WO2012123211A2 - Operating method for a plant in primary industry - Google Patents

Abstract

A basic part (1) of a plant in primary industry emits hot exhaust gases in a first phase (P1) of the plant cycle, but not, or only scarcely, in a second phase (P2) of the plant cycle. The exhaust gases are discharged via a system of pipelines (2). In an evaporator device (5, 7) installed there, at least in the first phase (P1) water is evaporated and fed to a steam storage device (9, 11). In the first phase (P1), the stored steam is passed through a superheater (6), installed in the system of pipelines (2), and superheated there. A first part of the superheated steam is passed in a charging direction through a buffer store (16). It heats up a storage medium located there. The remaining superheated steam is passed to a steam turbine (17) while bypassing the buffer store (16). In the second phase (P2), saturated steam is taken from the steam storage device (9, 11), at least partially passed through the superheater (6) and combined with superheated steam, which is removed from the buffer store (16) counter to the charging direction. The combination of the two streams of steam is passed to the steam turbine (17).

Description

description

Operating method for a plant of the basic industry The present invention relates to an operating method for a plant of the basic industry,

 - Wherein a base part of the plant is operated according to a plant cycle,

- During the system cycles in a first phase of the respective system cycle hot exhaust gases occur and arise in egg ^¬ ner second phase of each plant cycle either no hot exhaust gases or the hot exhaust gases compared to the first phase arise only to a significantly reduced extent,

- The hot exhaust gases are discharged in the respective extent in which they arise, via a piping system from the base part of the system and discharged to the outside air,

 - In a built-in piping evaporator means of the hot exhaust gases, at least in the first phase, water is evaporated to saturated steam and the saturated steam is fed to a steam storage device.

The present invention further relates to a plant of the primary industry, which is formed such that it is operable ge ^¬ Mäss such a method of operation. The base part of the plant may be, for example, an LD plant or an electric arc furnace for steelmaking. Such an operating method and the corresponding plant of the basic industry are known, for example, from US Pat. No. 3,175,899 A and from US Pat. No. 3,398,534 A.

DE 1 401 381 A1 discloses a substantially identically stored disclosure content.

From WO 2010/138 597 A2 an operating method for a plant of the basic industry is known, wherein a base part the system is operated according to a plant cycle. During the plant cycles, hot exhaust gases are produced in a first phase of the respective plant cycle. In a second phase of the respective plant cycle, either no hot exhaust gases are produced or the hot exhaust gases are produced in comparison with the first phase only to a significantly reduced extent. The hot exhaust gases are removed in the respective extent in which they arise, via a piping system from the base part of the system. In a built in the piping system heat exchanger by means of the hot exhaust gases at least in the ers ^¬ th phase a liquid heat transfer medium - for example, a molten salt - heated and fed to a salt memory.

The main problem in the energy recovery from the waste heat of electric arc furnaces lies in the discontinuous and difficult to control energy emission of the arc furnaces, the strong temperature fluctuations of the exhaust gases and their high dust load. Corresponding problem also exists in LD plants for steelmaking.

The arc furnace process is a batch process in which off-gas side (depending on the furnace design and furnace operating mode) once or twice per hour, the emission of thermal power between a maximum value (emission phase) and zero (emission ^¬ pause) fluctuates. Since the units for converting thermi ^¬ shear energy into mechanical energy (typically turbines) are sensitive to strong power and temperature variations, and further requires the synchronization of a generator driven by the turbine electrical generator with an external power time, the turbines must, if Once they have reached the synchronous speed, kept at this speed to be able to feed stable electrical energy into the external network. Energy from the emission phases must therefore be stored in order to be available during the emission breaks. The object of the present invention is to provide possibilities by means of which, in particular, the efficiency in the utilization of the thermal waste heat is increased.

The object is achieved by an operating method with the features of claim 1. Advantageous embodiments of the operating ^method according to the invention are the subject of dependent claims 2 to 13.

