WO2015188976A1 - Method for cooling a power plant unit - Google Patents

Abstract

The invention relates to a power plant unit (1) and to a method for controlling a cooling line in a power plant unit (1). The power plant unit (1) has a turbine (10), a generator (20) and a cooling system (30). The power plant unit (1) further has a controller (40) for controlling a cooling power, in particular the cooling power of the generator (20). Also provided is a data processing device (50) for predicting a planned capacity utilization of the power plant unit (1). The controller (40) has an interface (41) with the data processing unit (50), the cooling power of the cooling system (30) being controlled by means of the predicted capacity utilization of the power plant unit (1).

Description

description

Method for cooling a power plant block

The present invention relates to a power plant block and a method for cooling a power plant block.

In modern energy supply systems, the utilization of a power plant block is easy to plan. However, the increased Integra ^¬ tion and connection of renewable energy sources such as solar and wind power plants requires a faster availability and regulate power, a power plant ^¬ blocks. The controllability of the generator of the power plant ^block is ^limited by the mechanical stresses during load changes. Excessive stress on the generator also leads to a reduced service life of the generator components. It is therefore desirable to operate the generator as possible at a constant temperature or to limit the temperature fluctuations. So far, cooling systems are used, in which the cooling takes place as a function of the temperature and / or the current performance of the generator, which can be easily measured during operation. In this case, generator-specific time constants, such as the heating or cooling time constants, have hitherto not been taken into account. This leads in some operating conditions to excessive cooling, whereby the efficiency of the power plant ^¬ blocks is reduced. The object of the invention is to know the load of the power plant ^¬ blocks and to adjust the cooling system based on the planned utilization in advance of a power increase or reduction, that the thermal gradient and thus the mechanical stresses occurring are minimized.

The power plant block according to the invention according to claim 7 and the inventive method according to claim 1 have the advantage that the cooling capacity of the cooling system depending on the predicted capacity utilization of the power plant block. This can be done by a variable cooling. To control these variable cooling a control concept is used, which in terms of smart grid control taken into the planned utilization of the power plant unit ^¬ consideration. Thereby, the thermal gradients and thus the mechanical stresses can be reduced, whereby the life of the respective components is increased and the efficiency of the power plant block can be increased, because the cooling can be reduced by the cooling system to a minimum.

A feature of the method is that a generator of the power plant block is cooled so that a temperature of the generator during operation of the power plant block is maintained in an operating range between a maximum temperature and a minimum temperature. By regulating to a temperature band and not to a maximum allowable tempera ^ture , wherein the cooling is reduced with decreasing load of the power plant block such that the temperature of the generator remains as long as possible above the minimum temperature. As a result, the thermal load during a subsequent re-startup of the power plant block can be kept as low as possible and the power plant block can be brought back into power operation more quickly.

Advantageous refinements and improvements of the power plant unit specified in the independent claim as well as the method for cooling the power plant unit block are possible by the measures cited in the dependent claims.

It is particularly advantageous if the minimum temperature of the generator is adjusted depending on the planned utilization of the power plant block. By adjusting the minimum temperature can be responded depending on a pause between a load operation and a subsequent load operation of the power plant block according variable variable on the break. A further advantageous development of the method ^{involves the} fact that the regulation takes account of relevant time constants for the generator. It is particularly advantageous if a heating or cooling time constant for the stator or rotor of the generator is taken into account. By taking into account the heating and cooling time constants of the anticipatory control of the cooling system can be ^¬ invested in expanding, so that the cooling capacity of the cooling system and reduces the efficiency of the power unit can be further increased.

It is also provided with advantage that the cooling capacity is reduced before a planned stop of the power plant block in such a way that the generator can be started at the next start with uniformly warm generator components.

Furthermore, it is advantageously provided that a cooling Leis ^¬ processing of the refrigeration system for different regions of the genes ^¬ rators is regulated separately depending on the planned utilization of the power block. By a separate control different generator areas, for example, the more ^¬ burdened end zones can be increasingly cooled at certain operating points of the generator.

A further advantageous development consists in that the cooling system has a latent heat storage, wherein the temperature drop of the generator is limited by the latent heat storage when switching off the power plant block and the temperature can be kept longer than a minimum temperature.

In the following, an embodiment of a power plant block according to the invention and of the method according to the invention for controlling the cooling of a power plant unit will be explained in more detail with reference to the attached drawing. Same components or Components with the same function are identified by the same reference numbers ^¬ Be.

1 shows a schematic representation of a power plant block according to the invention.

The power plant block 1 comprises a turbine 10, a genera ^¬ tor 20 and a cooling system 30. The turbine 10, in particular a gas turbine 11, is arranged on a shaft 15, which at least indirectly ver ^¬ the turbine 10 to the generator 20 ver ^¬ binds. For cooling the generator 20, a cooling system 30 is provided, wherein the cooling system 30 comprises a pump 31, with which a cooling medium can be conveyed through lines 32, 33 of the cooling system. Furthermore, the cooling system 30 comprises a reservoir 35, which is connected via a first line 32 to the generator 20, while a second line 33 leads from the generator 20 back to the reservoir 35. In addition, the cooling system 30 may have a heat exchanger 34 with which heat is released from the cooling system 30 to an environment outside the power plant block 1. Alternatively, the heat can also be used to heat components of the power station blocks ^¬ 1 or belonging to the power plant unit 1 building. In addition, the cooling system 30 may have a latent heat accumulator 37, in which a cooling medium of the cooling system 30, in particular water, can be stored. Thus, a temperature drop of the cooling medium at a shutdown of the power plant block 1 can be at least significantly reduced.

