KR20200125007A - Method for generating turbine performance curve of gas turbine device - Google Patents

Abstract

According to one aspect of the present invention, a method for generating a turbine performance curve of a gas turbine device including a compression unit, a combustion unit, and a turbine unit, comprises the steps of: (a) preparing a compressor performance map indicating relationship between a pressure ratio, a non-dimensional flow rate, and a non-dimensional rotational speed of the compression unit at at least one operating point of the compression unit; (b) calculating an inlet pressure of the turbine unit and an inlet temperature of the turbine unit by using data of the compressor performance map; (c) calculating a pressure ratio, a non-dimensional flow rate, efficiency, and a non-dimensional rotational speed of the turbine unit at an operating point of the turbine unit matching the operating point of the compression unit by using the inlet pressure of the turbine unit and the inlet temperature of the turbine unit; and (d) generating a turbine performance curve by using the pressure ratio, the non-dimensional flow rate, the efficiency, and the non-dimensional rotational speed of the turbine unit at the operating point of the turbine unit. According to the present invention, it is possible to provide a method capable of easily generating a turbine performance curve of a rotational speed area that is not provided by a turbine manufacturer.

Description

Method for generating turbine performance curve of gas turbine device}

The present invention relates to a method of generating a turbine performance diagram for a gas turbine device.

The gas turbine device includes a compressor, a combustor, and a turbine, which compresses air in the compressor, combusts compressed air and fuel in the combustor, and generates kinetic energy using the gas expanded at high temperature and high pressure in the combustor in the turbine. It is a device to let you know.

In the process of developing a gas turbine device, a start-up operation of the entire gas turbine device in which a compressor, a combustor, and a turbine is assembled is required. During the start-up operation, unexpectedly, damage to the gas turbine device may occur due to a surge phenomenon or damage to parts.

Therefore, a simulation process using a computer or the like is required before starting operation of the gas turbine device. However, in the turbine performance map provided by the turbine manufacturer, turbine performance diagrams in some rotational speed regions required for start-up operation analysis are often omitted, so that simulation analysis of the rotational speed region in which the start-up operation is in progress was difficult.

Patent Publication No. 10-0788212 discloses a technique for simulating the performance of a gas turbine engine using system identification and genetic algorithms.

The main task is to provide a method for easily generating turbine performance diagrams in the rotational speed range that are not provided by turbine manufacturers.

According to an aspect of the present invention, in a method for generating a turbine performance diagram of a gas turbine device including a compression unit, a combustion unit, and a turbine unit, (a) a pressure ratio of the compression unit at at least one operating point of the compression unit, dimensionless Preparing a compressor performance map representing a relationship between a flow rate and a dimensionless rotational speed; and, (b) obtaining an inlet pressure of the turbine unit and an inlet temperature of the turbine unit using data of the compressor performance map; and, ( c) Using the inlet pressure of the turbine unit and the inlet temperature of the turbine unit, the pressure ratio of the turbine unit at the operating point of the turbine unit that matches the operation point of the compression unit, the dimensionless flow rate, efficiency, and the dimensionless rotation speed are obtained. Step; And, (d) using the pressure ratio of the turbine unit at the operating point of the turbine unit, a dimensionless flow rate, efficiency, and a dimensionless rotation speed, providing a turbine performance diagram generating method comprising the step of generating a turbine performance diagram do.

Here, the outlet temperature of the compression unit may be obtained using the pressure ratio and efficiency data of the compression unit, and the inlet temperature of the turbine unit may be obtained using the outlet temperature of the compression unit.

Here, the inlet temperature of the turbine unit may be determined using an outlet temperature of the compression unit and a state of fuel input to the combustion unit.

Here, the generated turbine performance diagram may be a part of the turbine performance diagram.

According to an aspect of the present invention, since it is possible to easily generate a turbine performance diagram in a rotational speed region that is not provided by a turbine manufacturer, there is an effect of helping to perform a simulation of a gas turbine device.

