JP2896522B2 - Integrated coal gasification combined cycle power plant - Google Patents

Abstract

PURPOSE:To avoid stopping of the whole of a plant even at the time of trouble of a gas turbine, by leading steam generated by a cooling device for cooling emergently discharged gas, and gas discharged therefrom in a steam turbine and recuperator respectively. CONSTITUTION:A bypass line 23 is provided on an upper course side from a gas turbine 5, and a gas cooling device 13 is provided on the way of the bypass line 23 in order to cool emergently discharged gas. Two lines are provided in order to lead steam generated in the gas cooling device 13 into a steam turbine 9, and lead gas discharged from the gas cooling device 13 into a recuperator 8 respectively. At the time of trouble of a plant, for example, when there happens necessifity for stopping the gas turbine 5, the emergently discharged gas is led into the gas cooling device 13 through the bypass line 23, and steam generated therein is led into the steam turbine 9, while gas from the gas cooling device 13 is led into the recuperator 8 so as to recover heat. It is thus possible to avoid stopping the whole of the plant.

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to an integrated coal gasification combined cycle power plant that gasifies coal, burns generated gas with a gas turbine, and generates power.

[Conventional technology]

The integrated coal gasification combined cycle system is expected to become the mainstay of the future coal-fired thermal power plant in combination with high efficiency and excellent environmental adaptability, and recent advances in gas turbine high temperature technology.

IGCC plant, the partial oxidation process coal by air or oxygen to produce a gas rich in H ₂ and CO, and the product gas performs power generation led to the gas turbine, during the gasification of coal This is a power generation system using two types of turbines that guides steam generated by recovery of generated sensible heat and heat generated by heat recovery of gas turbine exhaust gas to a steam turbine, and generates power by utilizing the high efficiency of the gas turbine.

While the power generation efficiency of a steam turbine power plant using existing boilers is limited to a maximum of about 40%, the combined power generation system for coal gasification is expected to have a power generation efficiency of 43% to 44%. I have.

Here, FIG. 3 shows a system diagram of a conventional integrated coal gasification combined cycle power plant. In FIG. 3, 2 is a gasifier, 3 is a gas purifier, 4 is a compressor, 5 is a combustor, 6 is a gas turbine, 8 is a heat recovery device, 9 is a steam turbine, 18 is a denitration device,
19 is a chimney, 21 is a flare stack, and 22 is a condenser.

[Problems to be solved by the invention]

This integrated coal gasification combined cycle power plant is in the technical development stage, and it cannot be said that various problems in the practical stage have been sufficiently studied. For example, the reliability of high-temperature gas turbines, coal gasification facilities, etc., must be proven from now on. Further, even if the reliability is improved, there is no failure of the mechanical device, and it is necessary to take thorough measures for failure.

If it becomes necessary to stop the gas turbine 6 during these failures, even if the gasification furnace 2 is urgently stopped, that is, the supply of the raw coal 1 and the gasification air is stopped, Release of this gas is necessary due to residual coal and gas. In addition, the emergency stop has a serious adverse effect on the gasification furnace 2 and other facilities, and may cause a secondary failure. Further, once the device is stopped, a re-startup causes a great waste of labor, time, fuel and the like.

Heretofore, sufficient consideration has not been given to these in power plants. Generally, a gas release line is provided at an appropriate location, and an emergency release gas combustion facility such as the flare stack 21 is provided to release the combustion gas to the atmosphere. However, considering the power transmission and distribution, it is advantageous to install the power plant near the power demand area, and in the future, it will be often installed near the city, and the flare stack 21 will emit and burn a large amount of gas. There are problems such as the impact of environmental pollutants on the environment and anxiety to nearby residents.

Also, gas release from the gas release line leads to shutdown of the entire plant. That is, when the gas to the gas turbine 6 stops, the amount of steam generated in the downstream heat recovery device 8 disappears, the steam turbine 9 also stops, and therefore, all the plants are stopped. This shutdown of the entire plant wastes a great deal of time, including restarting, and operating costs such as fuel.

An object of the present invention is to solve the above-mentioned problems of the prior art,
In the event that emergency processing becomes necessary due to failure,
An object of the present invention is to provide an integrated coal gasification combined cycle power plant which does not adversely affect the environment, reduces the range of facilities to be stopped, and can avoid the entire shutdown.

[Means for solving the problem]

The above object is to provide a bypass line from the upstream of the gas turbine, a cooling device for cooling the emergency release gas in the middle of the bypass line, and a line for introducing steam generated by the cooling device to the steam turbine; This is achieved by providing a line for introducing gas discharged from the device into the heat recovery device.

Further, the above-mentioned object is to provide a bypass line from the upstream of the gas turbine, a buffer tank for introducing an emergency release gas in the middle of the bypass line, a combustion furnace for burning gas from the buffer tank, and a combustion furnace. This is achieved by providing a cooling device for cooling the gas of the present invention, providing a line for introducing steam generated by the cooling device to the steam turbine, and a line for introducing gas discharged from the cooling device to the heat recovery device. You.

