipe body without replacing the pipe body during maintenance and repair of the nozzle pipe It is possible to provide ease of maintenance and repair, and maintenance cost can be reduced.

Further, the dummy nozzle may include a closing member coupled to one end of the nozzle pipe outside the end cover. At this time, the closing member may be formed with a receiving portion for receiving one end of the nozzle pipe. In addition, a washer may be interposed between the nozzle flange and the closing member.

The temperature sensor is disposed along the inside of the nozzle pipe. By forming a cooling hole for cooling the temperature sensor on the nozzle pipe, it is possible to obtain an effect of preventing the temperature sensor from being overheated to a certain degree.

1 is a perspective view for explaining an apparatus for measuring a combustion chamber temperature of a gas turbine according to the present invention.
2 is a cross-sectional view illustrating an apparatus for measuring a combustion chamber temperature of a gas turbine according to the present invention.
3 and 4 are views for explaining the structure of a dummy nozzle, which is an apparatus for measuring a combustion chamber temperature of a gas turbine according to the present invention.
5 is a view for explaining the structure of a temperature sensor as an apparatus for measuring a combustion chamber temperature of a gas turbine according to the present invention.
FIGS. 6 and 7 are views for explaining a process of adjusting the length of a dummy nozzle, which is an apparatus for measuring a combustion chamber temperature of a gas turbine according to the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments. For reference, the same numbers in this description refer to substantially the same elements and can be described with reference to the contents described in the other drawings under these rules, and the contents which are judged to be obvious to the person skilled in the art or repeated can be omitted.

FIG. 1 is a perspective view for explaining an apparatus for measuring a temperature of a combustion chamber of a gas turbine according to the present invention, and FIG. 2 is a sectional view for explaining an apparatus for measuring a temperature of a combustion chamber of a gas turbine according to the present invention. 3 and 4 are views for explaining a structure of a dummy nozzle as an apparatus for measuring the temperature of a combustion chamber of a gas turbine according to the present invention, and FIG. 5 is an apparatus for measuring a temperature of a combustion chamber of a gas turbine according to the present invention, FIGS. 6 and 7 are views for explaining a process of adjusting the length of a dummy nozzle, which is an apparatus for measuring a combustion chamber temperature of a gas turbine according to the present invention.

1 to 7, an apparatus for measuring a combustion chamber temperature of a gas turbine according to the present invention includes an end cover 100 mounted to a combustion chamber of a gas turbine, And a dummy nozzle 300 inserted into the fuel nozzle 200. The dummy nozzle 300 is exposed to the inside of the combustion chamber along the inside of the dummy nozzle 300 and has a temperature And a temperature sensor 400 for measuring the temperature.

An end cover 100 is mounted to the combustion chamber of the gas turbine so as to be exposed to the outside. The shape and structure of the end cover 100 may be variously changed according to required conditions and design specifications, and the present invention is not limited or limited by the shape and structure of the end cover 100. For example, the end cover 100 may be formed in a substantially disc shape, and the end cover 100 may be equipped with a fuel nozzle 200 and other nozzles, pipes, and the like.

The fuel nozzle 200 is formed in the shape of a hollow tube and mounted on the inner surface of the end cover 100 so as to be disposed inside the combustion chamber to supply fuel to the inside of the combustion chamber.

In addition, a core tube 210 is closely inserted into the fuel nozzle 200, and fuel can be supplied along the inside of the core tube 210.

Referring to FIGS. 2 to 4, a dummy nozzle 300 is inserted into the fuel nozzle 200 and supplies atomizing air to the inside of the combustion chamber.

More specifically, the dummy nozzle 300 is inserted into the core tube 210 from the outside of the end cover 100 to pass through the end cover 100, and the tip end of the core tube 210 and the dummy nozzle 300 Automassing air can be supplied through the gap between the tips.

Preferably, the dummy nozzle 300 is formed to be selectively adjustable in length within the fuel nozzle 200 along the length of the fuel nozzle 200.

The dummy nozzle 300 is selectively length-adjusted in the fuel nozzle 200 along the longitudinal direction of the fuel nozzle 200. The dummy nozzle 300 is disposed in the fuel nozzle 200 along the longitudinal direction of the fuel nozzle 200 300 may optionally be lengthened or shortened.

As described above, according to the present invention, the length of the dummy nozzle 300 can be selectively changed, so that even if a length deviation occurs between the core tube 210 and the dummy nozzle 300, It is possible to adjust the length of the core tube 210 so that the length of the core tube 210 does not vary.

In the present invention, the amount of the automation air by the dummy nozzle 300 is set in advance, and the amount of air to be injected by the dummy nozzle 300 is set in advance. The dummy nozzle 300 can be uniformly maintained in the set range, so that it is possible to prevent the dummy nozzle 300 from being burned or damaged in advance.