1 is a schematic diagram of a gas turbine device according to an embodiment of the present invention.
2 is a flow chart schematically showing a method of generating a turbine performance diagram according to an embodiment of the present invention.
3 is a diagram showing a compressor performance map according to an embodiment of the present invention.
4 is a diagram showing a turbine performance map for an embodiment of the present invention.

Hereinafter, the present invention according to a preferred embodiment will be described in detail with reference to the accompanying drawings. In addition, in the present specification and drawings, redundant descriptions are omitted by using the same reference numerals for components having substantially the same configuration.

1 is a schematic diagram of a gas turbine device according to an embodiment of the present invention.

The gas turbine device 100 according to the present embodiment illustrated in FIG. 1 includes a compression unit 110, a combustion unit 120, and a turbine unit 130.

The compression unit 110 is driven by receiving power from the turbine unit 130 through the shaft M. As the compression unit 110, a compressor used in a known gas turbine device may be applied without limitation. That is, as the compression unit 110 according to the present embodiment, various compressors such as a centrifugal compressor, a four-flow compressor, and an axial compressor may be applied, and not only a single-stage compressor but also a multi-stage compressor may be applied. A compression device in which two compressors are arranged in series or in parallel can also be applied.

As for the combustion unit 120, a combustor used in a known gas turbine device may be applied without limitation, and various fuels may be used as the fuel input to the combustion unit 120.

As for the turbine unit 130, a turbine used in a known gas turbine device may be used without limitation. That is, not only a single-stage turbine but also a multi-stage turbine may be applied, and a turbine device in which several turbines are installed in series or in parallel may be used.

Hereinafter, a method for generating a turbine performance diagram applicable to the gas turbine apparatus 100 according to the present embodiment will be described with reference to FIGS. 1 to 4.

2 is a flowchart schematically showing a method for generating a turbine performance diagram according to an embodiment of the present invention, FIG. 3 is a view showing a compressor performance map according to an embodiment of the present invention, and FIG. A diagram showing a turbine performance map for one embodiment.

In the turbine performance map shown in FIG. 4, since the "conventional turbine performance diagram" is omitted from the "low rotational speed region", in this embodiment, the data of the compressor performance map and measurement data (rotation speed and fuel amount) A method of additionally generating a turbine performance diagram in the "low rotational speed region" will be described.

), 무차원 회전속도(

)의 관계를 나타내는 압축기 성능 맵을 준비한다(단계 S1).First, as shown in Fig. 3, the pressure ratio (P ₂ /P ₁ ) of the compression unit 110 at a plurality of operating points (a, b, c) of the compression unit 110, a dimensionless flow rate (

), dimensionless rotation speed (

A compressor performance map indicating the relationship of) is prepared (step S1).

)은 압축부(110)에서의 질량 유동량(

), 압축부(110)의 입구(①)에서의 온도 T₁, 압축부(110)의 입구(①)에서의 압력 P₁를 이용하여 표현될 수 있고, 무차원 회전속도(

)은 압축부(110)의 로터의 회전속도(N)와 압축부(110)의 입구(①)에서의 온도 T₁를 이용하여 표현될 수 있다. As shown in Figure 3, the compressor performance map is a map showing the performance of the compression unit 110, in which the pressure ratio (P ₂ /P ₁ ) is the pressure P at the inlet (①) of the compression unit 110 ₁ is the ratio of the pressure P ₂ at the outlet (②), and the dimensionless flow rate (

) Is the mass flow rate in the compression unit 110 (

), the temperature T ₁ at the inlet (①) of the compression unit 110, the pressure P ₁ at the inlet (①) of the compression unit 110, and a dimensionless rotation speed (

) Can be expressed by using the rotational speed (N) of the rotor of the compression unit 110 and the temperature T ₁ at the inlet (①) of the compression unit 110.

