JP2856860B2 - Gas turbine equipment - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial application field) The present invention is performed in a gas turbine facility having a dual fuel system of liquid and gas before switching fuel from liquid fuel to gas fuel. The present invention relates to inert gas purging of gas fuel piping.

(Prior Art) In recent years, gas turbines using low calorie fuels (calorific value of 3000 Kcal / Kg or less) such as blast furnace exhaust gas and coal gas have been widely used for energy saving and energy diversification.

Such low-calorie gas fuel generally has poor ignitability at start-up and combustion stability at low load, so a dual fuel system of liquid fuel and gas fuel is provided in the fuel system of the gas turbine equipment. At the time of startup and low load, liquid fuel is used.

Of course, even when using a high calorie gas fuel such as LNG, a dual system may be configured to provide flexibility in switching the fuel used during operation, but like coal gas, In the case of gas turbines that use fuel gas with a low calorific value, use a dual fuel system from the viewpoint of safety.
At the time of startup, a method is adopted in which the gas turbine is started up using liquid fuel, and after reaching a predetermined load, the gas turbine is switched to low calorie gas fuel. Also, when the gas turbine is stopped,
It is common practice to switch to liquid fuel after reaching a predetermined load and stop with liquid fuel.

FIG. 2 shows an example of a conventional gas turbine facility provided with a dual liquid and gas fuel system.

In the figure, the operation at the time of starting the gas turbine and up to the switching load to the fuel gas is performed with the liquid fuel. In this case, the liquid fuel is sent out from the liquid fuel tank 1, and is pressurized by the fuel transfer pump 2 and the gear pump 3 and supplied to the combustor 5. At this time, the flow rate of the liquid fuel is adjusted by the liquid fuel control valve 4.

The liquid fuel that has entered the combustor 5 is sprayed air (not shown).
As a result, the fuel becomes mist-like fuel, mixes with air from the compressor 6 and burns, and turns into high-temperature combustion gas to drive the turbine 7.

On the other hand, in the gas fuel system, a fuel gas gate valve 9, a gas fuel pressure control valve 10, and a gas fuel control valve 11 are sequentially provided in a line from the fuel gas generator 8 to the combustor 5.
Further, the bleed air of the compressor 6 is supplied to the downstream side of the gas fuel control valve 11 via the booster compressor 12 and the air purge inlet valve 13. Reference numeral 14 denotes an inert gas stop valve.

During the combustion of the liquid fuel, the fuel gas gate valve 9 is closed, and the combustor 5 and the fuel gas generator 8 are partitioned. In this case, after the air purge inlet valve 13 is opened and the bleed air from the compressor 6 is boosted by the boost compressor 12,
It is supplied to the downstream of the gas fuel control valve 11 as purge air.

As described above, when the liquid fuel is used, the gas fuel control valve 11 is used.
The purpose of purging the downstream of the air with the air is to prevent the high-temperature combustion gas from cross-flowing between the combustion chambers through the fuel gas pipe immediately before the combustor 5 and to prevent the gas fuel nozzle operating with the liquid fuel from flowing. This is to keep it clean.

When the gas turbine reaches a predetermined load, the fuel is switched from liquid fuel to gas fuel. At this time, the gas fuel is directly introduced into the combustor 5 because the mixed atmosphere of fuel gas and air is provided downstream of the gas fuel control valve 11. It is not preferable because of the danger of explosion.

Therefore, just before switching from liquid fuel to gas fuel,
The downstream side of the gas fuel control valve 11, which has been performing the air purge, is purged with the inert gas.

The inert gas purge is performed by closing the air purge inlet valve 13, opening the inert gas stop valve 14, and introducing the inert gas downstream of the gas fuel control valve 11 for a certain period of time.

On the other hand, shortly before the inert gas purge, the fuel gas gate valve 9 is opened and the fuel gas flows until just before the gas fuel pressure control valve 10 in preparation for the coming fuel switching, and the piping is warmed. Here, the gas fuel pressure control valve 10
Is for controlling the pre-pressure of the gas fuel control valve 11,
It also has a gas fuel shutoff function on the gas turbine side.

