DE1214701B - Arrangement of a steam power plant - Google Patents

Description

Arrangement of a steam power plant It is known to have a hot water heating system, which is heated by tapping an engine, for example a steam turbine is to be provided with a memory that, at the time, increased power output by Charged withdrawals, at the time the high power requirement is the heat transfer to the heating system in whole or in part with a reduction or cancellation of the removal from the engine takes over. The engine or turbine can thereby be independent of the heating requirement the full output resulting from the boiler output in condensation mode, submit. The required storage capacity results from the diversity the chronological progression of heat and power requirements; the price of the memory will be essentially determined by the pressure of the water and is special; favorable if none There is overpressure. As advantageous as this arrangement may be, the mutual Dependence on heat and power is a disadvantage, and it is not an increase in performance possible beyond the maximum output of the boiler, but only the fluctuating, Reduction in output due to seasonal heat demand due to tapping eliminated in this known arrangement at times of high power requirements.

The invention is based on the object of a steam power plant to create the type in question, which at relatively low investment and Operating costs permits an increase in the power output that is not limited in principle.

According to the invention, for this purpose in a steam power plant with a steam turbine with a regenerative system and a tap for supply a hot water heating system. via a circulation system operated for Time of reduced power requirement for the hot water tank to be charged, the one at peak time the power requirement with a reduction or cancellation of the extraction from the turbine to supply the hot water heating system with hot water, a combination of the hot water storage tank with other storage systems known per se (feed water storage, Relaxation of storage water for steam generation), which in principle did not restrict one Allow the output to be increased beyond the boiler output, provided, where for at least two of the systems mentioned the heat extraction from the storage the heat is extracted from a storage vessel and the expansion steam is suitable Low pressure stages of the turbine is supplied. Need in the system according to the invention thus, in spite of the possibility of using three storage systems, only two storage facilities to be installed. Another advantage of the storage combination according to the invention is that also de heat capacity of the heat distribution network of the heating system can be used to bridge load peaks.

A first increase in performance can be known, very economically Reach way by applying feed water storage; it consists in that at the time of low exposure to the usual regenerative system, additional feed water is heated and stored in order to then feed the boiler at peak times, under Diverting the regenerative steam into the condenser, to be used, whereby the full temperature range up to that of the condensate is used.

The storage tank is circulated as a displacement storage tank. and unload.

With this method, the increase in performance is limited to 10 to 11% (at high vapor pressures and temperatures), so that even when used at the same time both methods - namely heat transfer to the heating system from the associated Hot water storage tank and discharge of the feed water storage tank for boiler feeding - a limit remains drawn for the increase in performance.

The limitation mentioned applies to the storage combination according to the invention continued, since with correspondingly high force peaks a relaxation of the storage water via one or more connected in series Expansion vessels made can be, with the resulting steam for work performance in suitable stages the turbine is guided. The water can be used both in the feed water storage tank as well as the hot water storage tank. .

In the latter case, the following applies: since the storage water can hardly be cooled below 80 ° C by expansion - since an external gradient must remain in the turbine - the water remaining in the expansion vessels can be fed directly to the heating network during the short peak period; the resulting slightly lower flow temperature for the hot water heating can be permitted without any disadvantages due to the large heat capacity of the heat distribution network and the consumer systems. The temperature difference in spoke "water, which is crucial for an economic assessment of the storage vessels, remains for this fed from memory Krafterzeugungsprözeß sufficient. Is, for. Example, in a pure heat storage dt between supply and return 100 to 50 ° C, During the short power peak time, a cooling from 100 ° C to 80 ° C through relaxation and from 80 ° C to 50 ° C = or temporarily less - through heat dissipation will take place.

This is in view of the aforementioned large heat capacity of the heat distribution network and the customer facilities and in view of the relatively short duration of the Power requirement peaks are still quite permissible.

In principle, you can also use the feed water storage tank additionally by circulating over an expansion chain and feeding in the resulting Discharge steam to suitable turbine stages and the cooled water, as well Use in the heating network as described above. In all cases you need for three Storage types only two storage units and continue to cool their content on average from than would be possible without the combination according to the invention.