According to the invention, it is provided to design an operating method of the type mentioned at the outset,

 - that in the first phase

 - The stored in the steam storage device saturated steam through a built-in piping system

Superheater passed and is overheated there by the hot exhaust gases to superheated steam,

 - The superheated steam is directed by means of a arranged between the superheater and a buffer memory first valve means to a first part in a loading direction through the buffer memory,

 - heated the first part of the superheated steam in the buffer memory located there storage medium, and

 - The superheated steam by means of the first valve device to a second, complementary to the first part

Part bypassing the buffer memory is passed to a steam ^¬ turbine and

 - that in the second phase

 - The steam storage device is taken saturated steam, at least in part is passed through the superheater and is combined by means of the first valve means with superheated steam, which is taken against the loading direction of the buffer memory, and - the merger of passed through the superheater

 Steam and superheated discharged from the buffer

Steam is routed to the steam turbine. By this procedure is achieved for the first that the superheater can be sufficiently cooled not only in the first phase, but also in the second phase, of any hot exhaust gases that occur in the second phase, so not overheated. Secondly, the steam turbine can kontinuier ^¬ Lich - are operated with superheated steam - that both in the first and in the second phase. Particularly to have the third of the buffer memory can be used efficiently without the storage medium ^¬ chermedium the buffer circulate forcibly ^¬ sen.

The operating method according to the invention is, for example, a method for operating an electric arc furnace or an LD plant for steelmaking.

In a first possible embodiment of the operating method, in the first phase, the first part of the superheated steam after flowing through the buffer memory is combined with the second part of the superheated steam by means of a second valve device arranged between the buffer store and the steam turbine, and the first and second parts are combined the superheated steam to the steam turbine ge ^¬ passes. By means of this embodiment, it can be achieved, in particular, that the steam turbine can be operated with relatively high power in the first phase.

In a further preferred embodiment of the operating method, in the second phase the superheated steam taken from the buffer store counter to the loading direction is removed from the steam storage device as saturated steam. This refinement makes it possible to ensure that the steam mass flow supplied to the steam turbine-at least approximately-can be kept constant, and furthermore that the buffer cylinder can be dimensioned relatively small even in the case of extensive second phases.

In a particularly preferred embodiment of the operating method of the steam storage device is removed Saturated steam in the second phase by means of a between the steam storage device on the one hand and the superheater and the buffer on the other hand arranged third valve means divided into the superheater supplied saturated steam and fed into the buffer memory saturated steam. This design simplifies the structural design of the water-steam cycle.

The buffer memory can be embodied in particular as concrete storage. Alternatively, the buffer memory can be designed, for example, as a sand store or as a liquid salt store, wherein necessary conveyors are required for circulating such storage media.

In a second possible embodiment of the operating method, the first part of the superheated steam is condensed in the first phase after flowing through the buffer memory and fed back to the vapor storage device. In particular, for this purpose in the first phase, the first part of the superheated steam after condensing and prior to feeding to the vapor storage device may be passed through a primer preheater which is installed behind the evaporator means in the piping system with respect to the piping system.

In the second possible embodiment of the operating method is preferred that in the second phase of ent ^¬ withdrawn against the direction of loading the buffer memory previously superheated steam as the hot water of a dining of

Steam storage device is taken with hot water serving supply line or tapped behind the Grundvorwärmer.

The removal of hot water from the feed line can be done for example by means arranged in the feed line fourth valve means. Preferably, the buffer memory comprises a buffer superheater, a buffer preheater, a latent heat storage, and a buffer steam drum. In this case it is preferably provided

- that in the first phase the first part of the overheated

Steam is first passed through the buffer storage superheater, from there through the latent heat storage and from there, bypassing the buffer steam drum through the Bufferspei ^¬ cher preheater,

- That in the second phase, the hot water in the case that it is removed from the feed line is first passed through the buffer storage preheater and from there into the buffer storage steam drum and in the case that it is tapped behind the Grundvorwärmer under Bypassing of the buffer storage preheater is passed into the buffer storage ^¬ cher steam drum, then the buffer steam drum removed and converted into latent heat storage to wet or saturated steam and fed from there again as saturated steam of the buffer steam drum and finally borrowed the buffer steam drum removed saturated steam and is passed through the storage tank superheater, wherein the saturated steam in the storage tank superheater is overheated to superheated steam. As part of the last-mentioned embodiment of the hot water, saturated steam and overheated steam ^¬ about a fifth to ninth valve means are preferably provided for guiding. The fifth valve means is disposed between the buffer storage preheater, the buffer steam drum and the latent heat storage. The sixth valve device is arranged between the buffer steam drum, the Latentwär ^¬ mespeicher and the buffer storage superheater. The seventh valve device is arranged in a connecting line connecting the basic preheater and the buffer steam drum. The eighth valve device is arranged in a connecting line, via which, bypassing the sixth valve device, the buffer storage steam drum and the buffer storage superheater are connected to one another. The ninth valve device is arranged in a line which leads from the buffer steam drum to a connecting line, via which the fifth valve device and the latent heat accumulator are connected to each other.

