DE4209169C2 - Working method for processing parameters of an automation device for an industrial plant - Google Patents

Description

Cars are increasingly being used to manage switchgear automation systems, in particular control equipment gene, used. For the functioning of these facilities plant-specific data of the switchgear specified and in the control system can be introduced. The pretending and on Bringing the data is called parameterizing.

The Siemens publication A19100-E765 / B356 refers to the Pages 22 and 23 a device arrangement shown, the Para metering of a switchgear control system. In the Parameterization of the switchgear control system is ver drive that the data required for parameterization and information using the parameterization device in so-called Configuration lists can be entered. The project The structure of the lists of lists is based on the circuit plant control system (device or hardware-oriented). At Changes to the switchgear control system can lead to changes in the Program of the parameterization system may be required. A The data can only be checked based on plausibility. Other such configuration tools for automation devices of a general type are from electronics, 22/4, Nov. 1983, Special section, pages 103 to 110 known.

From DE-A1 29 36 914 is a sequence control system be knows the standard programs for specific tasks can be used within the control system. As from Art and manner of the addresses and data values used there obviously, the system is orien to the hardware of the system animals. Hardware changes may have changes standard programs.

The invention has for its object a work process for processing plant-related parameters of a Automation unit ready, in which a club easy specification of the system information and an easy one Changeability with regard to adaptation to a new goal system is given.

The object is achieved with the features of claim 1.

In this way, the parameters are ge-neutral leads and processes. A reference to the technology of the Target system - namely the automation device - like it was not previously required for telecontrol systems more needed. If the target system changes, the ge All procedures are maintained. If necessary only target system information changed or special Sub-procedures or sub-steps added or changed. The Ease of reticulation permeates all partial processes of the part systems of the target system alike, since of an object oriented programming (OOP) is used. There is an object-oriented data management or model ling (OODM) possible.

Preferred configurations are in the further claims specified.

With an interactive communication interface, e.g. B. a human-machine interface, system information stations from which a model is derived. The Model stands for various purposes, e.g. B. for simulation ready. All information of the model is saved can be saved and used for generation on other systems be transmitted.

The interactivity of the method allows the person skilled in the art a review of the Work result in a direct way. Additional generators  runs or data transfers are eliminated. He immediately gets and the work result without detours. This even goes so far that After a data change, a simulation run of the Model is possible.

The invention and advantageous embodiments are based on explained below using the drawing as an example. It shows gene:

Fig. 1 shows a schematic structure of a configuration system for an automation system and

Fig. 2 shows a basic hardware configuration.

The configuration system 1 shown in Fig. 1 is used for encryption work of plant-related parameters of an optimization unit automation. Automation system is understood here in particular to mean a control system for a switchgear system, hereinafter referred to as LSA for short.

Processing plant-related parameters understood here all the procedures related to the Planning and the creation of the LSA are related. This includes, for example, the configuration, the Para metration, the creation of documentation Parameterization of the telecontrol interface and generation of operating data for the LSA.

The basis for the method to be carried out with the configuration system 1 is a basic program 3 , to which a so-called construction box 5 with program modules 7 is assigned. The pro gram blocks 7 each coding for interconnecting definable program blocks 7. Each program module 7 has a general functionality, which can also be referred to as the largest common sub-step of all methods to be carried out. By interconnecting program modules 7 , functions or steps of sub-processes are generated. Examples of this are: memory function, screen output, printer output, etc. . If a function or a step is contained in several sub-processes, this step is also used in different processes.

The modular system 5 is based on object-oriented data modeling (OODM). Each program block 7 is checked for itself. Part processes composed of programming modules 7 therefore no longer need to be subsequently checked in complex tests.

The program modules 7 are accessible from different access levels A, B, C. The access levels A, B, C have a hierarchical structure, with only predeterminable methods, sub-methods or information being retrievable from a respective access level.

At least one program module 7 of the modular system 5 is designed as an access module. With this access building stone, entry into the modular system 5 is made possible, so that program modules 7 can be switched together to form modules 9 , 11 , 13 . Each access level A, B, C is preferably assigned at least one access module.

At least one base module 9 is arranged in the first access level A, which is based on the modular system 5 . This basic module 9 essentially serves for the specification of LSA-specific knowledge that is required for the creation of a model of the LSA. For this, e.g. B. selectable resources and resource information of the LSA and / or the system. In addition, the base module 9 is also used to create access and input modules 11 , 13 which use the predetermined LSA knowledge of the base module 9 .

The basic module 9 represents a sub-method of the projecting system 1 , which itself also consists of program modules 7 . This in turn is used to generate further modules consisting of program modules 7 (recursivity). There are interactive interactions between the respective modules of each access level. This applies in particular to their human-machine interface, so that a testable result is available immediately after entering information.

An access module 13 is seen in the second access level B. This is used to generate, in particular to duplicate, information contents that can be stored with different base modules 9 , 9 a, 9 b. In this way, application-related knowledge can be brought in. An application for this is, for example, country-specific knowledge, e.g. B. Language. By duplicating the corresponding information content and changing it using the access module 13 , the language used by the user interface of a module can be changed in a simple manner. As a result, a selection of specifications for the input module 11 can be generated.

