DE19843492A1 - Planning, construction and maintenance method for technical plan esp. nuclear power plant - Google Patents

Abstract

A method of planning, constructing, and/or maintaining a technical plant or installation having a multitude of components, and in which for each component or piece of equipment, a first set (SP) of interface parameters (W,DN,B) is put in place. For a given type of plant (A) or installation, the components for drawing up a building plan (42) for the plant etc. are selected such that a first given component, and each additional component to be connected to this component, is determined on the basis of its first set (SP) and on the basis of the respective set (SP) of those components already formulated in the building plan (42). Circuit engineering criteria, such as material- and operating engineering- parameters, and/or geometric parameters are used for the first set (SP) of interfacing parameters (W,DN,B) for each component.

Description

The invention relates to a method for planning to Construction and / or maintenance of a technical system, especially a power plant.

Each power plant can be equipped with a corresponding system be described. It includes one after an ent speaking plant type built power plant a more number of related components.

Usually when planning a complex techni system, for example a power plant, the process-technical and function-specific requirements the planning of components. About who the com. to be used for a given system type components selected in a first step and then linked to a system layout plan. A well-known procedure consists in connecting at least circuitry two components according to the plant and process structure door.

On the basis of the plant layout plan, the circuit-related Ver bindings used to create a function plan. At The creation of the function plan is based on the scarf technical connections of the components a change effect between the components, the one Exchange of process signals between the components in ge appropriately describes. For example, for an An location section of the power plant to be provided that the interaction between a component "blower" and a component "chimney" via a ge from the fan to the chimney led gas flow is described. Suitable parameters for  Description of this gas flow can for example its temperature, its mass flow and a pressure drop. These interactions of the components become one another through appropriate function connections in the function diagram described, which further converted into an automation program be set.

With such a planning of the system structure and the radio tion plan is in the event of incorrect input of the circuit technology connection or if the function is entered incorrectly connection an inconsistency of interfaces or an error Educational automation program possible. This can be too faulty system construction or failure of the automation program. In addition, at In maintenance of the system, troubleshooting and elimination, especially in a particularly complex technical system with a large number of components, such as a power plant, particularly time-consuming and complex.

The invention is therefore based on the object, a Ver drive to planning, building and / or maintaining a technical system with a plurality of components ben, the system with very little effort their structure and function are particularly reliable can be built.

The object is achieved in that for each Component a first set of interface parameters is stored, whereby the com components for creating a system layout plan be chosen that a first component is given and each further components to be connected to this on the basis of their most sentence and the com component that is already installed in the system layout plan is averaged. The two components are by means of egg ner corresponding circuitry connection in the System layout diagram interconnected, the system  is built on the basis of the plant layout plan. Un ter circuit connection is here for example understood a pipe or a flange, whereby the individual components are interconnected.

The invention is based on the consideration that for egg a particularly reliable and consistent structure the technical system, in particular a power plant, incorrect or redundant entries of a component or Links between components should be avoided as far as possible should. To do this, each component should only be at the front Enter or initialize a system type.

For redundant entry or multiple entry of a compo Avoidance of the nente will advantageously be processed component with regard to its circuitry egg properties based on a set of interface parameters classified. Among components of a power plant who for example fittings, valves, transmitters, heat rope shearers, pumps etc. understood. Components are the same chen type, e.g. B. pumps from different manufacturers, by similar characterized interface parameters. In a ver circuit of this component of the type "pump" is therefore a Clear identification and / or selection of the pump possible Lich by making the selection taking into account this cha characterizing interface parameters, such as. B. one or more material parameters, one or more Dimensions.

The first set of interface parameters are useful some circuitry criteria that are used for specify the respective component, which material, operational and / or geometric parameters this Has component. For example, as material technology cal parameters of material parameters, as operational Parameters physical operating parameters, such as. B. Pressure or flow, and dimensions as geometric parameters or dimensions of the component. The respective he  is the highest set of interface parameters of the components for example a data record like a data sheet.

It is therefore possible for the creation of the plant construction plan light, based on a selected component based on it res first sentence another one available and with to connect the selected component in terms of circuitry to determine the end component. Agree two sets of one other components to be connected, so to link These two components do not require parameter input such. As a result, is up for a complete plant blueprint the specification of a first component with the associated The first sentence is required, with the compo nent additional compo nent / n based on the corresponding first sentence is or will be.

