DE102012103617A1 - Fossil-fired power plant with heat storage - Google Patents

Abstract

In a power plant comprising a steam generator with connected water / steam circuit (1) and turbine or turbo set integrated therein, wherein the water / steam circuit (1) steam side with a heat storage (3) and / or a thermal to the heat storage ( 3) coupled heat exchanger (2) connected by conduction and / or thermally coupled, a solution is to be created, which makes it possible to adapt a power plant to the fluctuating feed demand of the connected power grid and to flexibilize its Stromeinspeisemöglichkeiten. This is achieved by virtue of the fact that the water / steam cycle (1) is conductively connected to the heat store (3) and / or the heat exchanger (2) in such a way that thermal energy of the steam from the water / steam cycle (1) thermally enters the heat accumulator (3) and / or in the heat exchanger (2) can be coupled out.

Description

The invention is directed to a power plant comprising a steam generator with connected water / steam circuit and integrated turbine or turbo set, wherein the water / steam cycle on the steam side with a heat storage and / or thermally coupled to the heat storage heat exchanger connected and / / or thermally coupled. Furthermore, the invention is directed to a method for storing generated in a power plant with a steam generator with connected water / steam cycle and integrated turbine or turbine set heat, wherein the water / steam circuit steam side with a heat storage and / or a thermal connected to the heat storage heat exchanger conductively connected and / or thermally coupled.

In the electric power grid, the electric power feeding power generation and the electric power taken from the power grid must be balanced. Due to the expansion of renewable energies, there are at times strong overcapacities, but in some cases also undercapacities in the grid. The fluctuating supply of renewable energy and thus the fluctuating feed-in of renewable energies into the electricity grid must be compensated for using conventional power plants. This makes it necessary to equip conventional power plants with a quickly controllable power plant capacity, so that they can shut down quickly in case of overcapacity and quickly booted up under sub-capacity, depending on the requirements of the grid. Alternatively, there is the possibility of switching off the renewable energy capacities, for example wind turbines, in the case of overcapacity or else of storing the generated power in energy storage systems such as pumped storage power plants, compressed air storage power plants or batteries.

The operation of fossil-fueled or refuse derived fuel-fired power plants, such as biomass, makes it necessary in this scenario to quickly design power plant capacity to stabilize and regulate grids in their capacity. These are on the one hand fast startable or loadable in the power stations necessary, for example, wind turbines in windless times their feed capacity quickly back, or if, for example, in peak demand times to cover the additional needs additional capacity is needed.

However, fossil-fueled power plants, especially coal-fired power plants, are now provided with the disadvantage that they can not be switched on and off at will and are movable up and down in relation to their output power. The power of steam power plants, especially the coal-fired steam generator, can not be changed arbitrarily strong and fast. In addition, minimum operating and minimum downtimes must be observed to avoid excessive system wear. If power plants are to remain on the grid as a so-called "hot reserve" for an immediate restart for power generation, they must be ready for operation with their minimum power or minimum load in permanent operation. The same applies in the event that one wants to make power plants more flexible in daily operation, for example, in such a way that electricity is fed into the grid during the power demand-intensive times of day, but at night the power plant is reduced to a "state of rest". The operation of the steam generator or power plant with minimal load is necessary, inter alia, so that in the fire (ungs) space of the steam generator temperatures do not fall so far that the necessary for the fuel ignition, especially coal ignition, operating temperature is reached again after hours of heating. Thus, the start-up times for a so-called "hot start" after less than eight hours downtime currently about 2 hours, for a so-called "hot" less after 48 hours downtime about 5 hours and a so-called "cold start" after less than 72 hours Standstill about 8 hours. In order to enable at least a "hot start", such a power plant must be kept in operation with its minimum power in permanent operation. The minimum capacity for hard coal power plants is approx. 38% and approx. 40% for lignite power plants. In addition, minimum standstill times for hard coal power plants are approx. 2 hours and brown coal power plants approx. 8 hours, minimum operating times for hard coal power plants approx. 4 hours and lignite power plants approx 6 hours to follow. Include these operating times in minimum performance with efficiency losses of about 5%. In addition, it should be noted in coal-fired power plants that restarting is only possible with a power change of approx. 3-5% per minute.

