DE967201C - System for generating compressed air - Google Patents

Description

The invention relates to a system for generating compressed air such. B. blast furnace wind, in the a gas turbine is used to drive a compressor, which is used both for the compressed air consumer as well as the amount of air required for the gas turbine’s own use to that for the compressed air consumer required pressure, and in which the gas turbine also has at least one Compressor drives in which the proportion of air required for gas turbine operation on the Maximum pressure of the gas turbine system is further compressed.

The operation of gas turbine systems to drive one to deliver compressed air to one Consumers of specific compressors usually require the supply of compressed air can be ensured at any time. This is particularly the case when the compressed air consumer is a blast furnace; here there may be an interruption in wind generation for the blast furnace have catastrophic consequences. With a failure of the gas turbine system, however, must without further ado be reckoned; A shutdown is not only achieved through periodic cleaning work on the turbine rotors or through overhaul of the plant parts of the gas turbine. Namely, the furnace gas of the blast furnace as If fuel is used for the gas turbine plant, the operation of the blast furnace entails, that there is not always an amount of blast furnace gas available that is necessary for the operation of the gas turbine system stands. Must have similar requirements

709 732/55

be fulfilled in other processes where an uninterrupted supply of compressed air is required is e.g. B. in compressed air systems in steelworks, production of nitric acid from ammonia gas etc.

A system according to the present invention makes it possible to solve the problem mentioned in an advantageous manner Way to solve. The invention is characterized in that in a known manner with

ίο the gas turbine connected via a transmission and the downstream compressor that can be decoupled from this has approximately the same pressure ratio as the Compressed air compressor and has such a swallowing ability that it can after disconnection from the Gas turbine and connection to one that also drives it in a manner known per se via a transmission electrical machine to deliver the amount of air required by the compressed air consumer - likes, after he continues on the inlet side from the flow path of the compressed air compressor Compressed air and on the pressure side separated from the gas turbine system and on its inlet side connected to the atmosphere and on its outlet side with the compressed air consumer has been.

There have already been proposed gas turbine systems for generating compressed air, in which a withdrawal of compressed air for the compressed air consumer from an intermediate stage of a single Compressor takes place. It has also been proposed to use gas turbine systems Generation of compressed air, the air supplied to the consumer and that for the gas turbine system to compress certain combustion air in separate flow paths, furthermore the gas turbine system only to be used for charging the wind heater during compression the blast furnace wind takes place in an independent flow path by means of turbo fans, which are driven by steam turbines. Furthermore, a gas turbine system for driving a for Delivery of compressed air to a consumer specific compressor known at which the pressure the air to be supplied to the consumers is less than the maximum pressure in the gas turbine system is. In this case, the gas turbine system can extract operating air from the machine, which is designed as a machine in itself Compressed air compressor supplied and further compressed in at least one compressor of the gas turbine system and a device can be provided to which a power excess of the turbine delivered and supplied by the additional power required by the drive of the compressor and which can also serve as a starting motor for the machine group when starting up. With none of these already proposed systems, the possibility has been recognized to set up the system in such a way that that in the event of a complete failure of the gas turbine, the air supply for the compressed air consumer is guaranteed under all circumstances.

The invention is described below with reference to the exemplary embodiments shown in the drawing explained in more detail.

1 and 2 show a schematic representation two different gas turbine plants according to the invention; The same parts shown in the figures are provided with the same reference numerals.

Part of the air sucked in from the atmosphere by the compressed air compressor 1 (Fig. 1) through the line 2 flows in a compressed state through the line 3 to a compressed air consumer labeled A - for example as furnace wind in a blast furnace or as compressed air in the converter of a Steel mill. A second part of the air conveyed by the compressed air compressor 1 flows through the line 4 via the intercooler 5 and the line 6 into the compressor 7 of the gas turbine system, which is used to drive the compressed air compressor. The air further compressed in the compressor 7 passes through the line 8 into the heat exchanger 9, from which it is fed in the preheated state through the line 10 to the combustion chamber 11 of the gas turbine system as combustion air. The combustion air is used here to burn the combustion gases supplied to the combustion chamber through the line 12 — for example furnace gases discharged from a blast furnace — which have been sucked in by the compressor 13 and compressed to the combustion chamber pressure. The hot combustion gases leave the combustion chamber 11 via the line 14, which feeds them to the gas turbine 15. After expansion in this turbine, the expanded combustion gases pass through line 16 into heat exchanger 9, where a remaining part of the heat still contained in them is withdrawn from them as they flow through pipe system 17 to preheat the combustion air supplied to the heat exchanger. The exhaust gases finally leave the system through line 18.

The gas turbine 15 is used to drive the compressed air compressor 1, with which it is coupled via a common shaft. At the same time, this serves Turbine to drive the compressor 7, with the X05 to increase the speed via a gearbox 19, 20 and a coupling 21 is connected. With the gear 19, the wheel 22 is also in Intervention which converts part of the drive power generated by the turbine 15 to the fuel gas no compressor 13 transmits. The gear 19, 20, 22 allows the compressor 7 and 13 with a for drive the required speed to achieve the most favorable efficiency possible.

