DE1103687B - Gas turbine plant - Google Patents

Description

Gas turbine system The invention relates to a gas turbine system with the use of waste heat, preferably in the sense of a heating and power plant. the through Heat exchanger for the exhaust gases. heat is extracted from the turbine and from the medium of the heating circuit is fed.

With the previously known combined heat and power systems, it is only partially possible to use the waste heat from the gas turbine to deliver .der Heilzwärm @ e. The temperatures, with which the Alb gases leave the plant in the open gas turbine process are then still relatively high. In contrast, the invention solves the problem of exhaust gas losses significantly reduce and thus increase the profitability of the system.

In such a gas turbine system with waste heat utilization - preferably in the sense of a heating and power plant - in which the exhaust gases are passed through heat exchangers Heat extracted from the turbine is fed to the medium of the Hoi @ zlcre-is, barrel and; a part .the turbine exhaust gases are returned to the turbine working fluid the discovery that the return is carried out in a known manner via im low temp, eraturberench lying at least partially as trickle devices trained heat exchange devices and a regenerative Verd.ichter takes place and that the amount of toilet returned is metered so that it comes from fresh Working medium and recirculated vapors create a mixture. with steam generator boiler exhaust gases has a comparable content of carbonic acid and water vapor.

A method for operating a gas turbine system with a regenerative heat exchanger and waste heat recovery has already become known, in which heat extracted from the exhaust gases of the turbine by heat exchangers is fed to the medium of a heating circuit. Here, a subset of the turbine exhaust gases is also fed back to the turbine working fluid. World genetic it has become known to .sich at a powered with a gaseous Arbeitstnitbel Kraftmaschinenandage this feedback opposite in low temperature region formed as Rieseleinrichtung Wärmeau.stauschereinrichtung un d ativ make a compressor Regene @. On the other hand, it is important for the invention to dose the recirculated partial amount in a very specific way. In this way, the invention provides the possibility of an extremely economical mode of operation, in that the mixture has a carbon fringing and water vapor content comparable to that of economically operated boiler firing systems by means of the measurement of the vapor supply.

The invention is to be explained in more detail with reference to the drawing. the Figure shows an embodiment in its essential parts for the invention in a simplified schematic representation.

The gas turbine is denoted by 1. With the aid of the compressor 2, air at a temperature of, for example, 15 ° C. is compressed to a pressure of about 4 to 5 ata % receives. In the compressor 2 3 Water may be some injection-molded in a suitable manner via a line and are evaporated. With 5 the combustion chamber is referred to, which in the illustrated embodiment, a liquid fuel, for. B. heating oil, via which line 6 is supplied. It would of course also be conceivable to supply gaseous or finely atomized solid fuels.

The amount of heating gas generated in the combustion chamber 5 by the supply of heating oil is mixed with vapors, which are brought to the combustion chamber pressure in a special valve 7 be compressed. The importance of this compressor as a regenerative compressor will be explained in more detail below.

One could also think of the two compressors 2 and 7 together to unite. However, one then has to take care that the combustion goes through the vapors are not too heavily polluted. If necessary, however, you can do a part of the vapors, which are brought in via line 8, with the aid of a vapor blower Bring 9 into the suction line of compressor 2. By influencing the vapor fan 9 can: a metering of the vapor supply can be made, because with recirculation a partial amount can be achieved that the combustion chamber temperature is reduced. Furthermore, the partial return of the vapors to the Air compressor the possibility of the compressor units 2 and 7 in terms of their power consumption and their blading to be able to design the same or similar, which may be brings constructive advantages.

The regenerative compressor 7 can optionally be similar to the compressor 2 be provided with a water injection 10. It is injected through the Water not only reduces the work of compression, it is also reduced at the same time an additional amount of heat for the heating circuit connected to the gas turbine made available.

The exhaust gases from the combustion chamber 5 pass through the line 11 with the desired Temperature, e.g. B. 620 ° C, 'in the gas turbine 1 and: leave this in turn with a temperature of, for example, 400 to 450 ° C. These exhaust gases are initially a heat exchanger 12 and are used here to warm up the in the heating circuit located medium, e.g. B. water, the desired flow temperature for example 100 ° C. In the heat exchanger 12, the exhaust gases are at a temperature value cooled by 180 ° C, for example.

