DE102009033605B4 - Method for simulating an operation of a technical system based on state variables - Google Patents

Abstract

Method for simulating a power plant operation of a power plant based on state variables, wherein one or more plant parts of the power plant in a number of segments (S1 to S4, S1 'to S18') are divided and in addition to metrologically detected state variables of at least one of the plant parts a variety of state variables determined by a simulator and determined segment by segment for the respective segment (S1 to S4, S1 'to S18'), characterized in that based on the determined values of one or more state variables for individual segments (S1 to S4, S1 'to S18') a profile of the state variable or a state profile along the segment (S1 to S4, S1 'to S18') is determined.

Description

The invention relates to a method for simulating an operation of a technical system, in particular a power plant operation of a power plant based on state variables.

In general, methods for simulating a power plant operation of a power plant are known, with the aid of known simulators, for example, a power plant personnel trained and / or trained. For example, it is possible to record a temperature profile for a plant part of the power plant based on a set of selected, time-dependent trend curves. However, the selection of these trend curves is limited to values actually measured in the equipment part. As a result, only a selection of characteristic values for the plant part can be observed. Simulators usually provide a wealth of additional information without, however, using it for training purposes, for example.

Static temperature profiles for different load points are often provided by a plant operator and / or a plant manufacturer.

From the DE 196 18 745 A1 For example, a simulation method for a power plant is known in which, for example, the "primary circuit" subarea is subdivided into a number of subvolumes, the simulation of the temporal evolution of each phase ("liquid" and "gaseous") of the cooling medium being carried out separately for each subvolume becomes.

From the DE 196 35 033 A1 is a method for analyzing a process state of a technical plant is known in which, based on analytical comparisons for each part of the current share state condition is determined in response to the influence of adjacent adjacent plant parts.

The invention has for its object to provide a method for simulating an operation of a technical system, in particular a power plant operation of a power plant based on state variables.

The object is achieved by the features specified in claim 1.

Advantageous developments of the invention are the subject of the dependent claims.

An inventive method for simulating an operation of a technical system, in particular a power plant operation of a power plant, using state variables provides that one or more parts of the plant power plant are divided into a number of segments and in addition to metrologically detected state variables at least one of the plant parts a variety of State variables determined by means of a simulator and location-dependent, in particular segmentally, d. H. for the respective segment the associated state variable (s) can be determined.

For example, the plant part may be a countercurrent heat exchanger and / or a flue gas duct of the power plant.

Furthermore, the method according to the invention provides that, based on determined values of one or more state variables for one, several or all segments of individual plant sections, a course of the state variable or a location-dependent state profile along the segment or segments is determined and displayed. A possible embodiment of the invention provides that all values of a state variable for a segment are averaged, and the segment value is the mean value, ie. H. the averaged value of the respective state variable of the respective segment is used.

The inventive method is used in a profitable way to produce a complex relationship between cause and effect, for example, load change within the overall technical system and / or part of the plant and illustrate this complex context, in particular a power plant staff and to illustrate. For example, it can be determined and visualized by means of the method according to the invention how a temperature is distributed during a starting process of the simulated power plant operation and / or which effects result, for example, from an additional fire within the plant part.

In addition, by a graphic dynamic representation of the state variables in the form of a location-dependent state profile, i. H. Location-dependent progressions of several state variables, a stability of the power plant operation by simultaneous control of a variety of state variables are checked with a relatively low cost. As a result, implausibilities can be detected early and instabilities can already be identified during runtime.

For example, the respective state variable is determined as a function of at least one system parameter.

In one possible embodiment, for. B. as a plant parameter a part of the plant determined by flowing medium, wherein the respective state variable is determined in dependence of a material property of the medium flowing through the system part.

Alternatively or additionally, the respective state variable can be determined as a function of a material property of a wall of the plant part.

Preferably, at least one temperature and / or at least one pressure of at least one plant part, in particular a heat exchanger unit, are determined as state variables.

