KR102141894B1 - A device of temperature sensor for gas turbine with the increased function of radiant heat - Google Patents

Abstract

The present invention relates to a temperature sensor apparatus for a gas turbine with an increased heat dissipation function. An object of the present invention is to provide the temperature sensor apparatus for the gas turbine capable of dissipating heat transferred from a portion coupled to a gas turbine casing to the maximum. The present invention relates to the temperature sensor apparatus for the gas turbine with the increased heat dissipation function, comprising: a temperature sensor rod inserted into a well formed in the gas turbine casing; a well coupling unit which has a predetermined length and wherein one side thereof is coupled to the inner surface of the well in a status that the temperature sensor rod is passed through the same; and a heat dissipation unit formed while surrounding the outer peripheral surface of the well coupling unit.

Description

A device of temperature sensor for gas turbine with the increased function of radiant heat

The present invention relates to a temperature sensor device for a gas turbine with an increased heat dissipation function, in a state in which a temperature sensor device is mounted on a well formed in a gas turbine casing to measure the temperature inside the gas turbine, through the well from inside the gas turbine. It relates to a temperature sensor device for a gas turbine in which a heat dissipation portion is formed in a well coupling portion to minimize measurement error or damage to the temperature sensor device by heating to a portion located outside the gas turbine casing due to flowing hot gas. .

Unlike gas turbines that use high-temperature steam as a working fluid, gas turbines used in combined cycle power plants expand the high-temperature and high-pressure gas heated in the combustor to extract rotating mechanical energy to turn the compressor and generator shaft with its power, or to use the available power. It is a device to get.

In the case of a combined cycle power plant, the temperature of the gas turbine is around 650℃, and the gas turbine casing is equipped with a temperature sensor device radially to detect the temperature inside the turbine, and when the temperature deviation varies by more than a predetermined temperature Turbine rotation is caused by non-uniform rolling and expensive equipment is damaged, so the operation of the turbine is set to stop automatically. Such a gas turbine operation interruption causes not only power generation loss due to power generation stop but also enormous economic loss in restarting. do.

In order to take measures before the temperature deviation increases, the gas turbine casing is equipped with a temperature sensor device.

On the other hand, in general, a thermocouple type temperature sensor device is a temperature sensor device that measures temperature by using electromotive force generated by the Seebeck effect when heating or cooling the junction of two different types of thermocouple metals. to be.

Since the thermocouple type temperature sensor device can measure a wide range of temperatures from cryogenic temperatures to high temperatures of about 3000° C. depending on the type of thermocouple metal, it is widely used in various industrial temperature measurements throughout the industrial field, especially the above-mentioned. It is also used as a temperature sensor device for gas turbines.

Look at Korean Utility Model Registration No. 20-0309999, which is a prior art.

The prior art relates to a temperature sensor device used in a gas turbine, etc. In particular, it is configured to prevent detachment of a hot gas blocking portion provided in the sensor bar and to prevent damage to the sensor bar by a fastening means, thereby improving the safety of the temperature sensing device itself. It relates to a temperature sensor device for a gas turbine that improves and prevents a power generation stop accident due to a temperature sensing device problem.

However, despite the fact that the temperature sensor device is mounted as a well formed in the gas turbine casing, and further, the hot gas blocking part is formed in the temperature sensor device, and the hot gas is blocked due to the well coupling part that is in close contact with the outer surface of the gas turbine casing, it is still As the flow of hot gas through the well is heated by heat transfer to a portion located outside the gas turbine casing, an error occurs in the temperature sensing or damage to the lead wire occurs as the lead wire of the temperature sensor device is heated. The problem remains.

Therefore, there is an urgent need for a technical means capable of dissipating heat as much as possible to a portion coupled to a well of a gas turbine casing.

In order to solve the problem that the temperature sensing error or lead wire is damaged due to heat transfer to the outside of the gas turbine casing according to the above-described prior art, in order to minimize heating by heat transferred to the outside of the gas turbine casing, the gas turbine An object of the present invention is to provide a temperature sensor device for a gas turbine capable of dissipating heat transferred from a portion coupled to a casing as much as possible.

Furthermore, it is intended to provide a temperature sensor device for a gas turbine that can withstand vibrations caused by the operation of the gas turbine and at the same time has an increased heat dissipation effect.