Storage in the hot water tank or coverage. the heat demand the heating system from this storage tank, which enables the full boiler output to be used for the power output is possible with relatively very low thermal Associated losses. The losses in feedwater storage (withdrawal of stored hot water for boiler feed) are due to the shift in the Turbine flow a little higher. Thermodynamically, it is much less favorable Relaxation discharge of the accumulator.

The waste heat is used in all cases; the diversity the losses have a corresponding effect on the storage costs per kilowatt hour. The storage efficiencies are in their order of magnitude over 90 and 80 or: 50% lie.

When operating the steam power plant according to the invention, it is therefore always advantageous to proceed in such a way that when covering power demand peaks a relaxation. storage water is only used to generate steam, if the power requirement exceeds the value; the through the other systems of Heat extraction from the storage tanks (extraction of hot water for boiler feed or to supply the hot water heating) can still be covered. Another Voi-leil the memory combination according to the invention is the; däß if seasonally the The heat demand for the thermal water heater fails, the corresponding heat storage tank is available for longer hours for discharge by relaxation, which z. $. currently de? ' Mäschinenübdfhölüngen and / or the morning cooking tips are an advantage can be.

Of course, the pressure at the taps must be used to load the storage tank of the turbine must be so high that the required Water temperature for each storage tank is reached. This can be done in a known manner by drawing from a higher tapping stage or - especially for the low-pressure heat storage tank - take place by building up the pressure by means of throttle valves; more economical it is in the case of multi-flow low-pressure ends to switch off individual rivers, what if necessary can be combined with the aforementioned throttling.

In FIG. 1 of the drawing is an embodiment of the invention Steam power plant shown schematically.

In it 1 it means the medium and low pressure part of a turbine which receives its steam through the duct 2 and emits it through the duct 3 to the condenser 4. From there, the condensate goes through the line 5, a pump 6, past an equalizing tank 7 to a fork 22, from where the condensate in normal operation through the regenerative preheater 8 - which receives steam through the lines 10 from the turbine - to the degasser 11 and from there to boiler 23.

The content of the feed water tank 9 is at rest. This is the one between the fork 22 and the first regenerative preheater 8 Valve 24 open so wide that the pump 25 arranged in front of this valve is accurate pumps as much water as you can with the pump 6. For charging the memory 9, the valve 24 is opened further in a manner known per se, so that the pump 25 also sucks in water from below from the storage tank, which then heats the upper one End of storage flows in again. When the memory 9 is discharged, it is closed by closing of the valve 24, the flow through the regenerative preheater 8 is known per se Way reduced, in the limit made to zero, thereby reducing the flow of steam to the condenser 4 grows and the power of the turbine is increased. The condensate then goes from the Bifurcation 22 through the displacement reservoir 9 to the degasser 11.

With 12 the hot water tank for the heating system is referred to, whose generally low pressure is determined by the hot water temperature. This memory is on the one hand with the consumers, not shown, by the Lines 15, 16 and, on the other hand, connected to a preheater 17 via lines 13, 14.

The latter receives its steam from one of the steam lines 10 (junction at 26) possibly in a switchable manner. The condensate produced in the preheater 17 can be fed back to the steam power plant's feed water system via a line 27 will. Pumps and valves (not shown) allow in a manner known per se the feeding of the heat consumers directly from the preheater 17 or the load and -Discharge of the storage tank 12, which is used as a displacement storage tank either cold water from downstairs or hot water is supplied from öberi.

Finally, according to the third system of heat extraction - here shown as mediated via an expander 20 to the hot water tank 12 the lines 18 and 19 connected - thereby discharging and increasing the power, that the steam produced in the expander from the circulated storage water over the line 21 of one of the lines 10 - mainly the lower - and thus the Turbine is fed. It is also possible to use this type of accumulator discharge to connect the memory 9, and then - according to the greater cooling of the circulated storage water - instead of an expansion valve, several connected in series Relaxers step, each of which is then connected to one of the lines 10 will. This is in FIG. 1 indicated by dashed lines to the left of memory 9.