The invention has for its object to provide a solution that makes it possible to adapt a power plant to the fluctuating feed demand of the connected power grid and to flexibilize with respect to its Stromeinspeisemöglichkeiten.

In a power plant of the type described in more detail, this object is achieved in that the water / steam circuit is connected in such a manner with the heat storage and / or the heat exchanger that heat energy of the steam from the water / steam Circuit thermally in the heat storage and / or in the heat exchanger can be coupled out. In a method of the type described in more detail, this object is achieved in that in the heat storage and / or the heat exchanger heat energy from the steam of the water / steam cycle coupled and coupled into the heat storage and / or the heat exchanger.

Advantageous developments and advantageous embodiments of the invention are the subject of the respective subclaims.

The invention thus provides that from the water / steam cycle heat energy of the steam is indirectly coupled via a heat exchanger in a heat storage or directly directly into a heat storage, both decoupling paths can also be operated in parallel if necessary. This makes it possible to flexibilize power plants insofar as generated steam does not necessarily have to be routed to generate electricity through the turbine set or turbo set, but is passed through at least one heat exchanger or at least one heat storage where the steam gives off (its) energy. In the case of, for example, constant generation of steam, the amount of steam used for power generation can thereby be reduced and thus the amount of electricity or electrical energy fed into the network by the power plant can be regulated, so that part of the steam quantity is "stored". This makes it possible to drive back a grid-connected power plant relatively quickly with respect to the amount of electricity delivered to the grid. On the other hand, as stated above, in particular coal power plants must be operated with a minimum or minimum load, this "steam control" can be used to shut down the firing capacity in the allowable and economically acceptable speeds. The stored in the heat storage heat energy in turn, then in the case when the power plant is to be restarted to be used to provide energy, for example, by converting water into steam for restarting or re-startup available. For example, when the power plant is restarted, the stored energy may be used to achieve a higher rate of power change in percent / minute than the usual 3-5% / minute by the energy stored in the form of thermal energy when starting in the form of steam, for example, to the low-pressure preheaters of the water / steam cycle of the power plant is provided. Further, when a higher feed is needed temporarily in the power grid, peak / midload current in addition to the (main) water may be provided by means of a salt / water steam heat exchanger, preferably a once-through steam generator, and any additional turbine circuit / Steam cycle of the power plant are provided and fed into the grid.

In order to be able to transfer current overcapacities present in the network from the grid to a storage, the invention also provides that the heat storage is electrically heated, or that the heat storage in the power grid existing overcapacity of electricity and / or operation of the power plant in his Minimum or minimum load range generated, not to be fed into the grid excess power supplied via a with the respective current and / or excess current electrically heated and preferably arranged in the heat storage heater thermal energy and stored in the heat storage. This makes it possible to store energy, if due to the fluctuating feed-in of renewable energies such as wind or photovoltaic in the grid is too high a feed. In order to be able to flexibly provide power capacity in times of overcapacity and increased demand in the power grid, the invention provides that, on the one hand, the power plant can be restarted relatively quickly, but alternatively, on the other hand, also parallel to the (main) water / steam cycle the power plant, a second water / steam cycle can be operated with associated turbine set or turbo set, which then immediately without the power plant must be powered up, generates electricity and fed into the grid. The invention therefore provides in an embodiment that the heat storage of the power plant in stored heat coupled out manner with the or a second steam generator is connected. Likewise, the invention provides that the heat storage of the power plant in stored heat auskoppelbarer manner is connected to at least one other heat exchanger, which forms a preheater, superheater or reheater in the or a second water / steam cycle.

In the embodiment according to the invention, the method is characterized in that heat stored in the heat accumulator is decoupled into the or a second steam generator, wherein steam generated in the steam generator is fed to a turbine as live steam or reheater steam and / or heat stored in the heat accumulator at least one further heat exchanger is decoupled, which forms a preheater, superheater or reheater in the or a second water / steam cycle. This steam is then fed in each case to a turbine or turbo set with a connected generator.

In particular, the power plant according to the invention and the method according to the invention can be used to decouple and store the heat energy arising during operation of the power plant in its minimum or minimum load range in the form of steam from the water / steam cycle. The invention therefore further provides, in an embodiment of the method, that the heat energy from heat generated during operation of the power plant in its minimum or minimum load range and not used for power generation excess steam from the water / steam cycle thermally coupled into the heat storage and / or the heat exchanger becomes. In this case, it may also be provided in a further development of the method that when the power plant is restarted from its minimum or minimum load range stored in the heat accumulator heat is coupled into the and / or in the second water / steam cycle in the range of Niederdruckvorwärmern.