In the context of the second embodiment of the operating method, furthermore, the saturated steam withdrawn in the second phase of the steam storage device is preferably conducted completely through the superheater.

The valve devices may be formed as Proportionalventileinrich lines. The valve means - with the exception of the seventh and eighth valve means - may further be designed as three-way valves.

The object is further achieved by a plant of the basic material ^¬ industry, wherein the system is designed such that it is operable according to an operating method according to the invention.

Further advantages and details will become apparent from the following description of exemplary embodiments in conjunction with the drawings. In a schematic representation:

1 schematically shows a plant of the basic industry,

2 shows schematically a plant cycle,

 3 schematically shows the mode of operation of a first embodiment of a water-steam cycle in a first phase of the plant cycle,

4 schematically shows the mode of operation of the water-steam

Cycle of FIG. 3 in a second phase of the conditioning cycle;

5 shows schematically the operation of a second extended ^¬ staltung a water-steam circuit in which it ^¬ th phase of the conditioning cycle, and

 6 schematically shows the mode of operation of the water-steam

Circuit of FIG 5 in the second phase of the investment cycle. FIG. 1 shows, in a very simplified representation, a plant of the basic industry. According to FIG 1, the system has a Ba ^¬ sisteil. 1 The base part 1 is operated in accordance with FIG 2 in a plant cycle. According to FIG. 2, the plant cycle has at least a first phase PI and a second phase P2. In the first phase PI of the respective investment cycle hot gases are produced on the basis of the running in the base part 1 technical Prozes ^¬ ses the primary industry in the base part. 1 It is possible that in the second phase P2 of the respective system cycle in the base part 1, no hot exhaust gases. Al ^¬ tively, it is possible that while the gases are produced, but only come in significantly geringfügigerem extent than in the first phase PI. In particular, during the second phase P2, on average, a maximum of one sixth of the amount of hot exhaust gases arises on average, as in the first phase PI.

The phases PI, P2 are determined as needed. As a rule, the duration of phase P2 for the total time of the system cycle is a maximum of 30%, in particular a maximum of 25%.

The representation of FIG 2 is also simplified. In particular ^¬ sondere it is possible that the number of first stages is PI and the second phase P2 during a system cycle is greater than one. This will be explained in more detail below with reference to a typical base ^¬ part 1, namely a base part 1 in the form of an electric arc furnace.

In an electric arc furnace, the operation is typically carried out in the sequence of phases a) parting off and partial charging,

b) melting the partial batch,

c) full charging and

d) Melting of the total batch plus refining.

During the phases of parting off and partial charging as well as full charging, hot exhaust gases are produced only to a small extent. During the two stages of fusion hot exhaust gases are produced to a considerable extent.

Typical durations are for example for the

 under,

 for the

 for the

 for the

 and

 for the

 Minutes.

The times mentioned can vary to a certain extent from base part 1 to base part 1 and also from plant cycle to plant cycle.

On the other hand, during operation with directly reduced iron or with pig iron, only one of the phases PI, P2 accumulates during a given system cycle.

According to FIG 1, the hot exhaust gases are discharged through a pipe system 2 ^¬ from the base part 1 and discharged to the outside air. The removal of the hot exhaust gases takes place at any time to the extent to which the hot exhaust gases each fall on, so in the first phase PI on a large scale, in the second phase P2 to a small extent or not at all.

Before the hot exhaust gases are released to the outside air, they must be filtered. Filtering takes place in a filter 3. At the time of filtering, the temperature of the hot exhaust gases may not exceed about 130 ° C. It is therefore necessary to cool the hot exhaust gases.

Part of the cooling takes place in a mixer 4, in which the hot exhaust gases are mixed with supply air and / or cold exhaust gases (maximum temperature 50 ° C., generally much lower). the. Beforehand, the hot exhaust gases in the pipeline system 2 are cooled. This part of the plant of the basic industry is designed in accordance with the invention. In connection with FIG. 3, the structure of a water-steam cycle and its integration into the pipeline system 2 will be explained below. Furthermore, the operation of the water-steam cycle in the ers ^¬ th phase PI of the system cycle is explained in conjunction with FIG. Thereafter, in connection with FIG. 4, the operation of the water-steam cycle in the second phase P2 of the system cycle will be explained.