After the inert gas purge downstream of the gas fuel control valve 11 is completed in a predetermined time, the gas fuel pressure control valve 10 and the gas fuel control valve
11 is opened, fuel gas is introduced into the combustor 5, and fuel switching is performed. This fuel switching is described in, for example,
This is performed by a method as described in JP-A-243934.

The fuel switching procedure during the use of the liquid fuel described above is summarized as follows.

(B) Air purge downstream of the gas fuel control valve 11 in the gas fuel line.

(B) Open the gas fuel isolation valve 9 and warm the gas fuel line.

(C) Inert gas purging downstream of the gas fuel control valve 11.

(D) After the inert gas purge is completed, the gas fuel control valve 11 is opened, and the fuel is switched from liquid fuel to gas fuel.

(Problems to be Solved by the Invention) In the above-described fuel switching according to the related art, before the gas fuel switching, the gas fuel isolation valve 9 is opened and the gas fuel pressure control valve 10 is warmed up to the front. When the fuel gas leaks from the gas fuel pressure control valve 10 and the gas fuel control valve 11 and flows downstream of the gas fuel control valve 11 during air purging, a mixed atmosphere of gas fuel and air is formed in this portion, Because of the oxygen-rich state, there is a risk of explosion even with a small amount of ignition medium.

SUMMARY OF THE INVENTION The present invention has been made in order to solve such a problem, and the fuel gas leaks downstream of the gas fuel control valve during warming of the fuel gas line performed before switching from liquid to gas fuel. It is an object of the present invention to provide a gas turbine facility that prevents gas fuel from mixing downstream of a gas fuel control valve during an air purge to an inert gas purge, thereby avoiding the risk of explosion.

[Configuration of the Invention] (Means for Solving the Problems) A gas turbine facility of the present invention is capable of burning liquid fuel and gas fuel, and capable of switching between fuels during operation, and a dual fuel system. In a fuel system of a gas turbine facility having a purge air supply system for supplying purge air downstream of a gas fuel control valve during combustion of liquid fuel, an inert gas supply system is provided upstream of the gas fuel control valve. An inert gas having a pressure higher than a pressure of purging air is supplied to an upstream side of the gas fuel control valve downstream of the liquid fuel during combustion of the liquid fuel by the gas turbine. It is.

(Operation) As described above, in the gas turbine equipment of the present invention, a high-pressure inert gas is supplied between the gas fuel pressure control valve and the gas fuel control valve. (It shall be sufficiently higher than the downstream purge air pressure and the inert gas purge pressure, and higher than the fuel gas pressure.)
This shuts off the fuel gas in front of the gas fuel pressure control valve and the air during the air purge downstream of the gas fuel control valve.

This high-pressure inert gas purge is performed at the time of piping warming to the gas fuel pressure control valve before switching to gas fuel is started, and a high-pressure inert gas atmosphere is provided between the gas fuel pressure control valve and the gas fuel control valve. This prevents the formation of a mixed atmosphere of gas fuel and air downstream of the gas fuel control valve due to fuel gas leakage.

Example Next, an example of the present invention will be described with reference to the drawings. The same reference numerals are given to the same parts in FIG. 2, and description of the same parts will be omitted unless necessary.

In FIG. 1, a high-pressure inert gas supply line 20 is connected upstream of the gas fuel control valve 11,
And an inert gas gate valve 21 between the gas fuel pressure control valve 10 and
A high-pressure inert gas is supplied via the.

Further, downstream of the gas fuel control valve 11, an inert gas from a high-pressure inert gas supply line 20 is supplied under reduced pressure by a pressure reducing valve 22.

When switching the fuel system from liquid fuel to gas fuel in the equipment of the present invention having such a configuration, first, the inert gas separation valve 21 is opened, and a high-pressure inert gas is provided upstream of the gas fuel control valve 11. In order to warm the gas fuel pipe to the gas turbine, the gas fuel isolation valve 9 is slightly opened, and a small amount of gas fuel flows to the upstream of the gas fuel pressure control valve 10 to perform warming. At this time, the air downstream of the gas fuel control valve 11 is still being purged.