Advantageously, the plant layout plan is graphical represents and for example on a data display device give. The components and the circuit tech African connections shown in two or three dimensions become. This is particularly in a three-dimensional len representation of the system structure in the manner of a real application location reproduced virtually.

In an advantageous development there is a for each component second set of function parameters, whereby for the specified system type based on the system layout plan and based on the second sentence creates a function plan in this way is that starting from a first component every further with this component to be connected based on its second Sentence and based on the respective second sentence of the compo elements that are already implemented in the function diagram and a corresponding functional connection in the radio tion plan is implemented, the automation pro program to control and regulate the system based on the er function plan is generated.  

As a second set of functional parameters are more advantageous function-specific criteria, which are stored for the respective component control engineering, control engineering cal, safety-relevant and / or surveillance-specific Specify parameters. For example, a heat exchanger from flows through a primary medium, the heat of which the heat Transmit secondary medium also flowing through will. As function-specific criteria Heat exchanger that characterizes the inflowing media influences risky parameters. These parameters can, for example be wise: as a control and / or regulation technology Pa rameter - temperature, pressure and mass flow of the primary and of the secondary medium; as security relevant and / or over watch-specific parameters - limit values for temperature, Pressure and mass flow of the primary and secondary medium.

Based on the circuit connection of at least two components according to the system plan and based on the for these two components determined function-specific Criteria are the procedural interrelationship true, by means of simple logical and / or mathematical operations in automation functions for the user location is implemented. The automation radio implement functions as function connections in the function diagram animals. For example, a pre-affects the heat exchanger switched and in terms of circuitry in connection with this standing valve the mass flow of the primary medium of heat exchangers. This procedural interrelation between between the two components - heat exchanger and valve - is by means of the radio describing the two components tion-specific criteria in one or more functional connections implemented. Suitable functional connections for A description of this connection is, for example: IF the temperature of the secondary medium is too high, THEN open it Valve for a higher mass flow of the primary medium or IF the primary medium mass flow is too high, THEN close it  Valve. The function plan with the Functional connection created and output graphically.

The first and / or selected for the two components second sentences are expediently compared with one another and checked for plausibility. This is a possible one faulty circuit connection or a fault Adherent functional connection due to incorrect input si avoided. Alternatively or additionally, each can automatically determined connection between the components can be changed by an input, whereby this is also manual Every input is checked for plausibility.

The first and the second sentence are preferably on one data processing system in the form of one or more data tables implemented. The process is advantageously under Use of an electronic data processing system or a computer. The tables are then part of the Data processing system or part of a larger, for Data processing system associated magnetic, optical or electronic storage. The use of an electro African data processing system for carrying out the procedure rens offers the additional advantage that the process is wide automated and without switching on human ver standing activity can be carried out. This is special in the planning, construction and / or maintenance of very large and complex systems is an advantage because one manual implementation of the procedure by project planning or Service personnel can easily make mistakes.

Furthermore, by comparing the two Sets of two components automatically created, stale technical connections and / or functional connections manually changed using a data input device if necessary the. For this purpose, the respective connection is made by the operator nal z. B. on a visual display device. For example is a by a corresponding input on a component  "Pump" arranged and circuitry with this ver bound, also referred to as a component "Pressure gauge" with regard to the pressure range to be measured or the underlying measurement method or the manufacturer changeable. The either automatically selected or manually fixed connection of two components is then gra phisch with the corresponding circuitry connection applications and functional connections in the system layout plan or the function plan installed or implemented.

Furthermore, the method enables a particularly simple war plant and maintenance, especially the integration or replacement of individual components. One can additional component with the associated functions in one existing system layout plan and / or function plan be incorporated. For example, in an exchange of components as the first component the comm component selected and replaced by the new component. There at all with the component to be replaced in Ver related components with these characteristics parameters determined, the new component by Comparison with the components already determined and is involved.

An embodiment of the invention is based on a Drawing explained in more detail. In it show:

Fig. 1 shows a data processing system for a technical system, and

Fig. 2 schematically shows the process flow of a gena construction plan and / or a functional diagram of a technical plant generating process.