According to FIG 3, the water-steam circuit of a first Ver ^¬ liner element 5, a superheater 6, a second evaporator element 7 and a Grundvorwärmer 8, which are incorporated in the embodiment shown in FIG 3 sequence in the piping system. 2 The evaporator elements 5, 7 together correspond to an evaporator device. The evaporator elements 5, 7 remove hot water at least in the first phase PI of a steam drum 9, evaporate it by means of the hot exhaust gases and feed the vaporized hot water back into the steam drum 9 as saturated steam. The saturated steam is via a line 10 a

Steam storage 11 supplied. In the line 10, a proportional valve 12 is arranged. The opening state of the proportional valve 12 is controlled on the basis of the pressure in the line 10 on the input side of the proportional valve 12

prevails.

From the steam reservoir 11, the saturated steam flows via a Zyk- ion 13 to a valve device 14. The valve device 14 is preferably designed as a proportional valve device. It can be designed in particular as a three-way valve according to the illustration of FIG. Said Ventilein ^¬ direction 14 corresponds to a third valve device in the sense of claim 4. The control of the third valve means 14 is independent of the extent and the temperature of the resulting exhaust gas in the first phase PI. In the first phase, the third valve device 14 is controlled in such a way that that the saturated steam is passed through the superheater 6 in its entirety. This is indicated in FIG. 3 by a corresponding arrow A. In the superheater 6, the saturated steam is superheated by means of the hot exhaust gases to superheated steam. The superheated steam is passed through a further valve device 15. The valve ^{¬ device} 15 corresponds to a first valve device in the sense of claim 1. Also, the first valve device 15 is preferably designed as a proportional valve device. It can be designed as a three-way valve according to the representation of FIG. The first valve device 15 can furthermore be controlled in the first phase PI as a function of the extent and the temperature of the hot exhaust gases.

By means of the first valve device 15, the superheated steam is divided into a first and a second part. This is also indicated in FIG. 3 by corresponding arrows B. The second part is complementary to the first part.

The first part of the superheated steam is directed into a loading ^¬ direction by a buffer memory sixteenth The first part of the superheated steam heats up a storage medium located there in the buffer memory 16. The storage medium may be in particular concrete, the buffer memory 16 may thus be designed as concrete storage. Alternatively, other SpeI ^¬ chermedien are possible, such as sand, gravel, solid salts, liquid salts, etc .. It is critical that the heating (= loading) of the buffer memory 16 and the cooling (= decision load) of the buffer memory 16 with a Strömungsrichtungsum- sweep of the buffer 16 flowing through the steam is connected.

The second part of the superheated steam is passed via a line 16 'bypassing the buffer 16 directly to ei ^¬ ner steam turbine 17. The steam turbine 17 drives electric generator ei ^¬ NEN 18th The first part of the superheated steam can also be passed to the steam turbine 17 after flowing through the buffer 16. In this case, a further valve device 19 is preferably present (second valve device in the sense of claim 2). By means of the second valve device 14, the two vapor streams are combined in this case. The union of the two vapor streams is passed in this case to the steam turbine 17. The second valve device 19 is preferably oriented as a proportional valve device. It can be configured as a three-way valve according to the illustration of FIG 3 in particular ^¬ sondere.

Starting from the steam turbine 17, the now relaxed steam can be fed to a condenser 20 and condensed there. Starting from the condenser 20, the condensed steam can be pumped via a condensate pump 21 to a condensate preheater 22. Alternatively, the expanded steam, starting from the steam turbine 17, can be led via a line 23 to the condensate preheater 22. In this case, in this line 23, a proportional valve is preferably arranged ^¬ 24 whose opening degree is adjusted as a function of tempera ture ^¬ of the hot water leaving the Kondensatvor ^¬ warmer 22nd Alternatively, the expanded steam, starting from the steam turbine 17, can be led via a line 25 to a degasser 26. In this case, in the line 25, a proportional valve is preferably arranged 27 whose opening degree is adjusted in dependence on the temperature of the hot water which flows out of the degasser from ^¬ 26th

Starting from the degasser 26, the hot water is fed via a feedwater pump 28 to the basic preheater 8. Depending on the temperature of the hot water leaving the basic preheater 8, a pump 29 is controlled, so that the hot water leaving the basic preheater 8 is supplied to the preheater 8 or the steam drum 9 again via the degasser 26. 4 shows the same water-steam circuit as FIG 3, depending ^¬ but in the second phase P2.