[Action]

In the event of a plant failure, for example, the need to shut down the gas turbine, the emergency release gas is introduced into the cooling device via the bypass line, where the generated steam is
The gas from the cooling device while being introduced into the steam turbine is introduced into the heat recovery device to recover heat.

Also, in the event of a plant failure, for example, when it is necessary to shut down the gas turbine, the emergency release gas is introduced into the combustion furnace after the pressure and flow rate of the emergency release gas are adjusted in the buffer tank, and is burned. Is introduced into a cooling device, the steam generated here is introduced into a steam turbine, and the gas from the cooling device is introduced into a heat recovery device to recover heat.

Therefore, even when the gas turbine is shut down, it is possible to avoid shutting down the heat recovery system and the steam turbine power generation system, avoiding shutting down the entire plant, and not releasing emergency release gas to the atmosphere. Is eliminated.

〔Example〕

 Hereinafter, embodiments of the present invention will be described with reference to the drawings.

FIG. 1 is a system diagram showing one embodiment of the integrated coal gasification combined cycle power plant of the present invention.

In this integrated coal gasification combined cycle power plant, a bypass line 23 is provided from the upstream of the gas turbine 5, and a buffer tank 15 and a combustion furnace 1 are provided in the middle of the bypass line 23.
2. A gas cooling device 13 is sequentially installed. An emergency valve 16b is provided upstream of the buffer tank 15, and a pressure adjusting valve 17a is provided in a line connecting the buffer tank 15 and the combustion furnace 12.

The gas cooling device 13 includes a steam drum 14a,
The gas cooling device 13 and the steam drum 14a are connected by a heat pipe 20. And the gas cooling device 13
A line for introducing gas from the heat recovery device 8 to the heat recovery device 8 is provided.
A line returning to 14a is provided. Further, a line for introducing steam generated by the steam drum 14a into the steam turbine 9 is provided. Further, the gas purification device 3 and the combustion furnace 12 are connected by a fuel line 24 in which a pressure regulating valve 17b is interposed.

Note that, in the embodiment shown in FIG. 1, the same or corresponding parts as those in the apparatus configuration in FIG. 3 are denoted by the same reference numerals, and description of the configuration is omitted.

Next, the operation of the embodiment configured as described above will be described.

The coal 1 supplied to the gasification furnace 2 is partially burned by the gasification air 7 from the compressor 4 to produce H ₂ , CO and N ₂ , CO _2.
After gas removal and desulfurization by the gas purification device 3,
Introduced to the combiner 5 attached to the gas turbine 6,
Electric power is generated by the gas turbine 6, and the exhaust gas is recovered by the heat recovery device 8 and then guided to the chimney 19.

During normal operation, the emergency valve 16a on the upstream side of the
Is in an open state, the emergency valve 16b of the bypass line 23 is in a closed state, a purified gas is introduced into the combustion furnace 12 from a fuel line 24, and the fuel is constantly burning using this fuel as an ignition source.

If the plant fails and the gas turbine 6 needs to be shut down, an emergency valve on the main line to the gas turbine 6
16a is closed, and the valve 16b for emergency discharge to the combustion furnace 12 is opened. Since the released gas gradually decreases in pressure from the equivalent pressure in the system at the time of release, it is led to the buffer tank 15, where the pressure and the flow rate to the combustion furnace 12 are adjusted, and a sudden load change in the combustion furnace 12 is moderated. In addition, misfire or burnout of the combustion furnace 12 is prevented. A part of the purified gas from the gas purification device 3 is introduced into the combustion furnace 12 via the pressure regulating valve 17b, and is used as fuel for the combustion furnace 12.

In addition, the heat pipe type cooling device 13 installed downstream of the combustion furnace 12 easily absorbs the load increase and the combustion gas temperature increase during the emergency gas combustion, and reduces the heat recovery amount by generating steam in response to the load increase. Can increase. Steam drum 14a
Generated by the gasifier 12a
And the steam 11 b from the heat recovery device 8 and the steam 11 b. Further, the gas from the gas cooling device 13 is introduced into the heat recovery device 8 to recover heat.

For this reason, a decrease in steam in the power generation system of the steam turbine 9 can be suppressed, and the heat recovery device 8 and the steam turbine 9
Of the power generation system can be avoided, the stop range can be reduced to the gas turbine power generation system 9, and therefore, the stop of the entire plant can be avoided.

At start-up, until the gas from the gasifier 2 satisfies the conditions for introduction into the gas turbine 6, the gas is introduced into the combustion furnace 12 and subjected to combustion processing. After the heat is recovered by the gas cooling device 13,
Further, it flows to the heat recovery device 8. For this reason, it is possible to recover the heat loss at the start-up, which has conventionally been burned and released by the flare stack or the like, resulting in the heat loss.

When a failure occurs in the gas turbine 6 while satisfying the predetermined condition and performing the steady operation, the emergency valve 16a on the upstream side of the gas turbine 6 is closed and the emergency valve 16b of the bypass line 23 is opened. At this time, since the high-pressure gas suddenly flows into the bypass line 23, the high-pressure gas is introduced into the buffer tank 15, and after the fluctuation of the gas pressure is relieved, the pressure is regulated by the pressure regulating valve 17a. Sent to Thereafter, after the heat recovery as in the startup, the heat recovery device 8
Will be introduced. The heat pipe in the gas cooling device 13 can automatically follow the temperature rise caused by the sudden change in the amount of combustion in an emergency, and generate steam.