The same parts are in all figures with the same reference characters.

The data processing system 1 shown in FIG. 1 comprises a computer module 2 , to which an input / output unit 4 is connected. As an input / output unit 4 , a terminal with a screen 5 as output medium and a keyboard 6 and a mouse 7 are provided as input media in the exemplary embodiment. The computer module 2 is also connected to a first memory module 8 and to a second memory module 10 . The data processing system 1 is used for planning, building and / or maintaining a technical system comprising a number of components, not shown in more detail.

In the exemplary embodiment according to FIG. 2, a subsystem 20 of a power plant system is provided as the technical system. It can also be any other technical system. The components of the technical system are divided into component types. The components of a component type have comparable circuit-specific and function-specific criteria. For example, a power plant usually includes a large number of heat exchangers, pumps, fittings, etc. as components. In the construction of the system, for example, each heat exchanger is recognized as belonging to the "heat exchanger" component type and is accordingly integrated in terms of circuitry and function.

The circuitry criteria of each component are stored in the form of a first set SP of interface parameters in the first memory module 8 . In example, a heat exchanger is usually flowed through by a primary medium, the heat of which is transferred to a secondary medium also flowing through the heat exchanger. A heat exchanger has material-technical, operational-technical and / or geometric parameters as circuit-technical criteria. These parameters can be, for example:
Material technology: copper or steel, especially the material-technical execution of the connection elements, z. B. copper or steel flange, the components are described by means of the mate rial technical parameters of the heat exchanger,
operational: temperature, pressure and mass flow of the primary medium and the secondary medium, and
Geometric: dimensions of the heat exchanger and the connection element for connecting the circuitry connection.

The heat exchanger is therefore in accordance with the example mentioned completely characteristically in terms of circuitry terized.

The function-specific criteria of each component are stored in the form of a second set SF of function parameters in the second memory module 10 . Each component has z. B. control-related, control-related, safety-relevant and / or monitoring-specific parameters. For example, the following parameters are defined for the heat exchanger and a valve upstream of it:
control technology: valve "open", valve "closed",
control engineering: pressure or mass flow of the primary medium or the secondary medium "too high" or "too low",
safety-relevant: temperature, pressure, mass flow of the primary medium or the secondary medium "too high" or "too low", valve "NOT open", valve "NOT closed", and
Monitoring-specific: "Closed" valve, "Open" valve, measured value for temperature, pressure and mass flow of the primary medium or the secondary medium.

Both the heat exchanger and the valve are therefore in accordance the example given by the associated parameters fully characterized for specific functions.

The example shown in Fig. 2 of a highly simplified and schematic process flow for planning, building and / or maintaining a technical system begins in a first step S1 with an input or selection of a type A system to be created or already created technical system, e.g. B. a power plant of the type gas and steam turbine plant with an output of 450 MW.

Using the system type A entered, the components stored in the first memory module 8 and in the second memory module 10 with the associated first set SP of interface parameters and second set SF of function parameters are selected in a second step S2.

As components of the subsystem 20 of the given type A plant are a heat exchanger 22 , a control valve 24 , a flap 26 , a first pump 28 , a second pump 30 , a flue gas duct 32 , a chimney 34 , a water tank 36 and a feed water tank 38 and pipes 40 selected.

The first set SP of interface parameters and the second set SF of functional parameters for the heat exchanger 22 are described as examples. The first set SP includes as interface parameters a material-technical parameter W, a geometric parameter DN and operational-technical parameters B. The material-technical parameter W be, for example, describes the material of the connecting element of the heat exchanger 22 , for. B. steel or copper flange. The geometric parameter DN describes, for example, the dimensions of the heat exchanger 22 , in particular its height and width, and the diameter or the dimensions of the associated connecting element. The operational parameter B describes the permissible range of operating values, e.g. B. permissible temperature range, pressure range and Massenstrombe rich of the heat exchanger 22 flowing through the primary medium and the secondary medium.

