JPH1047079A - Anti-surge controller - Google Patents

Abstract

PROBLEM TO BE SOLVED: To improve the limitation of a load changing rate when a boiler load is reduced, by providing an inlet guide vane by which an inlet of supply air to a compressor is closed when the boiler load is reduced and a supply air amount to a boiler is limited, and also providing a blow-off valve which blows a part of the supply air amount to the boiler on the downstream side of the compressor. SOLUTION: A pressure fluidized bed compound power plant is equipped with a gas turbine 2 by which high temperature exhaust heat (combustion) gas is fed from a fluidized bed boiler in a pressure container 1, and a compressor 3 by which air for combustion is fed to the fluidized bed boiler, and an inlet guide vane(IGV) 4 for throttling a supply air amount to the pressure container 1 is arranged in this compressor 3. Also, a blow-off pipe 7 in which a blow-off valve 8 is interposed, is connected between the delivery port of the compressor 3 and an exhaust gas pipe 6, and the blow-off valve 8 is controlled by a controller 11 according to the output of a pressure detector 10 by which the discharge pressure of the compressor 3 is detected. That is, the supply air amount corresponding to a limit amount more than a supply air limit amount in a lowest allowable opening for preventing surging by the closing operation of the IGV 4, is blown and controlled by the blow-off valve 8.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control device for preventing surging caused by closing operation of an inlet guide vane (IGV) of a gas turbine compressor when a boiler load in a pressurized fluidized bed combined cycle power plant (PFBC) is reduced. About.

[0002]

2. Description of the Related Art Conventionally, in a compressor in a gas turbine facility, the amount of air supplied is restricted by restricting an inlet guide vane (hereinafter referred to as IGV). In this compressor, when the IGV is throttled, the outlet pressure of the compressor is also reduced by the throttled amount, so that there is no surging limitation in the operation of the IGV.

On the other hand, a gas turbine compressor applied to a pressurized fluidized bed combined cycle power plant (hereinafter referred to as PFBC) has a function as a blower for sending combustion air to a boiler provided in a pressurized container. Therefore, when the boiler load is reduced, as described later, even if the compressor is in contact with surging and the IGV is operated, a pressure change can be immediately generated even when the IGV is operated. Can not.

Here, PFBC is a combined power generation plant combining steam turbine power generation using steam generated from a fluidized bed boiler housed in a pressurized vessel and gas turbine power generation using high temperature combustion gas from a boiler. It is a method.

[0005]

The gas turbine compressor applied to the PFBC has a wide range of air flow control in order to satisfy the function as a blower for sending combustion air to the boiler. In this control, since the flow rate is reduced to, for example, 60% of the fully opened state, an operation that pays attention to surging is required. In the PFBC, the compressor discharge port is connected to a large pressurized container. Therefore, when the boiler load is reduced, the IGV closing operation is restricted due to a collision with the compressor surging line, and the load change rate is restricted. That is, when the IGV is closed in order to reduce the amount of air, the pressure in the pressurized container does not decrease because of a time delay, and the surge is in conflict with surging. This means that the pressurized container is equivalent to a large buffer tank, and that the pressure does not change immediately due to a change in the amount of air supplied thereto. That is, the pressure in the pressure vessel is balanced at a pressure at which the flow rate of the air supplied from the compressor is equal to the flow rate of the combustion gas discharged through the turbine provided downstream.
This supply air flow rate increases or decreases according to the opening degree of the IGV. The combustion gas flow rate is approximately proportional to the square root of the pressure of the pressure vessel.
Therefore, when the IGV is throttled and the supply air flow rate is reduced, the pressure in the pressure vessel eventually decreases and balance occurs, but the time required to shift to this balance point is:
It is proportional to the volume of the pressure vessel. In the PFBC, the response delay time of the pressure caused by the volume of the pressure vessel is IGV.
, The pressure of the pressure vessel hardly changes within the time required for the opening degree change operation of the IGV. Therefore, in order to prevent surging, there is a problem that the load change rate is largely limited, and good operability of the IGV cannot be obtained.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is possible to improve the limitation on the rate of change in load, to narrow down the IGV without being restricted by surging, and to reduce the IGV.
It is an object of the present invention to provide an anti-surge control device capable of satisfactorily controlling the operation of the device.

