DE1128437B - Steam power plant, in particular block plant with once-through boiler - Google Patents

Description

Steam power plant, in particular block plant with once-through boiler High pressure and high temperature turbines, especially those with reheating, are known to tolerate only limited load changes or load change rates on the fresh steam side, during load changes using the turbine tapping points easily can be admitted. In addition, the Durchlaufkes.sel has over others Boiler types, such as B. the drum shell, a very low storage capacity. It were therefore already. various measures to increase the storage capacity suggested by flow boilers.

So a device has already become known to enlarge the Storage capacity of a steam power plant working in block connection with a once-through boiler and a turbine with uncontrolled withdrawals for feed water preheating Extraction steam in which the condensate discharge is controlled depending on the water level from the condenser through direct action on the water level dependent Control also dependent on the change in load, e.g. pressure-dependent, is controlled. With increasing boiler pressure (load reduction) the promotion of the condensate pump for the low-pressure preheater to the feed water tank is increased and reduced with falling pressure (load increase).

The steam power plant according to the invention is in particular around a block system, and the steam generator is a once-through boiler with feed water preheating through extraction steam and feed water storage to compensate for load fluctuations and a hot water tank. Feed water storage has already been used many times, in order to compensate for load fluctuations. In general, containers are used here, the boiler feed water as a condensate tank in contrast to feed water tanks record at a lower pressure level. The known storage tanks are in front of the boiler feed pump arranged. It is only known to have an additional one parallel to the high-pressure preheaters Provide storage pump, which is used to fill the hot water storage tank. In contrast The inventive novelty is that in addition to the feed water tank and, if necessary, a hot water storage tank provided with a cold condensate storage tank has a higher pressure and a higher temperature than the one in front of the boiler feed pump arranged feed water tank and the filling of the hot water tank with water from the feed water tank in a manner known per se with step-by-step preheating by means of extraction steam, the emptying of the hot water storage tank into the feed water tank in a manner also known per se by refluxing hot water in stages Heat release to the feed water or steam release to the turbine takes place, namely each depending on the direction and size of the load changes.

The hot water storage tank is thus at the highest pressure and temperature level Hot water supplied and withdrawn and thus an economical storage of the in the discharge and an economic transfer of the in the debit required storage heat achieved.

In a further development of the invention, the filling and emptying takes place of the hot water tank by separate valves known per se, which apart from Load signals are also regulated according to the water level in such a way that in the steady state (constant load) a mean water level is regulated and when the load changes Exceeding and falling below load changes is prevented. Furthermore, the Hot water storage tank on the water inflow side to the storage tank water pressure line behind the feed pump be connected in the area of the high pressure preheating stages and in addition to the admission with hot water in a manner known per se with steam from one of the uppermost turbine extraction points or the main steam line can be heated. The pressurization of the hot water storage tank With extraction steam or live steam, the storage tank is kept warm with constant load.

The storage effect can be increased by the fact that in addition to the hot water storage tank and the food Water tank a cold water tank of lower level Pressure and lower temperature than the feed water tank is provided. Included become hot water storage tanks while keeping the water level constant in the feed water tank and cold water storage tank in opposite directions filled and emptied, so that z. B. in case of load hot water is taken from the hot water tank, while the cold condensate not via the low pressure preheater into the feed water tank, but into the Cold water storage tank is conducted. In this way there is a discharge of extraction steam prevented to the low pressure preheater, so that this steam to work is available in the turbine.

The - in the direction of flow of the discharged from the hot water tank The first heat emission from the storage water can either be in an expander or in a water / water heat exchanger. Close to this heat emission one or more relaxation levels. When using a heat exchanger Water / water is the first expansion valve in the form of the accumulator discharge valve behind the heat exchanger. The heat dissipation in a water / water heat exchanger can without pressure reduction, d. H. at the same temperature as in the hot water tank prevails. In a sense, it represents an indirect delivery of steam, since it is adhered to the high temperature level prevents the supply of extraction steam from the top stage the turbine can be reduced or stopped entirely. The amount of heat transferred here is much greater than that achieved in a relaxation stage can.

In contrast, the release of heat with relaxation results in a direct delivery of steam to one of the removal stages.

The feed water tank can, for. B. by load-dependent setpoint change its water level control, with can be used for storage by also its filling in the same direction as the hot water tank between an upper and a lower one Limit water level is subject to fluctuations. Due to the load-dependent regulation of the An alternating condensate flow rate can flow through the inlet valve to the feed water tank the low-pressure extraction stages and thus a storage control of the Low pressure withdrawals can be achieved.

In the event of a load surge, the relaxation of the water is the result the hot water tank in one of the preheating stages with excess steam With the help of a differential pressure overflow control of one of the following extraction stages fed. The steam released as a result of expansion would flow back into the turbine via its own extraction line due to its low temperature possibly cause a temperature shock in the turbine. Through the differential pressure overflow control the point in time at which an excess amount of steam is present is detected and that Check valve is closed. This regulation is independent of the load, since they only control the pressures in the sections of the sampling line upstream and downstream of the Check valve detected.