As described above, in an emergency at the time of start-up, it is possible to cope with the operation of the gasification furnace 2 while the amount of heat recovery is not largely changed. Therefore, it is extremely effective in an integrated coal gasification combined cycle power plant installed near a city where importance is placed on stability and reliability while avoiding shutdown of the entire plant.

The heat recovery in the heat recovery device 8 is performed in the form of steam generation, and the steam turbine 9 is driven by the steam to generate power, so that highly efficient combined power generation with the gas turbine 6 becomes possible.

FIG. 2 is a system diagram showing another embodiment of the integrated coal gasification combined cycle power plant of the present invention, showing an example applied to a pressurized fluidized bed boiler power generation system.

In FIG. 2, reference numeral 27 denotes a pressurized fluidized-bed boiler, reference numeral 28 denotes a dust remover, and other reference numerals indicate the same parts as those in FIG.

Also in this integrated coal gasification combined cycle power plant, when a failure occurs in the plant and the gas turbine 6 needs to be stopped, the emergency valve 16a of the main line to the gas turbine 6 is closed, and the emergency release of the bypass line 23 is performed. Open the valve 16b.
The released gas is introduced into the heat pipe type cooling device 13 after the pressure is adjusted by the pressure adjusting valve 17a. In the heat pipe type cooling device 13, the amount of heat recovery can be increased due to generation of steam or the like according to the load increase. The steam generated in the steam drum 14a is introduced into the steam turbine 9 together with the steam 11a from the pressurized fluidized bed boiler 27 and the steam 11b from the heat recovery unit 8. Further, the gas from the gas cooling device 13 is introduced into the heat recovery device 8 to recover heat.

[Effects of the Invention] As described above, according to the present invention, even when a gas turbine fails, it is not necessary to stop the entire plant, and the reliability as a power generation plant is improved. In addition, it is possible to suppress the loss of utilities and labor during the start-up operation due to the shutdown of the entire plant. Further, it is possible to prevent the occurrence of secondary trouble due to the emergency stop of the gas turbine, and it is possible to use the heat that has been wasted at the time of start-up as electric power at an early stage.

[Brief description of the drawings]

FIG. 1 is a system diagram showing one embodiment of an integrated coal gasification combined cycle power plant of the present invention, FIG. 2 is a system diagram showing another embodiment of the integrated coal gasification combined cycle plant of the present invention, and FIG. 1 is a system diagram of an integrated coal gasification combined cycle power plant. 2 ... Gasifier, 3 ... Gas purification device, 4 ... Compressor,
5 Combustor, 6 Gas turbine, 8 Heat recovery device, 9 Steam turbine, 12 Combustion furnace, 13
… Gas cooling equipment, 14a, 14b …… Steam drum, 15 ……
Buffer tanks, 16a, 16b Emergency valves, 17a, 17b Pressure control valves, 20 Heat pipes, 23 Pipe lines, 24 Fuel lines, 27 Pressurized fluidized bed boilers, 28
... Dust removal device.

Continuation of front page (56) References JP-A-1-147124 (JP, A) JP-A-59-231112 (JP, A) JP-A-63-147928 (JP, A) JP-A-63-290301 (JP) , A) Japanese Utility Model Application Sho 64-56502 (JP, U) Patent 2578210 (JP, B2) (58) Fields investigated (Int. Cl. ⁶ , DB name) F01K 23/02 F02C 9/46 F02C 3/28 F01K 23/10

Claims (2)

(57) [Claims] 1. Coal is converted into a gas containing hydrogen and carbon monoxide as a main component using a gasifying agent such as air using a coal as a raw material, and the gas is used as fuel for a gas turbine to generate power. In a coal gasification combined cycle power plant that includes a heat recovery device that recovers heat from gas and combines steam turbine power generation with by-produced steam, a bypass line is provided from the upstream of the gas turbine, and an emergency is provided in the middle of the bypass line. A cooling device for cooling the released gas is provided, and a line for introducing steam generated by the cooling device to the steam turbine and a line for introducing gas discharged from the cooling device to the heat recovery device are provided. Characteristic integrated coal gasification combined cycle power plant. 2. Using coal as a raw material and converting it into a gas containing hydrogen and carbon monoxide as a main component by using a gasifying agent such as air, generating a gas as fuel for a gas turbine, and generating a gas from the gas turbine. In a coal gasification combined cycle power plant that includes a heat recovery device that recovers heat from gas and combines steam turbine power generation with by-produced steam, a bypass line is provided from the upstream of the gas turbine, and an emergency is provided in the middle of the bypass line. A buffer tank for introducing the released gas, a combustion furnace for burning the gas from the buffer tank, and a cooling device for cooling the gas from the combustion furnace are provided, and steam generated by the cooling device is introduced into the steam turbine. A line for introducing gas discharged from the cooling unit to the heat recovery unit, If the power plant.