At this temperature, the exhaust gases then enter below - if necessary Interposition of an injection cooler 28 - in a second heat exchanger 13 a, which od in the manner of a trickle device. The like. Is formed. An intermediate water circuit 14, which is kept in motion by the feed pump 15, takes in the trickling device 13 heats up and transfers it to the heating circuit 17 via a heat exchanger 16.

The trickle device can be like a. Gas scrubber trained be, in which with the help of spray devices or by means of water curtain forming Cascades and the like in countercurrent flow a liquid coolant with a gas flow in intimate Is brought into contact. One could also think of adding a gas scrubber use, which is similar to the scrubbers with kaschig fillings common in gasworks is provided. A drainage of acid, which may be necessary, is denoted by 27.

The heat exchanger 16 m, if necessary, consists of h, 3. shockproof parts be manufactured, but is not stressed very high in terms of temperature. That the Cooled return water belonging to the heating circuit 17 is supplied by means of the circulation pump 18 fed to the heat exchanger 16 and occurs, for example, with a temperature of 40 ° C into it. In the heat exchanger 12 there is then a warming up to, for example 100 ° C. Before the circulation pump 18, a line branches off to the expansion vessel 19, in this way to ensure a safe water supply to the pump at all times. The heat consumers are denoted by 26.

In the grinder 13, the exhaust gases from the gas turbine 1 entering at a temperature of around 180 ° C. are cooled to around 40 to 50 ° C. by the intermediate circulating water flowing in the closed circuit 14. This temperature value depends on how much heat is withdrawn from the system by the heat consumers 26 in the heating circuit 17. If the heating circuit is primarily intended for space heating purposes, the operating conditions in the cold season are different from those in the summer months.

According to the partial pressure of the water vapor it is 40 or 50 ° C a part of the circulated water is evaporated and discharged with the warm vapors. A water separator 20 is arranged at the outlet of the Riesler. The regenerative V The main task of the sealer is to remove the water vapor in the amount of vapor gas is contained at the outlet of the Riesler, to be brought back into the cycle. The heat of vaporization the amount of water vapor is so considerable that: that the loss of water vapor or the Most of it would be unsustainable in the open atmosphere.

As mentioned, the heating power requirement - especially when using for space heating purposes - subject to certain more or less large fluctuations. Furthermore, there may be fluctuations in the electrical power requirement be expected. In order to ensure that the system works economically at various To ensure shark performance, it should be advisable to use as much as possible constant load on the gas turbine to work and the plant for a medium Interpret heating power requirement. If then in the cold season or in special In cases where a higher demand for heating power .should prove to be necessary, an additional combustion chamber can be used to create the necessary heating performance are provided.

The secondary combustion chamber 21 and its exhaust gases also serve this purpose are introduced into the exhaust pipe 22 of the gas turbine 1. The secondary combustion chamber 21 receives its combustion air via the compressor 23, while the fuel, z. B. heating oil is introduced via line 24. At 25 there is a vapor blower for the auxiliary combustion chamber. The auxiliary combustion chamber 21 also receives like the gas turbine 1 some of the vapors from the Riesler 13.

With the help of the secondary combustion chamber 21, it succeeds. the great heat demand to cover part of the winter peak, preferably around 50%. By the waste heat from the Gastarbi, ne is then only covered for the basic load. To this Way results for the gas turbine -oine high number of hours of use.

A mixture of vapors flows through the regenerative compressor 7 a carbonic acid content, as it is in a similar amount in economically operated Boiler firing is available and is, for example, 13 to 16 percent by volume. In addition, the vapor mixture has a high water vapor content of, for example 7 to 12 percent by volume. A small amount of gas escapes from the circuit is greater - namely only by the residual water vapor content - than the amount of exhaust gas Boiler firing, based on! A certain amount of fuel fired. The exhaust gas loss is small because the amount of exhaust gas itself is much smaller than the amount of exhaust gas of a Gas turbine system based on the open process, which uses excess air from 500 to 600% is working. In contrast, the excess air in the system according to the invention is only about 10 to 20%.

