DE102012215569A1 - Method for fast active power change of fossil fuel-fired steam power plants, involves diverting vapor fraction from water-vapor-working cycle as process energy for carbon dioxide-separation unit - Google Patents

Abstract

The method involves diverting vapor fraction from the water-vapor-working cycle (1) as process energy for carbon dioxide-separation unit (2). The diverted vapor fraction is quickly reduced or increased on requirement for fast active power change. The reduction or increase of the active power takes place within 5 to 600 seconds, particularly within the region of 5 to 30 seconds. The changed active power is kept during another time period in the range of 5 to 50 minutes. An independent claim is included for a fossil fuel-fired steam power plants with a boiler.

Description

The invention relates to a method for rapid change in active power of fossil-fired steam power plant according to claim 1, as well as a correspondingly formed fossil-fired steam power plant according to claim 4.

In steam power plants, fossil fuels, such as coal, are used to generate electricity. The thermal energy of the steam generated by the combustion is converted into kinetic energy in a steam turbine and then converted into electrical energy in a generator and fed into the power grid.

In a deregulated electricity market, flexible load operation and frequency control facilities are becoming more and more important for power plants connected to the grid. In addition, the expansion of renewable energies, such as wind energy, is expected to exacerbate the regulatory requirements of the different types of power plants.

With regard to the frequency control in power grids, a distinction is essentially made between a primary and a secondary control.

Since electrical energy can not be stored on the way from the producer to the consumer, electricity generation and electricity consumption must be balanced at all times in the electricity grid. The frequency of the electrical energy is the integral control variable and assumes the mains frequency rating as long as power generation and power consumption are in balance. The speeds of the power plant generators connected to a power grid are synchronized with this grid frequency.

If there is a generation deficit in the power grid at a specific time, this deficit is initially covered by the energy contained in the rotating masses of the rotating machinery (turbines, generators). As a result, the machines are slowed down, which further reduces their speed and thus the (mains) frequency. Failure to counteract this drop in grid frequency by appropriate power or frequency regulation in the grid would lead to grid collapse.

Such frequency deviations are first divided by the primary control on the power plants involved in the primary control throughout the power grid. These provide for a so-called primary control reserve, ie a power reserve available, which is automatically discharged from the power plants involved in the power grid, thereby to compensate for the imbalance between production and consumption within seconds by regulating the production. The primary control thus serves to stabilize the grid frequency with as small a deviation as possible, but at a level deviating from a predetermined nominal grid frequency value.

The adjoining the primary control secondary control has the task to restore the balance between the generators and consumers in the power grid and thus the network frequency back to the predetermined power frequency nominal value, z. B. 50 Hz, due. For this purpose, the power plants involved in the secondary control provide a secondary control reserve in order to return the grid frequency to the nominal grid frequency and restore the balance in the power grid.

While the requirement for the primary control and the delivery of the primary control reserve to the power grid is automatic by the control equipment of the power plants involved in the primary control, the secondary control is requested by a higher power grid in the power grid of the power plants involved in the secondary control.

It is known that one, for example, in the case of a frequency control required, active power increase of a coal power plant out of any power point but takes much longer than, for example, pumped storage or gas power plants, where the power can be accessed as needed in seconds range. The control of the firing at coal-fired power plant blocks leads namely only after a delay in the minute range to a change in the output power into the power grids, so that the achievable performance ramps are rather moderate. One reason for this performance inertia in coal power plants is the thermal inertia of the fuel coal. That is, a change in coal firing usually leads to an active power change of the coal power plant only after a long delay in the minute range, which is primarily due to a time-consuming process of coal feed and comminution. Benefits and increases in output can only be released to the corresponding distribution grids with a time delay. Nevertheless, it is already possible today to meet the grid connection conditions of the transmission codes (minimum requirement) currently valid in Germany with, for example, a required primary control reserve of two percent power increase in 30 seconds, which must then be maintained for 15 minutes.

But if you want to provide the necessary for secondary and / or primary control rapid power changes, fast-acting additional measures are required. Examples of such measures to improve the system dynamics, such as the throttling of the high-pressure turbine control valves, an overload introduction to high-pressure turbine section, the condensate backwash, the feedwater side bypass the high-pressure preheater or the throttling of the bleed steam lines to the high-pressure preheaters are already off "Flexible Load Operation and Frequency Support for Steam Turbine Power Plants", Wichtmann et. Al, VGB PowerTech 7/2007 page 49-55 known.

Power plants, especially fossil-fired steam power plants, are increasingly subject to legal regulations on air pollution control. For example, CO2 capture facilities are increasingly being integrated into these power plants. The components of the CO2 capture device, such as absorbers, desorbers and compressors, require energy for the deposition process. This is how, for example, in the EP 2 333 256 A1 described steam from the water-steam working cycle of the steam power plant decoupled and fed to the CO2 capture device.

The object of the invention is now to provide a method and a steam power plant, with the use of an integrated CO2 capture device a short-term, fast and temporary increase but also reduction of the active power of the fossil-fired steam power plant can be achieved in the simplest way.

This object is achieved by the method having the features of claim 1, as well as the steam power plant according to claim 4. Further advantageous developments can be found in the dependent claims.

By installing and controlling a valve as an additional control element in the Dampfentnahmezweig a fixed proportion of steam from the steam cycle, which is provided to supply the CO2 separation device can be quickly reduced or increased on request, so that the steam cycle to increase the active power or reduction in the short term more or less steam is available. The effect in the steam cycle change in the turbine flowing through the steam mass flow leads to a correspondingly fast and targeted active power change, which can be used for frequency control, in particular for secondary and / or primary control. In particular, a fast increase in active power in the range of 2-5% of the rated power can be achieved.