The gas sensor temperature sensor device according to the present invention for solving the problems according to the prior art, the temperature sensor rod 200 is inserted into the well 120 formed in the casing 100 of the gas turbine; In the state in which the temperature sensor rod 200 is penetrated, one side of the well coupling portion 300,500 having a constant length coupled to the inner surface of the well 120; And a heat dissipation part 400,600 formed while surrounding the outer circumferential surface of the well coupling part 300,500.

Preferably, the heat dissipation part 400 is composed of a plurality of heat dissipation fins extending from the outer circumferential surface of the well coupling part 300.

Preferably, the well coupling portion 500, one side is inserted into the well 120, the shear coupling portion 520 is fastened to the inner surface of the well 120; And a rear end coupling portion 540 coupled to the shear coupling portion 520 as the shear coupling portion 520 is inserted or inserted into the shear coupling portion 520,

The heat dissipation unit 600, the rear end heat-dissipating body 620 is formed to surround the outer circumferential surface of the rear end coupling part 540 is coupled as one side of the rear end coupling part 540 is inserted; And a plurality of rear heat dissipating fins 640 formed extending from the rear heat dissipating body 620.

Preferably, the rear end coupling portion 540 is made of stainless steel, and the rear end heat dissipation body 620 and the rear end heat dissipation pin 640 are made of aluminum.

Preferably, the rear end coupling portion 540 is inserted into the rear end heat dissipating body 620, the rear end heat dissipating portion 544; And a rear end body portion 546 extending in a stepped form from the rear end heat dissipation coupling portion 544 and coupled to the front end coupling portion 520,

The rear end heat dissipating body 620 is positioned at regular intervals from the rear end body part 546 in a state coupled to the rear end heat dissipation coupling part 544, so that the rear end heat dissipating body 620 and the rear end heat dissipating body 546 ), a constant space 550 is formed.

According to the above-described problem solving means, as the heat-dissipating portion of an aluminum material having an excellent heat dissipation effect is formed in the well-coupled portion coupled to the well of the gas turbine casing, heat transferred through the well is dissipated as much as possible from the well-coupled portion for temperature sensing. Errors such as errors or lead wires can be minimized.

Furthermore, the body portion of the well coupling portion is made of stainless steel and can withstand vibrations caused by the operation of the gas turbine.

1 is a view schematically showing a temperature sensor device for a gas turbine according to the present invention.
2 is a view showing a state in which a temperature sensor device for a gas turbine according to the present invention is inserted into a well formed in a gas turbine casing.
3 to 5 are views showing the first to third embodiments of the heat dissipation unit in the gas turbine temperature sensor device according to the present invention.

Hereinafter, preferred embodiments of the method according to the present invention will be described with reference to the accompanying drawings. In this process, the thickness of lines or the size of components shown in the drawings may be exaggerated for clarity and convenience. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or practice. Therefore, the definition of these terms should be made based on the contents throughout the present specification.

Components common to each embodiment will be described with reference to FIGS. 1 to 5.

The temperature sensor device for a gas turbine according to the present invention includes a temperature sensor rod 200, a well coupling part 300,500, a heat dissipation part 400,600, a tension holding part 700, and a connector part 800.

The temperature sensor rod 200 is inserted into the well 120 formed in the gas turbine casing 100 to sense the inner temperature of the gas turbine while one end of the temperature sensor rod 200 is located inside the gas turbine.

One end of the temperature sensor rod 200 may be formed with a diameter larger than the diameter of one end, and a hot gas blocking portion 222 may be formed. The hot gas blocking portion 222 may be seated on the stepped portion formed in the well 120 near the inside of the gas turbine in the state inserted into the well 120. Due to the hot gas blocking portion 222 seated on the stepped portion formed in the well 120, the flow of hot gas flowing from the inside of the gas turbine through the well 120 to the outside can be minimized.

In a state in which a hot gas blocking portion 222 is not formed near one end of the temperature sensor rod 200, the temperature sensor rod 200 is inserted into the well 120 and one side of the well coupling portion 300,500 is a well 120 ) As it is coupled to the inner surface of the gas turbine, it is of course possible to block the flow of hot gas flowing out through the well 120.

The temperature sensor rod 200 penetrates inside the well coupling parts 300 and 500. The temperature sensor rod 200 is inserted into the well 120 in a state of being penetrated inside the well coupling portions 300 and 500. In the state where the well coupling parts 300 and 500 are coupled to the inner surface of the well 120 formed near the outer surface of the gas turbine casing 100, the gas turbine of the well 120 is due to the coupling of the well coupling parts 300 and 500. The passage to the outside of the casing 100 is blocked. As described above, the hot gas flow is blocked.