)를 나타내는 곡선이 3개로 도시되었지만, 본 발명은 이에 한정하지 않는다. 즉 도 3에서는 이해를 위해, 터빈 성능 선도를 추가적으로 생성하기 위한 운전점들에 대응하는 3개의 무차원 회전속도(

)들만을 나타낸 것이지만, 실제 압축기 성능 맵에서는 무차원 회전속도(

)를 나타내는 더 많은 개수의 곡선으로 도시될 수도 있다. In the compressor performance map of Fig. 3, the dimensionless rotation speed (

) Is shown as three curves, the present invention is not limited thereto. That is, in FIG. 3, for understanding, three dimensionless rotation speeds corresponding to operating points for additionally generating a turbine performance diagram (

), but in the actual compressor performance map, the dimensionless rotation speed (

It may be shown as a larger number of curves representing ).

In addition, in the compressor performance map of FIG. 3, the number of operating points of the compression unit 110 corresponding to operating points for additionally generating a turbine performance diagram is set to three, but the present invention is not limited thereto. That is, according to the present invention, as long as it is possible to generate a turbine performance diagram, there is no particular limitation on the number of operating points of the compression unit corresponding thereto. That is, as will be described later, the number of operating points of the compression unit may vary according to the required number of operating points of the turbine unit matched thereto, or may vary according to the number of information on the amount of fuel matched thereto.

Then, the pressure P ₃ and the temperature T ₃ of the inlet 3 of the turbine unit 130 are obtained using the data of the compressor performance map described above (step S2).

At this time, the pressure P ₃ of the inlet (③) of the turbine unit 130 can be obtained by an equation that considers the outlet pressure P ₂ of the compression unit 110 and the pressure loss generated in the combustion unit 120. Assuming that the pressure P ₃ of the inlet (③) of 130 is similar to the pressure P ₂ of the outlet (②) of the compression unit 110, the pressure P ₂ of the outlet (②) of the compression unit 110 may be used as it is. have.

The temperature T ₃ of the inlet (③) of the turbine part 130 can be obtained by using the temperature T ₂ of the outlet (2) after obtaining the temperature T ₂ of the outlet (2) of the compression part (110).

In detail, by using the temperature T ₁ of the inlet (①) of the compression unit 110 and the pressure ratio and efficiency data of the compression unit 110, the temperature T ₂ of the outlet (②) of the compression unit 110 is obtained, Using the obtained temperature T ₂ of the outlet (②) of the compression unit 110 and the state of the fuel injected into the combustion unit 120 (type of fuel and amount of fuel), the turbine unit ( The temperature T ₃ of the inlet (③) of 130) can be obtained.

In summary, using the temperature T ₁ of the inlet (①) of the compression unit 110 and the pressure ratio and efficiency data of the compression unit 110, the temperature T ₂ of the outlet (②) of the compression unit 110 is calculated, and then combustion The temperature T ₃ of the inlet (③) of the turbine unit 130 can be obtained using the data for and the combustion modeling equation.

Looking at this in detail, the temperature T ₂ of the outlet (②) of the compression unit 110 can be obtained using the following [Equation 1].

In [Equation 1], η _C means the efficiency of the compression unit 110, h _out,s is the enthalpy of the outlet (②) of the compression unit 110 in an isentropic state, and h _out is the compression unit 110 The enthalpy of the outlet (②) of, h _in is the enthalpy of the inlet (①) of the compression unit 110, and using the above [Equation 1], the temperature T ₂ of the outlet (②) of the compression unit 110 can be obtained. You will be able to.

In addition, the temperature T ₃ of the inlet (③) of the turbine unit 130 can be obtained using the following [Equation 2] and [Equation 3].