Also in the second phase P2 of the Dampfspeichereinrich- device 11 is taken as shown in FIG 4 saturated steam. In contrast to the first phase PI, however, in the second phase P2 the control state of the third valve device 14 is controlled as a function of the quantity and / or the temperature of the hot exhaust gases. Depending on the activation state of the third valve device 14, the extracted saturated steam is divided by means of the third valve device 14 into a third part and into a fourth part of the saturated steam. This is indicated in FIG. 4 by corresponding arrows C. The third part of the saturated steam is passed through the superheater 6 and then fed to the first valve means 15. The steam coming from the superheater 6 is combined by means of the first valve device 15 with superheated steam, which is taken out of the buffer reservoir 16 counter to the loading direction. The combination of the two vapor streams is - see the corresponding arrows D in FIG 4 - passed via the line 16 'and the second valve means 19 to the steam turbine 17. The fourth part of the saturated steam is conducted via a line 30 against the loading direction through the buffer memory 16 and overheated there to the superheated steam, which is the first valve means 15 is supplied and combined there with the incoming from the superheater 6 steam.

The rest of the operation of the water-steam cycle remains unchanged ^¬ .

The embodiment of the water-steam cycle according to FIGS. 3 and 4 can be operated in particular in such a way that the temperature of the superheated steam supplied to the steam turbine 17 remains at least approximately constant across phases. Under certain circumstances, even the amount of steam can be kept substantially constant or even completely constant.

In connection with the Figures 5 and 6, the structure of a further water-steam cycle and its integration into the piping system 2 will be explained below. In connection with FIG. 5, the operation of the water-steam cycle in the first phase PI of the system cycle will be explained. In Verbin ^¬ tion with FIG 6, the operation of the water-steam circuit is explained in the second phase P2 of the plant cycle.

As in the embodiment of Figures 3 and 4, the water-steam cycle of Figures 5 and 6, the two evaporator ^¬ elements 5, 7, the superheater 6 and the Grundvorwärmer 8, which in the same order as in the FIG and 4 are installed in the piping system 2. The Verdampferele ^¬ elements 5, 7 correspond together again the evaporator device. They remove at least in the first phase PI of the steam drum 9 hot water, evaporate it by means of hot exhaust gases and lead the evaporated hot water as saturated steam back to the steam drum 9. In contrast to the FIGS. 3 and 4, in the embodiment of FIGS. 5 and 6, however, the steam drum 9 already corresponds to the steam storage device 9. The steam drum 9 can be dimensioned larger than the steam drum 9 of the embodiment, with the same or comparable base part 1 3 and 4. Alternatively, the dimensioning of the steam drum 9 can be maintained. In this case, the steam drum 9 operates at a relatively low SpeI ^¬ cherkapazität. The vapor pressure in both cases is kept constant or, if possible, constant. The steam mass flow taken from the steam drum 9 varies in both cases, depending on the heat supply to the evaporator elements 5, 7.

In the first phase PI, the saturated steam generated in the evaporator elements 5, 7 and stored in the steam storage device 9 (possibly briefly) is passed through the superheater 6 where it is superheated to superheated steam by means of the hot exhaust gases. The design of the steam-water circuit of Figure 5 and 6, the first valve means 15, the preference ^¬ as a proportional valve device is formed. Appropriate to the representation of FIG 5 and is designed as a three-way valve. By means of the first valve device 15, the superheated steam is divided into a first and a second part in the first phase PI of the system cycle. This is indicated in FIG 5 by corresponding arrows E.

The first part of the superheated steam is passed in accordance with the illustration of FIG 5 in a loading direction through the buffer memory 16 and heated in buffer memory 16, the storage medium located there. The second part of the superheated steam is passed bypassing the buffer 16 via a line 31 directly to the steam turbine 17, which in turn generates electrical energy via the connected generator 18. Starting from the steam turbine 17, the now relaxed steam is - as in the case of FIGS. 3 and 4 - conducted as steam or as condensate to the condensate preheater 22 or directed to the degasser 26.