When a predetermined time has elapsed and the warming upstream of the gas fuel pressure control valve 10 is completed, an inert gas purge downstream of the gas fuel control valve 11 is performed.

This inert gas purge is performed by first closing the air purge inlet valve 9 provided on the outlet side of the air pressure compressor 12, opening the inert gas stop valve 14, and discharging the low-pressure inert gas reduced by the pressure reducing valve 22. This is carried out by introducing the fuel control valve 11 downstream.

After performing the inert gas purge for a certain period of time, the low-pressure inert gas stop valve 14 is closed, and at the same time, the high-pressure inert gas gate valve 21 is closed.
To close the inert gas purge, open the fuel gas gate valve 9, and control the opening of the gas fuel pressure control valve 10 and the gas fuel control valve 11, while introducing the fuel gas into the combustor 5, and The fuel is switched from gas to gas fuel.

As described above, in the gas turbine equipment of the present invention, when switching fuel from liquid fuel to gas fuel, high-pressure inert gas is introduced upstream of the gas fuel control valve 11 in order to avoid contact between fuel gas and air. However, by creating a high-pressure inert gas atmosphere on the secondary side of the gas fuel pressure control valve 10, even if there is a leak when the gas fuel pressure control valve 10 is fully closed, the back pressure of the fuel gas causes Intrusion can be suppressed, and therefore, contact between air and gas fuel downstream of the gas fuel control valve 11 can be prevented.

In the above description, the embodiment in which the high-pressure inert gas is supplied before the fuel is switched from the liquid fuel to the gas fuel has been described. When the gas generating section is operating and the gas pressure in the fuel gas pipe to the gas turbine is high to some extent, that is, when the gas fuel supply pressure is higher than the gas turbine combustor pressure (about 20 kg / cm ² ) Since there is a risk that fuel gas leaks downstream of the gas fuel control valve 11,
In such a case, a high-pressure inert gas may always be supplied to the upstream side of the gas fuel control valve 11.

For example, when the gas pressure detector 23 indicates a predetermined pressure or more during the use of the liquid fuel, the inert gas gate valve 21 is kept open to allow the gas fuel to flow upstream of the gas fuel control valve 11. Intrusion can be prevented. FIG. 3 shows an example of the control logic of the inert gas gate valve 21 in this case.

[Effects of the Invention] As described above, according to the present invention, when the gas turbine equipment is operated with the liquid fuel, the formation of the mixed atmosphere of the fuel gas and the air caused by the leak of the fuel gas is suppressed, whereby the mixing is performed. The risk of explosion due to the fuel can be avoided, and the fuel switching from liquid fuel to gas fuel can be realized safely.

[Brief description of the drawings]

1 is a system diagram showing an embodiment of the gas turbine equipment of the present invention, FIG. 2 is a system diagram illustrating a conventional gas turbine equipment, and FIG. 3 is a control of an inert gas gate valve in a modification of the present invention. It is a logic diagram. DESCRIPTION OF SYMBOLS 1 ... Liquid fuel tank 2 ... Fuel transfer pump 3 ... Gear pump 4 ... Liquid fuel control valve 5 ... Combustor 6 ... Compressor 7 ... Turbine 8 ... Fuel gas generation part 9 ... Fuel gas partition Valve 10: gas fuel pressure control valve 11: gas fuel control valve 12: boost compressor 13: air purge inlet valve 14: inert gas stop valve 20: high-pressure inert gas supply line 21: inert Gas gate valve 22 Pressure reducing valve 23 Gas pressure detector

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Claims (1)

(57) [Claims] 1. A dual fuel system capable of burning liquid fuel and gas fuel and capable of switching between fuels during operation, and supplying purge air downstream of a gas fuel control valve during combustion of liquid fuel. In a fuel system of a gas turbine facility having a purge air supply system, an inert gas supply system is provided upstream of the gas fuel control valve. Gas turbine equipment characterized in that an upstream side is supplied with an inert gas having a pressure higher than a pressure of purging air downstream thereof.