DE2458961A1 - Steam storage installation with super heat storage - uses water from latter to super heat stored stream and returns it to main storage vessel - Google Patents

Abstract

The arrangement is particularly intended for providing peak hour energy and is of the type wherein the steam produced in the main storage vessel (3) is superheated by heat provided by the superheat storage vessel (1). The superheat storage vessel drives the hot water collecting at its lower end via the superheater (2), where it superheats steam from the main storage vessel, and from there into the main storage vessel. The water may be fed into the main storage vessel via its normal feed water system. The water emerging from the superheater may be fed to an expansion steam generator (M) before being fed into the main vessel, the steam so produced being fed to an injector in the steam discharge line of the main vessel upstream of the superheater.

Description

Steam storage system The invention relates to a storage tank system, in particular for the generation of peak energy, in which the one generated in the main neicher Steam is overheated by the heat of the overheating storage tank.

Such steam sneezing systems are known and have the disadvantage that for the operation of the plant conveying devices, such as e.g.

Circulation pumps, which are necessary at times of peak energy demand have to be put into operation and thus increase the need for cutting even more.

The present invention avoids the stated disadvantage and is characterized in that the overheating store is designed as a driving store is, the hot water, in particular at its lower end by means of a discharge line is taken, which is generated after cooling in the superheater in the main memory Saturated steam is fed to the memory content of the main memory, in particular the cooled hot water through the charging device of the main storage tank into the water room same introduced. According to a further feature of the invention, the cooled Hot water is fed to an expansion steam generator, from which the pressure is greater than the main storage tank expanded water to the main storage tank and the generated steam to an ejector in the Discharge line of the main storage tank is fed before entering the superheater.

The invention is shown schematically and by way of example in FIGS. 1 to 3 shown.

Fig. 1 shows a circuit diagram of a steam storage system.

Fig. 2 shows a similar steam storage system with a reheater.

Pig.3 shows a steam storage system with a phase separator in the Discharge line of the propellant storage.

The steam storage system according to FIG. 1 comprises a haunt storage system consisting of several slope storage 3, which is shown in simplified form by a symbol is. A superheater 2 is provided in the discharge line 8 of the main store 3, through the Hot water of one trained as Creik.-seicher Overheating memory 1 is heated. The hot water cooled in the superheater 2 is through the discharge line via a control element, which is designed as a throttle element 12 is fed to the water space of the main reservoir 3. Appropriately this is done the charging device 5 of the main memory 3 used, the same in the water space 4 is arranged. This storage system allows the main memory to be overheated twice generated saturated steam.

The first overheating occurs as a result of that which is arranged in the discharge line 8 Throttle body 13. The second overheating, which can also take the place of the first, then takes place in the superheater 2 heated by the hot water of the propellant reservoir 1. To start up the system, the throttle valve 13 is therefore first opened and then as soon as the throttling of the delivery steam in the discharge.

line 8 is no longer sufficient to overheat it, it will Throttle member 12 open, whereby the heating of the superheater 2 and at the same time a reloading of the main storage occurs, so that the steam capacity of the main storage is increased.

In Figure 2, a similar steam storage system is shown in which however, the discharge line 9 is a branch line before it enters the superheater 2 10 is provided, which heats a reheater 11. To regulate the partial flows two throttle elements 12 are provided here.

In Fig. 3, a further steam storage system is shown in which in the discharge line 9 of the propulsive store 1 after the superheater 2, a phase separation device is provided, which is designed as a relaxation steam generator 6. That relaxed Hot water is via line 14 via a check valve 15 with the water space of the main storage tank 1 in connection, so that the water content in the main storage tank is increased is. The steam generated in the desnazing steam generator 6 is via the steam line 16 fed to an ejector 7 in the discharge line 8 of the main memory 3, so that a mixing of the two vapors takes place before they enter the superheater 2. The circuit of FIG. 3 relieves the steam space of the main memory 3 scored. In addition, the pressure of the steam withdrawn from the main storage elevated.

Claims (6)

P a t 0 t p ü h e 1. Steam storage system, in particular for the generation of Snitzenergy, in which the damnf generated in the main storage unit by the heat of the overheating storage unit is overheated, characterized in that the overheating accumulator (1) acts as a driving store is designed, the hot water, in particular at its lower end, by means of a Discharge line (9) is removed after cooling down in the superheater (2) of the The saturated steam generated in the main memory (3) corresponds to the memory content of the main memory (3) is fed. 2. Steam storage system according to claim 1, characterized in that the cooled hot water of the overheating storage tank (1) by the charging device (5) of the main storage tank (3) is injected into the water space (4) of the same (Fig. 1 to 3). 3. Steam storage system according to claim 1, characterized in that the cooled hot water of the overheating storage tank (1) after it has cooled down Relaxation steam generator (6) is supplied, from which the pressure is greater than the main accumulator expanded water to the main storage tank (3) and the generated steam to an ejector (7) in the discharge line (8) of the haunt storage tank (3) before entering the superheater (2) is supplied (Fig. 3). 4. Steam storage system according to claim 1, characterized in that the discharge line (9) has a branch line (10) to a reheater (11) and that both lines (9,10) after flowing through the superheater (2,11) again be united (Fig. 2). 5. Steam storage system according to claim 1 or 4, characterized in that that in the discharge line (9) and / or branch line (10) a control element, in particular Throttle member (12) is arranged. 6. Steam storage system according to claim 1, characterized in that the steam accumulator of the main storage system (3) as, in particular, vertical incline accumulator are trained. L e r s e i t e