DE952223C - Power generation plant with gas turbine set - Google Patents

Description

ISSUED NOVEMBER 15, 1956

P 126671a} 46h

The invention relates to a power generation system with a gas turbine set, and on a machine system in which a gas turbine set and an internal combustion piston engine work in a network.

In the invention, a gas turbine set is used, which in the so-called "reverse" open circuit works. In such a cycle, the hot working fluid (gas) is in time Sequence initially relaxed to negative pressure in a turbine, then cooled, then compressed to approximately atmospheric pressure and finally blown out into the open.

It is already known to use hot exhaust gases with some atmospheric pressure as a working medium to use a "reverse" cycle. Another one has already been suggested Gas flow in an appropriate manner the main flow of the working medium before its entry into the turbine and mix it beforehand with simultaneous cooling of the from the turbine to heat the exiting working medium flow.

The invention aims to improve the adaptability of a reverse cycle working gas turbine set to the operational requirements.

The invention also aims to provide a power generation system with an internal combustion piston engine and to create a gas turbine set that allows for different power requirements

requirements to always achieve a good level of efficiency.

It is already known in power generation systems of the type mentioned in the connecting line an exhaust valve between the internal combustion engine and the gas turbine set provide that also allows operation of the internal combustion piston engine alone while the gas turbine set after appropriate switching of valves as a normal gas turbine set is operated.

The invention consists in that in a power generation system with an internal combustion piston engine and a gas turbine set with switching devices (Valves) is provided which allow the gas flow flowing through the system to be switched over, the switching devices or valves are designed and arranged in such a way that in one of their positions the gas flow flows first through a compressor and then through a turbine while in a second position hot gases from the internal combustion engine first through the turbine and then through the compressor stream.

In the first position of the valves, the gas turbine set works in the normal open circuit, while in the second position of the valves the gas turbine set works in the reverse cycle, whereby it absorbs the hot exhaust gases from the internal combustion engine. In this mode of operation an additional heat source may be present, which is added to the gas flow fed to the turbine set Provides heat, while the gas turbine set is a supercharger for the internal combustion engine drives.

Let particularly advantageous degrees of efficiency; achieve when the internal combustion engine is on | Diesel engine is. I.

For the practical implementation of the invention are in a power generation system with a gas turbine set operating in an open circuit, devices for suction, compression, expansion, controllable heating, cooling and purging of the working medium used and valves which allow the stages passed through by the work equipment in the following order: Inlet, heating, expansion, cooling, compression and blowing, or in the order: inlet, To switch compressing, heating, relaxing and blowing out.

The invention is illustrated below using the example of the combination of an open circuit Gas turbine set and a diesel engine are explained in more detail.

Such a machine system is shown schematically in the drawing; it shows

Fig. Ι the circuit diagram of a machine system, Fig. 2 a compilation of the possible Operating modes of the system according to FIG. 1 in the form of a table.

The machine system, the basic structure of which is shown in Fig. Ι, contains a diesel engine 10. The exhaust gases of the diesel engine are 'led from the exhaust manifold of the engine to valve Ά , which - depending on 6g of its position - the gases either through line 11 to The inlet of the turbine 12 or via the pipe 13 directly into the open air. With the inlet of the turbine 12, the outlet of the combustion chamber 14 is also connected, which is supplied via the valve B working medium. The valve B can be connected either to the valve C or to one side of the heat exchanger 16 via the line 15.

The exhaust line 17 of the turbine 12 is directly connected to a valve D which either switches this line to the pipe 18 leading directly into the open air or connects it to the other side 19 of the heat exchanger 16. The other end of the heat exchanger side 19 is connected to the valve E via a second heat exchanger 20. A line leads from valve E to the inlet connection of the compressor 21.

A pipe 22 which is open to the outside is seated on the valve F, which allows this pipe to be connected to the inlet connection of the compressor 21 or to the part 16 of the first heat exchanger.

