JPH0861012A - Evaporation amount control device for exhaust gas boiler - Google Patents

Abstract

PURPOSE: To prevent the amount reduction of middle or low pressure steam from an exhaust gas boiler, which is utilized for cooling of gas turbine and heating of deaerator, from lowering when an exhaust gas source such as a gas turbine, etc., becomes a partial load in a combined cycle plant. CONSTITUTION: A part of the hot exhaust gas on the upstream side of the middle evaporator 19 or low pressure evaporator 23 of an exhaust gas boiler 8 is taken out, and re-introduced into the inlet of the middle evaporator 19 or low pressure evaporator 23 through a bypass duct 9A, etc., and mixed there. Thus the gas temperature at the inlet of the evaporators 19 or 23 is increased.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an evaporation control device applied to an exhaust gas boiler of a combined cycle plant.

[0002]

2. Description of the Related Art In a conventional combined cycle plant, when the exhaust gas source such as a gas turbine is partially loaded, the evaporation amount of the exhaust gas boiler also changes, and the evaporation amount at medium pressure or low pressure cannot be controlled arbitrarily. That is, the evaporation amount of the exhaust gas boiler is determined by the exhaust gas conditions of the gas turbine and the inlet pressure of the evaporation turbine, and the evaporation amount cannot be controlled by itself.

[0003]

Conventionally, the amount of evaporation of an exhaust gas boiler depends on the load (exhaust gas condition) of a gas turbine or the like, and the amount of evaporation at a partial load cannot be arbitrarily controlled. I couldn't get it. Therefore, when the deaerator heating steam, the gas turbine cooling steam, or other auxiliary steam is supplied to the outside from the medium-pressure or low-pressure steam system, it is not possible to obtain an arbitrary evaporation amount according to the demand.

[0004]

In order to solve the above-mentioned conventional problems, the present inventor took out a part of the high temperature exhaust gas from the upstream of the inlet of the medium pressure evaporator in the exhaust gas boiler of the combined cycle plant. An evaporation control device for an exhaust gas boiler, comprising a bypass duct re-introduced to the inlet of the medium-pressure evaporator and a damper provided in the bypass duct; and an exhaust gas boiler of a combined cycle plant for low-pressure evaporation. Evaporation amount of the exhaust gas boiler, comprising a bypass duct for extracting a part of the high-temperature exhaust gas from the upstream of the inlet of the reactor and reintroducing it into the inlet of the low-pressure evaporator, and a damper provided in the bypass duct. A control device is proposed.

[0005]

In the present invention, a part of the high temperature exhaust gas is taken out upstream of the medium pressure evaporator or the low pressure evaporator, re-introduced into the inlet of the medium pressure evaporator or the low pressure evaporator through the bypass duct, and mixed. By controlling the bypass amount with the damper, the temperature of the exhaust gas at the inlet of the medium-pressure evaporator or the low-pressure evaporator can be arbitrarily increased. As a result, the amount of heat recovered in the medium-pressure evaporator or the low-pressure evaporator increases, making it possible to control the increase of the medium-pressure evaporation amount or the low-pressure evaporation amount.

Further, if the exhaust gas bypass state is set to the rated state, it is possible to control the constant evaporation amount.

[0007]

1 is a system diagram showing a first embodiment of the present invention. This embodiment is an example in which, in a gas turbine / steam turbine combined cycle plant, medium pressure steam of an exhaust gas boiler is used as gas turbine cooling steam and the evaporation amount of the medium pressure steam is controlled.

In FIG. 1, (1) is a generator, (2) is a low pressure turbine, (3) is a medium pressure turbine, and (4) is a high pressure turbine.
(5) is a gas turbine, (6) is a gas turbine cooled part, (7) is a condenser, (8) is an exhaust gas boiler, (9A)
Is an exhaust gas bypass duct, (10A) is an exhaust gas bypass damper, (11) is a high pressure superheater, (12) is a reheater, (1
3) is a high pressure drum, (14) is a high pressure evaporator, (15) is a high pressure secondary economizer, (16) is a medium pressure superheater, (17) is a low pressure superheater, (18) is a medium pressure drum, ( 19) is a medium pressure evaporator, (20) is a medium pressure economizer, (21) is a high pressure primary economizer, (22) is a low pressure drum, (23) is a low pressure evaporator,
(24) is a low pressure economizer, (25) is a condensate pump, (2
6) is a low pressure economizer recirculation pump, (27) is a medium pressure feed pump, and (28) is a high pressure feed pump.