The heat storage can be designed as a steam storage or Ruths storage, salt storage, concrete storage or hot water storage. A particularly suitable heat storage medium is molten salt, in particular a mixture of KNO ₃ and NaNO ₃ .

Further support of the flexibility of a particular fossil-fired power plant can be achieved according to the invention of the power plant, characterized in that the steam generator with a fossil fuel and / or biomass combustible combustion chamber whose burner are preferably part of an indirect firing.

In combination with the operation of the supplied from an excess current heater of the heat accumulator, it is therefore possible, in times when excess electricity is fed into the grid, the heat storage, for example, from two reciprocally operated containers (hot / cold) with the storage medium, eg , As molten salts, or a stratified storage tank with molten salt, to use temporarily excess electricity from the power grid and / or temporarily excess steam from the steam power plant (steam power plant with connected water / steam cycle) for heating the storage medium provided in the heat storage use. Since electric heating has an efficiency of nearly 100% and conventional steam power processes in the temperature range 530 ° C have cycle efficiencies of 38-42%, the efficiency of the energy storage is higher than many other alternatives. If the heat storage is used only for heating a heat exchanger (for example, preheating / overheating / reheat) in an otherwise otherwise heated steam cycle, the efficiency is correspondingly lower. The system works but analog. For example, short-term replacement of the tap at thermal power plants allows increased power delivery to the grid within the existing turbine or generator design.

The measure according to the invention to integrate power plants with a heat storage and possibly an associated heat exchanger in the steam generation of the power plant or possibly equip with its own associated steam generation including a turbine or turbo set with attached generator, can in the replanning of power plants, especially in a new construction of Fossil-fired power plants, as an additional facility or additional equipment planned and provided. But it is also possible to retrofit this additional system in an existing power plant as part of a conversion or upgrade.

The invention is explained in more detail below by way of example with reference to an exemplary embodiment.

The single figure shows in a schematic way the water / steam cycle 1 a fossil-fired power plant. The water / steam cycle is usually equipped and includes in a manner not shown preheater, superheater, reheater, a turbine or turbo set with attached generator and a water treatment. In the water / steam cycle 1 is a heat exchanger 2 thermally coupled, which allows heat energy to be released in the water / steam cycle 1 guided steam in the heat exchanger 2 circulating heat transfer medium 8th is decoupled. The heat exchanger 2 is also thermally to a heat storage 3 coupled. In the heat storage 3 is that of the heat transfer medium 8th of the heat exchanger 2 absorbed heat energy to the heat storage 3 decoupled. If desired, the energy transmission path can also be reversed. In this case, then in memory 3 stored heat energy to the heat transfer medium 8th of the heat exchanger 2 decoupled and from this in the heat exchanger 2 to the water / steam cycle 1 decoupled from the power plant. In the heat storage 3 is also a heater 4 arranged in electrical connection with a power grid 5 stands. When operating the heater 4 , For example, by means of excess current present in the power grid, heat energy is generated by means of the heater, which in the heat storage 3 is stored.

The heat storage 3 is thermally to a second heat exchanger 6 coupled, which in turn thermally to a second steam generator 7 or a second water / steam cycle is coupled. This makes it possible, from the heat storage 3 Disconnect energy and parallel to steam generation in the water / steam cycle 1 to create. The second steam generator 7 or water / steam cycle is associated with a turbine set or turbo set with a connected generator, so that electricity can also be generated here. Preferably, this second heat exchanger 6 then put into operation if undercapacity in the power grid 5 to be balanced.

At the heat exchangers 2 and 6 it can be preheaters, superheaters or reheaters of the respective water / steam cycle 1 . 7 act. The second heat exchanger 6 can be designed as a once-through steam generator (continuous steam generator).