The heat dissipation units 400 and 600 may be formed while auditing the outer circumferential surfaces of the well coupling units 300 and 500. Due to the hot gas flowing into the well 120, heat transferred to the well coupling parts 300 and 500 located outside the gas turbine casing 100 dissipates heat.

The tension holding part 700 may be coupled to the other side of the well coupling parts 300 and 500. In a state in which an elastic member is positioned between the well coupling parts 300 and 500 and the tension holding part 700, the tension holding part 700 may be fixedly coupled to the other side of the well coupling parts 300 and 500. In the state where the tension holding portion 700 is coupled to the other side of the well coupling portion 300,500 and the well coupling portion 300,500 is coupled to the inner surface of the well 120, the temperature sensor rod 200 due to the elastic force of the elastic member In the state inserted into the well 120, the state in which the gas turbine is advanced to the inside can be maintained. One end of the temperature sensor rod 200 is positioned at a certain position inside the gas turbine, thereby minimizing the possibility of sensing error due to one end of the temperature sensor rod 200 being moved or out of a certain range.

In a thermocouple type temperature sensor device generally used to measure the temperature of a gas turbine, a pair of thermocouple metals are located inside the temperature sensor rod 200, and a wire is connected to the pair of thermocouple metals. The lead wire is connected to the cable of the thermocouple terminal box that displays the temperature value by calculating the temperature sensed by the temperature sensor rod 200.

In the connector unit 800, the above-described cables and conductors are connected.

Referring to Figure 3 will be described a first embodiment according to the organic coupling of the well coupling portion 300,500 and the heat dissipation portion 400,600 in the gas sensor temperature sensor device according to the present invention.

The well coupling part 300 is formed by extending from the well insertion coupling part 320 and the well insertion coupling part 320, which are inserted into and coupled to the inner surface of the well 120, but the well insertion coupling part 320 is a well 120 ) In close contact with the outer surface of the gas turbine casing 100 in the state of being inserted into the inner surface of the contact portion 340, the contact portion 340 extending to the body portion 360 and the tension formed portion 700 formed in a constant length ) May be coupled to the tension retention coupling portion 380 is coupled.

The well insertion and coupling portion 320, the contact portion 340, the body portion 360, and the tension maintaining coupling portion 380, of course, may be one body, and therefore, as a body when manufacturing the well coupling portion 300 Of course, it can be manufactured.

The heat dissipation part 400 may be formed to surround the outer peripheral surface of the body part 360. The heat dissipation part 400 may be a plurality of heat dissipation fins extending from the outer circumferential surface of the well coupling part 300.

The well coupling part 300 needs to be made of a material having a strength capable of withstanding vibration according to the operation of the gas turbine in the state coupled to the well 120. Therefore, the well coupling portion 300 is preferably made of stainless steel. Of course, materials of similar strength to stainless steel are also possible.

The heat dissipation unit 400 is a material that dissipates heat, and is preferably a material having a high heat dissipation effect, for example, an aluminum material. However, according to the first embodiment, the heat dissipation part 400 may be a plurality of heat dissipation fins formed extending from the outer circumferential surface of the well coupling part 300, and the heat dissipation part 400 and the well coupling part 300 are manufactured. It can only be made of one body, and thus the heat dissipation part 400 may be made of the same material as the well coupling part 300. The well coupling portion 300 is preferably a stainless steel material capable of sufficiently withstanding vibrations caused by the operation of the gas turbine. Accordingly, the heat dissipation unit 400 may also be made of stainless steel.

Referring to Figure 4 will be described a second embodiment according to the organic coupling of the well coupling portion 300,500 and the heat dissipation portion 400,600 in the gas sensor temperature sensor device according to the present invention.

In this embodiment, unlike the first embodiment, the well coupling portion 500 may be a stainless steel material or a material having a higher strength, and the heat dissipation portion 600 may be an aluminum material having excellent heat dissipation effect. Therefore, it is preferable that the well coupling part 500 and the heat dissipation part 600 are separately manufactured and assembled rather than being manufactured as one body. This is to maximize the effect of dissipating heat transferred through the well 120 while being able to withstand vibrations caused by the operation of the gas turbine.