The second set SF includes for the heat exchanger 22 as a function parameters function-specific criteria, for. B. a safety-relevant parameter S and a surveillance-specific parameter C. The safety-relevant parameter S describes z. B. Protection criteria for the heat exchanger 22 , for. B. "Temperature of the primary medium too high". The monitoring-specific parameter C describes the operating parameters to be monitored of the heat exchanger 22 , for. B. temperature, pressure and mass flow of the primary medium and the secondary medium. For the Stellven valve 24 upstream of the heat exchanger 22 , a control-technical parameter T and a control-technical parameter R are also provided as function-specific criteria. The control engineering parameter T describes z. B. the control for the Stellven valve 24 - "valve on", "valve off". The control parameter R describes the control function for the control valve 24 - "valve open", "valve close".

Starting from a component that e.g. B. by entering all components belonging to system type A selected each additional component is based on its first sentence SP and based on the respective first sentence SP of the component, which is already specified. These two components are then interconnected in terms of circuitry and implemented in a system layout plan.  

For example, starting from the structure characterizing the subsystem 20, the control valve 24 is specified in a third step S3 via an input E, the flue gas channel 32 , the identi cal interface parameter W, DN, being determined on the basis of the interface parameters W, DN, B that characterize this , B has. For this purpose, in a fourth step S4, the respective interface parameters W, DN, B are compared with one another and checked for plausibility. In the event that the interface parameters W, DN, B are identical, the control valve 24 and the flue gas channel 32 are connected to one another in a circuit-technical manner in a fifth step S5 and implemented in a system layout plan 42 .

The system layout 42 shows the structure for the subsystem 20 determined from the selected components. The Anla genaufbauplan 42 includes the circuit connections Ver components of the subsystem 20 , which are determined using the first set SP of interface parameters W, DN, B respectively. In terms of circuitry, the components mentioned for the subsystem 20 are connected to one another as follows: the flue gas duct 32 , which is followed by a chimney 34 , is preceded by the control valve 24 designed as a throttle valve. The control valve 24 is the heat exchanger 22 downstream for cooling the flue gas channel 32 by flowing flue gas. Immediately before the flue gas channel 32 opens into the chimney 34 , the second pump 30 is connected to increase the flow rate of the flue gas into the flue gas channel 32 . As further components of the subsystem 20 , the feed water tank 38 is connected upstream of the heat exchanger 22 and the water tank 36 is connected downstream. To promote the feed water of the feed water container 38 , the first pump 28 , which is designed as feed water, is connected into the access line 40 . In the outlet line 40 opening into the container 36 , the valve 26 designed as a shut-off valve is connected. The circuitry connections of the components and the components themselves are preferably implemented as two- or three-dimensional graphics elements in the system layout diagram 42 . The plant layout plan 42 is shown in graphic form on the screen 5 or another output medium, for. B. a printer, not shown, is output. In addition, the system layout plan 42 is stored in the form of a file on a memory block of the computer block 2 . Comprises according to the complexity of the power plant comprises a plurality of these Teilsy Stemen 20 which are shown as a function of the associated number of components by means of a system design plan 42 or more schematic diagrams 42nd

On the basis of the created system layout plan 42 for the subsystem 20 and on the basis of the respective second set SF of functional parameters T, R, S, C, corresponding functional connections 44 between the components are determined in a sixth step S6. The functional connections 44 describe ben, as shown in the seventh step S7, the circuit-related and process-related interactions between the components. For subsystem 20 , the components mentioned interact with one another as follows:
Starting from the control valve 24 , a flue gas stream flows into the flue gas channel 32 . This is characterized by a temperature T1 and a mass flow Q1 and a pressure P1. The pressure P1 is in turn determined by the position of the control valve 24 , which is indicated by the functional connection 44 . Starting from the flue gas duct 32 , an exhaust gas flow flows into the chimney 34 . This is defined by a mass current Q2. As a further variable, starting from the chimney 34 and the pump 30, a pressure P2 acts on the flue gas duct 32 , the effect being indicated by the functional connections 44 .