은 연료 유동량을 의미하고,

는 연료의 저위 발열량(low heating value)을 의미하고,

는 터빈부(130)의 입구(③)의 질량 유동량을 의미하고,

는 압축부(110)의 출구(②)의 질량 유동량을 의미하고, h₃는 터빈부(130)의 입구(③)의 엔탈피를 의미하고, h₂는 압축부(110)의 출구(②)의 엔탈피를 의미한다. 여기서, 터빈부(130)의 입구(③)의 질량 유동량

은 압축부(110)의 출구(②)의 질량 유동량

와 연료 유동량인

의 합이며, 터빈부(130)의 입구(③)의 엔탈피 h₃를 이용하면 터빈부(130)의 입구(③)의 온도 T₃를 구할 수 있다. 이 때 계산에 사용되는 연료량은 측정된 연료량을 사용한다.In [Equation 2] and [Equation 3], Q means calories,

Means the amount of fuel flow,

Means the low heating value of the fuel,

Means the mass flow amount of the inlet (③) of the turbine unit 130,

Is the mass flow of the outlet (②) of the compression unit 110, h ₃ is the enthalpy of the inlet (③) of the turbine unit 130, and h ₂ is the outlet (②) of the compression unit 110 Means the enthalpy of Here, the mass flow amount of the inlet (③) of the turbine unit 130

Mass flow of the outlet (②) of the silver compression unit 110

And the fuel flow

It is the sum of and, by using the enthalpy h ₃ of the inlet (③) of the turbine part 130, the temperature T ₃ of the inlet (③) of the turbine part 130 can be obtained. At this time, the measured fuel amount is used as the amount of fuel used for calculation.

), 무차원 회전 속도(

)를 구하고, 또한 측정되는 터빈부(130)의 출구(④)에서의 온도 T₄를 이용하여 터빈부(130)의 효율을 구한다(단계 S3). Then, using the pressure P ₃ and the temperature T ₃ at the inlet (③) of the turbine unit 130, the turbine unit 130 matching the operating points (a, b, c) of the compression unit 110 ), the pressure ratio of the turbine unit 130 at the operating points (a', b', c') (P ₃ /P ₄ ), the dimensionless flow rate (

), dimensionless rotation speed (

) Is obtained, and the efficiency of the turbine unit 130 is obtained by using the temperature T ₄ at the outlet ④ of the turbine unit 130 to be measured (step S3).

In addition, the efficiency η _T of the turbine unit 130 can be obtained using the following [Equation 4].

In [Equation 4], η _T means the efficiency of the turbine unit 130, h _in is the enthalpy of the inlet (③) of the turbine unit 130, and h _out is the outlet (④) of the turbine unit 130 Is the enthalpy of, and h _out,s is the enthalpy of the outlet (④) of the turbine unit 130 in an isentropic state. The enthalpy of the outlet (④) of the turbine part 130 using the measured temperature T ₄ at the outlet (④) of the turbine part 130 and the calculated pressure P ₄ at the outlet (④) of the turbine part 130 After obtaining h _out , the efficiency η _T of the turbine unit 130 can be obtained from [Equation 4].

)은 터빈부(130)에서의 질량 유동량(

), 터빈부(130)의 입구(③)에서의 온도 T₃, 터빈부(130)의 입구(③)에서의 압력 P₃를 이용하여 표현될 수 있고, 무차원 회전속도(

)은 터빈부(130)의 로터의 회전속도(N)와 터빈부(130)의 입구(③)에서의 온도 T₃를 이용하여 표현될 수 있다. As shown in Figure 4, the turbine performance map is a map showing the performance of the turbine unit 130, in which the pressure ratio (P ₃ / P ₄ ) is the pressure P at the inlet (③) of the turbine unit 130 ₃ is the ratio of the pressure P ₄ at the outlet (④), and the dimensionless flow rate (

) Is the mass flow amount in the turbine unit 130 (

), the temperature T ₃ at the inlet (③) of the turbine unit 130, and the pressure P ₃ at the inlet (③) of the turbine unit 130, and a dimensionless rotational speed (

) Can be expressed by using the rotational speed N of the rotor of the turbine unit 130 and the temperature T ₃ at the inlet ③ of the turbine unit 130.