Another property of the plant according to: the invention consists in .that the waste heat from the gas turbine is used to a greater extent as a heating source can be, than this, for example, with a gas turbine after .dem open process possible eats. With these: common gas turbine systems must with exhaust gas temperatures of normally 180 ° C can be expected. In addition, one works there with excess air numbers from 500 to 600% instead of 10 to 20% in the system according to the invention. Man has already: tried to reduce exhaust gas losses from gas turbines using the open process, like them many times be used for heating systems, thereby reduce the fact that you have suitable chemicals, e.g. B. Ammoni, alc, the exhaust gases and thereby the exhaust gas temperature to 150 ° C, maybe even to 140 or even 130 ° C. Even if they were reduced as a result, they always lie still quite high, while the system according to the invention has significantly lower temperatures allowed to reach.

Another advantage of the system according to the invention is. that the high water vapor and carbonic acid content of the gases reduces the specific heat of the Working medium increases, thereby reducing the compression work and the expansion work is enlarged at the same time. The enlargement of the expansion work mainly eats in which takes place during the expansion process. slower cooling this Work equipment to see. Finally, there is another advantage that the wet compression, -d. H. the water injection into the compressor at the plant according to the invention is particularly effective, because the compression by the Evaporation of the water bound heat is in the trickle device 13 again made free for heating supply. So the wet compression is twofold Advantage, there will be: namely not only the injected water to reduce the Compression work is exploited, but at the same time is also used for heating an additional amount of heat is made available.

As already mentioned, it is recommended to use the auxiliary combustion chamber for about 50% of the required amount of heat. The exhaust temperature of the auxiliary combustion chamber should be chosen so that there is an inlet temperature for the heat exchanger from 170 to 190 ° C.

Claims (10)

PATENT CLAIMS: 1. Gas turbine plant with waste heat utilization, preferably in the sense of a heating and power plant, in which the exhaust gases from the turbine are passed through heat exchangers extracted heat is supplied to the medium of the heating circuit and a subset of the Turbine exhaust gases are returned to the turbine working fluid, characterized in that that the recirculation in a manner known per se over in the low temperature range Lying heat exchanger devices, at least partially designed as trickle devices and a regenerative compressor takes place and that the returned partial amount can be metered is dimensioned so that the resulting from the fresh working medium and recirculated vapors Mixture has a carbonic acid content comparable to that of steam generator boiler exhaust gases as well as water vapor. 2. Plant according to claim 1, characterized in that that the carbonic acid content of the fresh working medium and recycled vapors resulting vapor mixture is about 13 to 16 percent by volume. 3. Appendix after Claim 1 or 2, characterized in that the water vapor content of the fresh Working medium and recirculated vapors resulting Briidengemisches about 7 to 12 percent by volume. 4. Plant according to claim 1 to 3, characterized in that that the excess air is about 10 to 20%. 5. Plant according to claim 1 to 4, characterized by a known Zwischenwärinekreislauf between the designed as a trickle device and the heat exchanger for the Heating circuit. 6. Plant according to claim 1 to 5, characterized by an additional combustion chamber, whose exhaust gases are fed to the heat exchange system together with the exhaust gases from the gas turbine are. 7. Plant according to claim 6, characterized in that the auxiliary combustion chamber recirculated vapors are also supplied. B. System according to claim 6 or 7, characterized in that the auxiliary combustion chamber for about 501 / o of the required amount of heat is designed. 9. Plant according to claim 6 to 8, characterized in that the The exhaust gas temperature of the auxiliary combustion chamber is chosen so that the inlet temperature for the heat exchange system is about 170 to 190 ° C. 10. Plant according to claim 1 to 9, characterized in that a selectable partial flow amount of the vapors supplied to the regenerative compressor is supplied in a manner known per se upstream of the combustion air compressor of the gas turbine. Documents considered: German Patent No. 695 838; German interpretative document No. 1038 344.