In the flue gas duct 32 , heat is transferred from the flue gas to a medium flowing in the heat exchanger 22 . This heat transfer is characterized by a corresponding amount of heat and temperature T2. Furthermore, the temperature T2 emanating from the heat exchanger 22 in turn influences the holding of the media in the flue gas duct 32 . The amount of heat is transferred to a medium supplied to the heat exchanger 22 . This is fed by the feed water tank 38 into the heat exchanger 22 by means of the pump 28 , the media flow being characterized by its temperature T3 and its mass flow Q3. The behavior of the feed water container 38 , in particular its fill level F1, in turn is influenced by the quantity conveyed - the mass flow Q3 - which is indicated by the associated functional connection 44 .

Starting from the heat exchanger 22 , preheated fluid flows to the water tank 36 . The associated media flow is characterized by a temperature T4 and a mass flow Q4. The fill level F2 of the water tank 36 is significantly determined by the supplied mass flow Q4.

On the basis of the circuit connections of the components according to the system plan 42 and on the basis of the functional parameters T, R, S, C, which characterize the components, the procedural interrelation between the components is determined. The functional relationship is described using the associated functional connection 44 . Each functional connection 44 is implemented by means of simple logical and / or mathematical operations in automation functions for the subsystem 20 . In an eighth step S8, the function connections 44 are implemented as automation functions 48 in a function plan 50 . The function plan 50 is preferably created graphically and on an output medium, e.g. B. on the screen unit 5 , output.

Analogously to the creation of the system layout plan 42 , a component can be specified when the function plan 50 is created, e.g. B. the control valve 24 . Each additional component, e.g. B. the flue gas duct 32 is determined on the basis of its second set SF of function parameters T, R, S, C. The associated second sets SF are compared with each other and checked for plausibility found for the components, where at further the two sets SF by any one of Funktionsver connection 44 appropriate automation function is created 48, z. B. "Valve" OPEN "AND pressure" TOO HIGH "in the flue gas channel 32 , THEN control valve 24 " CLOSE ". All other components of the subsystem 20 are implemented in an analogous manner in the function plan 50. In the manner of a linked planning, this is done circuitry structure of the subsystem 20 of the components connected in series followed.

Both for the system layout plan 42 and for the function plan 50 , the circuitry connection and / or the function connection 44 can be changed via a parameter input. Existing system layout plans 42 as well as existing function plans 50 can thus be renewed with regard to components or functions to be newly integrated. The method is therefore suitable both for planning, for construction and for maintenance of a technical system, in which, for example, components that can be clearly, quickly and reliably exchanged during the operation of the system can be replaced by a component selected by means of the method described. The automatic selection of the new component avoids inconsistencies that may result from incorrect parameter input.

Claims (7)

1. Method for planning, building and / or maintaining a technical system with a plurality of components, in which a first set (SP) of interface parameters (W, DN, B) is stored for each component, in which for a predetermined plant type (A) the components for the creation of a plant layout plan ( 42 ) selected who the that a first component is given and each further component to be connected to this on the basis of its first sentence (SP) and on the basis of the respective first sentence (SP ) of the component that is already installed in the system layout plan ( 42 ). 2. The method according to claim 1, in which the first sentence (SP) of interface parameters (W, DN, B) circuitry Criteria for each component, e.g. B. material technology, be technical and / or geometric parameters are. 3. The method according to claim 1 or 2, in which the Anlagenauf construction plan ( 42 ) is graphically created and output. 4. The method according to claim 1, in which a second set (SF) of functional parameters (T, R, S, C) is stored for each component, for the given system type (A) using the system layout plan ( 42 ) and on the basis of the second sentence (SF), a function plan ( 50 ) is drawn up in such a way that, starting from a first component, each component to be connected to it is based on its second sentence (SF) and on the respective second sentence (SF) of the component which is be already implemented in the function diagram (50) is determined and a corresponding function compound (44) is implemented in the functional plane (50), wherein the Automatisierungspro program for controlling and regulating the basis of the created radio option plan (50) is generated. 5. The method according to claim 4, wherein the second sentence (SF) of function parameters (T, R, S, C) function-specific Criteria for each component, e.g. B. control technology, right technical, safety-relevant and / or supra specific parameters are stored. 6. The method according to claim 4 or 5, wherein the function plan ( 50 ) is graphically created and output. 7. The method according to any one of claims 1 to 6, in which for two selected components the first and / or second Sentences (SP, SF) compared with each other and on plausibility being checked.