In addition to filling or emptying the hot water tank and for filling the feed water tank through step-by-step heating with extraction steam can also be the emptying depending on the direction and size of the load changes of the feed water tank by gradually releasing heat using the lower Turbine extraction points take place. This also means that there is an additional supply of steam to the turbines or the low-pressure extraction stages.

Furthermore, parallel to the feed pump and the high pressure preheaters a storage pump and a special one to fill the hot water tank feed water preheating parallel to the main feed water circuit can be provided. The pump to be used to fill up the hot water tank is for lower Design delivery pressure and smaller quantities than the boiler feed water pump.

The emptying of the hot water tank can in a further development of the invention by bypassing the feed water tank.

1 to 4 show embodiments of the invention in their essential features in a simplified schematic representation. Be there the same reference numerals are used for the same parts.

Fig. 1 shows a boiler 1 with reheater 2 and turbine 3 with high pressure, medium pressure and low pressure part. The turbine exhaust steam is in the condenser 4 precipitated and the condensate through the condensate pump 5 via the condensate cooler 8 and the low-pressure preheaters 9, 10 and 11 with the mixer preheater and degasser provided feed water tank 12 is supplied. From here the condensate is with Help the boiler feed pump 13 via the condensate cooler 14, the high pressure preheater 15, 16, the desuperheater 16a and the high-pressure preheater 17 are fed to the boiler 1.

The hot water storage tank 19 is on the water inflow side to the feed water pressure line in the area of the highest preheating stage 17 and also once on the steam side via the Overflow and cooling station 20 with the main steam line, on the other hand via the Expander 22 connected to the uppermost removal stage I.

In the event of a load surge, the load-dependent memory signal 31, the storage discharge valve 29 is opened, so that hot water from the storage unit 19 into the expander 18 a and from there via the expander 23 and 24 into the feed water tank 12 can flow. With the release of heat in the ventilators, the withdrawals go into the Levels 1I, III and IV back to zero.

Further provides 25 an overproduction valve, 26 a reducing valve, 21 a check-in and Abfahrventil and low load valve, 36 to 41 flow control valves, and 28 an accumulator charging valve. Over the latch signal 32 can supply to the hot water storage tank 19 via the latch signal 31 of the effluent from the hot water storage 19 be managed. With 34 turbine control valves are designated with 35 quick-closing valves.

In the event of a surge in relief, the accumulator charging valve 28 is opened via the accumulator signal 32. At the same time, the hot water storage tank 19 can be heated with high-temperature steam via the extraction line I and the expander 22. The boiler feed pump 13 conveys an increased amount of feed water via the condensate cooler 14 and the high-pressure preheaters 15 and 16, 16a, but the additionally conveyed feed water does not flow to the boiler 1, but to the hot water tank 19 via the valve 28. In this way, the heat generated during a relief surge is transferred via the extraction stages 1I and III not only to the working medium corresponding to the boiler load, but also to an additional amount of condensate, which is withdrawn from the feed water tank 12 in a circulating flow and fed to the hot water storage tank 19 will. V, VI and VII represent low pressure taps.

In the system according to FIG. 2, a cold water storage tank 7 is provided in addition to the hot water storage tank 19, which is filled and emptied in the opposite direction to the hot water storage tank 19, a constant water level being maintained in the feed water tank. In the event of a load, the excess steam released in the expander 24 flows with the aid of an overflow valve 27 with differential pressure overflow control via the next low-pressure extraction line to the turbine and is available here for mechanical work. Furthermore, with the help of the load-dependent water level control valve 30 operated via the storage signal 33, the feedwater flow through the low-pressure preheating stages 8, 9, 10 and 11 can be throttled down to zero in addition to the water level control, so that the condensate pump 5 conveys the turbine condensate into the cold condensate storage 7. In this way, the steam flowing through the extraction lines V to VII during normal operation is available for work in the turbine.

In the event of a relief surge, a storage pulse 33 can be sent to the water level control valve 130 are given, so that the condensate pump 6 except that promoted by the condensate pump 5 Amount of condensate also condensate from the cold condensate reservoir 7 via the Low-pressure preheater 8 to 11 feeds the feed water tank 12. This will make the in the embodiment of FIG. 1 described, the delivery of an additional Feed water volume draining of feed water tank 12 balanced, so that in this steady state again a constant water level is regulated can be.

The embodiment of Figure 3 differs from the Embodiments of FIGS. 1 and 2 initially characterized in that to warm up the the hot water storage tank 19 flowing water separate storage water preheater 46 and 47 are provided. These storage water preheaters can use the pipe 50 is supplied from the feed water tank 12 by means of an additional pump 45 will.