The turbine 12 and the compressor 21 have a common shaft 23; they are designed as a self-propelled unit. On the over the Compressor 21 protruding extension 24 of the shaft 23, a supercharger 25 is attached. Fresh air can enter the blower 25 through the open pipe 26. The compressed in the fan 25 Air is supplied to the diesel engine 10 via the line 27. The shaft 23 ends in the Stub shaft 28 on which a coupling 29 is provided for taking off mechanical power. Mechanical power can also be drawn from the coupling flange 30 of the diesel engine shaft will. If desired, these two coupling flanges can be mechanically connected to one another. In the heat exchanger 20, the working medium flow flowing through the heat exchanger can heat can be withdrawn by the cooling water circuit 31.

The machine installation according to FIG. 1 can be operated in several different operating modes. These different operating modes are specified in detail in a table (FIG. 2).

Initially, the diesel engine can work alone, with the entire power being output via the coupling flange 30. The exhaust gases from the diesel engine are blown through the pipe 13 into the open. The working medium circuit of the gas turbine set is closed off from the open air space by valves C, D and F. It should be clear that the circular segments in the columns of the table indicate the positions of the valves and correspond to the respective position of the valves shown in FIG.

In the second operating mode, the exhaust gases of the diesel engine are not through the pipe 13 into Blown free, but passed through the pipe 11 to the inlet of the turbine 12. The exhaust

Gases are of course hot and have a pressure that is only slightly above atmospheric pressure. In the turbine 12, the exhaust gases are expanded to below atmospheric pressure; they are then passed to the compressor 21 via the heat exchangers 16/19 and 20. It should be noted that the valves A, D and E in Fig. 1 are drawn in that position which they assume in such an operating mode. In contrast, the valve B closes off any air flow via the heat exchanger 16 to the combustion chamber 14, so that no air can flow through the upper side of the heat exchanger. As a result, the gas flow through the side 19 of the heat exchanger 16 does not give off any heat. The water cooling circuit 31 is in operation, however, and the heat from the turbine exhaust gases is absorbed by the water. The cooled gases pass through the compressor 21 - which is driven by the turbine 12 - and are compressed to or slightly above atmospheric pressure. The gases are expelled via valve C, which opens the exhaust line leading to the outside.

In the third operating mode, use is made of an already known operating mode, according to which an additional flow of working medium is introduced in an inverted open circuit and is to be combined with the main working medium flow immediately at the inlet of the turbine. In the present case, this additional flow is fresh air, and since it is passed over the heat exchanger 16, it is able to absorb heat from the expanded exhaust gases which flow through the other side 19 'of the heat exchanger. In order to pass from the second mode into the third, it is only necessary to change the position of the valve B so that via valve F from the suction nozzle 22 forth fresh air through the heat exchanger 16, the valve B _1, the combustion chamber 14 the inlet of the turbine 12 can flow. In order to suck in the air, a fan can be built into this circuit on the intake port 22. The power output at the coupling flange 29 can in this case be easily controlled by burning fuel in the combustion chamber 14 and bringing the amount of fuel supplied to the combustion chamber in accordance with the required power. If a larger amount of fuel has to be burned in the combustion chamber 14, an additional air supply to this chamber may be necessary. The supply pipe that may be required for this is indicated by dashed lines in FIG. 1. The additional supply of thermal energy in the manner described above can be viewed as a further operating mode of the machine installation, although here the valves remain in the position that they assume in the third operating mode.

If a very large power output is required, the compressor gas turbine set can be operated in an ordinary open circuit as a departure from the previously described reverse open cycle. All that is required for this is a corresponding setting of valves A to F 6g. In this fifth operating mode, the exhaust gases from the diesel engine are again conducted directly into the open via the pipe 13 and the working medium for the gas turbine circuit is sucked in through the intake port 22. The valve F is then in such a position that this freshly drawn in air is supplied directly to the compressor 2 L, while the valve E is in such a way that it prevents the air from flowing into the heat exchanger 20. The air compressed by the compressor 21 is prevented from being blown out into the open by the valve C and is pressed directly into the line 15. From here it flows through the valve B to the combustion chamber 14. The compressed hot gases flow from the combustion chamber into the turbine 12 and, after they have been expanded, through the tubes 17 and 18 to the outside. In this operating mode, the pressure of the working medium in the compressor and the turbine is higher than the corresponding pressure that is present in the reverse cycle. As a result, more useful work can be achieved.