The system described has an electrical machine 23, for example a three-phase motor, which is able to drive the compressor 7 independently of the gas turbine system via the gear 24, 25 and the clutch 26. Further, the inlet side of this compressor is connected by the line 27 with the atmosphere and its outlet side by the subsequent line 8 to the line 28 with the compressed air consumer A. In the lines 3, 6, 8, 27 and 28 arranged closing organs 29, 30, 31, 32 and 33 also enable the compressor 7 to selectively

wise can be connected to the compressed air compressor ι or to the atmosphere on the inlet side and optionally to the combustion chamber ii or to the compressed air consumer A on the outlet side. The clutches 21 and 26 are designed so that they can be engaged and disengaged in a manner not shown; By means of these clutches, the compressor 7 can be driven either by the turbine 15 of the gas turbine system or by the electric motor 23. For operation with drive by the gas turbine system, the closing elements 30, 31, 29 are opened and the clutch 21 is engaged, while the closing elements 32, 33 are closed and the clutch 26 is disengaged. For operation with direct delivery of compressed air to the compressed air consumer A by the compressor 7, which is driven independently of the gas turbine system by means of the motor 23, however, the closing elements 32, 33 are opened and the clutch 26 engaged, while the closing elements 29, 30, 31 are closed and the Clutch 21 can be disengaged.

The use of the compressor 7 of the gas turbine system to directly supply the compressed air consumption point A with compressed air means a valuable reserve option for the operation, because if the gas turbine system or the compressed air compressor fails for any reason, such as overhaul, repair or lack of fuel, the compressed air generation will continue to be maintained without having to keep a full reserve group on standby. This compressor 7 also proves to be readily suitable for such a use with regard to pressure increase, since the requirement that it can work with the same pressure ratio as the compressed air compressor 1 ensures economical operation of the gas turbine system. In addition, the gears 19, 20 and 24, 25 allow the speed of the compressor 7 to be adapted to the two different operating modes in such a way that the optimum efficiency can be achieved in each case.

The electric machine 23 can also be used as a motor for starting the gas turbine system will. For this purpose, both clutches 21 and 26 are engaged, as are all rotating machines in the system driven by the motor 23. After the speeds of the various turbo machines have been increased so high that ignition can be initiated in the combustion chamber the clutch 26 disengaged and the power supply to the motor 23 interrupted.

A successful operation of the system can also be achieved in that the electrical Machine 23 is designed such that it can act both as a motor and as a generator can come. DC machines or three-phase synchronous machines are particularly suitable for this purpose. These allow them, depending on the prevailing operating state of the system to cover the lack of drive power of the turbine 15 as well as to convert excess Driving power of this turbine could be used in electrical energy. The usage an electric start-up motor of a gas turbine plant as a generator for conversion excess power in electrical energy is known in and of itself.

Another system according to the invention is shown schematically in FIG. This differs from the in Fig. ι drawn system from the fact that the compressed air compressor 1 and the compressor 7 of the Gas turbine system with two mechanically independent, in the flow path of the combustion gases one behind the other gas turbines of the plant are driven. Same parts of the In Fig. ι and 2 systems shown are provided with the same reference numerals.

The combustion gases flowing out of the combustion chamber 11 are fed through the line 41 to the high-pressure turbine 42, from which, after they have been expanded to an intermediate pressure, they are passed through the line 43 into the downstream low-pressure turbine 44. The combustion gases, which have expanded to the final pressure in this turbine, are discharged through the line 16 via the heat exchanger 9 in a manner analogous to the exemplary embodiment shown in FIG. 1. The high-pressure turbine 42 drives the compressor 7, which in turn can optionally be driven via engaging and disengaging clutches 21 and 26 by the mentioned turbine or by the electric machine 23 and can thus also be used to directly supply compressed air to the compressed air consumption parts A. The low-pressure turbine 44 is used to drive the compressed air compressor 1 connected to it by a common shaft. This arrangement is particularly suitable for systems which, in addition to generating compressed air, are also used to generate electrical energy by means of the electric machine 23 that acts as a generator .

Claims (1)

PATENT CLAIM: System for generating compressed air, e.g. B. blast furnace wind, in which a gas turbine for Drive a compressor is used, both for the compressed air consumer and the amount of air required for the gas turbine’s own use to that for the compressed air consumer compresses required pressure, and in which the gas turbine also drives at least one compressor in which the for the Gas turbine operation required proportion of air to the maximum pressure of the gas turbine system is further compressed, characterized in that the in a known manner with the Gas turbine connected via a gear and disengaged from this downstream compressor approximately the same pressure ratio as the compressed air compressor and such Has the ability to swallow that he is after disconnection of the gas turbine and connection to an electrical one that also drives it in a manner known per se via a transmission Machine is able to deliver the amount of air required by the air consumer after it continues on the inlet side from the flow path of the air compressor Compressed air and on the pressure side separated from the gas turbine system and on its inlet side connected to the atmosphere and on its outlet side with the compressed air consumer has been. Considered publications: German Patent No. 744 427; Swiss Patent No. 244 430; "Stahl und Eisen", 1941, pp. 465 to 473; "Brown Boveri Communications," Nov-Dec. 1943, P. 369. 370- 1 sheet of drawings © 709 732/55 10.57