)은 압축부(110)의 출구(②)의 질량 유동량

와 연소부(120)에 투입되는 연료 유동량인

를 이용하여 구할 수 있으며, 서로 매칭되는 각 운전점들에서 터빈부(130)의 회전수(N)는 압축부(130)의 회전수(N)와 동일하다고 가정할 수 있다. Here, the pressure P ₃ and the temperature T ₃ at the inlet (③) of the turbine unit 130 are in step S2 It has been obtained, and the pressure P ₄ at the outlet (④) of the turbine unit 130 can be assumed to be atmospheric pressure. In addition, as described above, the mass flow rate in the turbine unit 130 (

) Is the mass flow rate of the outlet (②) of the compression unit 110

And the amount of fuel flow input to the combustion unit 120

It can be obtained by using, and it can be assumed that the number of revolutions (N) of the turbine unit 130 at each of the matching operating points is the same as the number of revolutions (N) of the compression unit 130.

), 무차원 회전속도(

), 효율(η_C)을 이용하여, 압축부(110)의 출구(②)의 온도 T₂와 압력 P₂를 구한다. 이어, 압축부(110)의 출구(②)의 압축 공기와 연소부(120)에 투입되는 연료를 연소 반응시켜 터빈부(130)의 입구(③)에서의 온도 T₃를 구하고, 연소부(120)의 압력 손실을 반영하여 터빈부(130)의 입구(③)에서의 압력 P₃를 구한다.Summarizing the above, the pressure ratio (P ₂ /P ₁ ) of the operating points (a, b, c) of the compression unit 110 shown in FIG. 3, a dimensionless flow rate (

), dimensionless rotation speed (

) And the efficiency (η _C ), the temperature T ₂ and the pressure P ₂ of the outlet (②) of the compression unit 110 are obtained. Then, the compressed air at the outlet ② of the compression unit 110 and the fuel input to the combustion unit 120 are subjected to combustion reaction to obtain a temperature T ₃ at the inlet ③ of the turbine unit 130, and the combustion unit ( The pressure P ₃ at the inlet (③) of the turbine unit 130 is calculated by reflecting the pressure loss of 120).

), 무차원 회전 속도(

), 효율(η_T)을 구한다.After obtaining the pressure P ₃ and the temperature T ₃ at the inlet (③) of the turbine unit 130, the operation of the turbine unit 130 matching each of the operating points (a, b, c) of the compression unit 110 The pressure ratio (P ₃ /P ₄ ) of the turbine unit 130 at points (a', b', c'), a dimensionless flow rate (

), dimensionless rotation speed (

) And the efficiency (η _T ).

), 무차원 회전 속도(

), 효율(η_T) 데이터를 이용하여, 터빈 성능 맵에서 터빈 성능 선도를 생성한다(단계 S4).Then, the pressure ratio (P ₃ /P ₄ ) of the turbine unit 130 at the operating points (a', b', c') of the turbine unit 130 obtained in such a manner, the dimensionless flow rate (

), dimensionless rotation speed (

), the efficiency (η _T ) data is used to generate a turbine performance diagram from the turbine performance map (step S4).

In this embodiment, the number of operating points (a, b, c) of the compression unit 110 matched with the operating points (a', b', c') of the turbine unit 130 is three. It is configured and it is determined that the number of such operating points is sufficient to generate a turbine performance diagram in the turbine performance map, but when a more precise turbine performance diagram is required, a compression unit matching each other using more measured data ( 110) and the appropriateness of the number of operating points of the turbine unit 130 (step S4-1), the above processes may be repeated when more operating points are required. If a turbine performance diagram is required more quickly, the number of operating points of the compression unit 110 and the turbine unit 130 that match each other may be reduced. For example, the number of operating points of the compression unit 110 and the turbine unit 130 that match each other may be 1, 2, 4, 5, 6, etc., respectively.