It is also conceivable that the state variables are determined as a function of characteristic values of at least one heating surface arranged in the heat exchanger unit and / or of a heat exchanger arranged in the heat exchanger unit.

Furthermore, based on the determined values of one or more state variables of several plant parts, these state profiles can be combined to form a dynamic overall state profile.

In one possible embodiment, a determined course of the state variable, the state profile and / or the overall state profile are graphically output. The course of the state variable, the state profile and / or the overall state profile are preferably output or displayed graphically in a coordinate system as a function of the location in the simulator and / or on the operator control and monitoring surface of a control system.

Embodiments of the invention are explained in more detail below with reference to drawings. Show:

1 a coordinate system with a temperature profile of a plant part, wherein the plant part is divided into four segments,

2 a coordinate system with a temperature profile of flowing media within an entire system at full load, the entire system is composed of 16 parts of the system, which in turn are individually segmented,

3 a coordinate system with a temperature profile of flowing media within an overall system according to 2 at partial load.

Corresponding parts are provided in all figures with the same reference numerals.

In 1 is a coordinate system 1 with a temperature profile P, which was determined within a plant part, in particular a Gegenstromwärmeübertragers represented.

The coordinate system 1 is output as a result of a simulation of a power plant operation of a power plant in a particularly advantageous manner in the simulator and / or on an operating and monitoring surface of a control system.

A counterflow heat exchanger is a device that transfers thermal energy from a first medium M1 to a second medium M2. In this case, countercurrent designates that the media M1, M2 flow past each other in an accommodating manner and, ideally, the temperatures of the media M1, M2 flowing past one another are exchanged. That is, an originally cold medium reaches a temperature of the originally hot medium, and vice versa.

The abscissa of the coordinate system 1 represents the location s within the Gegenstromwärmeübertragers, the countercurrent heat exchanger is divided as part of the plant in four equal segments S1 to S4 and thus the abscissa is divided into four equal segments S1 to S4 analog.

The ordinate indicates the state quantity, which in the present embodiment is a temperature of the media M1, M2.

Alternatively or additionally, as a state variable, for example, a pressure within the plant part can be determined.

In the present embodiment, in the coordinate system 1 two temperature curves T1, T2 of the flowing in the opposite direction media M1, M2 shown. In this case, a first temperature profile T1 represents a change in the temperature of the first medium M1 when it flows through the system part in the form of the countercurrent heat exchanger. A second temperature profile T2 indicates the change in the temperature of the second medium M2.

For example, the first medium M1 is a flue gas and the second medium M2 is a water / vapor flow, wherein it can be seen within the countercurrent heat exchanger based on the temperature profiles T1, T2 that a heat of the first medium M1 is transferred to the second medium M2.

The first medium M1 flows according to 1 from left to right, whereby an entry Ei of the first medium M1 takes place in a first segment S1. The second medium M2 flows counter to, wherein an inlet E2 of the second medium M2 takes place in a fourth segment S4 of the countercurrent heat exchanger.

It is provided that for each segment S1 to S4 of the counterflow heat exchanger at least one value of the state variable, for. B. temperature value T1 _S1 to T1 _S4 for the first medium M1, and at least one temperature value T2 _S1 to T2 _{S4 of} the second medium M2 are determined. Preferably, an average of all values of the state variable in the respective segment S1 to S4 is determined and used as the segment state value for the simulation.

In addition, the respective state variable can be determined as a function of at least one system parameter, a material property of the media M1 or M2 flowing through the system component, and / or a material property of a wall of the system component.

From the determined temperature values T1 _S1 to T1 _S4 and T2 _S1 to T2 _S4 , an interpolation curve for the respective medium M1, M2 is determined as the temperature profile T1, T2 of the state variable temperature. A first interpolation curve here identifies the first temperature profile T1 of the first medium M1 within the four segments S1 to S4, and a second interpolation curve identifies the second temperature profile T2 of the second medium T2 within the four segments S1 to S4. In this case, the respective temperature profile T1, T2 is shown as a function of the location s, in particular as a function of the segments S1 to S4.