This active power increase is expediently carried out in a time range of 5-600 s for the secondary control and preferably in the range of 5-30 s for the primary control. A further increase in performance can be maintained as a further power reserve for a further period in the range of at least 5-50 min, in particular for a period of 5-30 min.

With the invention, the dynamic system behavior and the frequency control in a fossil-fired steam power plant, in particular in a coal-fired power plant with integrated CO2 separation device, can be improved in an advantageous manner very simply and without major structural changes. According to the invention, the inertia of the CO2 deposition process is utilized. Primary control is a process that corrects for stochastic fluctuations in the grid frequency around an average. Although a reduction in the steam supply of the CO2 separation device leads to a deterioration of the deposition rate and vice versa. Due to the stochastic behavior, the achievable deposition rate remains unchanged despite the onset of primary control. If a performance increase in the context of secondary regulation leads in the meantime to a significant deterioration of the separation rate, this can be compensated in the longer term by a subsequent slow increase of the steam supply. With small changes, the effects are negligible due to the inertia of the deposition process, so that the interaction between short-term rapid increases in active power of the steam power plant and the integrated CO2 capture process are very low and thus largely negligible.

Especially in combination with the known measures for the acceleration of active power changes in the context of the frequency or primary and / or secondary control in a steam power plant, especially in a coal power plant, can be so by the present invention, the frequency or primary and / or or secondary control range.

The invention will now be explained by way of example with reference to a very schematic representation of a water-steam working cycle of a steam power plant. In the water-steam cycle 1 Water is heated in the boiler B and the steam generated thereby supplied to the turbine unit T. By relaxing the steam in the turbine unit, a generator G connected thereto is driven. The expanded water vapor is fed to a condenser K and from there by means of pumps P back to the boiler B. In fossil fueled Steam power plants can - as indicated here - additionally a CO2 separator 2 be used. For this purpose, part of the steam from the water-steam working cycle 1 at a junction 3 branched off and via a steam extraction line 4 the CO2 separator 2 provided as process energy.

According to the invention it is now provided that in the event that an active power increase of the steam power plant is necessary in the short term, the branched off steam fraction via an adjustable valve 5 reduced and thus the water-steam cycle 1 remaining steam can be increased quickly. If, in the short term, an active power reduction of the steam power plant is necessary, then the branched-off steam component will become via the adjustable valve 5 increased and thus the water-steam cycle 1 remaining steam is rapidly reduced. Preferably, the diversion takes place in the water-steam working cycle 1 either in front of a sub-turbine T, or from the boiler B itself, or from one or more taps of the turbine T. In the arrangement of the branch, it should be noted that the higher the pressure and the temperature of the branched steam, the greater the resulting achievable active power change, but the more complex and expensive is the involvement of the diversion 3 and the adjustable valve 5 , The choice of the place of diversion 3 and the fitting 5 in the water-steam working cycle 1 In the end, however, a steam power plant will also be influenced by the design features of the plant and the space available. Preferably, the adjustable fitting 5 be realized in the simplest way as a continuously adjustable control valve or a continuously adjustable control valve.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2333256 A1 [0012]

Cited non-patent literature

• "Flexible Load Operation and Frequency Support for Steam Turbine Power Plants", Wichtmann et. Al, VGB PowerTech 7/2007 page 49-55 [0011]

Claims (9)

Process for rapid change of active power of fossil-fired steam power plants with a water-steam cycle ( 1 ) and a CO2 capture device ( 2 ), in which from the water-steam cycle ( 1 ) a vapor content as process energy for the CO2 separation device ( 2 ) is branched off, wherein for rapid change in active power of the branched-off steam fraction can be reduced or increased on demand quickly. A method according to claim 1, characterized in that the reduction or increase of the active power within 5-600 s, more preferably in the range of 5-30 s, takes place. A method according to claim 2, characterized in that the changed active power during a further period in the range of at least 5-50 min, in particular during a period of 5-30 min is maintained. Fossil-fired steam power plant with a water-steam cycle ( 1 ) and a CO2 capture device ( 2 ), as well as a branch ( 3 ) in the water-steam working cycle ( 1 ) for branching off a vapor portion from the water-steam working cycle ( 1 ) for use as process energy for the CO2 capture device ( 2 ), where in the branch ( 3 ) or a subsequent steam extraction line ( 4 ) an adjustable valve ( 5 ) is provided for rapid increase and reduction of the branched vapor content. Steam power plant according to claim 4, characterized in that the branch ( 3 ) in the water-steam working cycle ( 1 ) is provided at the location before or after a sub-turbine. Steam power plant according to claim 4, characterized in that the branch ( 3 ) in the water-steam working cycle ( 1 ) is provided on the boiler (B). Steam power plant according to claim 4, characterized in that the branch ( 3 ) in the water-steam working cycle ( 1 ) are one or more taps of the turbine. Steam power plant according to one of claims 4 to 7, characterized in that the steam extraction line ( 4 ) with at least one adjustable fitting ( 5 ), preferably a continuously adjustable control valve or a continuously adjustable control flap is provided, which can be used for rapid and targeted change of the branched vapor content. Steam power plant according to claim 8, characterized in that for changing the branched steam portion, a control or control device, in particular a block guide of the steam power plant, is provided, taking into account the required change in active power the adjustable valve ( 5 ) regulates or controls.

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