In the present embodiment, a part of the high temperature exhaust gas is taken out at the inlet of the high pressure evaporator (14) (that is, upstream of the inlet of the intermediate pressure evaporator (19)) and is fed to the inlet of the intermediate pressure evaporator (19). An exhaust gas bypass duct (9A) to be reintroduced is provided, and the exhaust gas bypass duct (9A) is provided with an exhaust gas bypass damper (10A).

At the rated load, when the medium pressure evaporation amount is sufficiently obtained and the required steam amount of the gas turbine cooling steam is satisfied, the exhaust gas bypass damper (10A) installed in the exhaust gas bypass duct (9A) is It's closed. When the medium pressure evaporation amount is less than the required evaporation amount at the time of partial load, the exhaust gas bypass damper (10A) is opened to introduce high temperature gas, and the exhaust gas temperature at the inlet of the intermediate pressure evaporator (19) is increased. To increase heat recovery in the medium pressure evaporator (19). As a result, the medium pressure evaporation amount increases, and the required evaporation amount is secured.

Next, FIG. 2 is a system diagram showing a second embodiment of the present invention. This embodiment is an example of controlling the evaporation amount of low-pressure steam used as auxiliary steam according to other needs such as deaerator heating steam. In FIG. 2, the same parts as those of the first embodiment described with reference to FIG. 1 are designated by the same reference numerals to avoid redundancy, and detailed description thereof is omitted.

In the present embodiment, the high pressure evaporator (14)
Part of the hot exhaust gas is taken out at the inlet of the low pressure evaporator (2) (that is, upstream of the inlet of the low pressure evaporator (23)).
Exhaust gas bypass duct (9B) reintroduced to the inlet of 3)
The exhaust gas bypass duct (9B) is provided with the exhaust gas bypass damper (10B).

At the rated load, when the low-pressure evaporation amount is sufficiently obtained and the required steam amount such as the deaerator heating steam is satisfied,
The exhaust gas bypass damper (10B) installed in the exhaust gas bypass duct (9B) is closed. When the low-pressure evaporation amount is less than the required evaporation amount at the time of partial load, the exhaust gas bypass damper (10B) is opened to introduce high-temperature gas to raise the exhaust gas temperature at the inlet of the low-pressure evaporator (23), Increases heat recovery in the low pressure evaporator (23). As a result, the medium pressure evaporation amount increases, and the required evaporation amount is secured.

[0014]

EFFECTS OF THE INVENTION In a combined cycle plant, the amount of medium or low pressure evaporation of an exhaust gas boiler is reduced during partial load, and the required amount of steam for gas turbine cooling steam, deaerator heating steam, and other auxiliary steam cannot be obtained. Even in such a case, according to the present invention, it is possible to increase the amount of medium-pressure evaporation or the amount of low-pressure evaporation to generate the required amount of steam.

[Brief description of drawings]

FIG. 1 is a system diagram showing an embodiment of the present invention.

FIG. 2 is a system diagram showing another embodiment of the present invention.

[Explanation of symbols]

 (1) Generator (2) Low pressure turbine (3) Medium pressure turbine (4) High pressure turbine (5) Gas turbine (6) Gas turbine cooled part (7) Condenser (8) Exhaust gas boiler (9A), ( 9B) Exhaust gas bypass duct (10A), (10B) Exhaust gas bypass damper (11) High pressure superheater (12) Reheater (13) High pressure drum (14) High pressure evaporator (15) High pressure secondary coal economizer (16) Inside Pressure superheater (17) Low pressure superheater (18) Medium pressure drum (19) Medium pressure evaporator (20) Medium pressure economizer (21) High pressure primary economizer (22) Low pressure drum (23) Low pressure evaporator ( 24) Low pressure economizer (25) Condensate pump (26) Low pressure economizer recirculation pump (27) Medium pressure water supply pump (28) High pressure water supply pump

Claims (2)

[Claims] 1. In an exhaust gas boiler of a combined cycle plant, a bypass duct for extracting a part of high-temperature exhaust gas from an upstream side of an inlet of an intermediate pressure evaporator and reintroducing it to the inlet of the intermediate pressure evaporator, and the bypass duct. An exhaust gas boiler evaporation amount control device, comprising: 2. In an exhaust gas boiler of a combined cycle plant, a bypass duct for extracting a part of high temperature exhaust gas from an upstream side of an inlet of a low pressure evaporator and re-introducing it to the inlet of the low pressure evaporator, and the bypass duct. An evaporation amount control device for an exhaust gas boiler, comprising: a damper.