[0007]

An IGV (4) is provided on the inlet side of the supply air of the compressor (3). The discharge pipe 5 connecting the compressor 3 to the pressurized container 1 is provided with a blow-off pipe 7 communicating with the exhaust pipe 6 of the gas turbine 2, and the blow-off pipe 7 is provided with a blow-off valve 8 and its control device 11. Provide. The control of the blow-off valve 8 by the control device 11
To prevent surging due to the closing operation of IGV4, IGV
4 of the minimum acceptable supply air amount corresponding to the limit amount exceeding the supply air restriction amount in the opening z ₁ for preventing surging performed so as to blow-off the blow-off valve 8.

Further, the control unit 11, based on the discharge pressure detection value p of the compressor 3, an instruction opening a for the output control of the boiler, the allowable minimum opening degree z ₁ of IGV4 for surging prevention blow-off Control the valve 8.

[0009]

[Action] When the boiler output control instruction opening a is smaller than the allowable minimum opening degree z ₁ of IGV4, it becomes necessary surging avoidance. Therefore, the controller 11 opens the blow-off valve 8 so as to blow-off the air amount corresponding to the limit amount exceeding the limit amount of allowable minimum opening z ₁ of IGV4. By performing such control, it is possible while preventing surging by keeping IGV4 the allowable minimum opening degree z _1, corresponds to the load reduction.

[0010]

BEST MODE FOR CARRYING OUT THE INVENTION

Embodiment 1 FIG. First Embodiment A first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a block diagram showing a part of a combined pressurized fluidized-bed power plant (PFBC). In FIG. 1, PFBC includes a pressurized container 1 containing a fluidized-bed boiler (not shown), a gas turbine 2 to which high-temperature exhaust heat (combustion) gas is sent from the fluidized-bed boiler of the pressurized container 1, and a pressurized container 1
And a compressor 3 for a gas turbine that sends combustion air to a fluidized-bed boiler.

The compressor 3 is provided with an IGV 4 for reducing the amount of air supplied to the pressurized container 1, and an outlet 3a of the compressor 3
The pressure vessel 1 is connected to the pressure vessel 1 by a discharge pipe 5. The pressurized container 1 and the gas turbine 2 are connected by an exhaust gas pipe 1a. An exhaust pipe 6 for discharging gas passing through the gas turbine 2 is connected to the gas turbine 2. The IGV 4 is driven to open and close by a servo motor 12 provided therein.

A discharge pipe 7 is connected between the discharge port 3a of the compressor 3 and the exhaust pipe 6, and a discharge valve 8 for opening and closing the discharge pipe 7 is connected to the discharge pipe 7. Is provided. Further, between the blow-off valve 8 and the discharge port 3a in the blow-off pipe 7,
Discharge pressure detector 1 for detecting discharge pressure of compressor 3
0 is provided, and the output side of the pressure detector 10 is connected to one input terminal of the control device 11.

The PFBC is provided with a boiler output control device 9 for controlling the output of the fluidized bed boiler at an appropriate position, and the output is connected to another input terminal of the control device 11. One output terminal of the control device 11 is a servo motor 12 for opening and closing the IGV 4.
The other output terminal of the control device 11 is connected to the blow-off valve 8.

In the above configuration, combustion air is sent from the compressor 3 for the gas turbine 2 to the boiler to the fluidized bed boiler housed in the pressurized vessel 1. When the boiler load decreases, the IG of the compressor 3
V4 is reduced.

At this time, the blow-off valve 8 is controlled in order to avoid surging due to the time in which the pressure in the pressurized container 1 is delayed and the pressure does not decrease. This blow-off valve 8
Is input to the control device 11 by inputting an instruction opening signal a of the boiler output control device 9 and a pressure detection value (signal) p of the compressor discharge pressure detector 10 to the instruction opening of the IGV 4 with respect to the pressure detection value p. z and the designated opening y of the blow-off valve 8 are calculated, the opening of the IGV 4 is controlled by the designated opening (signal) z, and the blow-off valve 8 is controlled by the designated opening (signal) y.

FIG. 2 is a block diagram showing control elements of the control device 11. In FIG. 2, reference numeral 11a denotes a pressure detector 1.
0 from the pressure detected by the pressure detector 10 to IGV4
, A function generator 11a and a subtractor connected to the boiler output controller 9; 11c, a setting device for setting a factor k; 11d, a setting device 11c; A multiplier 11e connected to the subtractor 11b and an upper / lower limiter 11e connected to the multiplier 11d output all negative values as zero. Also,
A positive value equal to or greater than a predetermined value can be output as a predetermined value. 11f is an upper / lower limiter 11e and a setting device 1
A divider 11g is connected to the divider 1f, and an adder 11g is connected to the divider 11f and the boiler output controller 9.