In the event of a load surge, there is the one leaving the hot water storage tank 19 Water does not get its heat according to the embodiments of FIGS. 1 and 2 to an expander, but first to a heat exchanger water / water 18 and only afterwards to the expansion devices 23 and 24 as well as the feed water tank 12 return. Due to the heat dissipation in the water / water heat exchanger without any pressure reduction not only does the withdrawal from stages II to VII go back to zero, but the topmost extraction I is also pushed back and thus the turbine in addition high quality steam provided for work performance.

The high pressure preheater 15 is by steam from the expander 23 and the turbine via the extraction line IV with excess steam from the primary tensioner 24 supplied for mechanical work performance. In addition, in the case of a relief shock The amount of condensate conveyed from the cold condensate container 7 is not only after it has flowed through the high pressure preheater 15 and 16, but before the feed pump 13 of the Main feed water line 50 branched off and via the pump 45 and the storage water preheater 46 and 47 are supplied to the hot water storage tank 19.

The embodiment shown in FIG. 3 has another one additional expander 24 a, the water from the feed water tank in the event of a load surge 12 relaxes and the low-pressure preheaters via a valve 42 controlled as a function of the water level 10 and 9 for further heat dissipation.

According to FIG. 4, the expander 24 a is not in the event of a load surge from the feed water tank 12, but bypassing the latter via a drain control valve 140 is supplied with water from the expander 24 which is controlled as a function of the water level. Of the Steam generated in the expander 24 a is fed to the low-pressure preheater II. That In the expander 24 a accumulating water flows through drain valves 42 and 43 the low pressure preheaters 10 and 9 too.

In this embodiment, too, the preheating of the hot water tank 19 inflowing water via parallel to the main feed water circuit accordingly 3 arranged storage water preheaters 46 and 47 are made.

Claims (7)

PATENT CLAIMS: 1. Steam power plant, in particular block system with once-through boiler, with feed water preheating by extraction steam and feed water storage to compensate for load fluctuations in a hot water storage tank, characterized in that the hot water storage tank (19) provided in addition to a feed water tank (12) and possibly a cold condensate storage tank (7) is higher pressure and has a higher temperature than the feed water tank (12) arranged in front of the boiler feed pump (13) and the filling of the hot water tank with water from the feed water tank (12) in a manner known per se with step-by-step preheating by extraction steam, the emptying of the hot water tank into the feed water tank (12) ) takes place in a manner also known per se by returning hot water with gradual release of heat to the feed water or steam release to the turbine (3), in each case depending on the direction and size of the load changes. 2. Steam power plant after Claim 1, characterized in that the filling and emptying of the hot water tank (19) by separate valves (28, 29) known per se, which apart from Load signals are also regulated according to the water level in such a way that in the steady state (constant load) a mean water level is regulated and when the load changes Exceeding and falling below limit water levels is prevented. 3. Steam power plant according to claim 1 and 2, characterized in that the hot water storage tank (19) is connected on the water supply side to the feed water pressure line behind the feed water pump (13) in the area of the high pressure preheating stages (14, 15, 16, 17) and in addition to the application of hot water can be heated in a manner known per se with steam from one of the uppermost turbine extraction points or the live steam line. 4. Steam power plant according to claim 1 to 3, characterized in that that in addition to the hot water tank (19) and the feed water tank (12) existing cold water storage tank (7) of lower pressure and lower temperature than the feed water tank of this (7) - while keeping the water level constant in the feed water tank (12) - in the opposite direction to the hot water tank (19) fill and can be emptied. 5. Steam power plant according to claim 1 to 4, characterized in that that the feed water tank (12) preferably by a load-dependent setpoint change (33) the water level control can also be used for storage by including its Filling in the same direction as the hot water tank (19) between an upper and a lower one Limit water level is subject to fluctuations. 6. Steam power plant according to claim 1 to 5, characterized in that in the event of a load surge the relaxation of water from the hot water storage tank (19) being released in one of the preheating stages Excess steam with the help of a differential pressure overflow control one of the following Removal stages is fed. 7. Steam power plant according to claim 1 to 6, characterized characterized in that in addition, depending on the direction and size of the load changes for filling or emptying the hot water storage tank (19) and for filling the feed water tank (12) also emptying it by gradually heating it up with extraction steam heat is gradually released using the lower turbine extraction points. B. steam power plant according to claim 1 to 7, characterized in that the - in Direction of flow of the storage water discharged from the hot water storage tank (19) seen - first heat release initially in a heat exchanger water / water (18) and only then takes place in one or more relaxation stages (23, 24) and the first expansion valve in the form of the accumulator discharge valve (29) behind the Heat exchanger water / water (18) is provided. 9. Steam power plant according to claim 1 to 8, characterized in that the emptying of the hot water tank (19) takes place by bypassing the feed water tank (12). Considered publications: German Patent No. 628 717, 633 684, 638119; German, interpretative publications No. 1058 072, 1070 644.