On the basis of the illustration of the first and the second temperature profile T1, T2 as a state or temperature profile P (hereinafter called temperature profile P for clarity), a temperature difference .DELTA.T between the media M1, M2 can be visualized in a particularly advantageous manner and in the simulator and / or be output on the operating and monitoring surface of the control system.

The temperature difference .DELTA.T is here a measure of a possible heat transfer between the first and the second medium M1, M2 and can be illustrated by the method in a particularly advantageous manner. Thus, a performance and / or efficiency of the simulated Gegenstromwärmeübertragers can or can be illustrated.

In addition, the values of the state variables can be measured.

In the 2 and 3 is a coordinate system 2 shown, where the coordinate system 2 in 2 as the overall state profile P 'a temperature profile of a full load case (hereinafter referred to for clarity overall temperature profile P') and the in 3 shown coordinate system 2 as a total state profile P '' is based on a temperature profile of a partial load case of the entire system, such as a flue gas duct of a power plant, as a result of a combination of state, in particular temperature profiles P multiple plant parts.

In particular, in the in 2 and 3 shown coordinate system 2 the total temperature profile P ', P''of the flue gas duct shown. In this case, the flue gas duct is divided in the present embodiment in a total of 16 system parts, in particular in 16 heating surfaces H1 to H16.

Here, each heating surface H1 to H16 is a specific part of the plant, such. As a low-pressure evaporator, a feedwater, a medium-pressure evaporator, a medium-pressure superheater and / or a high-pressure superheater assigned.

The plant parts in the form of the heating surfaces H1 to H16 are each divided into a specific number of segments S1 'to S18' in the simulation model analogous to the segmentation of a counterflow heat exchanger described above.

For the segments S1 'to S18' were the state variables to be displayed, the temperature values, z. B. average temperatures, the flowing through the flue gas channel media M1, M2 determined in the simulation model and dynamically displayed location-dependent graphically. In this case, each segment S1 to S18 of an installation part in the overall temperature profile P ', P "is represented by means of a single point, pixel, square or the like, wherein the point, the pixel or the square can be controlled individually. A composition of these individual points of a plant part, in particular a heating surface H1 to H16 gives the temperature profile P of this part of the plant. A combination of several or all of the temperature profiles P of several or all parts of the plant results in the total temperature profile P ', P "of plant areas and / or the entire plant. A course of the state profile of a plant part, in particular a heating surface H1 to H16 is formed in the present embodiment by stringing together Einzeiwerten the individual segments S1 'to S18.

This results in a local first temperature profile T1 'of the first medium M1 based on the thick solid line and a second temperature profile T2 of the second medium M2 shown by the dashed line. In addition, a first temperature profile T1 "of the first medium M1 corresponding to a thermal circuit diagram at full load is shown on the basis of the solid thin line.

A flow direction of the media M1, M2 is largely countercurrent, wherein the media M1, M2, as described above, flow past each other in the opposite direction.

An inlet E1 'of the first medium M1, for example flue gas, takes place from the right, ie in the segment S18 of the heating surface H16. During a flow to the left, the first medium M1 is cooled by the countercurrent second medium M2, water / steam. A flow of the second medium M2 takes place except at the heating surfaces H1 to H16 in the form of evaporators, from left to right, in which case a continuous total temperature profile P ', P' 'results if corresponding entrances and exits of the second medium M2 to the heating surfaces H1 to H16 are put together.

For example, the respective state variable of the media M1, M2 is determined as a function of characteristic quantities of the heating surfaces H1 to H16 arranged in the system part.