The control operation in the first embodiment will be described below with reference to FIG. Now, it is assumed that the detected value and each indicated opening degree are as follows as described above.

The compressor discharge pressure detection value: p boiler output control instruction opening: instructions opening of IGV for a p: z IGV allowable minimum opening: z ₁ blow-off valve opening: y

Here, the compressor discharge pressure detection value p and the IGV
The allowable minimum opening z ₁ is in a proportional relationship as shown in FIG. If the boiler output control instruction opening a is in the relationship of a ≧ z ₁ , the blow-off valve 8 may be inoperative, and the blow-off valve opening y is y = 0.
And the commanded opening degree z of the IGV with respect to the compressor discharge pressure detection value p may be z = a.

In FIG. 2, in the subtractor 11b,
When a ≧ z ₁ , the output from the upper / lower limiter 11e is 0, and the blow-off valve opening y is also 0. As for the indicated opening z, the output of the divider 11f becomes 0, and therefore the output of the adder 11g becomes a, and the indicated opening z of the IGV becomes a.

If a <z ₁ , surging must be avoided. In FIG. 2, the output of the subtractor 11b is z ₁ -a, and the output of the multiplier 11d is k (z ₁ -a).
a), and the same applies to the output of the upper and lower limiter 11e.
Therefore, the blow-off valve opening y becomes k (z ₁ -a), and IG
V is opened, and the increased amount of air is controlled by the opening operation of the blow-off valve.

In order to reduce the same amount of compressor discharge air flow, the scale factor k must be set to several times the change amount when the opening degree setting value of the IGV 4 is changed. Is a value (constant) indicating whether or not
This is the opening required to reduce (blow off) the supply air to the pressure vessel by the same amount as when the GV opening is closed by 1%. The upper / lower limiter 11e limits the opening signal of the blow-off valve 8 to a predetermined value when it exceeds the opening limit of the blow-off valve 8.

In the above-described embodiment, the control device 11 controls the opening and closing of the IGV 4 together with the blow-off valve 8. However, the present invention is not limited to this mode. It is obvious that the opening / closing operation of only the blow-off valve 8 may be performed independently of the opening / closing control of the IGV 4.

[0024]

As described in detail above, according to the anti-surge control device of the present invention, the limitation on the rate of change of the unit output when the load is reduced can be improved while preventing surging. Therefore, according to the present invention, when viewed from the boiler control device side, the limitation of the surging line is equivalently removed, and the IGV can be continuously narrowed, so that the operability is improved.

[Brief description of the drawings]

FIG. 1 is a block diagram showing a part of a combined pressurized fluidized bed power plant (PFBC) showing a first embodiment of the present invention.

FIG. 2 is a block diagram illustrating a control device according to the first embodiment.

FIG. 3 is a diagram showing a signal relationship between an IGV and a discharge valve.

[Explanation of symbols]

REFERENCE SIGNS LIST 1 pressurized vessel, 2 gas turbine, 3 compressor, 4 inlet guide vanes (IGV), 6 exhaust pipe, 7 blow-off pipe, 8 blow-off valve, 9 boiler output control device, 11 control device, 11
a function generator, 11b subtractor, 11c setting device, 1
1d multiplier, 11e upper / lower limiter, 11f divider, 11g adder.

Claims (2)

[Claims] 1. A gas turbine having a gas turbine, a compressor, and a pressurized container containing a boiler, wherein air is supplied to the boiler via the compressor, and combustion gas generated by the boiler is supplied to the gas turbine. In a pressurized fluidized bed combined cycle power plant that is sent to a turbine, the inlet of the supply air to the compressor is closed when the load of the boiler is reduced, and an inlet guide vane that limits the amount of air supplied to the boiler is provided, A blow-off valve that blows off a part of the amount of air supplied to the boiler on the downstream side of the compressor, to prevent surging by closing the inlet guide vanes, and to prevent surging of the inlet guide vanes. A control device for controlling the blow-off valve so that the supply air amount corresponding to the limit amount exceeding the supply air limit amount at the minimum allowable opening is blown by the blow-off valve. That the anti-surge controller. 2. The control device according to claim 1, wherein the control unit controls a discharge pressure of the compressor,
2. The anti-surge control according to claim 1, wherein the blow-off valve is controlled based on an instruction opening for controlling the output of the boiler and an allowable minimum opening of the inlet guide vanes for preventing surging. apparatus.