The well coupling part 500 may be composed of a front end coupling part 520 and a rear end coupling part 540 which is inserted into the front end coupling part 520 or coupled as the front end coupling part 520 is inserted.

Specifically, the shear coupling portion 520 is formed by extending from the well insertion and coupling portion 522, which is inserted into and coupled to the inner surface of the well 120, and the well insertion and coupling portion 522, but the well insertion and coupling portion 522 is well In the state inserted into the inner surface of (120), the contact portion 524, which is in close contact with the outer surface of the gas turbine casing 100, extends to the contact portion 524, and the front end body portion 526 formed in a constant length and rear end coupling It may include a front end insertion portion 528 is inserted into one side of the portion 540 or the rear end coupling portion 540 is inserted and coupled.

Furthermore, a shear heat dissipation portion 527 formed of a plurality of heat dissipation fins may be formed on the outer circumferential surface of the shear body portion 526. The heat transferred to the front end body portion 526 is dissipated by the front end heat dissipation portion 527.

As described above, the well coupling portion 500 should be a material that can sufficiently withstand vibrations caused by the operation of the gas turbine, and the shear coupling portion 520 should also be made of this strength. Preferably, the material of the shear coupling portion 520 may be made of stainless steel.

The shear-dissipating portion 527 formed on the outer circumferential surface of the shear-coupling portion 520 may be manufactured as a body with the shear-coupling portion 520, and the shear-dissipating portion 527 may also be made of stainless steel.

The rear end coupling part 540 is a stepped shape with a larger diameter in the rear end body part 546 and the rear end body part 546 in which the above-described front end insertion part 528 is inserted or inserted in the front end insertion part 528. It is extended to be described later is inserted into the rear end heat-dissipating body 620 is coupled to the rear end heat dissipation unit 544, the rear end heat dissipation coupling unit 544 is formed extending from the above-described tension holding portion 700 is coupled to maintain tension It may include a portion 542.

Further, in the rear end body portion 546, the above-described shear insertion coupling portion 528 is coupled to the tanned bolt hole 547 may be formed. When the front end insertion coupling portion 528 is inserted and coupled to the rear end body portion 546, the front end insertion coupling portion 528 and the rear end body portion 546 are increased by inserting the head bolt into the headless bolt hole 547 I can do it.

The heat dissipation part 600 is coupled to the rear end heat dissipation coupling part 544 of a constant length formed on one side of the rear end coupling part 540. Specifically, the rear end heat dissipation coupling portion 544 of a certain length may be coupled in the state inserted into the rear end heat dissipation body 620 of the heat dissipation portion 600.

A plurality of rear heat-radiating fins 640 may be formed extending from the rear heat-radiating body 620.

In the second embodiment, as the heat dissipation part 600 and the well coupling part 500 are not manufactured as one body and can maintain an organic coupling relationship by assembling, well coupling to withstand vibrations caused by the operation of the gas turbine The unit 500 is made of stainless steel or a material having similar strength, and the heat dissipation unit 600 which is separately assembled to the well coupling unit 500 to increase the heat dissipation effect does not require the strength of stainless steel, so the heat dissipation effect is Of course, it can be made of an excellent aluminum material.

Accordingly, it is possible to increase the heat dissipation effect while withstanding vibration caused by the operation of the gas turbine.

Furthermore, the rear end body portion 546 extends in a stepped form from the rear end heat dissipation coupling portion 544, and may be extended to a diameter smaller than the diameter of the rear end heat dissipation coupling portion 544. Accordingly, as the rear end heat dissipating body 620 is extended from the rear end heat dissipating coupling part 544 to the rear end heat dissipating body part 546 as it is coupled to the rear heat dissipation coupling part 544, the rear end heat dissipating body 620 of the rear heat dissipation body 620 A constant space 550 may be formed between the inner surface and the outer surface of the rear end body portion 546.

The air layer is formed in the constant space 550 and heat transferred to the rear body portion 546 is radiated to the air layer formed in the constant space 550, and then radiated to the rear heat-radiating body 620 and the rear heat-dissipating fin 640. As a result, the heat dissipation effect is increased.

As a result, the effect of heat dissipation is increased by the heat dissipation part 600 made of aluminum while resisting vibration with the front end engagement part 520 and the rear end engagement part 540 made of stainless steel.

Referring to Figure 5 will be described a third embodiment according to the organic coupling of the well coupling portion 300,500 and the heat dissipation portion 400,600 in the temperature sensor device for a gas turbine according to the present invention.