Under certain circumstances, the first part of the superheated steam conducted through the buffer reservoir 16 can likewise be fed to the steam turbine 17 analogous to the embodiment of FIG. According to FIG. 5, however, the first part of the superheated steam is condensed again after flowing through the buffer memory 16 and fed to the steam storage device 9-in accordance with the embodiment of FIG. 5, ie the steam drum 9. In particular, the condensed steam can be fed into the Lei ^¬ tung 28 'through which the Grundvorwärmer 8 hot water is supplied. In this case, in the first phase PI of the system cycle, the first part of the superheated steam is first passed through the basic preheater 8 after flowing through the buffer memory 16 and only then

Steam storage device 9 (= the steam drum 9) supplied. The buffer memory 16 is in the embodiment of Figures 5 and 6 is not a simple concrete, sand or salt storage (as in Figures 3 and 4), but is more complex. In particular ^¬ sondere includes the buffer memory 16 according to FIG 5 and 6, a buffer memory superheater 32, a buffer memory preheater 33, a latent heat storage 34, and a buffer memory steam drum 35. The buffer memory superheater 32 may, for example, as concrete, sand or salt superheater be educated. In an analogous manner, the buffer storage preheater 33 may be formed. In the first phase PI of the plant cycle, the first part of the superheated steam is first led ent ^¬ speaking the 5 depicted in FIG arrows through the buffer memory superheater 32nd From there, the first part of the superheated steam is passed through the latent heat accumulator 34 by means of a valve device 36 (sixth valve device in the sense of claim 11). From there, the first part of the superheated steam is supplied to the buffer storage preheater 33 by means of a further valve device 37 (fifth valve device in the sense of claim 11). For example, the superheated steam - then no longer overheated, but even condensed - leaving the buffer memory 16. For example, the condensate leaving the buffer memory 16 via a further valve means 38 (corresponding to a fourth valve device in the sense of claim 9) in the feed line 28 ' fed via the

Preheater 8 - the serving of the steam storage device 9 is used with hot water.

The fifth and the sixth valve device 36, 37 may be designed as proportional valve devices. Alternatively, they can be designed as simple, only binary (open / close) switchable valve devices. The fourth valve device 38 is preferably designed as a proportional valve device. Both the fourth and the fifth and the sixth valve means 36, 37, 38 may be ^{ausgebil ¬} det as shown in FIG 5 and 6 as three-way valves. In the second phase P2 of the system cycle, the steam storage device 9 (ie the steam drum 9) is also taken from saturated steam. The saturated steam is passed completely through the superheater 6 and the first valve means 15 according to the embodiment of the steam-water circuit of FIG 5 and 6 in the second phase P2. The fed through the superheater 6 saturated steam is combined by means of the first valve means 15 with superheated steam, which is removed as shown in FIG 6 against the loading direction of the buffer memory 16, see the corresponding arrows F in FIG 6. The combination of the two vapor streams over the line 31 passed to the steam turbine 17.

The overheated in the second phase P2 of the system cycle against the loading direction of the buffer 16 steam is previously supplied to the buffer memory 16 as hot water. According to the representation of FIG. 6, the hot water can be taken from the already mentioned feed line 28 '. Alternatively, the hot water behind the basic preheater 8 can be tapped off. Also mixed forms are possible. In the case of removal from the feed line 28 ', the removal can take place in particular by means of the fourth valve device 38.

In the event that the hot water of the feed line 28 'is removed, it is first passed through the buffer storage preheater 33 and then from there via the fifth valve ^{¬ means} 37 in the buffer storage steam drum 35 gelei ^¬ tet. In the event that the hot water is tapped behind the Grundvorwärmer 8, the hot water is passed directly - ie bypassing the buffer storage preheater 33 and the fifth valve means 37 - in the buffer storage steam drum 35. The control takes place via a valve device 38 '(seventh valve device in the sense of claim 11). The seventh valve device 38 'is preferably designed as a proportional valve device.

