DE1526896B2 - Thermal power plant - Google Patents

Description

The invention relates to a thermal power plant that is independent of one another in terms of time Generation of electrical energy and heat is used. A gas turbine system works according to the open process with a steam power plant together by removing the exhaust gases from the gas turbine plant are led to the steam generator.

It is known in the exhaust gas path of a gas turbine system operating in the open gas turbine process to arrange a steam generator that works either as a pure waste heat boiler or with an additional combustion is provided. The steam power plant can be used as a steam back pressure, steam withdrawal back pressure or be designed as an extraction condensation system. The heating network, which with heat is to be supplied, is then connected in a suitable manner to the steam engine.

The invention is based on the object of one or more heating networks in such a system To supply different pressure and temperature levels with fluctuating heating requirements, on the other hand but also to supply variable electrical energy requirements within wide limits. With the known Systems of the type described generally go with a higher supply of electrical energy increased heat generation associated, so that there are difficulties when the need for electrical Energy and heat diverge in time.

In contrast, the invention shows a way how one with such a system with high economy = possibility of a power supply from an extremely low load value up to the maximum load and also a heating supply from minimum to full load in any - ^ can perform temporal assignment. Accordingly, the invention is that in such Thermal power plant in the exhaust gas path of the gas turbine system in parallel to one, preferably in addition Fired high-pressure steam generator with steam engine at least one additionally fired Low-pressure steam generator is switched and both the high-pressure and the low-pressure steam generator are equipped with fresh air blowers.

An exemplary embodiment of the invention will 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 Depiction. .

Of the gas turbine system, for the sake of simplicity of illustration, only one compressor 1, one Combustion chamber 2 and a gas turbine with generator 4 illustrated. One of the combustion chamber 2 upstream The air preheater can be removed from the exhaust gas flow of the gas turbine 3 in a manner not shown be applied or z. B. the mixed gas turbine exhaust gas-flue gas stream at a further back point still withdraw heat and are accordingly assigned to the steam generator system. It is also possible to carry out a multi-stage compression, if necessary with intermediate cooling, also a multi-stage gas turbine, to use with reheating if necessary.

The exhaust gas path 31 of the gas turbine 3 forks behind the non-return valve 32 into the two branch lines 33 and 34. In this way there are a high pressure steam generator 8 and at least one Low-pressure heat exchangers connected in parallel to one another as a low-pressure steam generator 11. at the illustrated embodiment is the high-pressure steam generator 8 fuel 35 for a Additional firing and to the low-pressure steam generator 11 fuel 36 also for additional firing guided. In addition, both steam generators are equipped with fresh air fans 9 and 12.

The fresh air blowers 9 and 12 serve on the one hand to support the firing of the high-pressure steam generator 8 and the low-pressure boiler 11 and for stand-alone operation, if the gas turbine system except Operation is. It can also be possible to use either the steam generator 8 or the steam generator 11 to take into operation together with the working gas turbine system, then the other steam generator is switched off. The optional distribution of the gas turbine exhaust gases and their Quantitative allocation to the firing requirements of the steam generators 8 and 11 takes place with the aid of the controller 37, the control and regulating flaps 38 and 39 in the exhaust lines 33 and 34 are actuated and also / -noch on suitable control and regulating flaps 7 in the v. Bypass line 40 works. That of the extraction of the smoke gases leaving the steam generators 8 and 11 Serving induced draft fan .23. can with direct discharge of the gas turbine exhaust via the bypass line 40 can be switched off. With decreasing or ceasing gas turbine exhaust gas volume in the lines 33 and 34, the controllers 5 and 6 work to increase the supply of fresh air from the fans 9 and 12 and fuel supply 35 and 36 towards.

With this arrangement of the distribution of the turbine: 'nenabgases on the steam generator 8 and 11 is the Heating supply regardless of the respective load condition of the high pressure steam generator 8 and the load condition including standstill of the gas turbine system 1, 2, 3 ensured in each case.

As mentioned above, there is a particular task, two different heating networks different To supply pressure and / or different temperature with heating. In the illustrated embodiment I and II denote two heating networks, both at different pressure levels and are designed for different temperatures. In addition, if necessary a third heating network III can also be provided, which will be discussed later. The dimensioning of the low-pressure steam generator 11 is on both in terms of pressure and temperature adapted to the respective heating network, which is the heating network I in the present case and compared to the heating network II is at a higher pressure and temperature level. With regard to the total amount of heat that can be delivered the low-pressure steamer 11 should be dimensioned so that it essentially supplies both heating networks I and II sufficient, although with expected short-term heating demand peaks possibly suitable memory can also be used.

The back pressure steam turbine 13 connected to the high pressure steam generator 8 operates on the Heating network II, which is at a lower pressure and temperature level. Between heating networks I and II there is a cross connection 41, so that if necessary, heating from the state of the heating network I on the network II can be transmitted. In the line 41 is the reducing station 18, which may be with

a water supply 42 can be provided for injection cooling.