Of course, several base modules 9 , 9 a to 9 n can be generated, each for special parts of the LSA, z. B. families of devices, in particular protection or control, or for different LSAs.

With the creation of access and input modules 13 and 11 , the user interface of the respective modules is also created application-specifically. This can be checked interactively as soon as it is created. A first function block 15 in the base modules 9 to 9 n serves this purpose.

Furthermore, a generator 16 is provided, which is required for generating a data set for the operation of the LSA. This data record is generated from the specified and processed plant information. For further processing of the data record, an interface (not shown in detail) is provided for transfer to the LSA as the target system or to a further processing system. This can e.g. B. be a DV system. Alternatively, a removable memory can be used to transfer the data record.

The access to the generator 16 can have different functions depending on the authorization for the respective access levels. Alternatively, a generator 16 can also be assigned to the base modules 9 to 9 n.

The modules 9 , 11 , 13 of each access level A, B, C are accessible to a special group of users with the appropriate authorization. Access levels A and B are preferably accessible to the manufacturer of the LSA. Additional grip levels can be provided.

The input module 11 lies in the access level C, which for the end user, for. B. is accessible to the engineering engineer or for the customer. The modules 9 , 11 , 13 can be operated via a human-machine interface, in particular via a data display device with a keyboard.

On the basis of this configuration of the configuration system 1 , when processing parameters of the LSA, the procedure is such that system information is initially given by means of the input module 11 . This is done in a parameterization device. The resulting parameters are stored object-oriented in memories. A model of the LSA is automatically created from the system information. The system information is specified in relation to the system. All target device-specific data and information is namely within the project planning system 1 oriented towards objects or systems, i.e. related to the industrial or switchgear.

For example, technical documents, current flow plans, screen layouts, interface assignments, in short everything that arises in the context of project planning, getting produced. Corresponding documents are also included appropriate information about the LSA, e.g. B. device types, prices, Sizes and technical data.

Based on the model of the automation device created in this way, further steps for processing the model data can then be initiated. The following example shows this: In a sub-process of project processing, the plant images that will later appear on a data display device from the LSA are created. The structure of these pictures is supported by a pool with standard circuits for systems in various voltage levels as well as with typical equipment of branches, couplings, feeds, etc. The access module 11 has access to this pool. In a further step, more detailed processing information is defined for each field. The hardware required to implement the LSA, including the assignment of its inputs and outputs, is automatically determined from the scope of the inputs by the target system-specific knowledge.

If, for example, the project planning is still in the initial stage, offer documents and figurative images can be output based on these entries. If the configuration is already in the implementation stage, further steps can be carried out that specify the more precise functions of the individual devices. Thanks to modern window technology, the system is clear and easy to use. With the project planning system 1 , the user is able to carry out project planning independently without special knowledge.

Once the configuration is complete, you can either use a data connection or the project via a data carrier  tion data are transferred to the hardware provided. The parameters to be transmitted include, for example, In information about the system configuration, processing information Information about messages and commands, telegram assignments for control center connections and setting data for protection councils.

Essential for the present method with the associated one System is the continuity in all process phases. The particularly concerns object-oriented data storage in Connection with universally usable program modules, that allows hierarchical inheritance of properties. This data structuring of the method enables easy expandability and flexibility.

Fig. 2 shows a basic arrangement for this purpose. The actual project planning workstation comprises a computer 17 , a screen with a keyboard 18 and possibly a printer 19th The computer 17 and the screen with the keyboard 18 serve as a parameterization device. The computer 17 comprises generally customary memories.

An LSA 20 is shown here as the target system. This also comprises a screen with a keyboard 21 , a central device 22 and input / output devices 23 connected to it . The connecting lines are provided as serial data lines. The input / output devices 23 can be assigned in a switchgear unit or in a field-related manner. In the present example, the input / output device 20 is assigned to a high-voltage branch 24 of a switchgear. The central device 22 has an interface 25 for data exchange with a network control center. This can be used, for example, for control, reporting or remote parameterization.

To transfer parameters, the computer 17 is connected to the central device 22 via a data line 26 . The computer can also have a further interface 27 for data exchange with other systems.

Claims (5)

1. Working method for a parameterization device for the automatic creation and processing of parameters of an automation device ( 20 ) to be configured for an industrial plant, in particular parameters of a control device of a switchgear, wherein

• - parameters for the automation device ( 20 ) are automatically created with plant or object-oriented plant information in a computer ( 17 ) of the parameterization device,
• - the parameters are saved system- or object-oriented,
• - A model of the automation device ( 29 ) is automatically created and stored on the basis of stored and retrievable automation device-specific information from the system information, and
• - Then information on the projected automation device ( 29 ) are output.

2. Working method according to claim 1, wherein an interactive interface is used for specifying the system information ( 20 ). 3. Working method according to claim 1 or 2, wherein functions of the automation device ( 20 ) are simulated with the model. 4. Working method according to one of claims 1 to 3, wherein the parameters, the system information or model data are generated in data records and transmitted to the automation device ( 20 ). 5. Working method according to one of claims 1 to 4, wherein system-oriented standard information storage and are available.