Regardless of which of the two ways the hot water of the buffer storage steam drum 35 is supplied, it will taken over a line 39 by means of a pump 40 of the buffer storage ^¬ cher steam drum 35 and directed against the loading direction by the latent heat accumulator 34. In the latent heat storage 34, the hot water is evaporated to wet or saturated steam. The wet or saturated steam is fed back to the buffer storage steam drum 35 via the sixth valve device 36. This too is indicated in FIG. 6 by corresponding arrows. In line 39, a valve device 41 (ninth valve device in the sense of claim 11) can furthermore be arranged. The ninth valve means 41 may be formed as a simple switching valve (open / closed) or as a proportio ^¬ nalventileinrichtung.

Via a line 42 and a further valve device 43 (eighth valve device in the sense of claim 11)

Saturated steam taken from the buffer storage steam drum 35 and out against the loading direction through the buffer storage superheater 32. In the accumulator superheater 32, the saturated steam is overheated to superheated steam.

The seventh, eighth and ninth valve means 38 ', 43, 41 are simple two-way valves. You can be as Proporti ^¬ onalventile or as simple switching valves (open / closed) out forms ^¬.

Also in the second embodiment of the water-steam Kreislau ^¬ fes corresponding to FIGS 5 and 6 it can be achieved that the temperature of the steam turbine 17 supplied superheated steam in two phases PI, P2 of the system cycle essen- sentlichen is the same. Also the steam mass flow to

Steam turbine 17 can - at least substantially - be kept constant.

By means of the present invention, efficient use of the thermal energy contained in the hot exhaust gases is possible in a relatively simple manner. The above description is only for explanation of the present invention. The scope of the present invention, however, is intended to be determined solely by the appended claims.

Reference sign list

 1 base part

 2 piping system

3 filters

 4 mixers

 5, 7 evaporator elements

6 superheaters

 8 basic preheaters

 9 steam drum

 10, 16 ', 23, 25, 30, 31, 39, 42 lines

 11 steam storage

 12, 24, 27 proportional valves

13 cyclone

 14, 15, 19, 36, 37, 38, 38 ', 41, 43 valve means

16 buffer memory

 17 steam turbine

 18 generator

 20 capacitor

 21 condensate pump

 22 condensate orwärmer

26 degasser

 28 Feedwater pump

28 'feed line

 29, 40 pumps

 32 buffer heater superheater

 33 buffer storage preheater

 34 latent heat surveyor

35 buffer memory

steam drum

 A to F arrows

 PI, P2 phases

Claims

claims

1. operating method for a plant of the basic industry, - wherein a base part (1) of the plant is operated in accordance with an investment ^cycle ;

 - During the system cycles in a first phase (PI) of the respective system cycle hot exhaust gases and in a second phase (P2) of the respective plant cycle either no hot exhaust gases or the hot exhaust gases compared to the first phase (PI) only in considerable arise to a reduced extent,

 - whereby the hot exhaust gases in the respective circumference in which they arise are discharged via a pipeline system (2) from the base part (1) of the plant,

 in which in a pipe system (2) installed evaporator means (5, 7) by means of the hot exhaust gases at least in the first phase (PI) water is vaporized to saturated steam and the saturated steam is fed to a Dampfspeichereinrich- device (9, 11),

characterized,

 - that in the first phase (PI)

 the saturated steam stored in the steam storage device (9, 11) is passed through a superheater (6) installed in the piping system (2) and superheated there to superheated steam by means of the hot exhaust gases,

 - The superheated steam by means of a between the superheater (6) and a buffer memory (16) arranged first valve means (15) is passed to a first part in a loading direction through the buffer memory (16),

 - The first part of the superheated steam in the buffer memory (16) heats a storage medium located there, and

- The superheated steam by means of the first Ventileinrich- device (15) to a second, complementary to the first part part, bypassing the buffer memory (16) to ei ^¬ ner steam turbine (17) is passed and

- that in the second phase (P2) - The steam storage device (9, 11) is taken from saturated steam, at least in part through the superheater (6) and is combined by means of the first valve means (15) with superheated steam, which is taken against the loading direction of the buffer memory (16) will, and

 - The combination of passed through the superheater (6) steam and from the buffer memory (16) removed superheated steam to the steam turbine (17) is passed.

2. Operating method according to claim 1,

characterized,

that in the first phase (PI) the first part of the superheated steam after flowing through the buffer memory (16) with the second part of the superheated steam by means of a between the buffer memory (16) and the steam turbine (17) arranged second valve means (19) united and that the union of the first and second part of the superheated steam to the steam turbine (17) is passed.