Claims (17)

Power plant comprising a steam generator with connected water / steam cycle ( 1 ) and integrated therein turbine or turbo set, wherein the water / steam cycle ( 1 ) on the steam side with a heat storage ( 3 ) and / or a thermal to the heat storage ( 3 ) coupled heat exchanger ( 2 ) is conductively connected and / or thermally coupled, characterized in that the water / steam cycle ( 1 ) so with the heat storage ( 3 ) and / or the heat exchanger ( 2 ) is conductively connected, that heat energy of the steam from the water / steam cycle ( 1 ) thermally into the heat storage ( 3 ) and / or in the heat exchanger ( 2 ) can be decoupled. Power plant according to claim 1, characterized in that thermal energy of the steam in the heat exchanger ( 2 ) to a heat transfer medium ( 8th ) is transmitted. Power plant according to claim 2, characterized in that the heat transfer medium ( 8th ) transferred heat energy in the heat storage ( 3 ) is decoupled. Power plant according to one of the preceding claims, characterized in that thermal energy of the steam in the heat storage ( 3 ) is transferred to a heat transfer medium and / or a heat storage medium. Power plant according to one of the preceding claims, characterized in that the heat storage ( 3 ) Is formed electrically heated. Power plant according to one of the preceding claims, characterized in that the steam generator has a combustible with fossil fuel and / or biomass combustion chamber whose burner are preferably part of an indirect firing. Power plant according to one of the preceding claims, characterized in that the heat storage ( 3 ) in stored heat decoupled manner with at least one further heat exchanger ( 6 ) connected in the or a second water / steam cycle ( 1 . 7 ) forms a preheater, superheater or reheater. Power plant according to one of the preceding claims, characterized in that the heat storage ( 3 ) in stored heat decoupled manner with the or a second steam generator, preferably with associated turbine or turbo set is connected. Power plant according to one of the preceding claims, characterized in that the heat storage ( 3 ) as a heat storage medium, a molten salt, in particular a mixture of KNO ₃ and NaNO ₃ , having. Power plant according to one of the preceding claims, characterized in that it comprises a compressed air accumulator comprising a compressor and an expander, which generates heat of compression in the heat exchanger ( 2 ) or the heat storage ( 3 ) einkoppelbarer way with the heat storage ( 3 ) connected is. Power plant according to one of the preceding claims, characterized in that the heat storage ( 3 ) in stored heat decoupled manner with an air heating device, in particular an air preheating device for preheating combustion air, is connected. Power plant according to one of the preceding claims, characterized in that the heat storage ( 3 ) is designed as a steam storage, salt storage, concrete storage or hot water storage. Method for storing in a power plant with a steam generator with connected water / steam cycle ( 1 ) and therein integrated turbine or turbo set generated heat, wherein the water / steam cycle ( 1 ) on the steam side with a heat storage ( 3 ) and / or a thermal to the heat storage ( 3 ) coupled heat exchanger ( 2 ) is conductively connected and / or thermally coupled, characterized in that in the heat storage ( 3 ) and / or the heat exchanger ( 2 ) Heat energy from the steam of the water / steam cycle ( 1 ) and in the heat storage ( 3 ) and / or the heat exchanger ( 2 ) is coupled. A method according to claim 13, characterized in that in the heat storage ( 3 ) stored heat is coupled into the or a second steam generator, wherein steam generated in the respective steam generator as live steam or reheater steam is supplied to a turbine, and / or that in the heat storage ( 3 ) stored heat in at least one other heat exchanger ( 6 ) which is in the or a second water / steam cycle ( 1 . 7 ) forms a preheater, superheater or reheater. A method according to claim 13 or 14, characterized in that the heat energy of generated during operation of the power plant in its minimum or minimum load range and not used for power generation excess steam from the water / steam cycle ( 1 ) thermally into the heat storage ( 3 ) and / or the heat exchanger ( 2 ) is decoupled. Method according to one of claims 13-15, characterized in that the heat accumulator ( 3 ) generated in the power grid overcapacity of electricity and / or operation of the power plant in its minimum or minimum load range generated, not to be fed into the grid excess current via an electrically heated with the respective current and / or excess current and preferably in the heat storage ( 3 ) arranged heating device ( 4 ) Heat energy supplied and in the heat storage ( 3 ) is stored. Method according to one of claims 13-16, characterized in that when restarting the power plant from its minimum or minimum load range in the heat storage ( 3 ) stored heat in the and / or in the second water / steam cycle ( 1 . 7 ), is preferably decoupled in the range of Niederdruckvorwärmern.

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