An auxiliary reducing station 19 is also connected upstream of the heating network II. This apparatus is with working back pressure turbine 13 in their normal The company is not in use, so it is fully open. When the turbine is only working weakly or at a standstill 13, heating steam flows via the line 41 and the reducing station 18 via the auxiliary reducing station 19 to the heating network II, the reducing valves 18 and 19 can each be set so that on the Mixing point of the steam transferred via line 41 with that supplied via line 43 Exhaust steam from the turbine 13 is equal in pressure.

Conversely, however, the system also enables the counterpressure of the counterpressure turbine 13 to build up to a pressure level that can be equal to or even greater than the pressure in the heating network I. On this In this way, it is possible to supply the network I from the back pressure turbine 13. The bypass line44 is used for this purpose with the valve 21. Excess steam can be fed via the auxiliary reducing station 19 into the Network II are fed in.

Furthermore, it is also possible to connect the network I to an extraction line 24 of the back pressure turbine 13, whereby the pressure level of the tap is to be selected accordingly. In the illustrated embodiment is also connected to the extraction line 24, a third heating network III, whose The pressure level in the present case lies between the heating networks I and II.

For the generation of electricity there is a distribution of the load on the parts driven by the gas turbine 3. The generator 4 and the generator 14 assigned to the counterpressure steam turbine 13.

When the electrical energy requirement is low, the steam turbine and the gas turbine system can be switched off be driven with more or less high load depending on the power demand. As mentioned at the beginning, the low-pressure boiler 11 is dimensioned in terms of its heat delivery so that that it generates the maximum amount of heat required by the heating networks I and II together. Of the Exhaust gas flow of the gas turbine system is now exclusively via line 34 of the furnace Low-pressure steam generator 11 supplied; in addition, the corresponding amount is given to the furnace of fuel 36 supplied. In this way, the heating network I is immediately and the heating network II on the Connection line 41 and the reducing station 18 and 19 supplied.

If full electrical power is required, the gas turbine system works at full load and likewise the high-pressure steam generator 8 and the steam turbine 13. If not at the same time now even the highest heating demand is present, the low-pressure steam generator 11 can be shut down. The entire exhaust gas flow from the gas turbine system is now fed to the high-pressure steam generator via line 33 8 supplied. The heating is generated by the steam turbine 13 in the manner described above randomly distributed to heating networks I and II, with steam delivery for network I ζ. Β. mainly the extraction line 24 is used. If there is an increased heating requirement, the low-pressure steam generator can then 11 are more and more involved.

The high-pressure steam generator 8 and the low-pressure steam generator 11 are assigned their own feed pumps 16 and 15 with correspondingly different delivery heads. In this case, the feed pump 16 for the high-pressure steam generator 8 is divided into two pumps or a two-stage pump with stages 16 α and 16 b . The quantities fed into the networks I and II do not, of course, always have to agree with the delivery quantities of the pumps 15 and 16, respectively. In addition, a booster pump 17 is also provided in order to improve the assignment of the pumps 15 and 16 to the load condition of the steam generators 8 and 11. The pressure booster pump 17 is dimensioned in terms of its delivery head according to the pressure difference of the networks I and II.

Return condensate from the heating network II can be fed into the suction line of the pump 15 through a pressure-controlled distributor valve 20; analogously, when network I is oversupplied, condensate can be transferred from heating network I into the suction line of pump 16 via bypass valve 22. When the network I is oversupplied, the pressure of the pump 15 rises, so that the valve 20 closes and the valve 22 is now opened. When this network is underfed, the pressure at the pump 15 drops so that the valve 22 now closes and the valve 20 opens. Conversely, if the network II is over-fed, the pressure at the pump 16a increases, so that the valve 20 opens. In shortage in the network II, the pressure drops to the pump 16 a, so that the valve opens 22nd

Claims (5)

Patent claims: 1. Thermal power plant to generate electricity and heat independently of one another in terms of time a gas turbine system based on the open process with a steam counter pressure, steam extraction counter pressure or extraction condensation system, characterized in that in the exhaust gas path of the gas turbine system parallel to a preferably additionally fired high pressure steam generator with steam engine at least one additional Fired low-pressure steam generator is connected in parallel and both steam generators with Fresh air blowers are equipped. 2. Installation according to claim 1, characterized in that one for the heating heat supply or several heating networks with different pressure and / or temperature levels of the low-pressure steam generator is dimensioned for the heating network with the respective highest pressure level. 3. Plant according to claim 2, characterized in that the low-pressure steam generator (11) is dimensioned for a heating amount that meets the needs of the various heating networks (I, II; I, II, III) together. 4. Plant according to claim 2 or 3, characterized in that the heating networks (I, II) through Reduction stations operating in stages, optionally provided with injection cooling (42) (18,19) are connected to each other. 5. Plant according to claim 2 to 4, characterized in that with the help of a booster pump (17) in cooperation with a pressure-controlled distribution valve (20) and a . Return valve (22) distributes the return condensate quantities from heating networks of different pressure levels (I, II) to the feed pumps (15, 16) of the steam generator (11, 8). : 1 sheet of drawings