As in the second embodiment, the well coupling portion 500 is composed of the front end coupling portion 520 and the rear end coupling portion 540, and the heat dissipation portion 600 is positioned while surrounding the outer circumferential surface of the rear end coupling portion 540. .

The shear coupling portion 520 is formed by extending from the well insertion and coupling portion 522, the well insertion and coupling portion 522 is inserted into the inner surface of the well 120, but the well insertion and coupling portion 522 is a well 120 ) Inserted into one side of the rear end coupling portion 540 or extended to the close contact portion 524 and the close contact portion 524 that are in close contact with the outer surface of the gas turbine casing 100 in the inserted state of the rear end coupling portion ( 540) may include a shear insertion coupling portion 528 to which one side is inserted and coupled.

That is, in the third embodiment, unlike the second embodiment, the shear body part is excluded, and accordingly, a plurality of heat dissipation fins extending on the outer peripheral surface of the shear body part are excluded. The front end insertion coupling portion 528 extending straight from the contact portion 524 may be coupled to the rear end coupling portion 540 directly.

The coupling structure between the components of the rear end coupling part 520 and the heat dissipation part 600 in the third embodiment is the same as the second embodiment, and similarly, the inner surface of the rear end heat dissipating body 620 and the rear end body part 546 A constant space 550 is formed between the outer surfaces of the same to increase the heat dissipation effect, which is the same as in the second embodiment.

In the case of the third embodiment, the well coupling part 500 is assembled by separately assembling the heat dissipation part 600 made of aluminum material to the rear end coupling part 520 and then combining the front end coupling part 520 with the rear end coupling part 520. ) And the heat dissipation unit 600 may be organically combined.

As described above, the present specification has been described with reference to the embodiments shown in the drawings so that those skilled in the art can easily understand and reproduce the present invention, but these are merely exemplary, and those skilled in the art can make various modifications and equivalents from the embodiments of the present invention. It will be understood that embodiments are possible. Therefore, the protection scope of the present invention should be defined by the claims.

100: gas turbine casing 120: well
200: temperature sensor rod 222: hot gas cut-off
300,500: well coupling
320: well insertion coupling portion 340: close contact portion 360: body portion 380: tension retaining coupling portion
520: shear coupling
522: well insertion coupling portion 524: close contact portion 526: shear body portion 527: shear heat dissipation portion
528: shear insert coupling
540: rear end coupling
542: tension retaining coupling portion 544: rear end heat release coupling portion 546: rear end body portion 547: head bolt hole
550: constant space
400,600: heat sink
620: rear heat release body 640: rear heat release fin
700: tension maintenance
800: connector

Claims (5)

A temperature sensor rod 200 inserted into the well 120 formed in the casing 100 of the gas turbine;
In the state in which the temperature sensor rod 200 is penetrated, one side of the well coupling portion 300,500 having a constant length coupled to the inner surface of the well 120; And
It includes a heat dissipation portion (400,600) formed while surrounding the outer peripheral surface of the well coupling portion (300,500),
The well coupling portion 500,
One side is inserted into the well 120, the shear coupling portion 520 is fastened to the inner surface of the well 120; And
As the shear coupling portion 520 is inserted or inserted into the shear coupling portion 520 includes a rear end coupling portion 540 coupled to the shear coupling portion 520,
The heat dissipation unit 600,
A rear end heat-dissipating body 620 formed to surround the outer circumferential surface of the rear end coupling part 540 by being coupled as one side of the rear end coupling part 540 is inserted; And
A temperature sensor device for a gas turbine including a plurality of rear heat dissipation fins (640) formed extending from the rear heat dissipation body (620).
delete delete According to claim 1,
The rear end coupling portion 540 is made of stainless steel, and the rear end heat dissipating body 620 and the rear end heat dissipation fin 640 are aluminum gas temperature sensor devices.
The method of claim 4,
The rear end coupling portion 540 is a rear end heat dissipation coupling portion 544 inserted into the rear heat dissipation body 620; And a rear end body portion 546 extending in a stepped form from the rear end heat dissipation coupling portion 544 and coupled to the front end coupling portion 520,
The rear end heat dissipating body 620 is positioned at regular intervals from the rear end body part 546 in a state coupled to the rear end heat dissipation coupling part 544, so that the rear end heat dissipating body 620 and the rear end heat dissipating body 546 ) Between the space sensor 550 is formed a gas turbine temperature sensor device.

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