)들을 점들의 형태로 터빈 성능 맵에 나타내고, 이 점들을 점선의 형태로 연결하여 터빈 성능 선도를 생성한 후, 실선으로 표시된 기존의 터빈 성능 선도에 연결한다. 본 실시예의 경우에는 이러한 방식으로 저회전속도 영역의 터빈 성능 선도를 생성하여, 기존의 터빈 성능 선도에 연결하여 원하는 영역만큼 터빈 성능 선도를 보완시켜 완성할 수 있다.In the case of this embodiment, as shown in FIG. 4, the dimensionless rotation speed of the turbine unit 130 corresponding to the operating points (a', b', c') of the turbine unit 130 (

) On the turbine performance map in the form of dots, connect these dots in the form of dotted lines to create a turbine performance diagram, and then connect them to the existing turbine performance diagram indicated by a solid line. In the case of the present embodiment, a turbine performance diagram in a low rotational speed region is generated in this manner, connected to an existing turbine performance diagram, and completed by supplementing the turbine performance diagram as much as a desired region.

As shown in Fig. 4, the turbine performance diagram generated by the method provided in this embodiment supplements the low rotational speed region. If such data is used, it is very helpful in the simulation analysis of the low rotational speed region performed before the starting operation is performed, and thus problems that may actually occur during the above-described starting operation can be prevented.

In the case of the present embodiment, some turbine performance diagrams, that is, turbine performance diagrams in the low rotational speed region, are additionally generated and connected to the existing turbine performance diagrams, but the present invention is not limited thereto. That is, according to the present invention, there is no limitation in the area of the newly generated turbine performance diagram. For example, the area of the turbine performance diagram newly generated according to the present invention is a turbine performance diagram that is not part of the turbine performance diagram if only the number of measurement data of the compression unit 110 and the turbine unit 130 matching each other is sufficiently secured. You can also create a whole.

The method for generating a turbine performance diagram as described above may be performed by a simulation apparatus using an electronic circuit, a semiconductor chip, a computer program, or the like, and some may be performed by manual calculation.

In addition, the present embodiment provides a method of generating a turbine performance diagram in a turbine performance map after obtaining data, but the present invention is not limited thereto. That is, according to the present invention, the final form does not have to take the form of a turbine performance diagram. In that case, only data capable of drawing a turbine performance diagram may be taken and stored in a storage device, and then such data may be used for simulation analysis.

As described above, according to the turbine performance diagram generation method according to the present embodiment, since the turbine performance diagram in the rotational speed region of interest can be generated simply and easily, it may be helpful to perform the simulation of the gas turbine device. have.

The present invention has been described with reference to the embodiments shown in the accompanying drawings, but this is only exemplary, and those of ordinary skill in the art will understand that various modifications and other equivalent embodiments are possible therefrom. I will be able to. Accordingly, the true scope of protection of the present invention should be determined only by the appended claims.

The method of generating a turbine performance diagram of the present embodiment can be used in industries that manufacture, test, and operate gas turbine devices.

100: gas turbine device 110: compression unit
120: combustion unit 130: turbine unit

Claims (4)

In a method for generating a turbine performance diagram of a gas turbine device including a compression unit, a combustion unit, and a turbine unit,
(a) preparing a compressor performance map indicating a relationship between a pressure ratio of the compression unit, a dimensionless flow rate, and a dimensionless rotational speed at at least one operating point of the compression unit;
(b) obtaining an inlet pressure of the turbine unit and an inlet temperature of the turbine unit using data of the compressor performance map;
(c) Using the inlet pressure of the turbine unit and the inlet temperature of the turbine unit, the pressure ratio of the turbine unit at the operating point of the turbine unit matching the operation point of the compression unit, the dimensionless flow rate, efficiency, and the dimensionless rotation speed Obtaining steps; And
(d) using a pressure ratio of the turbine unit at an operating point of the turbine unit, a non-dimensional flow rate, efficiency, and a non-dimensional rotational speed, generating a turbine performance diagram. The method of claim 1,
The outlet temperature of the compression unit is obtained using the pressure ratio and efficiency data of the compression unit,
Turbine performance diagram generation method for obtaining the inlet temperature of the turbine part by using the outlet temperature of the compression part. The method of claim 2,
The inlet temperature of the turbine unit is determined using an outlet temperature of the compression unit and a state of fuel injected into the combustion unit. The method of claim 1,
The generated turbine performance diagram is a method of generating a turbine performance diagram that is part of a turbine performance diagram.

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