3. Operating method according to claim 2,

characterized,

in the second phase (P2), the superheated steam taken from the buffer store (16) counter to the loading direction is removed from the steam storage device (11) in the form of saturated steam.

4. Operating method according to claim 3,

characterized,

in the second phase (P2), the saturated vapor removed from the vapor storage device (11) is transferred to the superheater (6) by means of a third valve device (14) arranged between the vapor storage device (11) on the one hand and the superheater (6) and the buffer reservoir (16) ) fed saturated steam and in the buffer memory (16) supplied saturated steam is divided.

5. Operating method according to claim 2, 3 or 4,

characterized,

that the buffer memory (16) is designed as a concrete, sand or liquid salt storage.

6. Operating method according to claim 1,

characterized,

in the first phase (PI) the first part of the superheated steam is condensed after passing through the buffer reservoir (16) and returned to the vapor storage device (9).

7. Operating method according to claim 6,

characterized,

in the first phase (PI) the first part of the superheated steam, after condensing and before feeding to the steam storage device (9), is passed through a primary preheater (8) behind the evaporator device (5) with respect to the piping system (2); 7) is installed in the piping system (2).

8. Operating method according to claim 7,

characterized,

in the second phase (P2), the superheated steam taken from the buffer store (16) against the loading direction has previously been taken off as hot water from a feed line (28 ') serving to feed the steam storage device (9) with hot water or tapped behind the base preheater (8) becomes .

9. Operating method according to claim 8,

characterized,

the removal of hot water from the feed line (28 ') takes place by means of a fourth valve device (38) arranged in the feed line (28').

10. Operating method according to claim 8 or 9,

characterized, - That the buffer memory (16) comprises a buffer memory Überhit ^¬ zer (32), a buffer storage preheater (33), a latent heat storage (34) and a buffer steam drum (35),

- That in the first phase (PI) of the first part of the superheated ^¬ th steam first by the buffer storage superheater (32), from there by the latent heat storage (34) and from there bypassing the buffer steam drum (35) through the buffer memory Preheater (33) is guided,

- That in the second phase (P2) the hot water in the case that it is the feed line (28 ') is removed, first passed through the buffer storage preheater (33) and from there into the buffer storage steam drum (35) is passed and in the event that it is tapped behind the Grundvorwärmer (8), bypassing the buffer storage preheater (33) in the buffer storage steam drum (35) is gelei ^¬ tet, then the buffer storage steam drum (35) ent ^¬ accepted and in the latent heat accumulator (34) is converted to wet or saturated steam, and from there wet or saturated steam, the buffer memory steam drum (35) is supplied, and finally the buffer memory steam drum removed (35) saturated ^¬ vapor and through the buffer memory Superheater (32) is guided, wherein the saturated steam in the buffer storage superheater (32) is superheated to superheated steam.

11. Operating method according to claim 10,

characterized,

 - That for guiding the hot water, the saturated steam and the superheated steam, a fifth to ninth Ventileinrich- device (37, 36, 38 ', 43, 41) are present,

 - That the fifth valve means (37) between the buffer storage preheater (33), the buffer storage steam drum (35) and the latent heat storage (34) is arranged,

in that the sixth valve device (36) is arranged between the buffer storage steam drum (35), the latent heat accumulator (34) and the accumulator superheater (32), - That the seventh valve device (38 ') in a the preheater (8) and the buffer storage steam drum (35) ver ^¬ binding connecting line is arranged,

 - That the eighth valve means (43) in a connecting line (42) is arranged, via which, bypassing the sixth valve means (36), the buffer steam drum (35) and the buffer superheater (32) are interconnected, and

 - That the ninth valve means (41) is arranged in a line which leads from the buffer steam drum (35) to a connecting line via which the fifth valve means (37) and the latent heat accumulator (34) are interconnected.

12. Operating method according to one of claims 6 to 11, characterized

that in the second phase (P2) of the Dampfspeichereinrich- device (9) removed saturated steam is completely passed through the Überhit ^¬ zer (6).

13. Operating method according to one of claims 1 to 12, characterized

in that the valve devices (14, 15, 19, 36, 37, 38, 38 ', 41, 43) are designed as proportional valve devices.

14. plant of the basic industry,

characterized,

that it is designed such that it is operable in accordance with a Be ^¬ operating method according to any one of claims 1 to 13.