CH630441A5 - AIR STORAGE GAS TURBINE POWER PLANT AND METHOD FOR OPERATING IT. - Google Patents

Description

The present invention relates to an air storage gas turbine power plant according to the preamble of claim 1. It also relates to a method for its operation.

The previously operated gas turbine systems with air accumulators had to have their own drive machine in addition to a generator when the air accumulator was unloaded in order to start up the compressor group, which in addition to supplying the gas turbine combustion chamber with air and also filling the air accumulator. In order to start up the compressor group, this generator was electrically coupled to the drive motor of the compressor group via an additional line, which was separated from the rest of the network. The compressor group was then in the so-called frequency ramp-up from zero speed, i. H. ramped up from standstill to the generator frequency. After reaching the network frequency, the drive motor of the compressor group was switched to the network and thus the drive power for the compressor group was fed from the network, after which the generator, which was now free, could supply the network with power or be switched off (see BBC announcements No. 65 / 1975, No. 7/8).

In this known arrangement, the great technical effort had a particularly disadvantageous effect, since a high-performance drive machine had to be provided.

It is an object of the present invention to provide an air storage gas turbine power plant and a method for its operation, in which a compressor group of a gas turbine installation with a relatively low-conduction air storage unit can supply the gas turbine installation with the required combustion air when the air storage unit is discharged.

According to the invention, the aforementioned object is achieved by the characterizing features of patent claim 1.

The ability to switch the low-pressure part of the compressor group so that it is only connected to the low-pressure part of the gas turbine and to convey the medium and high-pressure parts of the compressor group into the atmosphere during start-up results in the advantage that a starter motor with low output is activated the compressor group can be used.

The method for operating the air storage gas turbine power plant of the type mentioned is characterized in claim 2.

The advantage of the method according to the invention can be seen in particular in the fact that a special starting group is not required due to the design of the starter motor with low power, as a result of which no special mains cable is required.

Furthermore, the gas turbine can be uncoupled from the motor generator and the motor generator can take power from the network to charge the air accumulator, and the middle and high-pressure parts of the compressor group can be switched on in succession according to the state of charge of the air accumulator, and that during generator operation and discharged air accumulator, the high-pressure part of the Ignited gas turbine and the compressor group alone takes over the air supply to the combustion chambers of the gas turbine.

Furthermore, in one embodiment of the method according to the invention, when the gas turbine is started up, the middle and high-pressure part of the compressor group can remove purge air from the atmosphere and convey it back into the atmosphere.

According to a further embodiment of the method, the high-pressure part of the gas turbine is acted upon by a reduced air flow when it starts up.

This prevents the high-pressure part of the gas turbine, the combustion chamber of which is not ignited, from being overheated by the compressed air.

In the drawing, an exemplary embodiment is shown as a circuit diagram, 1 being a gas turbine with a high-pressure part 2 and a high-pressure combustion chamber 3, and a low-pressure part 4 with a low-pressure combustion chamber 5. A compressor part 7 with a low-pressure part 8, a medium-pressure part 9 and a high-pressure part 10 is arranged on a common shaft 6 with the gas turbine 1. A gear 12, for example a reduction gear, is provided between a starter motor 11 and the compressor part 7. The gas turbine 1 and the compressor part 7 are connected to the motor 6 by means of couplings 13 on the shaft 6. The low-pressure part 8 of the compressor group 7 is connected via an outlet line 15 to the low-pressure part 4 of the gas turbine 1, while the outlet lines 16, 16 ', 17 of the compressor parts 9, 10 open into a common feed line 18 to an air reservoir 19, which via a branch line 20 is connected to the high pressure combustion chamber 3 of the gas turbine 1. Furthermore, the outlet from the compressor low-pressure part 8 is connected via a line 21 to the inlet of the compressor part of the medium-pressure part 9 and the outlet of the latter is connected to the inlet into the high-pressure part 10 via a line 22. Intermediate coolers 23, blow-out valves 24, 25, 26 and bypass valves 27, 28 designed as three-way valves are arranged in the lines 21, 22. A further cooler 29 and shut-off device 30, 31 are provided in the supply line 18 to the air reservoir 19. The outlet lines

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16.16 '. 17 to Ztifiihrungsleitiinj IS, heat accumulations can be avoided with non-return flaps. As soon as the full nominal

32,33,34. Before the entry of the branch line 20 in speed and thus the line frequency of the motor generator 14

the high-pressure combustion chamber 3 is a shut-off valve 35 and is reached in, the motor-generator 14 is connected via the connections 37

the outlet line 15 a valve 36 is arranged. The flow is switched to the network and now acts as a drive motor. The directions in the individual lines are indicated by arrows. 5 Low-pressure combustion chamber 5 is extinguished and the shut-off valve

points. Via connections 37, the motor-generator 14 can be closed on the valve 35, while the shut-off device 31 is open and on

Network. Blow-out valve 24 the air flow to the intercooler 23 entirely

The mode of operation of the method according to the invention is released. The valve 36 in the outlet line 15 becomes as follows: Before the starter motor 11 is switched on, it is also closed and the gas turbine 1 via the clutch 13

Couplings 13 between the gas turbine 1 and the engine 10 separated from the engine generator 14. Now the Lower

Generator 14, and between the motor generator 14 and the pressure part 8 of the compressor group 7 via the outlet line 15.