The method for operating the steam power plant according to the invention is in the following on the basis of one in FIG. 2 illustrated load diagram explains in which the power indicated by the steam power plant over time is applied. In it, the line A means the one which fluctuates according to the time of day Power requirement. The full boiler output is indicated by the horizontal line K. The difference between this line K and another line H means the for power required for the operation of the hot water heating system. The ones to be covered Load peaks are divided into horizontal strips in the diagram. In the case the relatively long peak load that occurs in the morning hours three strips I, II, III are provided to cover the power requirement.

The lower, longest strip I is by interrupting the removal for heating, i.e. by means of a pressureless or almost pressureless and therefore cheap memory (item 12 in F i g. 1) and has practically no thermodynamic Losses; its height depends on the heat output.

The next strip II is stored in the feed water (storage tank 9) which have an efficiency between 80 and 901 / o and still affordable storage prices has, but with modern steam conditions, as already mentioned, to 10 to 111 / o increase in output is limited.

Finally, the top part (strip III) goes through the relaxation system covered, its relatively unfavorable storage costs and efficiency in the short Useful life without any significant economic disadvantage. The high of In principle, the increase in performance is not restricted; the one already described Sharing the storage capacity of the network reduces storage costs and uses the waste heat directly.

Due to the division provided for the method according to the invention the load peaks according to Fig. 2, which always has the shortest time strip III of the top diagram, subdivided into horizontal strips, shows the relaxation process is assigned, the possibility is created to also apply relatively long-lasting force or power peaks that would otherwise no longer be economical for heat storage come into question to be able to cover. In this context it is for illustration mentioned; that the kilowatt-hour storage capacity for the lower strip I is at unpressurized memory about DM 10.-, for the middle strip II at about 20 atm DM 25.- costs; while the price in the case of the top strip I11, which is only temporary is set, is correspondingly higher.

In terms of the method according to the invention for operating the novel Steam power plant is analogously used in the case of the right-hand part of FIG. 2 recognizable, the cover is less high during the afternoon hours made only by using two of the named systems of heat extraction, in accordance with the strips I, II shown there by removing storage water for supplying the hot water heating system and by drawing off storage water for the boiler feed, since in the case of this selected example the two above The measures mentioned above are just sufficient to cover this peak load.

The memory combination according to the invention proves, as from the above Explanations emerges with regard to the investment and operating costs of the steam power plant advantageous, but the beneficial overall effect of this combination is still essential goes beyond a mere summation of the individual advantages listed.

Claims (4)

Claims: 1. Arrangement of a steam power plant with a steam turbine with a regenerative system and a tap to supply a hot water heating system via a currently reduced power requirement operated in the circulation process Hot water storage tank, which is reduced or decreased at peak times when power is required. Removal of the extraction from the turbine to supply the hot water heating system Hot water can be removed, characterized by a combination of the hot water tank with other storage systems known per se (feed water storage, relaxation 1 of storage water for steam generation), which in principle did not restrict one Allow the output to be increased beyond the boiler output, whereby for at least two of the named systems of heat extraction from the storage tank heat extraction takes place from a storage vessel and the expansion steam suitable low-pressure stages is fed to the turbine. 2. Procedure for operating a steam power plant according to Claim 1, characterized in that when covering power requirement peaks a relaxation of storage water for steam generation is only carried out, if the power requirement exceeds the value that is provided by the other systems of the Heat extraction from the storage tanks (extraction of hot water to feed the boiler or to supply the hot water heating) can still be covered. 3. Procedure for Operation of a steam power plant according to claim 2, characterized in that the for steam delivery into the turbine relaxed during the peak strength period Water is fed to the heating system or its storage. 4. Procedure for Operation of a steam power plant according to claim 2 or 3, characterized in that during the loading of the memory to increase the pressure at the taps of the Turbine builds up the pressure by actuating in the steam lines behind the taps lying throttle valve is made or that with multi-flow Turbines can be switched off, possibly in combination with individual rivers the operation of throttle valves.