By means of the method according to the invention it is possible in a particularly advantageous manner, based on the determined values of one or more state variables for individual segments S1 to S4, S1 'to S18', a course of the state variable, a state profile P and / or a dynamic overall state profile P ', P '' segmentally determine and by means of the coordinate system 1 graphically.

For example, during a training scenario for power plant personnel, it is possible to illustrate a complex interaction of heating surfaces H1 to H16 when changing the load within the plant part by displaying a dynamic location-dependent temperature profile P, P ', P ". It can be shown very clearly how, for example, changes in temperature at corresponding heating surfaces H1 to H16 to further, z. B. arranged in the system part, heating surfaces H1 to H16 impact.

Furthermore, can be illustrated by the graphical representation of how a temperature distribution during a starting process z. B. the power plant operation represents and / or how strong an additional fire affects. It should be noted here that the location-dependent representation of the state profile / e P and / or of the overall state profile / s P ', P "always provides a very clear overview of a current state of a simulated plant part or the entire plant. Thus, the location-dependent representation of the state profile / e P and / or the overall state profile P ', P "is a very good complement to the time-dependent trend curves mentioned in the prior art.

It is also possible for the state profile (s) P and / or the overall state profile (s) P ', P "in the coordinate system 1 . 2 statically labeled for different load points, so that on the basis of the determined state profile / e P and / or / the determined overall state profile / e P ', P''an instantaneous load can be estimated.

The described dynamic location-dependent state and / or overall state profiles P, P ', P ", for example with respect to the temperature of the media M1, M2 flowing in the plant part, allow a modeler to have a simulated power plant operation stability by simultaneously controlling a plurality of state variables to check with relatively little effort. Implausibilities and / or instabilities can be detected early during a runtime without much effort.

By static entry of different load points into the respective coordinate system 1 . 2 It is possible to gain an overview of the quality and / or accuracy of the simulation of a simulation model after approaching different load points. The state profile (s) P and / or overall state profile (s) P ', P "may be taken into account for decreases or may assist the modeler in fine-tuning a variety of parameters.

Claims (10)

Method for simulating a power plant operation of a power plant based on state variables, wherein one or more plant parts of the power plant in a number of segments (S1 to S4, S1 'to S18') are subdivided and in addition to metrologically detected state variables of at least one of the plant parts a variety of state variables determined by a simulator and determined segment by segment for the respective segment (S1 to S4, S1 'to S18'), characterized in that based on the determined values of one or more state variables for individual segments (S1 to S4, S1 'to S18') a profile of the state variable or a state profile along the segment (S1 to S4, S1 'to S18') is determined. A method according to claim 1, characterized in that the respective state variable is determined in dependence on at least one system parameter. A method according to claim 1 or 2, characterized in that the respective State variable is determined as a function of a material property of a medium flowing through the system component (M1, M2). Method according to one of claims 1 to 3, characterized in that the respective state variable is determined as a function of a material property of a wall of the plant part. Method according to one of claims 1 to 4, characterized in that as state variables at least one temperature and / or at least one pressure of at least one part of the plant, in particular a heat exchanger unit are determined. A method according to claim 5, characterized in that the state variables are determined as a function of characteristics of at least one arranged in the heat exchanger unit heating surface (H1 to H16) and / or arranged in the heat exchanger unit heat exchanger. Method according to one of claims 1 to 6, characterized in that based on the determined values of a plurality of state variables of a plurality of segments (S1 to S4, S1 'to S18') a plurality of state profiles are determined segment by segment and combined to form a dynamic overall state profile. Method according to one of claims 1 to 7, characterized in that the determined course of the state variable, the state profile and / or the overall state profile is graphically output or will. A method according to claim 8, characterized in that the determined course of the state variable, the state profile and / or the overall state profile graphically in a coordinate system ( 1 . 2 ) will be issued. A method according to claim 9, characterized in that the determined course of the state variable, the state profile and / or the overall state profile in the coordinate system ( 1 . 2 ) is output as a function of a location (s).

Images