Compressor part 7 coupled so that an uninterrupted line 21, cooler 23, check valve 32 and

A shaft line is created in the entire system. The blow-out valve feed line 18 directly into the air reservoir 19.

24 is closed, so that there is no connection either to the atmosphere or after the charge line 18 has reached a corresponding charge state. The shut-off 15 air accumulator 19 is at the blow-out valve 25 and the bypass valve 35 to the high-pressure combustion chamber 3 is also closed valve 27 release to the atmosphere and to the sen. while the valve 36 in the outlet line 15 remains open from the lines 16 and 21 and to the non-return valve 32, 33, the low-pressure part 9 of the compressor group 7. The and the further charging of the air accumulator 19 by the low blow-out valves 25 and 26, and the bypass valves 27, 28, which pressure part 8 and the medium pressure part 9 continue together, are designed as three-way valves so that 20 If the pressure in the air accumulator 19 increases further , which both the medium-pressure part 9 and the high-pressure part 10 of the connection of the high-pressure part 10 of the compressor part 7, the compressor part 7 can suck air from the atmosphere and makes it necessary, is by switching the Ausblasven-through the valves 25,26, in again the atmosphere tiles 26 and the bypass valve 28 can be blown out analogously to that previously described. This results in the medium and high pressure level of the medium pressure part 9, the high pressure part 10 for the Aufla part of the compressor divider 7 only a little resistance and it 25 dung of the air reservoir 19 is used. Now, in the last part of the filling process, a low-power prime mover can use the air flow to be used for air supply. After the starter motor 11 has been switched on, it additionally conveys air via the outlet line 17, the non-return low-pressure part 8 of the compressor group 7 via the flap 34 and the feed line 18.

Step line 15 directly into the low-pressure combustion chamber 5 of the case of the air accumulator 19 for some reason, at low-pressure part 4 of the gas turbine 1. After the ignition 30, for example, a revision, is not available, the speed of the low-pressure part 4 could become the low-pressure combustion system operate as a normal gas turbine plant, d. H. chamber 5 ignited and the system to the nominal speed and that after connecting the motor generator 14 to the network, the network frequency is ramped up. In order to ignite a backflow into the high-pressure combustion chamber 3 and to prevent the blow-out high-pressure part 2 of the gas turbine 1, as a result of which a tile 25, 26 and the bypass valves 27, 28 of the compressor part 7 could overheat this part, the shut-off valve 35 can be set that the medium-pressure part 9 and the high valve 35 and the shut-off element 30 are opened, but the pressure part 10 of the compressor part air into the gas turbine 1 for shut-off element 31 to the air reservoir 19 must then be closed. the. For this, the valve 36 must be closed and the shut-off valve 35 and the shut-off clutch 13 between the gas turbine 1 and the engine generator 30 are preferably only opened to the extent that a reduced connection gate 14 and between the engine generator 14 and that takes place to the high pressure part 2, whereby this is rinsed and 40 compressor part 7 remain coupled.

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1 sheet of drawings

Claims (6)

630 441 PATENT CLAIMS 1. Air storage gas turbine power plant, in which the gas turbine system consists of a multi-part gas turbine (1) and a multi-part compressor group (7), which can be uncoupled with a motor generator (14) on a common shaft (6), characterized in that a starter motor (11) is provided for driving the compressor group (7) and the low pressure part (8) of the compressor group (7) is connected to the low pressure part (4) of the gas turbine (1), and that the outlets of the compressor parts (7) are both connected an air reservoir (19) and also via a common line (20) to the high-pressure combustion chamber (3) of the gas turbine (1). 2. The method for operating the air storage gas turbine power plant according to claim 1 when the air storage is discharged, characterized in that the compressor group (7) is driven by the starter motor (11) and compressed air by the low pressure part (8) of the same in the separate low pressure part (4) of the gas turbine ( 1) is directed, the low-pressure combustion chamber (5) is ignited when the ignition speed is reached, whereby the gas turbine is run up to the nominal speed, and that when the nominal speed and thus the grid frequency is reached, the motor generator (14) is connected to the grid. 3. The method according to claim 2, characterized in that the gas turbine (1) is uncoupled from the motor generator (14) and the motor generator (14) draws power from the network for charging the air accumulator (19), and that correspondingly The state of charge of the air accumulator (19) can be switched on one after the other in the middle (9) and high pressure section (10) of the compressor group (7). 4. The method according to claim 2, characterized in that during generator operation and discharged air reservoir (19) the high pressure part (2) of the gas turbine (1) is ignited and the compressor group (7) the air supply to the combustion chambers (3, 5) of the gas turbine (1 ) takes over alone. 5. The method according to claim 2, characterized in that when starting the gas turbine (1) the middle (9) and the high pressure part (10) of the compressor group (7) remove purge air from the atmosphere and convey it back into the atmosphere. 6. The method according to claim 2, characterized in that the high pressure part (2) of the gas turbine (1) is acted upon during startup with a reduced air flow.