More specifically, the dummy nozzle 300 includes a nozzle flange 310 fixed to the end cover 100 and a nozzle flange 310 movably coupled to the nozzle flange 310 along the longitudinal direction of the fuel nozzle 200, The nozzle pipe 320 is moved relative to the nozzle flange 310 in a state where the nozzle flange 310 is fixed to the end cover 100 to move the nozzle pipe 320 to the dummy nozzle 300 can be adjusted.

The nozzle flange 310 is fixed to the outer surface of the end cover 100 by a common fastening member such as a fastening bolt and the nozzle flange 310 is fixed to the end cover 100, Is inserted into the interior of the fuel nozzle 200 so as to pass through the nozzle flange 310 from the outside of the end cover 100.

The length of the dummy nozzle 300 in the fuel nozzle 200 can be adjusted by adjusting the arrangement position (moving distance) of the nozzle pipe 320 with respect to the nozzle flange 310. 7, as the nozzle pipe 320 moves in the direction toward the inside of the combustion chamber (the nozzle pipe rotates counterclockwise with respect to the nozzle flange) with respect to the nozzle flange 310, The length L1 of the dummy nozzle 300 may be long and the nozzle pipe 320 may be moved in the direction toward the outside of the dummy cover with respect to the nozzle flange 310 The length L2 of the dummy nozzle 300 in the fuel nozzle 200 can be reduced as the nozzle pipe rotates clockwise.

By allowing the position of the nozzle pipe 320 to be adjusted with respect to the nozzle flange 310 as described above, even when the length of the core tube 210 and the dummy nozzle 300 are varied, The length of the nozzle pipe 320 in the core tube 210 is adjusted to fit the core tube 210 so that the amount of the automation air by the dummy nozzle 300 can be maintained uniformly within a preset range.

The nozzle pipe 320 may include a restricting portion 330 for restricting the position of the nozzle pipe 320 relative to the nozzle flange 310.

The restricting portion 330 refers to a restricting means for restricting the disposition state of the nozzle pipe 320 with respect to the nozzle flange 310 without flowing. The invention is not limited or limited.

The restricting portion 330 may include a first screw portion 332 formed on one of the nozzle flange 310 and the nozzle pipe 320 and a second screw portion 332 formed on the other of the nozzle flange 310 and the nozzle pipe 320 And a second threaded portion 334 formed to be fastened to the first threaded portion 332. Hereinafter, a first screw portion 332 formed by a male screw is formed on the outer circumferential surface of the nozzle pipe 320, and a second screw portion 334 formed by a female screw is formed on the inner circumferential surface of the through hole formed in the nozzle flange 310 . In some cases, the restricting portion may be composed of a combination of the restricting protrusion and the restricting groove, or may include a separate restricting member capable of fastening or coupling the nozzle pipe with respect to the nozzle flange.

The nozzle pipe 320 preferably includes a pipe body 322 inserted into the fuel nozzle 200 and a nozzle tip 324 coupled to the tip of the pipe body 322 and exposed to the combustion chamber.

As described above, the present invention can be configured such that the nozzle pipe 320 is composed of two parts (the pipe body 322 and the nozzle tip 324) It is possible to separate and replace only the nozzle tip 324 from the pipe body 322 without needing to replace the nozzle tip 324, so that maintenance and repair can be easily provided and the maintenance cost can be reduced. In some cases, the nozzle pipe may be constituted by only one component, or may be constituted by three or more components that are detachable.

The dummy nozzle 300 may include a finishing member 340 coupled to one end of the nozzle pipe 320 at an outer side of the end cover 100.

As the closing member 340, various members coupled to one end of the nozzle pipe 320 and capable of concealing the closing member 340 can be used. For example, a screw cap screw cap may be used as the closure member 340.

The end of the nozzle pipe 320 may be received in the receiving part 352 so that the nozzle flange 332 may be inserted into the receiving part 352. [ Can be entirely concealed by the closure member 340 without being exposed to the outside of the container 310.

A washer 350 may be interposed between the nozzle flange 310 and the closure member 340 to prevent unintentional rotation of the pipe body 322 through the washer 350 . At this time, a conventional washer 350 may be used as the washer 350, and the present invention is not limited or limited by the type and characteristics of the washer 350.

Referring to FIG. 5, the temperature sensor 400 is exposed to the inside of the combustion chamber along the inside of the dummy nozzle 300, and measures the temperature of the combustion chamber.

More specifically, the temperature sensor 400 is inserted from the outside of the end cover 100 along the inside of the nozzle pipe 320 of the dummy nozzle 300 so as to pass through the end cover 100, Thereby directly measuring the temperature of the combustion chamber.