The power plant block 1 also has a regulator 40 for controlling the cooling line in the cooling system 30. The controller 40 has an interface 41, via which the controller 40 with a data processing device 50, for example, a computer for planning the utilization of the power plant block 1, is connected. Via the interface 41, the data processing system can provide information about the planned utilization of the power plant block 1 to the controller 40, and thus, in addition to the current load and the current temperature, further parameters. ßen provide over the controller 40, the cooling capacity of the cooling system 30 controls.

In this case, the regulation takes place via the planned utilization of the power plant block 1, for example, by information from the grid or from the power plant control. In addition, information about generator-specific parameters such as heating time constants or cooling time constants of stator 21 or rotor 22 of the generator is taken into account.

The cooling line 32 has branches 36, which can be opened or closed via valves 38. Thus, the cooling capacity of the cooling system 30 can be such anpas ^¬ sen that surface in operation of the generator 20 Berei- higher loaded, for example, the end zones 23 can be cooled amplified.

In operation of the power unit 1 are members of the power plant ^¬ blocks 1, in particular the generator 20, cooled. In addition, cooling of the turbine 10, in particular of the rear compressor stages of the turbine 10, may also be provided. For this purpose, the pump 31 is connected via a cooling line 13 to the turbine ^¬ 10. The cooling medium can flow via a return line 14 from the turbine 10 back to the storage container. If the data processing device 50 receives information that the power of the power plant block 1 should be reduced, or the power plant block 1 should completely go from the grid, then the cooling capacity is already reduced in advance to a rapid cooling of the components of the power plant block 1, in particular of the generator 20, to avoid. Alternatively, at least a portion of the hot Kühlmedi ^¬ ums are promoted after a load operation of the power plant block 1 in the latent heat storage 37 to reduce a drop in temperature of the cooling medium. For this purpose, a valve 39 is opened on the second line 33, whereby the cooling medium can flow into the latent heat accumulator 37. Furthermore, shut-off valve 43,45 are closed, so that the cooling medium is not past the latent heat storage 37 in the reservoir 35th flowing back. To empty the latent heat storage valve 39 is closed and the shut-off valves 43,45 opened, so that the still warm cooling medium can flow back into the cooling circuit 30.

Due to the predictive control of the cooling capacity, a short-term increase in temperature compared to the temperature during load operation can possibly be accepted. If the power of the power plant block 1 is to be increased again after a phase of the low partial load or should the power plant block go back to the grid after a short-term standstill, the generator 20 starts by the proposed control of the cooling system 30 still in the warm generator components 21,22. Thus, a faster start-up and a faster absorption of a power operation of the power plant ^¬ block 1 are possible. Alternatively, the thermo-mechanical stresses in the generator 20 and / or the turbine 10 are reduced at an equally rapid startup of the power unit 1 as in konventi ^¬ tional solutions, resulting in a longer life of the components involved.

Although the invention has been described in detail by the preferred embodiments, the invention is not limited to the disclosed embodiment, and other variations can be derived therefrom by those skilled in the art without departing from the scope of the invention.

Claims

claims

1. A method for controlling a cooling capacity in a cooling system (30) of a power plant block (1),

wherein a planned utilization of the power plant ^block (1) is averaged ^¬ and

 the cooling capacity of the cooling system (30) being dependent on the predicted utilization of the power plant block,

 characterized in that

 a generator (20) of the power plant block (1) is cooled so that a temperature of the generator (20) is maintained in the operation of the power plant block in an operating range between a maximum temperature and a minimum temperature.

2. A method for controlling the cooling capacity according to claim 1, characterized in that

 the minimum temperature of the generator (20) is adjusted as a function of the planned utilization of the power plant block (1).

3. A method for controlling the cooling capacity according to claim 1 or 2,

 characterized in that

 the control for the generator (20) relevant time constants, in particular heating or cooling time constants for stator (21) and / or rotor (22) of the generator (20), taken into account.

4. A method for controlling the cooling capacity according to one of claims 1 to 3,

 characterized,

 the cooling capacity is reduced before a planned stop of the power plant block (1) in such a way that the generator (20) can be started at the next start with uniformly warm generator components (21, 22).

Method for controlling the cooling according to one of claims 1 to 4,

 characterized in that

Depending on the planned utilization of the power plant blocks ^¬ (1) a cooling capacity of the cooling system (30) for different areas of the generator (20) is controlled separately ge.

6. power plant block (1) with a turbine (10), a generator (20) and a cooling system (30),

 wherein the power plant block (1) has a controller (40) for controlling the cooling power and a data processing device (50) for predicting a planned utilization of the power plant block (1),

 characterized in that

the controller (40) comprises an interface (41) for Datenverarbei ^¬ processing device (50) and the cooling performance of the cooling system (30) on the predicted load of the power unit (1) controls.

7. power plant block (1) according to claim 6,

 characterized in that

 the controller (40) is a smart grid controller that receives data from the power plant controller or a grid.

8. power plant block according to claim 6 or 7,

 characterized in that

the cooling system (30) is divisible so that different Be ^¬ rich (21,22,23) of the generator (20) are different degrees of cooling.

9. power plant block according to claim 8,

 characterized in that

 End zones (23) of the generator (20) are cooled more than the rest of the generator.