It should be understood that the arrangement described above enables a number of modes of operation, from normal diesel operation just up to the combination of a diesel engine and one working in a simple open circuit Gas turbine set. There are a number of possibilities between these two extremes the operational management with mutually different thermal efficiencies "of the whole System and different power output. When evaluating the increase in thermal Efficiency of the entire system, it should be noted that 40% of the heat content of the dem Diesel engine fuel supplied in the exhaust gases during normal diesel operation; if 15% of this loss in a gas turbine set can be recovered, this is equivalent to an increase in the total thermal efficiency by 6%.

During the operation of the combustion chamber 14, both the mass and the temperature of the gas flow supplied to the turbine are increased. Correspondingly, the inlet pressure of the turbine must also be increased if its "absorption capacity" is not changed. This latter measure must be applied if <\ he will tolerate no diesel engine back pressure; variable inlet vanes at the turbine inlet provide a satisfactory solution. The compressor must then also be equipped with adjustable inlet blades; However, it can also be equipped with a blade-free inlet device for a further operating area.

A person skilled in the field in question here will understand that ¹ the combination of an internal combustion piston engine with a gas turbine operating in the reverse open circuit compared to the known proposals according to which an internal combustion engine is

driven simple turbine is used insofar as the reverse open one offers advantages Circuit does not lead to significant back pressures on the internal combustion engine. As a result, the engine kafm work at its normal performance; its utilization is made by the additional operation of the gas turbine set is not deteriorated in any way.

The use of a machine system ίο according to the invention results in a good thermal Efficiency; in addition, a very substantial additional peak power is available. A single control lever can be used for setting the valves and metering the System-supplied fuel are provided. One possible application of such a The system is useful for generating electrical power when peak loads are absorbed should. It can either be the diesel engine or the ao gas turbine - which is then in an open circuit works - be designed for the delivery of normal power, the diesel engine of course has a better thermal efficiency than Gass5, which works in a simple open circuit turbine. Nevertheless, there is the possibility of using either one or the other of the two power generators with the normal load alone, the advantage that you can take the diesel engine out of operation for necessary maintenance work can put. The combination of the diesel engine and the gas turbine set (reverse or simple open circuit) can meet all load requirements up to the permissible overload limit will.

If the above detailed description assumes a diesel engine for the internal combustion engine, this is done only because of the great advantages that according to the invention in use of a diesel engine. The thermal efficiency of the diesel engine is sufficient in itself high, so that the utilization of the large amounts of heat generated in the exhaust of such machines lost brings very significant advantages.

Claims (2)

PATENT CLAIMS: i. Power generation system with an internal combustion piston engine and a gas turbine set, wherein switching devices (valves) are provided which enable switching of the allow gas stream flowing through the system, characterized in that the switching devices, z. B. Valves, are designed and arranged such that in one of their positions, the gas flow initially through a Compressor and then flowing through a turbine while in a second position hot gases of the internal combustion engine first flow through the turbine and then through the compressor. 2. power generation system according to claim 1, characterized in that the switching devices, z. B. Valves, are arranged and designed so that they are simultaneously with the first gas flow path to create an inlet and an exhaust for the internal combustion engine. Considered publications: German Patent Nos. 881 125, 314347; British Patent No. 578,120; U.S. Patent No. 2503410; published documents of the German patent application L 5652 Ia / 46t (patent no. 884130); Journal: "The Engineer", Vol. 192 (1951), No. 5001, p. 707. 1 sheet of drawings © 609 526/40 5.56 (609 682 11.56)