As the temperature sensor 400, various sensors capable of measuring the temperature of the combustion chamber may be used. At this time, it is preferable that the temperature sensor 400 is provided in a structure in which the length can be adjusted according to the required conditions and design specifications. In the vicinity of the tip of the temperature sensor 400, A stopper 404 (constrained to the nozzle tip of the nozzle pipe) may be formed to prevent the nozzle pipe from entering the nozzle pipe.

In addition, the tip 402 of the temperature sensor 400 directly exposed to the combustion chamber is preferably formed of a material that can withstand high temperatures. For example, the tip 402 of the temperature sensor 400 may be formed by adding 15% of chromium, 6 to 7% of iron, 2.5% of titanium, 1% or less of aluminum, manganese, As a heat resistant alloy, it can be formed of an inconel material excellent in heat resistance.

The temperature sensor 400 is disposed along the inside of the nozzle pipe 320 and a cooling hole 322 for cooling the temperature sensor 400 may be formed in the nozzle pipe 320.

(For example, cooling air) can be introduced through the cooling holes 322a and the temperature sensor 400 can be prevented from being overheated by a certain amount of cooling gas introduced through the cooling holes 322a .

At least one cooling hole 322a may be formed on the outer circumferential surface of the nozzle pipe 320 and the present invention is not limited or limited by the number and shape of the cooling holes 322a.

As described above, according to the present invention, the temperature sensor 400 is disposed along the inside of the dummy nozzle 300 and the temperature of the combustion chamber is directly measured, whereby the combustion state and the combustion characteristic of the combustion chamber can be accurately detected .

In addition, since the temperature sensor 400 can be individually mounted in each of the plurality of combustion chambers, even if ignition failure occurs in any one of the plurality of combustion chambers, the ignition failure It is possible to accurately detect which combustion chamber the generated combustion chamber is.

Further, by directly measuring the temperature of the combustion chamber, it is possible to quickly detect the back flame of the flame according to the unstable combustion state in each combustion chamber, thereby minimizing the damage of the fuel nozzle due to the back flame of the flame.

Although the preferred embodiments of the present invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims. It will be understood that the present invention can be changed.

100: end cover 200: fuel nozzle
210: core tube 300: dummy nozzle
310: nozzle flange 320: nozzle pipe
322: Pipe body 324: Nozzle tip
330: restraining portion 332: first screw portion
334: second screw part 340: closing member
350: Washer 400: Temperature sensor

Claims (11)

An apparatus for measuring a combustion chamber temperature of a gas turbine,
An end cover mounted to the combustion chamber of the gas turbine;
A fuel nozzle mounted on the end cover and disposed inside the combustion chamber;
A dummy nozzle inserted into the fuel nozzle; And
And a temperature sensor which is exposed to the inside of the combustion chamber along the inside of the dummy nozzle and measures the temperature of the combustion chamber,
Wherein the dummy nozzle is selectively formed in the fuel nozzle along the longitudinal direction of the fuel nozzle so as to be adjustable in length,
Wherein the dummy nozzle includes a nozzle flange fixed to the end cover and a nozzle pipe movably coupled to the nozzle flange along a longitudinal direction of the fuel nozzle and inserted into the fuel nozzle, Wherein the length of the dummy nozzle is adjustable by moving the nozzle pipe with respect to the nozzle flange while being fixed to the end cover. delete delete The method according to claim 1,
And a restricting portion restricting an arrangement position of the nozzle pipe with respect to the nozzle flange. 5. The method of claim 4,
The restraining portion
A first screw portion formed on one of the nozzle flange and the nozzle pipe; And
A second threaded portion formed on the other of the nozzle flange and the nozzle pipe and fastened to the first threaded portion;
Wherein the temperature of the combustion chamber is measured by the temperature sensor. The method according to claim 1,
And a closure member coupled to one end of the nozzle pipe at an outer side of the end cover. The method according to claim 6,
Wherein the finishing member is formed with a receiving portion for receiving one end of the nozzle pipe. The method according to claim 6,
And a washer interposed between the nozzle flange and the closure member. The method according to claim 1,
Wherein the temperature sensor is disposed along the inside of the nozzle pipe,
Wherein the nozzle pipe is provided with a cooling hole for cooling the temperature sensor. The method according to claim 1,
The nozzle pipe includes:
A pipe body inserted into the fuel nozzle; And
A nozzle tip coupled to a front end of the pipe body and exposed to the combustion chamber;
Wherein the gas turbine temperature measuring device comprises: The method according to claim 1,
A core tube is provided inside the fuel nozzle,
Wherein the dummy nozzle is inserted into the core tube.

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